阅读说明：本技术 烹饪设备 (Cooking apparatus ) 是由 郭东星 尹动赫 金学秀 尹星文 于 2020-01-10 设计创作，主要内容包括：本发明公开一种烹饪设备。所述烹饪设备,包括：壳体,在内部形成有由底面、两个侧面以及背面围成的烹饪室,所述壳体的顶面和正面开放；门,包括覆盖所述壳体的顶面的门顶面部和连接于所述门顶面部的前侧并覆盖所述壳体的正面的门正面部,所述门以所述门顶面部的后方侧为中心转动以开闭所述壳体的顶面和正面；第一加热部,配置于所述门；以及门框,支撑所述第一加热部,并且结合于所述门。本发明能够将加热器设置于门。(The invention discloses a cooking device. The cooking apparatus includes: a housing in which a cooking chamber surrounded by a bottom surface, two side surfaces, and a back surface is formed, the top surface and the front surface of the housing being open; a door including a door top surface portion covering a top surface of the case and a door front surface portion connected to a front side of the door top surface portion and covering a front surface of the case, the door being rotated centering on a rear side of the door top surface portion to open and close the top surface and the front surface of the case; a first heating unit disposed on the door; and a door frame supporting the first heating part and coupled to the door. The invention can arrange the heater on the door.)

1. A cooking apparatus, characterized by comprising:

a housing in which a cooking chamber surrounded by a bottom surface, two side surfaces, and a back surface is formed, the top surface and the front surface of the housing being open;

a door including a door top surface portion covering a top surface of the case and a door front surface portion connected to a front side of the door top surface portion and covering a front surface of the case, the door being rotated centering on a rear side of the door top surface portion to open and close the top surface and the front surface of the case;

a first heating unit disposed on the door; and

a door frame supporting the first heating part and coupled to the door.

2. The cooking apparatus of claim 1,

the door frame is combined with the door top surface part.

3. Cooking apparatus according to claim 1 or 2,

the first heating part includes:

a heating element;

a first connection end disposed at one end portion in a length direction of the heating element;

and a second connection end disposed at the other end in the longitudinal direction of the heating element.

4. Cooking apparatus according to claim 3,

the door frame includes:

a heater mounting portion to which the first heating portion is coupled; and

and a combining part combined with the door top surface part and supporting the heater mounting part on the door top surface part.

5. Cooking apparatus according to claim 4,

the heater mounting part includes:

a first connection end fixing part for fixing the first connection end;

a second connection end fixing portion for fixing the second connection end,

either one of the first connection end fixing part and the second connection end fixing part includes:

a cover surrounding the first connection end or the second connection end from the outside in the circumferential direction;

and the first connecting end or the second connecting end is clamped and combined with the supporting wall.

6. Cooking apparatus according to claim 5,

the heating element is formed in a rod shape having a predetermined length,

at least one of the first connection end and the second connection end includes:

a cylindrical portion having a cylindrical shape, provided at each of both end portions in a longitudinal direction of the heating element;

a key-shaped portion disposed between the heating element and the cylindrical portion, the key-shaped portion being formed in a flat hexahedral shape having a thickness smaller than a diameter of the cylindrical portion and a width larger than the diameter of the cylindrical portion,

the support wall is formed with:

a coupling hole formed through the support wall in a shape corresponding to the shape of the outer peripheral surface of the cylindrical portion;

and a through hole formed through the support wall and forming a passage connecting an outside of the support wall and the coupling hole.

7. Cooking apparatus according to claim 6,

the width is greater than the thickness of the key shape part and smaller than the width of the pupil,

either one of the first connection end and the second connection end is inserted into the inside of the coupling hole through the through hole in a state where the first heating part is in the first posture,

the first posture is a posture in which a surface parallel to the thickness direction of the key shape portion is parallel to the width direction of the through hole (d).

8. Cooking apparatus according to claim 7,

further comprising an extension portion formed by extending from the cylindrical portion to the key shape portion side,

the extending portion is formed to protrude outward from a face parallel to the width direction of the key shape portion to form a step between the extending portion and the face parallel to the width direction of the key shape portion.

9. Cooking apparatus according to claim 8,

a distance L between the support wall of the first connection end fixing portion and the support wall of the second connection end fixing portion₁The following relationship is satisfied:

L_H＝L_H1+2L_H2+2L_H3

L₁＝L_H－L_H2－L_H3

wherein, L_HIs the total length of the first heating section, L_H1Is the length of the heating element, L_H2Is a distance between one side end portion of the heating body and the step, L_H3Is the distance between the step and the outermost end of the cylindrical portion.

10. The cooking apparatus of claim 9,

a distance L between the support wall of the first connection end fixing portion and the support wall of the second connection end fixing portion₁The following relationship is satisfied:

L₁＝L_H1+2L_H4

wherein, L_H4Is the length of the key shape portion.

Technical Field

The present invention relates to a cooking apparatus.

Background

A cooking apparatus is an apparatus that is provided in a kitchen space as one of home appliances for cooking food and cooks the food according to a user's intention. Such cooking apparatuses may be classified into various types according to the type of heat source or form used and the type of fuel.

If the cooking apparatuses are classified according to the forms of cooking foods, the cooking apparatuses may be classified into open type and closed type cooking apparatuses according to the space where the foods are placed. Examples of the closed cooking apparatus include an oven, an induction microwave oven, and the like, and examples of the open cooking apparatus include a cooktop, and the like.

The closed cooking apparatus is a cooking apparatus that shields a space where food is located and heats the shielded space to cook the food. In the closed cooking apparatus, a cooking chamber is provided, which is a space that is shielded when food is placed and cooked. Such a cooking chamber actually forms a space for cooking food.

The closed cooking apparatus may be classified into a gas oven and an electric oven according to the type of heat source. Unlike a gas oven, in which a plurality of heaters are operated using electricity as a heat source and food is cooked using heat emitted from the heaters, a gas oven uses gas as fuel and supplies gas to a burner to ignite the gas, thereby generating flames by burning the supplied gas and cooking the food using the generated flames.

Among them, the use rate is tending to increase because electric ovens have faster cooking speeds, higher thermal efficiencies, and better stability than gas ovens. Further, an electric oven is more easily miniaturized than a gas oven, and therefore, a mini-oven type electric oven (hereinafter, referred to as a "mini-oven") having a small size is also released on the market.

The mini oven is not suitable for cooking large food due to its small size, but is suitable for baking or heating a small amount of food when a burden is large for using a large capacity oven.

In particular, the mini-oven is advantageous in that it can be conveniently used for toasting toast, and also for cooking small-sized foods other than toast, and thus the trend of using cooking devices instead of the existing toaster is gradually increasing.

Generally, a mini oven includes a housing for accommodating all components, a plurality of shelves for placing food while cooking, and a cooking chamber having an open front and capable of cooking by placing food therein.

In addition, the mini oven includes an oven heater for heating food to an appropriate temperature and a door for opening and closing the cooking chamber.

The oven heater may be disposed at a lower portion of the shelf, or may be disposed at a top portion of the cooking chamber. The oven heater disposed at the lower portion of the shelf is mainly used to heat the shelf, and the oven heater disposed at the top of the cooking chamber may be used to directly heat food placed on the shelf.

The door is provided to partition the inside of the cooking chamber from the outside to form a closed space when food is placed in the cooking chamber and cooked. The door may further include a handle capable of easily opening and closing the door and a glass window for enabling observation of the inside of the cooking chamber without opening the door.

In the mini-oven, the door is mostly provided to be opened at a lower portion. That is, in the door applied to the mini oven, a lower end portion is rotatably coupled to a housing through a door hinge, and a cooking chamber is opened by rotating the door downward with a lower end portion of the door rotatably coupled to the housing as a center, and is closed by rotating the door upward in a state where the cooking chamber is opened.

The door opens the cooking chamber by rotating an angle of about 90 degrees in a state where the cooking chamber is closed, and insertion and extraction of the shelf can be performed in such a state where the cooking chamber is opened by the door.

That is, the door is opened in a state of being substantially parallel to the shelf inserted into the inside of the mini oven, and the insertion and extraction of the shelf is directly performed by the user.

However, the mini oven of the above structure has the following disadvantages.

First, when the door is opened, the door protrudes to the front of the mini oven only by the height of the door, and thus, when the mini oven is installed in a narrow space, it is difficult to accurately perform the opening operation of the door and the insertion and removal operation of the shelf.

Second, when the door is opened, a problem occurs in that the center of gravity of the mini oven is tilted forward as the door protrudes forward of the mini oven by the height of the door.

As a mini oven that is small or light in weight, due to its characteristics, when the door is opened forward, the center of gravity of the mini oven may be tilted forward, and in this case, the possibility of the mini oven tipping forward may be increased.

In particular, when taking out the shelf, in order to check the cooking state, or in order to temporarily place the shelf, it is often the case that the shelf is placed on the top of the door, and therefore, as described above, in the structure in which the center of gravity of the mini oven is inclined forward, the risk of the mini oven falling over will inevitably increase.

Furthermore, this risk is greater when the weight of the shelf or the food placed on the shelf is heavy. Thus, not only is such a risk increased when cooking heavier foods, but there is also a burden that requires an increase in the weight of the shelf. That is, even if it is necessary to use a thick and heavy shelf for improving cooking performance, it is difficult to use such a shelf due to the risk of the mini-oven falling over.

Third, a passage for inserting and taking out the shelf and a passage for confirming the cooking state are limited to the front of the mini oven, and thus various limitations occur.

That is, the direction of inserting and taking out the shelf is limited only to the front and rear direction, so that it is inconvenient to insert and take out the shelf when the mini oven is installed at a lower position. In addition, the passage for confirming the cooking state is limited to only the glass window provided on the door, and thus it is very inconvenient for confirming the cooking state when the mini oven is provided at a lower position.

In general, in order to accurately confirm the cooking state of the entire food, it is not enough to open the door, and the tray must be removed.

In other words, when the user wants to accurately confirm the cooking state of the whole food, the user must directly take out the shelf after directly opening the door and then insert the shelf, but when the mini-oven is installed at a lower position, the above operation is very inconvenient, and the possibility of the user being injured (such as scalding, etc.) during the process that the user directly takes out and inserts the shelf increases.

In view of the above, a structure capable of opening the doors at the front and the top of the cooking chamber at the same time may be considered. Such a door can be provided in such a manner that a front surface portion disposed in front of the cooking chamber and a top surface portion disposed on the top of the cooking chamber are integrally provided.

The door having such a structure can open the cooking chamber by rotating around the rear side thereof, and not only the front side of the cooking chamber but also the top side of the cooking chamber can be opened by the rotation of the door.

Therefore, the direction of inserting and taking out the shelf may be extended to the top in addition to the front and rear direction, and since the door does not protrude to the front of the mini oven when the door is opened, the possibility that the center of gravity of the mini oven is inclined to the front is reduced. In addition, since the tunnel confirming the cooking state when the door is opened is extended to the top of the cooking chamber in addition to the front of the cooking chamber, the cooking state can be confirmed more easily.

However, in the door-to-mini oven using the structure as described above, in order to dispose the oven heater on the top of the cooking chamber, the oven heater must be disposed on the door. However, in order to dispose the oven heater on the door, a structure for coupling the oven heater to the door must be disposed on the door, and a configuration of various electrical connections required for supplying power to the oven heater and transmitting a control signal to the oven heater must be disposed on the door.

Disclosure of Invention

An object of the present invention is to provide a cooking apparatus having an improved structure, which is capable of providing a heater to a door.

In addition, an object of the present invention is to provide a cooking apparatus having an improved structure, which can stably set various components to be disposed on a door on the door.

In addition, another object of the present invention is to provide a cooking apparatus having an improved structure, which can easily and quickly set various structures to be disposed on a door on the door and can easily separate the various structures for maintenance.

In a cooking apparatus according to an embodiment of the present invention to achieve the above object, a door frame is included, which supports a first heating part and is coupled to a door so that the first heating part can be disposed in the door.

The door frame may include: a heater mounting part coupled to the first heating part; and a combining part combined with the door top surface part to support the heater mounting part on the door top surface part.

With this configuration, the first heating part can be stably provided into the door, and the setting work of the first heating part can be efficiently performed.

In addition, a shielding plate may be provided in the door frame, and the emitter may be combined with the shielding plate.

In addition, a grill fixing portion may be provided in the door frame, and the protection grill may be fixed to the grill fixing portion.

In addition, a seating surface on which the glass is seated may be formed in the door frame.

In addition, a restricting rib and a stopper may be provided in the door frame to restrict movement of the glass seated on the seating surface.

With this configuration, it is possible to provide, in addition to the first heating part, the respective structures in the door frame for fixing the members such as the glass, the radiator, the protective grill and the like to the door frame, and with this door frame, it is possible to provide a frame capable of assembling the members such as the first heating part, the glass, the radiator, the protective grill and the like into one single body.

A cooking apparatus according to an aspect of the present invention includes: a housing in which a cooking chamber surrounded by a bottom surface, two side surfaces, and a back surface is formed, and the top surface and the front surface are open; a door including a door top surface portion covering a top surface of the housing and a door front surface portion connected to a front side of the door top surface portion and covering a front surface of the housing, the door being rotated centering on a rear side of the door top surface portion to open and close the top surface and the front surface of the housing; a first heating part disposed in the door; and a door frame supporting the first heating part and coupled to the door.

The door frame is coupled to the door so as to cover a lower portion of the door top surface portion, and the first heating portion is preferably provided in the door frame so as to be disposed at the lower portion of the door top surface portion.

In addition, the door frame preferably includes: a heater mounting part coupled to the first heating part; and a combining part combined with the door top surface part to support the heater mounting part on the door top surface part.

In addition, the first heating part includes an electric heater having: a heating element; a first connection end disposed at one end portion in a length direction of the heating element; and a second connection end disposed at the other end portion in the longitudinal direction of the heating element, and the heater mounting portion preferably includes a first connection end fixing portion for fixing the first connection end and a second connection end fixing portion for fixing the second connection end.

In addition, at least one of the first connection end fixing part and the second connection end fixing part preferably includes: a cover surrounding an outer periphery of the connection end from a circumferential direction outer side; and a support wall dividing a space surrounded by the hood portion into an inner space and an outer space in a longitudinal direction along the longitudinal direction of the first heating part, and the connection end is clip-coupled into the support wall.

Further, it is preferable that the heat generating body is formed in a rod shape having a predetermined length, and at least one of the first connection end and the second connection end includes: cylindrical portions arranged at both end portions in the longitudinal direction of the heating element; and a key-shaped portion disposed between the heating element and the cylindrical portion, and formed in a flat hexahedral shape having a thickness smaller than the diameter of the cylindrical portion and a width longer than the diameter of the cylindrical portion, the support wall having a coupling hole formed therein and penetrating the support wall in a shape corresponding to the outer peripheral surface shape of the cylindrical portion; and a through hole formed through the support wall and forming a passage connecting an outside of the support wall and the coupling hole to each other.

In addition, the through hole is preferably formed to have a width corresponding to the thickness of the key shape portion.

In addition, any one of the first connection end and the second connection end is inserted into the coupling hole through the through hole in a state where the first heating section is in a first posture, and the first posture is preferably a posture in which a plane parallel to a thickness direction of the key shape section is arranged parallel to a width direction of the through hole.

In addition, it is preferable to further include an extended portion formed by extending the cylindrical portion to the key shape portion side, the extended portion being formed to protrude outward on a surface parallel to a width direction of the key shape portion to form a step between the extended portion and the surface parallel to the width direction of the key shape portion.

In addition, a distance L between the support wall of the first connection end fixing portion and the support wall of the second connection end fixing portion₁Preferably L_H＝L_H1+2L_H2+2L_H3，L₁＝L_H－L_H2－L_H3Condition (Note: L)_HIs the total length of the first heating section, L_H1Length of heat-generating body, L_H2Distance between one side end of the heating element and the step, L_H3Is the distance between the step and the outermost end of the cylindrical portion).

In addition, a distance L between the support wall of the first connection end fixing portion and the support wall of the second connection end fixing portion₁Preferably L₁＝L_H1+2L_H4Condition (need forIllustratively, L_H4Is the length of the key shape portion).

Preferably, the heat generating element further comprises an outer wall disposed outside the support wall in the longitudinal direction of the heat generating element, and a distance L between the support wall and the outer wall₂Satisfy L₂≥L_H3And (4) conditions.

Further, it is preferable that at least a part of the cylindrical portion is inserted into a space surrounded by the cover, the support wall, and the outer wall, the outer wall is connected to the joint portion, and a connection portion of the outer wall and the joint portion is preferably formed with a groove portion recessed more than a top surface of the joint portion.

Further, it is preferable that a through hole is formed at an inner side of the combining portion in a plane direction, a glass covering the through hole is disposed at a top of the heater mounting portion, a seating surface is formed at an inner side surface of the combining portion adjacent to the through hole, the glass is seated on the seating surface, and the groove portion forms a surface recessed more downward than the seating surface.

In addition, it is preferable that a shielding plate is further provided, which is disposed on a side farther from a central portion of the cooking chamber in a front-rear direction than the first heating part, and connects the first connection end fixing part and the second connection end fixing part to each other.

Preferably, the heating apparatus further includes a protective grill disposed to be spaced apart from the shielding plate with the first heating unit interposed therebetween.

Further, preferably, the protection grid includes: a plurality of wires extending in a longitudinal direction of the first heating section; and a plurality of fixing members extending in an arrangement direction of the plurality of wires to fix the plurality of wires, the plurality of wires being arranged to surround a circumference of the first heating part on an outer side in a circumferential direction.

In addition, it is preferable that at least one of the first connection end fixing part and the second connection end fixing part further includes a grill fixing part fixing the steel wire to the heater installation part, the grill fixing part including a plurality of fixing ribs formed to protrude from the cover toward the first heating part, the plurality of steel wires being respectively clip-coupled to fixing grooves formed between the plurality of fixing ribs.

Preferably, a through hole is formed inside the coupling portion in a planar direction, and a glass covering the through hole is disposed on a top portion of the heater mounting portion.

In addition, preferably, the method further comprises: a shielding plate disposed on a side farther from a central portion of the cooking chamber in a front-rear direction than the first heating part and connecting the first connection end fixing part and the second connection end fixing part to each other; and an emitter which is horizontally arranged between the first heating part and the shielding plate and horizontally arranged between the first heating part and the glass to reflect the heat of the first heating part.

Further, it is preferable that an inner side surface of the coupling portion adjacent to the through hole is formed with a seating surface on which the glass is seated, the seating surface being disposed on both left and right sides of the through hole, the coupling portion being provided with a restricting rib disposed on one side in a front-rear direction of the through hole to restrict movement of the glass in one side and upward in the front-rear direction, and a stopper disposed on the other side in the front-rear direction of the through hole to restrict movement of the glass in the other side in the front-rear direction.

The cooking apparatus of the present invention provides a structure in which a first heating part can be easily and quickly installed in a door frame, and the door frame can be easily and quickly installed in a door, thereby having an effect of stably installing the first heating part in the door and effectively performing an installation work of the first heating part.

Further, according to the present invention, a structure for fixing members such as glass, a radiator, a protective grill and the like to a door frame can be provided in addition to the first heating part, and with this door frame, it is possible to provide a frame capable of assembling the members such as the first heating part, glass, radiator, protective grill and the like into one unit, and therefore, there is an effect that various members to be arranged in the door can be easily, quickly and stably provided in the door.

In addition, according to the present invention, the door frame is combined with the door top surface part to protect each component provided inside the door and is provided to be easily separated when necessary, and thus, there is an effect of stably protecting the components inside and also an effect of enabling maintenance work of the cooking appliance to be easily and rapidly performed.

In addition, the present invention provides an extended passage so that a user can easily and conveniently insert or remove food or a tray into or from a cooking chamber, while also providing a function of automatically removing or inserting the tray when the door is opened or closed, thereby more easily and conveniently removing and inserting the food or the tray.

In addition, the present invention is configured to rotate the door upward to open the front and top surfaces of the cooking chamber without unfolding the door forward, and thus, the door can be easily and smoothly opened even in a narrow space, and food or trays can be more easily and conveniently taken out.

In addition, the present invention can open the front and top surfaces of the door through the door, thereby exposing more trays due to the opening of the door, so that the cooking food can be easily put in or taken out even though only a portion of the tray is pulled out, thereby improving convenience and safety.

In addition, according to the present invention, it is provided to open and close the door by rotating upward without unfolding the door forward, so that even when the door is opened, there is less possibility that the center of gravity of the cooking appliance is biased forward, thereby having an effect of greatly reducing the risk of the cooking appliance tipping over.

In addition, according to the present invention, the center of rotation of the door is formed at the rear side of the cooking appliance, the center of gravity of the door is formed to be more biased to the door top surface portion than the door front surface portion, and the center of gravity of the cooking appliance is formed to be biased to the rear side of the cooking appliance when the door is opened, and therefore, the risk of the cooking appliance falling over is greatly reduced, and thus there is an advantage in that the safety and the convenience of use of the cooking appliance are improved.

In addition, the present invention provides a cooking apparatus having a stable structure, which greatly reduces the risk of falling over, thereby having an advantage that a tray increased in thickness and weight for improving cooking performance can be freely adopted, or a tray that can be used in an environment heated by an induction heating part can be freely adopted.

Drawings

Fig. 1 is a perspective view illustrating a cooking apparatus according to an embodiment of the present invention.

Fig. 2 is a perspective view illustrating a door-opened state of the cooking apparatus shown in fig. 1.

Fig. 3 is an exploded perspective view illustrating an exploded state of the cooking apparatus shown in fig. 1.

Fig. 4 is a perspective view illustrating the housing and the hinge assembly shown in fig. 1 separately.

Fig. 5 is a perspective view showing a door according to an embodiment of the present invention separated.

Fig. 6 is a bottom perspective view showing the bottom surface side of the door shown in fig. 5.

Fig. 7 is an exploded perspective view showing the door shown in fig. 6 in an exploded configuration.

Fig. 8 is a sectional view taken along line viii-viii of fig. 7.

Fig. 9 is a sectional view taken along line ix-ix of fig. 6.

Fig. 10 is a sectional view schematically showing the flow of air inside a door according to an embodiment of the present invention.

Fig. 11 is a perspective view illustrating a tray according to an embodiment of the present invention.

Fig. 12 is a sectional view schematically showing a coupling structure between the tray and the seating protrusion shown in fig. 11.

Fig. 13 is a sectional view schematically showing another example of the structure between the tray and the set projection shown in fig. 12.

Fig. 14 is a view showing a coupling process between the tray and the seating protrusion shown in fig. 13.

Fig. 15 is a sectional view schematically showing still another example of the coupling structure between the tray and the seating protrusion shown in fig. 12.

Fig. 16 is a view showing a coupling process between the tray and the seating protrusion shown in fig. 15.

Fig. 17 is a perspective view illustrating a door-closed state of a cooking apparatus according to an embodiment of the present invention.

FIG. 18 is a cross-sectional view taken along line "XVIII-XVIII" of FIG. 17.

FIG. 19 is a cross-sectional view taken along line "XIX-XIX" of FIG. 17.

Fig. 20 is a perspective view illustrating a door opened state of the cooking apparatus shown in fig. 17.

FIG. 21 is a cross-sectional view taken along line "XXI-XXI" of FIG. 20.

FIG. 22 is a cross-sectional view taken along line "XXII-XXII" of FIG. 20.

Fig. 23 is a diagram showing a state of change in the center of gravity of the cooking apparatus in the door-open state.

Fig. 24 is an exploded perspective view showing a part of the structure of the tray shown in fig. 11.

FIG. 25 is a cross-sectional view taken along line "XXV-XXV" of FIG. 11.

Fig. 26 is an exploded perspective view illustrating a case and a second heating part separately according to an embodiment of the present invention.

Fig. 27 is a plan view illustrating the second heating part illustrated in fig. 26.

Fig. 28 is an exploded perspective view showing the second heating unit, the receiving coil, and the electromagnetic shield plate shown in fig. 26 separately.

Fig. 29 is a cross-sectional view showing a state of coupling among the second heating unit, the temperature sensor, the receiving coil, and the electromagnetic shield shown in fig. 26.

Fig. 30 is a rear view showing the second control substrate shown in fig. 26.

Fig. 31 is a perspective view separately showing a door frame according to an embodiment of the present invention and various structures provided to the door frame.

Fig. 32 is an exploded perspective view of the door frame shown in fig. 31 and various structures provided in the door frame.

Fig. 33 is an enlarged view showing a part of the door frame shown in fig. 31 and the respective structures provided to the door frame.

Fig. 34 is a view showing a state where the first heating section and the protective grill are removed from the door frame shown in fig. 33.

Fig. 35 to 39 are views showing a process of installing the first heating part in the door frame.

Wherein the reference numerals are as follows:

100: shell body

105: cooking chamber

110: bottom surface

120. 130, 130: side surface

125: second slot

140: back side of the panel

150: rear shell

160: insulating board

170: outer casing

180: base seat

200: tray

205: tray main body

210: placing part

211: first projecting part

213: second projecting part

214: sliding surface

215: placing groove

220: water receiving tank

230: steam cover

231: lid body part

233: steam hole

235: water inlet guide surface

237: water inlet

300: door with a door panel

301: air inlet

303: exhaust port

305: handle bar

310: door top surface part

320: door frame

320 a: connecting hole

321: joining part

322: setting surface

323: limiting rib

324: stop piece

325: heater mounting part

326: first connecting end fixing part

327: second connecting end fixing part

328: shielding plate

330. 335: glass

340. 345 parts by weight: cable installation part

343: connecting member

350: front door face

360: input unit

370: a first cooling fan

400: a first heating part

410: heating body

420: first connecting end

421: cylindrical part

422: extension part

423: step

425: key-shaped part

430: second connecting end

440: emitter

450: protective grid

500: first control substrate

600: a second heating part

610: working coil

611: coil mounting base

613: coil

615: coil connection wiring

620: receiving coil

621: coil mounting base

623: coil

630: electromagnetic shielding plate

640: temperature measuring unit

700: second control substrate

710: noise filter PCB

720: coil control PCB

725：IGBT

726: heat radiator

730: second cooling fan

800: hinge assembly

810: hinge part

820: placing bulge

830: hinge shell

831: guide hole

832: first guide rib

833: second guide rib

835: first slot

W: perspective window

a: cover

b: supporting wall

c: combining hole

d: through hole

e: extended hole

f: outer wall

g: groove

h: fixing rib

Detailed Description

The foregoing objects, features and advantages will be described in detail with reference to the accompanying drawings, whereby those skilled in the art can easily embody the technical idea of the present invention. In describing the present invention, when it is judged that a detailed description of a known technology related to the present invention would obscure the gist of the present invention, a detailed description thereof will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals denote the same or similar constituent elements.

Although the terms first, second, etc. are used to describe various constituent elements, these constituent elements are not limited by these terms, of course. These terms are only used to distinguish one constituent element from other constituent elements, and the first constituent element may be the second constituent element unless otherwise explicitly stated in the description.

Hereinafter, the term "top (or lower)" of a component or the term "upper (or lower)" of a component refers to any component that is disposed in contact with the top surface (or bottom surface) of a component, and may also refer to any component that is disposed above (or below) the component and another component that is interposed between the component and the component.

In addition, when it is described that a certain constituent element is "connected", "coupled" or "connected" to another constituent element, it is to be understood that the above constituent element may be directly connected or connected to the above other constituent element, another constituent element may be "interposed" between the constituent elements, or each constituent element may be "connected", "coupled" or "connected" by another constituent element.

Throughout the specification, each constituent element may be singular or plural unless otherwise specified.

As used in this specification, an expression in the singular includes a plurality, unless the context clearly dictates otherwise. In the present application, terms such as "consisting of or" including "should not be construed as necessarily including each constituent element described in the specification or including all of various components, and should be construed as being capable of including some of the constituent elements or not including some of the steps, and may further include other constituent elements or steps.

Throughout the specification, unless otherwise specified, when referring to "a and/or B" means a and B or a or B, and unless otherwise specified, when referring to "C to D", it means that C is above and D is below.

[ integral Structure of cooking apparatus ]

Fig. 1 is a perspective view illustrating a cooking apparatus according to an embodiment of the present invention, fig. 2 is a perspective view illustrating a door-opened state of the cooking apparatus shown in fig. 1, and fig. 3 is an exploded perspective view illustrating an exploded state of the cooking apparatus shown in fig. 1.

Referring to fig. 1 to 3, a cooking apparatus according to an embodiment of the present invention includes a housing 100, a door 300, a tray 200, and heating parts 400 and 600.

The case 100 forms a frame of the cooking apparatus according to the present embodiment. Accordingly, various components constituting the cooking apparatus are respectively provided to the housing 100, and the housing 100 is internally formed with a cooking chamber 105 to provide a space for cooking food.

In the present embodiment, the case 100 is exemplified as being formed in a hexahedral shape with its top and front surfaces open. That is, the case 100 is provided in a form including a bottom surface 110, a pair of side surfaces 120, 130, and a rear surface 140, and is formed with a space therein, with the top surface and the front surface being open. A cooking chamber 105 surrounded by the bottom 110, the two sides 120, 130 and the back 140 of the housing 100 is formed inside the housing 100.

A tray 200 is disposed in the cooking chamber 105 formed inside the housing 100. The tray 200 is provided to allow food to be seated, and can be detachably provided inside the cooking chamber 105. In addition, the tray 200 may be provided to be removable from the front of the cooking chamber 105 for the convenience of the user.

The tray 200 may be provided to be movable in the front and rear direction in conjunction with the opening and closing operation of the door 300, and such front and rear movement of the tray 200 may be guided by a hinge assembly 800 described later. The detailed description thereof will be described later.

The door 300 is provided to open and close the opened top and front surfaces in the case 100. In the present embodiment, if the case 100 forms the external appearance of the bottom surface, the side surfaces, and the rear surface of the cooking apparatus, the door 300 forms the external appearance of the top surface and the front surface of the cooking apparatus. Such a door 300 may include a door top portion 310 and a door front portion 350.

The door top surface portion 310 constitutes a top surface of the door 300, and corresponds to a configuration of covering the top surface opened in the casing 100 when the door 300 closes the cooking chamber 105 inside the casing 100. Door front portion 350 constitutes the front surface of door 300, and corresponds to a configuration for covering the front surface opened in casing 100 when door 300 closes cooking chamber 105.

In the present embodiment, the door 300 is formed asThe shape is shown as an example. That is, the door 300 is formed so as toA door top surface part 310 shape-connected to the top surface of the door 300 and the door 300In the form of a front door front portion 350. When the door 300 formed in the above-described manner is rotated to open and close the cooking chamber 105, the door is opened and closedThe shape-coupled door top surface portion 310 and door front surface portion 350 rotate together and open and close the cooking chamber 105.

The door 300 is rotatably provided at the top of the housing 100, and rotatably coupled to the housing 100 using a hinge assembly 800 provided at the housing 100 as a medium. In this case, the hinge assemblies 800 are respectively disposed at both sides of the housing 100, and the rear side of the door top surface part 310 is rotatably coupled to each hinge assembly 800.

Also, a handle 305 is provided on the front surface of the door 300, and a user can open and close the cooking chamber 105 by rotating the door 300 in the vertical direction by holding the handle 305.

The heating parts 400 and 600 may be provided to the case 100 or the door 300 to heat the tray 200 disposed in the cooking chamber 105. In this embodiment, the heating units 400 and 600 include a first heating unit 400 disposed on the door 300 and a second heating unit 600 disposed on the housing 100.

The first heating part 400 may be provided at the door 300, and the first heating part 400 may be provided to be able to be received inside the cooking chamber 105 when the door 300 closes the cooking chamber 105. The first heating unit 400 is provided on the door top surface portion 310, and is disposed on the bottom surface side of the door top surface portion 310 facing the bottom surface of the housing 100.

In the present embodiment, a form in which the first heating part 400 is provided to include an electric heater is exemplified. Such a first heating part 400 may heat the food placed on the tray 200 from the top of the tray 200.

The second heating unit 600 is provided in the case 100 and disposed below the tray 200. Such a second heating part 600 is provided in the form of a heating part (e.g., an induction heating part) that heats the tray 200 in a different heating manner from the first heating part 400.

The second heating part 600 may be provided in the form of including a work coil 610 installed at a lower portion of the bottom surface 110 of the case 100, and inductively heats the tray 200 from a lower portion of the tray 200. For this, the tray 200 may be formed of a material that can be inductively heated by the second heating part 600.

In summary, the cooking apparatus according to the present embodiment includes: a housing 100 having a cooking chamber 105 formed therein; a door 300 provided to be able to open the front and the top of the cooking chamber 105 at the same time; a first heating part 400 provided to be able to heat the inside of the cooking chamber 105 from the top; and a second heating unit 600 that is provided to inductively heat the tray 200 inside the cooking chamber 105 and to allow the tray 200 to be inserted and removed in conjunction with the opening and closing operations of the door 300.

The following will describe in order a specific description of the above-described configuration and other configurations not yet mentioned.

[ Structure of case ]

Fig. 4 is a perspective view illustrating the housing and the hinge assembly shown in fig. 1 separately.

Referring to fig. 3 and 4, as described above, the case 100 includes the bottom surface 110, the pair of side surfaces 120 and 130, and the rear surface 140, a space is formed inside, and the top surface and the front surface are provided in an open form.

A cooking chamber 105 is formed in an inner space surrounded by the bottom surface 110, the two side surfaces 120, 130, and the back surface 140 of the casing 100, and it may be provided that the tray 200 can be taken out from such a cooking chamber 105.

The second heating unit 600 may be provided at a lower portion of the bottom surface of the housing 100, and an electric component related to the operation of the second heating unit 600, for example, a second control board 700, which will be described later, may be provided behind the rear surface of the housing 100.

In addition, hinge assemblies 800 may be provided outside both side surfaces 120, 130 of the housing 100, respectively, and the door 300 may be rotatably provided at the housing 100 by being coupled to the hinge assemblies 800 provided in this manner.

For example, the case 100 may be formed by bending a metal plateThe shape is made, and the metal plate bent in the above-described manner forms the bottom surface and both side surfaces of the case 100. When the case 100 is manufactured in the above-described manner, the bottom surface 110 of the case 100 can be integrally connected with the two side surfaces 120, 130 without forming a seam.

Accordingly, not only the aesthetic appearance of the inside of the cooking chamber 105 can be improved, but also an effect of preventing foreign substances from being caught in a gap between the bottom surface 110 and the both side surfaces 120 and 130 of the housing 100, or an effect of preventing contamination due to foreign substances falling to the second heating part 600 through the gap can be obtained.

As another example, the housing 100 may be manufactured by a method in which the respective components are separately assembledThe left and right projecting portions of the shaped metal plate are bent upward to form the bottom surface 110 and the two side surfaces 120, 130 of the case 100, and the rear projecting portion is bent upward to form the rear surface 140 of the case 100. When the case is manufactured in this form, the bottom surface 110, the two side surfaces 120, 130, and the back surface 140 of the case 100 may be integrally formed without seams between the bottom surface 110 and the two surfaces 120, 130 of the case 100, and between the bottom surface 110 and the back surface 140 of the case 100.

Thereby, a seam inside the cooking chamber 105 is hardly visible when viewed from the front and the top, and the inner side of the cooking chamber 105 can be kept smooth flat, and therefore, the components can further improve the beauty of the inside of the cooking chamber 105, and also an effect of easily removing stains stuck on the inner side of the cooking chamber 105 can be obtained.

In addition, the bottom surface 110 of the case 100 may include ceramic glass, which may be formed in a rectangular flat plate shape having a predetermined thickness.

For example, ceramic glass may be disposed at a central portion cut in the bottom surface 110 made of a metal material, and such ceramic glass may be disposed between the second heating part 600 and the tray 200.

A rear case 150 is disposed on the back of the rear surface 140 of the housing 100, and the rear case 150 accommodates a second control board 700 described later. The second control board 700 is accommodated in the rear case 150 and disposed on the rear side of the case 100, and an insulating plate 160 is disposed between the rear surface 140 of the case 100 and the rear case 150.

The insulating plate 160 insulates heat inside the cooking chamber 105 from being transferred to the second control substrate 700 side through the rear surface 140 of the case 100, and plays a role of insulating between the rear case 150 provided with the second control substrate 700 and the case 100.

In addition, the housing 100 of the present embodiment may further include a casing 170, and the casing 170 is disposed to cover the two side surfaces 120 and 130 and the back surface 140 of the housing 100. Such an outer case 170 surrounds and protects the hinge housing 800 provided at both sides 120, 130 of the housing 100 and the second control substrate 700 provided at the rear surface 140 of the housing 100 from the outside, and forms the appearance of the side and rear sides of the cooking apparatus.

[ Structure of door ]

Fig. 5 is a perspective view illustrating a door according to an embodiment of the present invention as separated, and fig. 6 is a bottom perspective view illustrating a bottom surface side of the door shown in fig. 5. Fig. 7 is an exploded perspective view showing the structure of the door shown in fig. 6, and fig. 8 is a cross-sectional view taken along line viii-viii of fig. 7. In addition, fig. 9 is a sectional view taken along line "ix-ix" of fig. 6, and fig. 10 is a sectional view schematically showing the flow of air inside the door according to an embodiment of the present invention.

Referring to fig. 5 to 9, the door 300 is formed with a door top surface part 310 constituting a top surface of the door 300 and a door front surface part 350 constituting a front surface of the door 300Shaped and integrally connected.

The door top surface portion 310 may be formed in a rectangular shape, and the length in the left-right direction may be longer than the length in the front-rear direction. The door frame 320 may be provided at the door top surface part 310. The door frame 320 is provided at a lower portion of the door top surface portion 310, and the first heating part 400 may be provided at the lower portion of the door top surface portion 310 in such a manner as to be coupled to the door frame 320.

The door 300 may include a see-through window W. The see-through window W is disposed on the door top surface portion 310, and may be installed to be located at a central portion in a plane direction of the door top surface portion 310.

Such a see-through window W may include a pair of glasses 330, 335 spaced apart by a predetermined interval in the up-down direction to form a space portion therein. For example, one glass 330 (hereinafter, referred to as "first glass") may be provided on the door top surface portion 310, and the other glass 335 (hereinafter, referred to as "second glass") may be provided on the door frame 320.

Each of the door top surface part 310 and the door frame 320 may be formed with a through hole. The through-holes may be formed at a central portion in the plane direction of the door top surface portion 310 and a central portion in the plane direction of the door frame 320, respectively.

According to the present embodiment, the first glass 330 covers the through hole formed in the door top surface portion 310 from the top and is provided in the door top surface portion 310, and the second glass 335 covers the through hole formed in the door frame 320 from the top and is provided in the door frame 320.

The first glass 330 and the second glass 335 may be made of glass of a transparent or translucent material, and the transparent window W may be a through hole portion formed in the first glass 330 and the second glass 335.

The user can confirm the cooking state of food in the cooking chamber 105 by looking down the inside of the cooking chamber 105 from the top through the see-through window W formed in the above manner. Due to the characteristics of the mini oven, it can be considered that the cooking apparatus of the present embodiment is used at a position significantly lower than the face of the user with a high frequency. Accordingly, the see-through window W formed at the top surface of the door 300 can be provided in a manner that allows the user to easily and conveniently confirm the cooking state of the food without lowering his posture or bending.

The pair of glasses 330 and 335 forming the see-through window W are arranged in different configurations, that is, one is coupled to the door top surface portion 310 and the other is coupled to the door frame 320, and are arranged at a predetermined interval from each other. Therefore, a space between the two glasses 330 and 335 is formed inside the transparent window W.

The air layer formed in the spaced space formed in the above-described manner serves to prevent heat, which heats the glass 335 directly exposed to the cooking chamber 105, from being transferred to the glass 330 located at the outermost side.

Accordingly, the see-through window W having the double window structure has a function of preventing occurrence of a safety accident due to overheating of the see-through window W and fogging due to a temperature increase of the see-through window W.

On the other hand, the first heating unit 400 is provided on the door top surface portion 310 and is disposed in a region that is not exposed through the transparent window W when viewed from the top. Such first heating unit 400 is disposed on the front outer side and the rear outer side of the transparent window W on the horizontal plane formed by the door top surface portion 310. That is, the cooking apparatus of the present embodiment may include a pair of first heating parts 400 respectively disposed at the front outer side and the rear outer side of the transparent window W.

If the first heating part 400 is disposed in the region exposed through the transparent window W, not only the appearance is not good, but also a problem may occur in securing the view through the transparent window W, and a problem of a temperature increase of a portion of the transparent window W may also occur.

Further, since the door front 350 is formed in a rectangular shape having a longer length in the left-right direction than in the front-rear direction, the first heating unit 400 can be increased in length by arranging the first heating unit 400 in front of and behind the see-through window W, and the thermal power of the first heating unit 400 can be expected to be increased as the length of the first heating unit 400 is increased.

In view of these points, the first heating part 400 is disposed at the front outer side and the rear outer side of the see-through window W, respectively, thereby contributing to ensuring functional advantages such as maintaining the beauty, securing the field of vision, suppressing the temperature rise of the see-through window W, and increasing the thermal power of the first heating part 400.

The door front portion 350 can be formed in a rectangular shape, similar to the door top portion 310. However, if the door top surface part 310 forms a plane in the lateral direction, the door front surface part 350 forms a plane in the longitudinal direction.

For example, the door front portion 350 may be formed to extend downward from a front end of the door top portion 310. The door front portion 350 and the door top portion 310 may be connected to each other to form an internal space therebetween350 and the door top face portion 310. That is, the door 300 can be integrally connected to the door front 350 and the door top 310, which are connected to each other with their inner spacesThe form of the shape is provided.

The input unit 360 and the first control board 500 may be disposed on the door front portion 350. In the present embodiment, a space portion is formed in the door front portion 350. At least a portion of the input part 360 and the first control substrate 500 may be accommodated in such a space part.

The input part 360 may include various operation switches for operating operation control of the cooking apparatus according to the present embodiment. For example, the input part 360 may include, for example, an operation switch for turning on/off the first heating part 400 or adjusting thermal power, an operation switch for turning on/off the second heating part 600 or adjusting thermal power, a timing operation switch for adjusting an operation time of the first heating part 400 or the second heating part 600 (refer to fig. 3), and the like. Such an input part 360 may be provided to be exposed to the front of the door front part 350, and a user may directly operate such an input part 360 to adjust the motion of the cooking apparatus.

The first control board 500 is disposed inside the door front portion 350. Various elements, circuits, and the like related to the reception of an operation signal input through the input section 360, the generation of a control signal for controlling the operations of the first heating section 400 and the second heating section 600, and the like are provided in the first control substrate 500.

The first control substrate 500 needs to be electrically connected to the input part 360, the first heating part 400, and the second heating part 600. Similarly to the input unit 360, the first control board 500 is disposed on the door front portion 350, and is disposed at a position very close to the input unit 360 and also at a position very close to the first heating unit 400 disposed on the same door 300.

According to the present embodiment, the input part 360 is electrically connected to the first control substrate 500 in a form of being directly mounted on the first control substrate 500, and the first heating part 400 may electrically connect a cable, which is provided through the inside of the door front surface part 350 and the inside of the door top surface part 310 connected to each other, to the first control substrate 500 as a medium.

That is, the first control substrate 500, the input section 360, and the first heating section 400, which need to be electrically connected to each other, are arranged at positions very close to and spatially connected to each other, and therefore, the work for establishing electrical connection between these can be easily and quickly achieved, and the connection structure between them can be maintained in a very stable state.

In addition, the cooking apparatus of the present embodiment may further include cable mounting parts 340, 345. The cable attachment portions 340 and 345 are disposed between the door top surface portion 310 and the door frame 320 disposed in the vertical direction, and are disposed outside both sides of the see-through window W.

The connecting members 343 are disposed on the front outer side and the rear outer side of the see-through window W, respectively. Such a pair of connecting members 343 connect the pair of cable mounting parts 340, 345 spaced apart from each other. That is, the pair of cable installation parts 340 and 345 and the connecting member 343 are provided in a "mouth" shape surrounding the see-through window W on the outside.

The combination of the cable installation parts 340 and 345 and the connection member 343 provided in the above manner is provided in the door top surface part 310 in a form of being inserted into a space part formed between the door top surface part 310 and the door frame 320.

As described above, the inside of the door top surface portion 310 provided with the cable attachment portions 340 and 345 is connected to the inside of the door front surface portion 350. Cables C1 and C2 are provided in the cable attaching portions 340 and 345 provided in the door top surface portion 310, and the cables C1 and C2 pass through the inside of the door top surface portion 310 and the inside of the door front surface portion 350 connected to each other, thereby connecting the first control board 500 and the first heating unit 400 to each other.

The power cable C2 for supplying power to the first heating unit 400 and the first control board 500 may be provided in any one of the cable attachment portions 340 and 345 disposed outside the transparent window W. In addition, a signal cable C1 for transmitting a control signal generated from the first control board 500 to the first heating unit 400 may be provided in the other of the cable attachment portions 340 and 345 disposed outside the transparent window W.

That is, in the door 300, the first heating unit 400 is disposed on both sides in the front-rear direction with respect to the transparent window W, and the power cable C2 and the signal cable C1 are disposed on both sides with respect to the transparent window W.

Such a configuration structure of the first heating part 400, the power cable C2, and the signal cable C1 is a design result in consideration of the configuration structure of the first heating part 400 and the hinge assembly 800.

According to the present embodiment, each of the first heating parts 400 is arranged in such a manner that the heating body thereof extends long in the left-right direction. The hinge assemblies 800 (see fig. 2) are disposed on the left and right sides about the see-through window W.

The power cable C2 and the signal cable C1 are connected to some components disposed in the door 300, such as the first heating unit 400 and the first control board 500, and to some components disposed in the housing 100, such as the second control board 700 (see fig. 30).

If such a power cable C2 and a signal cable C1 are to pass between the door 300 and the case 100 in a form as unexposed as possible, it is most preferable to pass through a portion provided with the hinge assembly 800 as the only connecting portion between the door 300 and the case 100.

As an example, the section of the power cable C2 and the signal cable C1 connecting the housing 100 and the door 300 to each other may be configured in a form of passing through the inside of the hinge assembly 800. Thereby, it is possible to suppress the power cable C2 and the signal cable C1 from being exposed to the outside of the cooking apparatus at the section between the case 100 and the door 300, and to avoid damage of the power cable C2 and the signal cable C1.

In view of the fact that the heating element of the first heating unit 400 is arranged to extend long in the left-right direction, the power supply cable C2 and the signal cable C1 are preferably arranged on the side away from the heating element as far as possible and are arranged to extend in a direction different from the direction in which the heating element extends.

This is a result of design to avoid the heat generated in the first heating section 400 from affecting the power cable C2 and the signal cable C1. In addition, in consideration of the arrangement of the plurality of first heating portions 400 spaced apart in the front-rear direction, the configuration in which the power cable C2 and the signal cable C1 are arranged on both right and left sides of the first heating portion 400 is advantageous in connecting the first heating portion 400 to the power cable C2 and the signal cable C1. .

In the present embodiment, the power cable C2 and the signal cable C1 may be disposed at a distance from each other in the left-right direction through the see-through window W, and may be provided in different cable attachment portions 340 and 345.

At this time, the power cable C2 passes through the inside of any one of the hinge assemblies 800 respectively disposed at both sides of the housing 100 to be disposed at the cable mounting parts 340 and 345 adjacent to the hinge assembly 800, and the signal cable C1 may pass through the inside of the other one of the hinge assemblies 800 respectively disposed at both sides to be disposed at the cable mounting parts 340 and 345 adjacent to the hinge assembly 800.

For example, the power cable may pass through the inside of the hinge assembly 800 disposed at the left side of the housing 100 and be disposed in the cable installation parts 340 and 345 at the left side of the door 300, and the signal cable C1 may pass through the inside of the hinge assembly 800 disposed at the right side of the housing 100 and be disposed in the cable installation parts 340 and 345 at the right side of the door 300.

As described above, the wiring work for establishing the electric connection work between the respective components constituting the cooking apparatus can be performed more simply and quickly by the structure in which the cables having different functions are arranged at different positions, respectively, and the maintenance work related thereto can also be performed more easily.

[ Cooling Structure of door interior ]

Fig. 10 is a sectional view schematically showing the flow of air inside a door according to an embodiment of the present invention.

Referring to fig. 10, a space portion is formed inside both the door top surface portion 310 and the door front surface portion 350. In particular, a space is formed between a pair of glasses 330 and 335 disposed at a predetermined interval in the inside of the see-through window W provided in the door top surface portion 310. The space inside the door top surface portion 310 including the see-through window W and the space inside the door front surface portion 350 are connected to each other.

An air inlet 301 is formed at the lower end of the door front portion 350. The air inlet 301 is formed to penetrate through the lower end of the door front portion 350, and a passage is formed in the door front portion 350 such that a space inside the door front portion 350 is opened to the outside.

The rear end of the door top surface portion 310 is formed with an air outlet 303. The exhaust port 303 is formed to penetrate the rear end of the door top surface portion 310, and a passage is formed in the door top surface portion 310 so that a space inside the door top surface portion 310 is opened to the outside.

In addition, the cooking apparatus of the present embodiment may further include a first cooling fan 370 disposed inside the door 300. The first cooling fan 370 may be disposed inside the door top surface portion 310 or inside the door front surface portion 350. In the present embodiment, a space portion in which the first cooling fan 370 is provided inside the door front portion 350 is exemplified. This is a design in consideration of the lack of the remaining space in the door top surface portion 310 due to the provision of the transparent window W, the first heating part 400, and the like in the door top surface portion 310.

The first cooling fan 370 provided in the above-described manner generates an air flow such that the external air flows into the interior of the door 300 through the air inlet 301 and the air inside the door is discharged through the air outlet 303.

As described above, according to the air flow generated by the first cooling fan 370, the external air flows into the door front portion 350 through the air inlet 301, and thus the external air flowing into the door front portion 350 cools the first control substrate 500. The air cooled by the first control board 500 flows into the door top surface portion 310, passes through the space inside the see-through window W, and is then discharged to the outside of the door 300 through the exhaust port 303.

When the cooking apparatus operates, the temperature level of the first control substrate 500 is much lower than the temperature of the transparent window W heated by the first heating part 400. Therefore, the air that has flowed into the interior of the door 300 through the intake port 301 and cooled the first control substrate 500 can pass through the interior of the see-through window W at a sufficiently low temperature to cool the see-through window W. Therefore, the cooling of the first control substrate 500 and the cooling of the see-through window W can be sufficiently and efficiently performed according to the air flow generated by the first cooling fan 370.

According to the cooling structure of the inside of the door 300 formed in the above-described manner, overheating and deterioration of some components such as the first control substrate 500 in the inside of the door 300 are suppressed, so that malfunction, low performance, and the like of the cooking apparatus can be effectively suppressed.

In addition, heat transfer between the pair of glasses 330, 335 constituting the see-through window W is blocked by the cooling air passing through the inside of the door 300, thereby suppressing the occurrence of overheating of the see-through window W, and thus it is possible to effectively reduce the occurrence of accidents (injuries such as burns) occurring due to the user's contact with the see-through window W.

[ Structure for taking out tray ]

Fig. 11 is a perspective view illustrating a tray according to an embodiment of the present invention, and fig. 12 is a sectional view schematically illustrating a coupling structure between the tray and a seating protrusion shown in fig. 11.

Referring to fig. 2 to 3 and 11 to 12, a tray 200 is disposed in a cooking chamber 105 formed inside the casing 100. The tray 200 may be provided to be movable in the front and rear direction in conjunction with the opening and closing motion of the door 300, and such front and rear movement of the tray 200 may be guided by the hinge assembly 800.

The tray 200 may include a tray main body 205 and a seating portion 210.

The tray main body 205 has a bottom surface formed in a shape corresponding to the bottom surface 110 of the case 100. In the present embodiment, the tray main body 205 is exemplified by being formed in a box shape which is open at the top and flat in the up-down direction. The bottom surface of the tray main body 205 is formed in a shape corresponding to the bottom surface 110 of the casing 100, for example, in a rectangular plate shape, and four side surfaces of the tray 200 are formed in a form extending upward from the edges of the bottom surface of the tray 200, respectively.

The placement portions 210 are respectively provided on a pair of side surfaces of the tray main body 205 that face the left and right side surfaces of the housing 100. The seating portion 210 may include a first protrusion 211 protruding from an upper end of a side of the tray main body 205 in an outer direction of the tray main body 205, and a second protrusion 213 extending downward from an outer end of the first protrusion 211. For example, the seating portion 210 may be formed as the first and second protrusion portions 211 and 213Form of shape connection.

When the door is opened, the hinge assembly 800 is coupled with the rotation of the door 300 to take out the tray 200 forward from the inside of the cooking chamber 105. In addition, when the door is closed, the hinge assembly 800 may be inserted backward toward the inside of the cooking chamber 105 in conjunction with the rotation of the door 300. Such hinge assemblies 800 are respectively provided at left and right sides of the case 100 to be respectively disposed at outer sides of the left and right sides of the tray 200, and each hinge assembly 800 may include a hinge portion 810 and a seating protrusion 820.

The hinge portion 810 is provided to be hinged to the rear side of the door top surface portion 310. Such a hinge portion 810 can change a state in conjunction with the rotation of the door 300.

The seating protrusion 820 is connected with any one of the connection members of the hinge part 810 inside the hinge housing 830, and passes through the first slot 835 formed on the hinge housing 830 and the second slot 125 formed on the housing 100 to protrude toward the inside of the cooking chamber 105. Here, the second slot 125 is formed at a side of the case 100, and may be formed in a position and shape overlapping with the first slot 835.

The tray 200 may be seated on the seating protrusion 820. Specifically, the tray 200 may be seated to the seating protrusion 820 by clamping the seating protrusion 820 into the seating groove 215 formed at the side of the tray 200.

According to the present embodiment, the seating grooves 215 are formed in the seating portions 210 respectively provided at both side surfaces of the tray 200. The seating groove 215 may be formed in a shape that the seating portion 210 is cut from a lower end thereof, and in more detail, the second protrusion 213 is cut from a lower end thereof. The seating protrusion 820 may be clamped into the seating groove 215 by a lower portion cut in the seating groove 215, and a clamping coupling between the tray 200 and the seating protrusion 820 may be achieved by such a clamping coupling between the seating groove 215 and the seating protrusion 820.

In addition, a sliding surface 214 may be formed at the seating portion 210, more specifically, at a lower end of the second protrusion 213. The sliding surface 214 is provided such that the seating protrusion 820 contacting the lower end of the second protrusion 213 can slidably move. Such a sliding surface 214 may extend in the front-rear direction and be connected to the seating groove 215.

The user may cook using the cooking apparatus in a state that the tray 200 is installed inside the cooking chamber 105, or may take out the tray 200 from the cooking chamber 105 to the outside to take out the cooked food or wash the tray 200.

When the tray 200 is taken out of the cooking chamber 105 to the outside, the tray 200 may be slightly lifted upward and then taken out such that the seating protrusion 820 can be escaped from the seating groove 215.

In addition, when it is required to install the taken-out tray 200 to the inside of the cooking chamber 105 again, it is only required to push the tray 200 into the inside of the cooking chamber 105 so that the seating protrusion 820 can be caught in the seating groove 215.

However, since the seating groove 215 is located at the lower portion of the tray 200 and the seating protrusion 820 is hidden by the tray 200, it is difficult for the user to accurately grasp the positions of the seating groove 215 and the seating protrusion 820.

In view of these points, in the present embodiment, a sliding surface 214 is formed extending in the front-rear direction at the lower end of the second projecting portion 213, the sliding surface 214 being connected to the seating groove 215.

Therefore, when the user pushes the tray 200 into the inside of the cooking chamber 105, it is not necessary to clip the seating protrusion 820 into the seating groove 215 accurately from the beginning, and it is only necessary to push the tray 200 such that the sliding surface 214 is placed on the seating protrusion 820, and then move the tray 200 back and forth.

In this process, the seating protrusion 820 may slide on the sliding surface 820 due to the tray 200 moving in the front-rear direction and then be clamped into the seating groove 215.

That is, in order to mount the tray 200 to the inside of the cooking chamber 105, it is not necessary to accurately clip the seating protrusion 820 into the seating groove 21, but only by a simple action of moving the tray 200 back and forth after being placed on the seating protrusion 820, the clip coupling between the seating protrusion 820 and the seating groove 215 can be achieved, and thus the clip coupling between the seating protrusion 820 and the tray 200 can be simply and rapidly achieved.

The sandwiching coupling structure between the seating groove 215 and the seating protrusion 820 as described above is only an example, and various other modified embodiments may exist.

Fig. 13 is a sectional view schematically showing another example of the structure between the tray and the set projection shown in fig. 12, and fig. 14 is a view showing a coupling process between the tray and the set projection shown in fig. 13. Fig. 15 is a sectional view schematically showing still another example of the coupling structure between the tray and the set projection shown in fig. 12, and fig. 16 is a view showing a coupling process between the tray and the set projection shown in fig. 15.

As another modified example of the sandwiching coupling structure between the seating groove 215 and the seating protrusion 820, as shown in fig. 13, an inclined surface 215a may be formed between the seating groove 215 and the sliding surface 214. As shown in fig. 14, the inclined surface 215a may be formed on a path where the seating protrusion 820 sliding in a state of being in contact with the sliding surface 214 is inserted into the seating groove 215 to guide the movement of the seating protrusion 820.

As described above, when the inclined surface 215a is formed between the seating groove 215 and the sliding surface 214, it is possible to reduce impact and noise that may occur during the seating protrusion 820 is sandwiched in the seating groove 215, and thus, the sandwiching coupling between the tray 200 and the seating protrusion 820 can be more smoothly and stably achieved.

The inclined surface 215a may be disposed at the rear side of the seating groove 215. This is a result of designing in consideration that, when the user pushes the tray 200 into the inside of the cooking chamber 105 to be installed to the inside of the cooking chamber 105, the tray 200 is not inserted deeply more than the position where the sandwiching coupling is performed between the seating groove 215 and the seating protrusion 820.

As described above, when the inclined surface 215a is formed at the rear side of the seating groove 215, the sandwiching coupling between the seating groove 215 and the seating protrusion 820 can be smoothly and stably guided when the tray 200 is mounted on the seating protrusion 820 in a state where the tray 200 is not inserted deeply compared to the position where the sandwiching coupling between the seating groove 215 and the seating protrusion 820 is performed.

As another of the alternative embodiments of the sandwiching coupling structure between the seating groove 215 and the seating protrusion 820, as shown in fig. 15, a sandwiching groove 215b may be further provided in the second protrusion 213. The nip groove 215b may be formed in a shape in which a portion of the second protrusion 213 is cut, and may be formed in a groove shape recessed in the front-rear direction. Such a sandwiching groove 215b is formed to be connected with the seating groove 215, and may be formed in a concave shape recessed in the front-rear direction at an upper end of the seating groove 215.

The clamping groove 215b may be disposed at a front side of the seating groove 215. Therefore, as shown in fig. 16, when the user further pushes the tray 200 backward toward the inside of the cooking chamber 105 in a state where the seating protrusion 820 is inserted into the seating groove 215, the seating protrusion 820 caught in the seating groove 215 can be caught in the catching groove 215b extending forward in the seating groove 215.

As described above, when the seating protrusion 820 and the catching groove 215b are caught in the catching engagement, the movement of the tray 200 in the up-and-down direction is restricted due to the engagement, and thus, the risk of the tray 200 falling down in the forward direction is greatly reduced.

On the other hand, the seating protrusion 820 may move in the front and rear direction in conjunction with the state change of the hinge part 810. Such a seating protrusion 820 enables the tray 200 seated on the seating protrusion 820 to move in the front-rear direction. That is, the tray 200 seated on the seating protrusion 820 may move in the front and rear direction in conjunction with the front and rear movement of the seating protrusion 820.

Fig. 17 is a perspective view showing a door-closed state of a cooking apparatus according to an embodiment of the present invention, fig. 18 is a sectional view taken along the line "xviii-xviii" of fig. 17, and fig. 19 is a sectional view taken along the line "xix-xix" of fig. 17. In addition, fig. 20 is a perspective view showing an opened state of a door of the cooking apparatus shown in fig. 17, fig. 21 is a sectional view taken along a line "xxi-xxii" of fig. 20, and fig. 22 is a sectional view taken along a line "xxii-xxii" of fig. 20.

According to the present embodiment, as shown in fig. 17 and 18, when the door 300 is in a state of closing the cooking chamber 105, the tray 200 has been inserted into the inside of the cooking chamber 105. Also, the seating protrusion 820 where the tray 200 is seated is disposed at a position biased to the rear side of the cooking chamber 105.

The rear side of the tray 200 may be supported by a pair of seating protrusions 820. And the front side of the tray 200 may be supported by a pair of supporting rollers 115.

That is, the tray 200 may be stably supported by the pair of seating projections 820 disposed at the rear side and the pair of supporting rollers 215 disposed at the front side, and may be movably disposed in the cooking chamber 105 in the front-rear direction.

The support rollers 115 are respectively disposed at both side surfaces 120, 130 of the housing 100, and may be disposed at a front side of the housing 100 adjacent to the door 300. The seating portions 210 of the tray 200 may be seated on the support rollers 115, and in more detail, the sliding surfaces 214 (refer to fig. 11) may be seated on the support rollers 115. Such supporting rollers 115 rotate as the tray 200 moves, thereby being capable of supporting the tray 200 so that the tray 200 can move smoothly.

Also, the door 300 may be rotatably provided at the housing 100 with the hinge assembly 800 as a medium, and may be rotated in the up and down direction to open or close the cooking chamber 105.

The hinge assemblies 800 are respectively disposed at both sides of the housing 100, and rear sides of the door top surface part 310 are respectively rotatably coupled to the hinge assemblies 800.

That is, the rear left and right side edge portions of the door top surface portion 310 are rotatably coupled to the hinge assemblies 800 disposed at both sides of the housing 100, respectively. The door 300 is rotated in the vertical direction about the rear side of the door top surface portion 310 rotatably coupled to the hinge assembly 800, thereby opening and closing the top and front surfaces of the housing 100.

Referring to fig. 17 to 19, the hinge assembly 800 may include a hinge housing 830, a hinge part 810, a seating protrusion 820, and a conversion output part 840.

The hinge housing 830 forms an external appearance of the hinge assembly 800 and internally houses the hinge portion 810 and a portion of the seating protrusion 820 and the switching output portion 840. Various structures for supporting the hinge part 810, the seating protrusion 820, and the conversion output part 840 may be formed in such a hinge housing 830.

The hinge 810 is provided to the hinge housing 830 in a position changeable manner. Such a hinge portion 810 may be provided to the hinge housing 830 in a form rotatable along a track corresponding to a rotation track of the door 300. The upper end of such a hinge portion 810 may be combined with the door 300. As described above, the hinge 810 coupled to the door 300 may be interlocked with the rotation of the door 300, thereby changing the posture of the hinge 810. Also, the rotation track and range of the door 300 coupled to the hinge portion 810 can be guided by the hinge portion 810.

As an example, the hinge portion 810 may be provided in a flat plate shape, and may be formed in a shape curved along a shape corresponding to a rotation track of the door 300.

Also, a guide hole 831 may be provided in the hinge housing 830, the guide hole 831 being formed in a shape corresponding to the rotation track of the door 300. The guide hole 831 may be formed to penetrate in the left and right direction on the hinge housing 830. The guide hole 831 formed as described above may provide a passage for guiding a rotation path of the hinge portion 830 on the hinge housing 830.

For example, the guide hole 831 may be provided as a passage that rises toward the front and falls toward the rear.

A stopper 811 may be included in the hinge portion 810. The stopper 811 may be provided to protrude on the hinge portion 810, and may be provided to protrude in the left-right direction. Such a stopper 811 may be inserted into the guide hole 831 and may move along a passage formed by the guide hole 831. That is, the stopper 811 may guide the rotation of the hinge portion 810 while moving along the guide hole 831.

In addition, the stopper 811 may interfere with the hinge housing 830 at the front and top ends of the guide hole 831 to restrict the hinge portion 810 moving forward and upward from further moving, and may interfere with the hinge housing 830 at the rear and lower ends of the guide hole 831 to restrict the hinge portion 810 moving backward and downward from further moving. That is, the stopper 811 may limit the moving range of the hinge portion 810 to a range corresponding to the range formed by the guide hole 831.

The seating protrusion 820 is connected to any one of the structures constituting the conversion output part 840 inside the hinge housing 830, and passes through the first slot 835 formed on the hinge housing 830 and the second slot 125 formed on the housing 100 to protrude toward the inside of the cooking chamber 105. Here, the second slot 125 is formed at a side of the case 100, and may be formed in a position and shape overlapping with the first slot 835.

The conversion output part 840 is provided inside the hinge housing 830. The conversion output part 840 may convert a force applied by the posture change of the hinge part 810 into a force in a linear direction for moving the seating protrusion 820 in the front-rear direction. Such a conversion output 840 may include a moving member and a conversion member.

The moving member corresponds to a constitution of moving the seating protrusion 820 in the front-rear direction. The conversion member is configured to move the moving member in the front-rear direction in conjunction with a change in the posture of the hinge unit 810 (i.e., movement of the hinge unit 810).

As an example, the conversion output portion 840 may include a belt 841, a plurality of rotating gears 842, 843, 844, 845, and a rack 846. Here, the belt 841 and the plurality of rotary gears 842, 843, 844, 845 corresponding to the conversion member are exemplified. The rack 846 is illustrated as corresponding to a moving member.

The belt 841 is provided in the form of an open timing belt (Timingbelt) having a gear formed on at least one of the top and bottom surfaces. The belt 841 may be provided such that a first guide rib 832 projected from an inner side surface of the hinge housing 830 restricts an up-and-down position, and may guide a forward-and-backward movement path.

A rear-side end of the belt 841 may be connected with the hinge portion 810. Such a belt 841 can move in the front-rear direction in conjunction with the posture change of the hinge portion 810. For example, when the hinge portion 810 moves forward and upward, the belt 841 can move forward in conjunction with the hinge portion 810. When the hinge 810 moves backward and downward, the belt 841 can move backward in conjunction with the hinge 810.

The gears formed at the belt 841 may be engaged with a plurality of rotating gears 842, 843, 844, 845.

Among the plurality of rotating gears 842, 843, 844, 845, the first rotating gear 842 is closest to the belt 841. In the present embodiment, the first rotating gear 842 is illustrated as including a Timing gear (Timing gear). The first rotating gear 841 is engaged with the belt 842 to rotate in conjunction with the movement of the belt 841.

The second rotating gear 843 and the third rotating gear 844 are arranged between the first rotating gear 842 and the fourth rotating gear 845 to transmit the rotation of the first rotating gear 842 to the fourth rotating gear 845.

That is, the belt 841 is moved in conjunction with the posture change of the hinge portion 810, and the plurality of rotary gears 842, 843, 844, and 845 are rotated in conjunction with the movement of the belt 841, and as a result, it is considered that the posture change of the hinge portion 810 can cause the rotation of the fourth rotary gear 845.

As described above, the rotating fourth rotating gear 845 may be engaged with the rack 846 disposed at the lower portion thereof. The rack 846 may be provided to limit the up and down position by the second guide rib 833 protruded from the inner side surface of the hinge housing 830, and may guide the forward and backward movement path.

The rack 846 may be moved in the front and rear direction in conjunction with the rotation of the fourth rotating gear 845. For example, when the hinge portion 810 moves forward and upward, and thus the fourth rotating gear 845 rotates in the first direction, the rack 846 may move forward in conjunction with the fourth rotating gear 845 (refer to fig. 22). When the hinge portion 810 moves backward and downward and thus the fourth rotating gear 845 rotates in a second direction opposite to the first direction, the rack 846 may move backward in conjunction with the fourth rotating gear 845 (see fig. 21).

The seating protrusion 820 is coupled to the rack 846. Accordingly, the seating protrusion 820 may move in the front and rear directions in conjunction with the movement of the rack 846. For example, when the rack 846 is moved forward, the seating protrusion 820 is also moved forward accordingly, and when the rack 846 is moved backward, the seating protrusion 820 is also moved backward accordingly.

In summary, the hinge assembly 800 having the above-described configuration is configured such that the states of the respective structures constituting the hinge assembly 800, i.e., the hinge portion 810 and the switching output portion 840 are changed in conjunction with the rotation of the door 300, and the respective structures changed in state can move the seating protrusion 820 in the front and rear directions.

As shown in fig. 20 to 22, when the door 300 is rotated upward to open the cooking chamber 105, the state of the hinge portion 810 of the hinge assembly 800 is changed by the rotational force due to the rotation of the door 300, and thus, the seating protrusion 820 is moved forward. The tray 200 may be moved forward by the seating protrusion 820 moved forward in this manner, so that the tray 200 may be taken out of the cooking chamber 105 to the outside.

That is, when the door 300 is opened, the tray 200 is automatically taken out, and thus, the user can easily and safely put the food to be cooked on the tray 200, or can take out the cooked food put on the tray 200 from the tray 200, or can easily take out and move the tray 200 taken out from the front from the inside of the cooking chamber 105.

Further, the cooking apparatus of the present embodiment is configured such that the door 300 can open the front and top surfaces of the cooking chamber 105. Therefore, the user can put the food or the tray 200 into or out of the cooking chamber 105 with a more expanded passage than the case where the door 300 opens only the front surface or only the top surface of the cooking chamber 105.

That is, the cooking apparatus of the present embodiment may not only provide an expanded passage that enables a user to more easily and conveniently put food or tray 200 into or take food out of cooking chamber 105, but also provide a function that tray 200 is automatically taken out when door 300 is opened to more easily and conveniently take food or tray 200 out.

In addition, the cooking apparatus of the present embodiment can also provide the following functions at the same time: as long as the tray 200 is seated on the seating protrusion 820, the tray 200 is automatically inserted into the inside of the cooking chamber 105 when the door 300 is closed. This function may eliminate the need to put a hand inside the cooking chamber 105 filled with hot air while cooking is being performed, when the tray 200 is taken out and put into the cooking chamber 105, thereby contributing to improvement of convenience and safety of the cooking apparatus.

In addition, according to the cooking apparatus of the present embodiment, since the door 300 is not opened forward but is opened by being rotated upward, the center of gravity of the cooking apparatus is not tilted forward even when the door 300 is opened. Instead, the center of gravity of the door 300 moves more rearward when the door 300 is opened than when the door 300 is closed.

As described above, in the structure in which the center of gravity moves rearward when the door 300 is opened, the risk of the cooking appliance tipping forward when the door 300 is opened is greatly reduced. In addition, in this structure, it is easy to increase the weight of the tray 200, but even if the weight of the tray 200 increases, the risk that the cooking apparatus falls down forward is low. That is, in the above-described structure, the tray 200 can be used thicker and heavier than the structure of the door opened forward.

Since the thicker and heavier the tray 200 is, the better the high-temperature cooking performance is, and the easier the long-time heat preservation is, the thicker and heavier the tray 200 is, and accordingly, the better cooking performance can be expected.

In addition, the tray 200, which can be used in an environment heated by the induction heating section, is generally heavier than a conventional tray. Therefore, if a thicker and heavier tray 200 than a conventional tray can be used, even if the second heating part 600 is provided in the form of an induction heating part, the tray 200 suitable for this can be provided.

[ Structure for suppressing tip-over in cooking apparatus ]

As described above, in the cooking apparatus of the present embodiment, when the door 300 is opened, the tray 200 can be taken out from the front. Also, the tray 200 may be provided in a thicker and heavier form than a conventional tray to improve high-temperature cooking performance and heat-retaining performance.

In such a state where the tray 200 is taken out from the front, the center of gravity of the cooking apparatus is inclined forward according to the degree to which the tray 200 is taken out, whereby the risk of the cooking apparatus tipping forward inevitably increases.

In view of these aspects, the cooking apparatus of the present embodiment includes various forms of constitutions for preventing the cooking apparatus from tipping forward when the door 300 is opened.

Hereinafter, each configuration for preventing the cooking apparatus from falling over forward when the door 300 is opened will be described in detail.

Fig. 23 is a diagram showing a state of change in the center of gravity of the cooking apparatus in the door-open state.

Referring to fig. 20 to 23, the hinge parts 810 are disposed on both side surfaces 130 of the case 100 and are disposed adjacent to the back surface 140 of the case 100, respectively. That is, the hinge parts 810 are disposed behind both sides of the case 100.

The hinge portion 810 is coupled to the door 300 and coupled to the rear side of the door top surface portion 310. That is, the hinge parts 810 are coupled to the rear of both sides of the door top part 310, respectively, and the door 300 can open or close the cooking chamber 105 while rotating in the vertical direction around the rear side of the door top part 310 coupled to the hinge parts 810 as described above.

The door 300 is rotatable about the rear side of the door top surface portion 310 such that the door 300 is located at a position further rearward in a state where the front and top surfaces of the casing 100 are opened (hereinafter, referred to as an "opened state") than in a state where the front and top surfaces of the casing 100 are closed (hereinafter, referred to as a "closed state").

As described above, the door 300 is rotated centering on the rear side of the door top surface portion 310, so that the position of the door can be more rearward in the opened state than in the closed state.

As described above, when the door 300 is disposed in a position relatively biased to the rear in the opened state, the center of gravity of the cooking apparatus may be biased to the rear from the center in the front-rear direction of the cooking apparatus in the state where the door 300 is opened.

That is, a first configuration provided to prevent the cooking appliance from tipping forward when the door 300 is opened is that the door 300 is turned around the rear side of the door top surface portion 310, and therefore the door 300 in the opened state is biased rearward compared to the closed state, and thus when the door 300 is opened, the center of gravity of the cooking appliance is biased rearward from the center in the front-rear direction of the cooking appliance.

On the other hand, when the structure of the door 300 itself is viewed, the door 300 is provided in such a manner that the vertical length of the door front surface portion 350 is shorter than the front-rear length of the door top surface portion 310. That is, when the door 300 is in the closed state, the vertical length of the door front portion 350 is shorter than the front-rear length of the door top portion 310.

Therefore, in the door 300, the proportion of the volume of the door top surface portion 310 is greater than the proportion of the volume of the door front surface portion 350, and thus the proportion of the weight of the door top surface portion 310 is greater than the proportion of the weight of the door front surface portion 350 in the total weight of the door 300.

When the door 300 is rotated in the rear direction to be opened, the center of gravity of the door 300 gradually moves in the rear direction. In the door 300, the door front surface portion 350 is disposed on the front side, and the door top surface portion 310 is disposed on the rear side.

Therefore, among the total weight of the door 300, the greater the weight of the door top surface part 310, the greater the degree to which the center of gravity of the door 300 moves rearward when the door 300 is rotated rearward.

In other words, among the total weight of the door 300, the greater the weight of the door top surface part 310, the more the weight of the door 300 is, the more rapidly the center of gravity of the door 300 can be moved rearward when the door 300 is rotated rearward.

That is, a second configuration provided to prevent the cooking apparatus from tipping forward when the door 300 is opened is that the door 300 is provided in such a manner that the vertical length of the door front surface portion 350 is shorter than the front-rear length of the door top surface portion 310, and therefore, when the door 300 is rotated backward, the center of gravity of the door 300 can be more rapidly moved backward.

On the other hand, the door 300 is provided with the first heater 400 and the transparent window W, and the first heater 400 and the transparent window W are disposed on the door top surface portion 310.

As described above, the see-through window W may include a pair of glasses 330 and 335 (refer to fig. 10). Typically, glass is made of heavier materials. Therefore, when the see-through window W formed of glass is disposed on the door top surface portion 310, the weight of the door top surface portion 310 inevitably increases accordingly.

Further, the see-through window W of the present embodiment may include a pair of glasses 330, 335, i.e., two layers of glasses, and accordingly, the weight of the door top surface part 310 is inevitably increased.

As described above, when the transparent window W is disposed on the door top surface portion 310, the weight of the door top surface portion 310 is increased by the weight of the glass forming the transparent window W, among the total weight of the door 300.

Accordingly, when the door 300 is rotated backward, the center of gravity of the door 300 may be more rapidly moved backward as the weight of the door top surface part 310 side increases due to the first heating part 400.

The pair of first heating units 400 is disposed on the bottom surface side of the door top surface portion 310. At this time, the first heating unit 400 is disposed at the front outer side and the rear outer side of the transparent window W, respectively. One of the pair of first heating parts 400 is disposed at a rear side of the door top surface part 310 adjacent to the hinge part 810.

As described above, since the first heating part 400 is disposed on the door top surface part 310, the weight of the door top surface part 310 is further increased by the weight of the first heating part 400 among the total weight of the door 300.

Accordingly, when the door 300 is rotated backward, the center of gravity of the door 300 may be more rapidly moved backward as the weight of the door top surface part 310 side increases due to the first heating part 400.

Further, since the center of gravity of the door 300 is disposed at the first heating part 400 at the rear side of the door top surface part 310 adjacent to the hinge part 810, it can be moved further rearward, and thus, when the door 300 is rotated rearward, the center of gravity of the door 300 can be moved more rapidly rearward.

That is, the third configuration provided to prevent the cooking appliance from tipping forward when the door 300 is opened is that the first heating part 400 and the see-through window W are disposed on the door top surface part 310, whereby the center of gravity of the door 300 can be more rapidly moved backward when the door 300 is rotated backward.

In summary, the door 300 of the present embodiment is provided such that the position of the door 300 can be moved backward when rotated backward, provided in a form in which the vertical length of the door front portion 350 is shorter than the front-rear length of the door top portion 310, and provided in a form in which the first heating part 400 and the transparent window W are disposed on the door top portion 310.

Such a door 300 is provided such that, when the tray 200 is taken out from the front after the cooking chamber 105 is opened, the door 300 itself moves to the rear side of the cooking apparatus, and the center of gravity of the door 300 rapidly moves rearward as the door 300 rotates rearward.

The door 300 provided in this manner acts on the center of gravity of the cooking apparatus when the tray 200 is taken out from the front after the cooking chamber 105 is opened, so that the center is biased to the rear from the center in the front-rear direction, thereby being able to contribute to greatly reducing the risk of the cooking apparatus tipping forward.

On the other hand, the door 300 is rotated about the rear side of the door top surface portion 310 coupled to the hinge portion 810, and most of the load of the door 300 acts on the hinge portion 810 side when the door 300 is in the open state.

Since the hinge 810 is disposed at the rear side of the cooking appliance, when the door 300 is in the open state, most of the load of the door 300 is intensively applied to the rear side of the cooking appliance as a result.

Therefore, when the door 300 is in the opened state, the center of gravity of the cooking apparatus moves to the rear side of the cooking apparatus as most of the load of the door 300 is concentrated on the rear side of the cooking apparatus.

In other words, when the door 300 is in the opened state, the influence of the most load of the door 300 concentrating on the rear side of the cooking apparatus may further bias the center of gravity of the cooking apparatus further to the rear side, in addition to the influence caused by the position change of the door 300 itself and the change of the center of gravity of the door 300 itself.

That is, a fourth configuration provided to prevent the cooking appliance from tipping forward when the door 300 is opened is that a coupling point between the door 300 and the hinge portion 810 is disposed at the rear side of the cooking appliance, so that the influence of the majority of the load of the door 300 concentrating at the rear side of the cooking appliance can be further exerted.

In addition, when the door 300 is in the opened state, a Moment (Moment) is applied to the cooking appliance centering on a coupling portion of the door 300 and the hinge part 810, and the Moment acts as a force to rotate the cooking appliance forward. That is, the greater the moment, the greater the force that rotates the cooking apparatus forward, and therefore the higher the risk of the cooking apparatus tipping over.

In addition, when the door 300 is in the opened state, the tray 200 is taken out from the front, and a moment generated when the tray 200 is taken out in this way is applied to the cooking appliance, and the moment also acts as a force to rotate the cooking appliance forward.

Therefore, a force that adds the moment acting on the door 300 side and the moment acting on the tray 200 side may act as a force that further increases the risk of the cooking apparatus tipping over.

The amount of moment acting on one side of the door 300 may be determined by the force acting on the door 300 and the distance between the position where the force acts and the rotation axis (the coupling portion of the door and the hinge portion). At this time, unless a force is otherwise applied, only gravity may be considered to act on the door 300, and since gravity acts on the entire portion of the door 300, gravity may be considered to act on the center of gravity of the door 300. Therefore, it can be considered that the moment is larger the farther the center of gravity of the door 300 is from the coupled portion of the door 300 and the hinge portion 810, and the moment is smaller the closer the center of gravity of the door 300 is to the coupled portion of the door 300 and the hinge portion 810.

According to the present embodiment, as the door 300 is rotated backward to open the cooking chamber 105, the center of gravity of the door 300 is also moved backward, and thus, the magnitude of the moment acting on one side of the door 300 can also be reduced together.

That is, when the door 300 is in the opened state, the moment on the side of the tray 200 increases as the tray 200 is taken out from the front, but the moment on the side of the door 300 may be relatively reduced.

Therefore, in the cooking apparatus of the present embodiment, the magnitude of the moment acting on the cooking apparatus through the door 300 when the door 300 is opened can be reduced, so that the risk of the cooking apparatus tipping over due to the tray 200 being taken out from the front can be greatly reduced.

That is, the fifth configuration provided to prevent the cooking appliance from tipping forward when the door 300 is opened is such that the center of gravity of the door 300 is offset rearward so as to reduce the magnitude of the moment acting on the cooking appliance due to the door 300.

On the other hand, as described above, the seating protrusion 820 may protrude toward the inside of the cooking chamber 105 through the first slot 835 formed on the hinge housing 830 and the second slot 125 formed in the longitudinal direction of the housing 100.

The first slot 835 and the second slot 125 may provide a passage for protruding the seating protrusion 820 connected with the conversion output part 840 inside the hinge housing 830 to the inside of the cooking chamber 105, and in addition, may provide a passage required for the seating protrusion 820 to move back and forth.

For this, the first and second slots 835 and 125 are formed to penetrate the hinge housing 830 and the side 120 of the housing 100, respectively, and may be formed in a slot shape having a width in the up-down direction and a length extending back and forth corresponding to the thickness of the seating protrusion 820.

Preferably, the front-to-back lengths of the first and second slots 835 and 125 may be less than 1/2 of the front-to-back length of the tray 200.

The length of the first slot 835 and the second slot 125 is related to the removal range of the tray 200. That is, the range in which the tray 200 can be taken out depends on the degree to which the seating protrusion 820 moves forward, and the range in which the seating protrusion 820 moves forward is limited by the first slot 835 and the second slot 125, and as a result, it can be considered that the taking-out range of the tray 200 can be determined by the first slot 835 and the second slot 125.

Therefore, when the front-to-rear length of the first slot 835 and the second slot 125 is less than 1/2 of the front-to-rear length of the tray 200, the movable distance of the tray 200 is also limited to 1/2 which is less than the front-to-rear length of the tray 200.

Therefore, when it is considered that the tray 200 is completely inserted into the inside of the cooking chamber 105 in a state where the seating protrusion 820 is located at the rearmost end of the first and second slots 835 and 125, if the seating protrusion 820 is located at the foremost end of the first and second slots 835 and 125, the tray 200 may be taken out of the cooking chamber 105 by a length of 1/2 smaller than the length of the tray 200 in the length direction.

This is designed to allow the center of gravity of the tray 200 to be positioned inside the cooking chamber 105 even when the tray 200 is removed. That is, in consideration of excessive removal of the tray 200, accordingly, the risk of the tray 200 tipping forward increases, thus allowing the center of gravity of the tray 200 to remain inside the cooking chamber 105 when the tray 200 is removed. In addition, when the tray 200 is excessively pulled out to tilt the center of gravity of the cooking apparatus forward, accordingly, the magnitude of the moment acting on the cooking apparatus becomes large, thereby increasing the risk of the cooking apparatus itself tipping forward.

In view of these aspects, in the present embodiment, the tray 200 is made to be removable only to the outside of the cooking chamber 105 by a length of 1/2 that is less than the length of the tray 200 in the lengthwise direction, so that when the door 300 is opened, the tray 200 is automatically pulled out, making it easier and convenient to remove the food or the tray 200, and also providing an effect of reducing the risk of the tray 200 and the cooking apparatus falling over.

In the case of the conventional cooking apparatus in which the door opens only the front of the cooking chamber, as described above, if the tray 200 takes out 1/2 smaller than the length of the tray 200 in the length direction to the outside of the cooking chamber 105, various inconveniences are caused.

That is, since the tray 200 is not completely exposed to the outside of the cooking chamber, it is difficult to accurately confirm the cooking state of the food placed on the tray 200, and there is an inconvenience in placing the food on the tray 200 or taking out the food placed on the tray 200.

In contrast, in the cooking apparatus of the present embodiment, when the door 300 is opened, not only the front surface of the cooking chamber 105 but also the top surface is opened together, so as described above, even if the tray 200 is pulled out of the cooking chamber by a length of 1/2 that is smaller than the length of the tray 200 in the lengthwise direction, the tray 200 can be exposed to the outside of the cooking chamber 105.

Therefore, as described above, even if the tray 200 is pulled out of the cooking chamber by a length of 1/2 that is less than the length of the tray 200 in the longitudinal direction, the entire cooking state of the food placed on the tray 200 can be easily confirmed, and therefore, as described above, even if the tray 200 is pulled out of the cooking chamber by a length of 1/2 that is less than the length of the tray 200 in the longitudinal direction, the entire cooking state of the food placed on the tray 200 can be easily confirmed, and it is also possible to easily and quickly place the food on the tray 200 or take out the food placed on the tray 200.

That is, the sixth configuration provided to prevent the cooking appliance from tipping forward when the door 300 is opened is to take out only 1/2 less than the length of the tray 200 in the longitudinal direction when taking out the tray 200 to the outside of the cooking chamber 105, thereby reducing the risk of the cooking appliance tipping and making it possible to expose the entire tray 200 to the outside.

[ steam generating Structure of tray ]

FIG. 24 is an exploded perspective view showing a part of the structure of the tray shown in FIG. 11, and FIG. 25 is a sectional view taken along line "XXV-XXV" of FIG. 11.

Referring to fig. 3, 24, and 25, a water receiving groove 220 may be formed in the tray 200. The water receiving tub 220 may be disposed in at least one of four sides of the tray 200. In the present embodiment, the water receiving tank 220 is disposed on the side surface of the front of the tray main body 205. Such a water receiving groove 220 may be formed in a groove shape recessed downward from the upper end of the side of the tray 200.

Water may be contained in the water receiving tank 220, and as described above, the water contained in the water receiving tank 220 can be provided as steam that evaporates to act on the inside of the cooking chamber 105 when the inside of the cooking chamber 105 or the tray 200 is heated.

In addition, the tray 200 may further include a steam cover 230. The steam cover 230 is provided to cover the water receiving tub 220 from the top, and may include a cover main body portion 231 and a water inlet guide surface 235.

The cover body portion 231 may cover the water receiving tub 220 from the top and may be detachably coupled to the tray 200. A plurality of steam holes 233 may be disposed in the cap body 231. Each steam hole 233 is formed to penetrate the cap main body 231 in the up-down direction. With each of the steam holes 233 formed in the above-described manner, a passage for connecting the inside of the water receiving tub 220 covered by the steam cover 230 and the cooking chamber 105 to each other may be formed on the steam cover 230.

According to the present embodiment, the water receiving tub 220 and the steam cover 230 are disposed in front of the tray 200 and extend in the left-right direction. The plurality of steam holes 233 are disposed in the cover body 231 of the steam cover 230 and spaced apart from each other at predetermined intervals in the left-right direction. That is, steam holes 233 are provided so as to be uniformly arranged in the left-right direction inside cooking chamber 105.

The water inlet guide surface 233 is formed on the cover main body 231 and is formed to be recessed in the vertical direction. In the water inlet guide surface 233, the water inlet hole 237 is formed vertically penetrating therethrough.

The water inlet hole 237 forms a channel on the steam cover 230, which connects the top surface of the steam cover 230 and the water receiving tub 220 to each other. And, the water inlet guide surface 233 guides the flow of water such that the water supplied through the top surface of the steam cover 230 is guided to the side of the water inlet hole 237.

Preferably, the water inlet hole 233 may be disposed at a central portion side in the left-right direction of the water inlet guide surface 233, and the water inlet guide surface 233 connects the cover main body 231 and the water inlet hole 237 obliquely. Therefore, the water supplied to the water inlet guide surface 233 can flow toward the water inlet hole 237 side by the inclined surface formed by the water inlet guide surface 233, and then be supplied to the inside of the water receiving tub 220 through the water inlet hole 237.

As described above, the water supplied to the inside of the water receiving tank 220 may be used as water supplied into the cooking apparatus for generating steam.

For example, in a state where water is received in the water receiving tank 220 and the tray 200 is inserted into the inside of the cooking chamber 105, when the cooking apparatus starts to operate, the tray 200 is heated by operating at least one of the first and second heating parts 400 and 600.

Thus, when the tray 200 is heated, the water contained in the water receiving tub 220 is heated, thereby generating steam. The steam generated inside the water receiving tub 220 may pass through the steam cover 230 through the steam holes 233 to flow into the inside of the cooking chamber 105. At this time, since the water receiving tub 220 is formed to extend in the left-right direction and the plurality of steam holes 233 are also provided to be uniformly arranged in the left-right direction inside the cooking chamber 105, the steam can be uniformly spread into the inside of the cooking chamber 105. In addition, the steam may be discharged through the water inlet hole 237 disposed at the center portion of the steam cover 230 in the left-right direction.

As described above, the steam may be uniformly distributed inside the cooking chamber 105 without being concentrated into a certain portion of the cooking chamber 105, so that the steam may be uniformly supplied to the entire food to be cooked. Thus, the cooking apparatus of the present embodiment can uniformly supply steam to the inside of the cooking chamber 105, and thus can provide a cooking function capable of effectively maintaining moisture inside food.

In addition, since the steam cover 230 and the tray 200 are detachably provided, the inside of the water receiving tub 220 can be easily cleaned, and only the steam cover 230 can be easily and quickly replaced when necessary, so that it is possible to provide a cooking apparatus that is easy to maintain sanitation and maintenance.

[ Structure of second heating section, receiving coil, and second control substrate ]

Fig. 26 is an exploded perspective view illustrating a housing and a second heating part separately according to an embodiment of the present invention, and fig. 27 is a plan view illustrating the second heating part illustrated in fig. 26. Fig. 28 is an exploded perspective view showing the second heating unit, the receiving coil, and the electromagnetic shield plate shown in fig. 26, fig. 29 is a sectional view showing a state of connection among the second heating unit, the temperature sensor, the receiving coil, and the electromagnetic shield plate shown in fig. 26, and fig. 30 is a rear view showing the second control substrate shown in fig. 26.

Referring to fig. 3, 26, and 27, the second heating part 600 is disposed at a lower portion of the tray 200. The second heating part 600 is provided at a lower portion of the bottom surface 110 of the case 100, and is provided in the form of a heating part, such as an induction heating part, that heats the tray 200 using a different heating manner from the first heating part 400. The inductive heating part may be provided in the form of including a work coil 610 disposed at a lower portion of the bottom surface 110 of the case 100, and may inductively heat the tray 200 from a lower portion of the tray 200.

The work coil 610 includes a coil mounting base 611. In the present embodiment, the coil mounting base 611 is formed in a rectangular shape close to the tray 200 as an example. This is a result designed to enable the entire area of the tray 200 to be heated using the work coil 610 so that the size and shape of the work coil 610 approaches the shape of the tray 200.

As shown in fig. 28 and 29, the coil mounting base 611 has a spiral groove in which the coil 613 can be provided with reference to the center thereof, and the coil 613 is accommodated in the spiral groove and tightly wound and fixed on the top of the coil mounting base 611. An end of the coil 613 is provided with a coil connection wiring 615 connected to a coil control PCB for controlling the coil 613.

In addition, the second heating part 600 may further include a receiving coil 620. The receiving coil 620 is provided to receive power transmitted wirelessly, and is disposed below the second heating unit 600. Further, a base 180 is disposed below the receiving coil 620. The base 180 is coupled to a lower portion of the bottom surface 110 of the case 100 to support the work coil 610 and the receiving coil 620, etc. from a lower portion of the receiving coil 620 and to form a bottom surface appearance of the cooking apparatus.

Similar to the work coil 610, the receiving coil 620 may include a coil mounting base 621 and a coil 623. Unlike the coil mounting base 611 of the work coil 610, the coil mounting base 621 of the reception coil 620 is formed in a substantially circular shape. This is designed to form the shape of the receiving coil 620 to be close to the shape of the work coil of the induction heating part provided on the Cooktop (Cooktop).

According to the present embodiment, the receiving coil 620 is provided to be able to receive power from another cooking apparatus (i.e., an inductive heating portion of a cooktop) provided separately from the cooking apparatus of the present embodiment.

For example, the cooking apparatus of the present embodiment may be used in a state where it is placed on a cooktop, in which case power required to operate the cooking apparatus may be received from an inductive heating portion of the cooktop.

As an example, when the working coil of the cooktop and the cooking apparatus of the present embodiment are simultaneously activated in a state in which the cooking apparatus of the present embodiment is placed on the cooktop, the power supplied through the cooktop may be transmitted to the receiving coil 620.

At this time, current is guided to the side of the receiving coil 620 by a magnetic field that varies in the work coil of the cooktop due to an electromagnetic induction phenomenon, so that power supplied through the cooktop can be transmitted to the receiving coil 620. In this process, in order to improve the power receiving efficiency of the receiving coil 620, it is preferable that the cooking apparatus of the present embodiment is placed on the cooktop, and the position of the receiving coil 620 and the position of the work coil provided in the induction heating part of the cooktop are placed in an overlapped manner.

In addition, the inductive heating portion may further include an electromagnetic shield plate 630 disposed between the work coil 610 and the receiving coil 620. The electromagnetic shield 630 may be provided in the form of a metal plate. Such an electromagnetic shield plate 630 is disposed between the work coil 610 and the receiving coil 620, and functions to minimize the influence of EMI generated by the work coil 610 on the receiving coil 620 or to minimize the influence of EMI generated by the receiving coil 620 on the work coil 610.

The cooking apparatus of the present embodiment including the receiving coil 620 as described above may be operated by receiving wireless power from the inductive heating portion of the cooktop. The cooking apparatus can provide a simple and neat appearance without providing a cluttered power cable, and can be operated by receiving wireless power only by placing the cooking apparatus on a cooktop, so that user satisfaction can be further improved.

As shown in fig. 26, 27, and 30, the receiving coil 620 may be electrically connected to the second control substrate 700 disposed behind the operating coil 610 and the receiving coil 620. The power wirelessly transmitted from the work coil of the cooktop to the receiving coil 620 is transmitted to the second control substrate 700 side electrically connected to the receiving coil 620.

According to the present embodiment, the inner space of the lower portion of the bottom surface 110 of the case 100 and the inner space of the rear side of the rear surface 140 of the case 100 are connected to each other. The work coil 610 disposed in the inductive heating portion below the bottom surface 110 of the housing 100 and the second control substrate 700 disposed behind the rear surface 140 of the housing 100 may be electrically connected to each other by a cable connecting the work coil 610 and the second control substrate 700 to each other through an internal space below the bottom surface 110 of the housing 100 and an internal space behind the rear surface 140 of the housing 100 connected to each other.

A power supply processing section that supplies power necessary for operation to an inductive heating section such as the second heating section 600 is provided in the second control substrate 700. The power supply processing portion is connected with the receiving coil 620 to receive power from the receiving coil 620, and processes the supplied power in a form suitable for use in the second heating portion 600 or the like. Such a power supply processing part may include a noise filter PCB710, and a coil control PCB720 for controlling the operation of the work coil 610 may be further provided in the second control substrate 700.

The function of the noise filter PCB710 is to remove noise from the power supplied to the work coil 610 and the control coil PCB720 controls the operation of the work coil 610. In the coil control PCB720, a chip (for example, a chip such as the IGBT 725) for controlling the operation of the work coil 610 may be mounted.

The IGBT725 is a high heat-generating chip requiring temperature management, and when the IGBT725 excessively rises in temperature above a predetermined temperature, the operating coil 610 cannot be controlled.

In view of this, the second control substrate 700 is provided therein with a second cooling fan 730. The second cooling fan 730 may be a sirocco fan (sirocco fan) that sucks air from the outside space of the case 100 and discharges the sucked air to the IGBT725 side.

The second cooling fan 730 may be disposed on the side of the IGBT725, and may suck air from the rear side of the case 100 and discharge the sucked air to the side toward the IGBT 725.

The air flowed into the space portion of the rear side of the rear surface of the case 100 by the second cooling fan 730 first contacts the IGBT725 and the heat sink 726 for cooling the IGBT725 to cool them, and may be discharged to the outside after cooling the noise filter PCB710 portion.

In addition, as shown in fig. 26 to 29, the second heating part 700 of the present embodiment may further include a temperature measuring module 640. A temperature measuring module 640 is provided to measure the temperature of the tray or the temperature inside the cooking chamber 105 in which the tray is disposed.

The temperature measurement module 640 may be configured to be located at a central portion of the work coil 610. Specifically, the temperature measurement module 640 may be disposed on a portion of the coil mounting base 611 where the coil 613 is not disposed, for example, may be disposed in a central portion of the coil mounting base 611.

Such a temperature measurement module 640 may be clip-coupled to the work coil 610 through a through-hole formed at a central portion of the coil mounting base 611. Also, the temperature measuring module 640 provided as described above may include a temperature sensor such as a Thermistor (Thermistor), etc., and may be disposed at a lower portion of the bottom surface 110 of the case 100 to measure the temperature of the tray or the temperature inside the cooking chamber 105 where the tray is disposed.

[ arrangement relationship of hinge module, second heating unit, second control substrate, see-through window, first heating unit, input unit, and first control substrate ]

Referring to fig. 3, 26 to 30, the hinge assembly 800, the second heating part 600, and the second control substrate 700 are disposed in the housing 100.

A cooking chamber 105 is formed inside the case 100, and a tray 200 can be removably provided in the cooking chamber 105. A second heating unit 600 for heating the tray 200 is disposed at a lower portion of the casing 100. And, hinge assemblies 800 are respectively disposed at both sides of the housing 100, and the hinge assemblies 800 rotatably support the door 300.

The hinge assembly 800 is disposed at both sides of the housing 100 to stably support the door 300 at both sides of the door 300. The hinge assembly 800 is coupled to the tray 200 so as to be able to move the tray 200 forward and backward, and the hinge assembly 800 is coupled to the tray 200 so as to be coupled to the door 300, and the hinge assembly 800 is disposed at both sides of the housing 100.

That is, the hinge assembly 800 should be disposed at both sides of the case 100 to achieve coupling with the tray 200, so that the door 300 can be stably supported and the tray 200 can be moved forward and backward.

In addition, since the top and front surfaces of the housing 100 are opened and the second heating part 600 is provided at the lower portion of the housing 100, the hinge assembly 800 can be disposed only at the rear side or both sides of the housing 100. The arrangement of the hinge assembly 800 on both sides of the housing 100 is advantageous for the reasons described above in many respects.

The receiving coil 620 is disposed at a lower portion of the case 100, and more specifically, at a lower portion of the second heating unit 600. The receiving coil 620 should be disposed at a position closest to a work coil that is a wireless power transmission target (e.g., a cooktop), and thus the disposed position of the receiving coil 620 should be at a lower portion of the case 100.

As described above, when the receiving coil 620 is disposed at the lower portion of the case 100 together with the working coil 610 of the second heating part 600, EMI of the working coil 610 or the receiving coil 620 may affect each other. In view of these aspects, an electromagnetic shield 630 may be disposed between the work coil 610 and the receiving coil 620.

The second control board 700 is preferably disposed adjacent to the receiving coil 620 and the operating coil 610 as a configuration closely related to power reception by the receiving coil 620 and operation of the operating coil 610.

Since the second heater 600 and the receiving coil 620 are disposed at the lower portion of the housing 100 and the hinge assemblies 800 are disposed at both sides of the housing 100, it is considered that the position where the second control substrate 700 is most suitably disposed is the rear.

In view of these points, the second control substrate 700 is disposed in a space behind the rear surface 140 of the housing 100. The second control board 700 provided as described above can be arranged in a position very close to the work coil 610 and the receiving coil 620, and therefore, the wiring connecting the second control board 700 to the work coil 610 and the receiving coil 620 can be simply configured.

In addition, as described above, the second control substrate 700 disposed at the rear of the housing 100 is also positioned close to each hinge assembly 800. Accordingly, when the wirings connecting the respective components disposed in the door 300 and the second control substrate 700 are configured, the respective wirings can be easily hidden inside the hinge assembly 800, and thus there is an advantage that the wirings can be neatly and simply configured without exposing the wirings to the outside.

As described above, the second heating part 600 and the receiving coil 620 are disposed at the lower portion of the housing 100, the hinge assembly 800 is disposed at both sides of the housing 100, and the second control substrate 700 is disposed at the rear side of the housing 100. These configurations are more suitable for the configuration of the housing 100 than the configuration of the door 300, and each configuration can exhibit an optimum function, has high structural stability, can configure neat and simple wiring, and can be disposed at an optimum position where interference between the configurations can be effectively avoided.

On the other hand, referring to fig. 3 and 5, the door 300 is provided with a transparent window W, a first heating part 400, an input part 360, and a first control substrate 500. These components are more suitable for being disposed on the door 300 than the case 100 for functional reasons. In consideration of the fact that some different components are already arranged in the housing 100 and it is more difficult to arrange other components, the arrangement positions of these components are more suitable for the door 300 side than the housing 100.

The perspective window W is disposed on the top of the cooking device. The mini oven is generally used at a position lower than the user's sight line, and thus, in consideration of the characteristics of the cooking appliance provided in the above-described form, it is preferable to dispose the see-through window W at the top of the cooking appliance as compared to disposing the see-through window W at the front of the cooking appliance.

The see-through window W is disposed on the top surface of the door 300, more specifically, on the door top surface 310. In this case, the larger the size of the see-through window W is, the more advantageous it is to ensure the visual field inside the cooking chamber 105, but the size of the see-through window W is preferably limited to a size that can ensure a space necessary for providing the first heating unit 400 and the cable installation parts 340 and 345 in the door top surface part 310.

The first heater 400 is disposed on the door top surface portion 310 in the same manner as the transparent window W. This is designed to dispose the first heating unit 400 at the top portion facing the second heating unit 600 with the tray 200 therebetween. That is, the first heating part 400 is provided on the door top surface part 310 so as to be disposed above the tray 200.

As described above, the first heating section 400 provided in the door top surface section 310 together with the transparent window W should be disposed at a position not exposed through the transparent window W when viewed from the top. If the first heating part 400 is disposed in the region exposed through the transparent window W, not only the appearance is not good, but also a problem may occur in securing the view through the transparent window W, and a problem of a temperature increase of a portion of the transparent window W may also occur.

Further, since the door front 350 is formed in a rectangular shape having a longer length in the left-right direction than in the front-rear direction, the first heating unit 400 can be increased in length by arranging the first heating unit 400 in front of and behind the see-through window W, and the thermal power of the first heating unit 400 can be expected to be increased as the length of the first heating unit 400 is increased.

In view of these points, the first heating part 400 is disposed at the front outer side and the rear outer side of the see-through window W, respectively, thereby contributing to ensuring functional advantages such as maintaining the beauty, securing the field of vision, suppressing the temperature rise of the see-through window W, and increasing the thermal power of the first heating part 400.

As described above, since the transparent window W and the first heating part 400 are disposed on the door top surface part 310, most of the area of the door top surface part 310 is occupied by the transparent window W and the first heating part 400. The input unit 360 and the first control board 500 are disposed on the door front 350 instead of the door top 310.

In consideration of a state where most of the area of the door top surface portion 310 is occupied by the transparent window W and the first heating portion 400, it is difficult to secure a space for providing the input portion 360 in the door top surface portion 310. Further, if the input part 360 is disposed on the door top surface part 310, there is a risk that an obstacle located on the top of the cooking appliance collides with the input part 360 to damage the input part 360 in the process of opening the door 300. In particular, if the input part 360 is provided in a form protruding from the door 300, the risk increases.

Further, the temperature of the door top surface portion 310 where the first heating unit 400 is disposed is likely to be higher than that of the door front surface portion 350. In view of the configuration in which the input unit 360 is operated by the hand of the user, when such an input unit 360 is disposed on the door top surface portion 310, the possibility that the user touches a hotter portion in the door top surface portion 310 during the operation of the input unit 360 increases. That is, if the input part 360 is disposed on the door top surface part 310, the risk of user injury (such as burn) may increase during the operation of the input part 360.

In view of these aspects, the input section 360 is disposed on the door front section 350 instead of the door top section 310. Since the input part 360 is disposed at the door front part 350, the user can safely and conveniently adjust the operation of the cooking appliance in front of the cooking appliance.

In addition to the input unit 360, the first control board 500 is also disposed on the door front portion 350. Various elements, circuits, and the like related to the reception of an operation signal input through the input section 360, the generation of a control signal for controlling the operations of the first heating section 400 and the second heating section 600, and the like are provided in the first control substrate 500. Therefore, the first control substrate 500 particularly needs to be electrically connected to the input portion 360.

According to the present embodiment, the first control board 500 is provided on the door front portion 350 in the same manner as the input portion 360, and is disposed in a position very close to the input portion 360. Accordingly, the connection between the input part 360 and the first control substrate 500 can be configured in a form of directly connecting the input part 360 to the first control substrate 500, and thus a very concise and stable connection structure of the input part 360 and the first control substrate 500 can be provided.

Further, since the first control board 500 is provided on the door front surface portion 350, not on the door top surface portion 310 on which the first heating unit 400 as a heat generating component is disposed, the first control board 500 can be disposed at a position that is out of the influence of heat generated by the first heating unit 400 to some extent. Thereby, the influence of heat generated during the operation of the first heating part 400 on the first control substrate 500 may be reduced accordingly, so that the stability and operational reliability of the cooking apparatus may be further improved.

[ Structure of door frame ]

Fig. 31 is a perspective view illustrating a door frame according to an embodiment of the present invention and respective structures provided to the door frame separately, and fig. 32 is an exploded perspective view illustrating the door frame shown in fig. 31 and respective structures provided to the door frame in an exploded manner. Fig. 33 is an enlarged view showing a part of the door frame shown in fig. 31 and the respective structures provided in the door frame, and fig. 34 is a view showing a state where the first heating unit and the protective grill are removed from the door frame shown in fig. 33.

In fig. 31, 33, and 34, illustration of the glass and the reflector is omitted.

Referring to fig. 31 to 34, the door frame 320 covers a lower portion of the door top surface part 310 and may be combined with the door 300. Such a door frame 320 may support the first heating part 400 and be combined with the door 300. The first heating part 400 coupled to the door frame 320 may be maintained in a state of being disposed at a lower portion of the door 300, more specifically, at a lower portion of the door top surface part 310.

The door frame 320 may include a coupling portion 321 and a heater installation portion 325. The heater installation part 325 is provided in a form protruding from the coupling part 321, and the first heating part 400 may be coupled into such a heater installation part 325.

The coupling portion 321 may be coupled to the door top surface portion 310 to support the heater mounting portion 325 at the door top surface portion 310. Such a joint 321 may be provided in the form of a frame of a "mouth" shape having a through hole formed therein.

A seating surface 322 may be formed on an inner side surface of the coupling portion 321 adjacent to the through-hole. The seating surface 322 forms a plane having a height lower than the recess of the top surface of the coupling portion 321, and the circumference of each edge of the glass 335 may be seated on the seating surface 322.

As described above, the glass 335 mounted on the seating surface 322 covers the through hole from the top, and may be disposed on the top of the heater mounting part 325 and the first heating part 400 provided to the heater mounting part 325. At this time, the seating surface 322 forms a plane having a height lower than the top surface of the bonding part 321, and the formed plane may be lower than the bonding part 321 by an extent approximately corresponding to the thickness of the glass 335. Thus, the glass 335 can be provided in the door frame 320 in a state of being disposed at a position not protruding upward from the top surface of the coupling portion 321.

The seating surfaces 322 may be disposed at left and right sides of the through-hole. The placement surface 322 may be disposed on one side or the other side in the front-rear direction of the through hole. In the present embodiment, the placement surfaces 322 are disposed on both the right and left sides and the front side of the through hole. Accordingly, the glass 335 is supported around three edges by the seating surface 322 and can be stably seated on the door frame 320.

Further, the left and right installation positions of the glass 335 can be guided by the restriction of the left and right movements thereof by the inner side surfaces of the coupling portions 321 surrounding the installation surface 322, and the glass 335 can be stably installed while suppressing the left and right shaking of the glass 335.

In addition, a restricting rib 323 and a stopper 324 may be further provided in the door frame 320. The restricting rib 323 may be disposed on one side of the through-hole in the front-rear direction, and the stopper 324 may be disposed on the other side of the through-hole in the front-rear direction. In the present embodiment, the restricting rib 323 is disposed behind the through hole, and the stopper 324 is disposed in front of the through hole.

The restriction rib 323 is formed to protrude from the coupling portion 321, and a portion protruding upward from the coupling portion 321 and a portion protruding from the portion in a direction of the through hole may be formed toShape-connected shapes. Such a restricting rib 321 interferes with the rear edge and the top face of the glass 335 at the rear of the glass 335, so that the movement of the glass 335 in the backward and upward directions can be restricted.

The stopper 324 may be formed to protrude upward from the combining portion 321. Such a stopper 324 interferes with the front edge of the glass 335 at the front of the glass 335, so that the glass 335 can be restricted from moving forward.

That is, the glass 335 is seated on the seating surface 322 such that the circumference of three edges of the glass 335 is supported by the seating surface 322, the left and right sides of the glass 335 are supported by the inner side surfaces of the coupling portions 321, the forward movement of the glass 335 is restricted by the stoppers 324, and the forward and upward movement of the glass is restricted by the restricting ribs 323, whereby the glass 335 can be stably supported and disposed on the door frame 320.

On the other hand, the first heating part 400 may include a heating body 410, a first connection end 420, and a second connection end 430.

The heating body 410 corresponds to a portion that radiates heat from the first heating part 400 provided in the form of an electric heater. Such a heat-generating body 410 may be formed in a rod shape having a predetermined length.

A first connection end 420 is disposed at one end of the heating element 410 in the longitudinal direction, and a second connection end 430 is disposed at the other end of the heating element 410 on the other side in the longitudinal direction.

At least one of the first connection end 420 and the second connection end 430 includes a cylindrical portion 421 and a key-shaped portion 425. In the present embodiment, it is exemplified that the first connection end 420 and the second connection end 430 each include the cylindrical portion 421 and the key-shaped portion 425.

The cylindrical portion 421 is disposed at an end in the longitudinal direction of the heating element 410. Such a cylindrical portion 421 may be formed in a cylindrical shape in which a circular lower surface is disposed at an outermost end portion of the first heating portion 410.

The key-shaped portion 425 is disposed between the heat-generating body 410 and the cylindrical portion 421. That is, key-shaped portions 425 are disposed at both ends in the longitudinal direction of the heating element 410, and a cylindrical portion 421 is disposed at the outermost side in the longitudinal direction.

The key shape portion 425 may be formed in a flat hexahedral shape having a thickness thinner than the diameter of the cylindrical portion 421 and a width longer than the diameter of the cylindrical portion 421. For example, a pair of quadrangular surfaces 426 (hereinafter, referred to as "first surfaces") parallel to the width direction of the key shapes 425 may be arranged to be spaced apart in the thickness direction of the key shapes 425 to constitute the top and bottom surfaces of the key shapes 425. Two pairs of quadrilateral surfaces 427 (hereinafter referred to as "second surfaces") parallel to the thickness of the key shape portion 425 may be arranged between the pair of first surfaces 426 to constitute four side surfaces of the key shape portion 425.

At this time, the first face 426 may be formed as a quadrangular face having sides longer than the diameter of the cylindrical portion 421, and the second face 427 may be formed as a quadrangular face having sides longer than the diameter end of the cylindrical portion 421.

Therefore, when the first connection end 420 or the second connection end 430 is viewed in the length direction of the first heating portion 410, in most regions, the cylindrical portion 421 protrudes further to the outside in the diameter direction of the cylindrical portion 421 than the key shape portion 425, and only in a part of regions, the key shape portion 425 may protrude further to the outside in the diameter direction of the cylindrical portion 421 than the cylindrical portion a.

The heater installation part 325 is provided to fix the first connection end 420 and the second connection end 430 which are provided in the above-described manner. Such a heater installation part 325 may include a first link end fixing part 326 for fixing the first link end 420 and a second link end fixing part 327 for fixing the second link end 430.

At least one of the first and second connection terminal fixing parts 326 and 327 may include a cover a and a support wall b. In the present embodiment, it is exemplified that the first connection end fixing portion 326 and the second connection end fixing portion 327 each include the cover a and the support wall b as well.

The cover a is provided so as to surround the periphery of the connection end from the outside in the circumferential direction. Such a cover a may be formed in a curved shape surrounding the lower portion and one side of the connection end, and may have a length corresponding to the length of the connection end or slightly longer than the length of the connection end.

In addition, the heater installation part 325 may further include a shielding plate 328. The shielding plate 328 is disposed on a side farther from a central portion of the cooking chamber in the front-rear direction than the first heating part 400, and connects the first connection end fixing part 326 and the second connection end fixing part 327. Such a shielding plate 328 may be formed in a plate shape having a length extending in a longitudinal direction of the first heating part 400.

According to the present embodiment, the first and second connection end fixing portions 326 and 327 are respectively disposed at both end portions in the longitudinal direction of the first heating part 400. Further, the shielding plate 328 is disposed on a side farther from the central portion in the front-rear direction of the cooking chamber than the first heating part 400, among the front side and the rear side of the first heating part 400.

Further, the hood a is disposed on a side closer to a central portion in the front-rear direction of the cooking chamber than the first heating part 400, from among the front side and the rear side of the first heating part 400. The cover a may surround the connection end from a side closer to a central portion of the cooking chamber in a front-rear direction than the first heating part 400 and a lower portion of the first heating part 400.

The lower side of cover a is connected to shield plate 328, so that a space surrounded by cover a and shield plate 328 connected in a "U" shape is formed around the connection end.

As described above, the support wall b may be disposed in the space surrounded by the cover a and the shield plate 328. Such a support wall b may be formed in a shape protruding from the cover a and the shield plate 328 toward the space. The support wall b formed in the above-described manner may divide the space surrounded by the cover a and the shielding plate 328 into an inner space and an outer space in the length direction of the first heating part 400. Also, the connection end may be clip-bonded to such a support wall b.

A coupling hole c and a through hole d may be formed at the support wall b.

The coupling hole c is formed to penetrate the support wall b, and may be formed to penetrate in a shape (e.g., a circular shape) corresponding to the outer circumferential surface shape of the cylindrical portion a. The cylindrical portion a sandwiches such a coupling hole c, so that the connection end can be sandwichingly coupled to the support wall b.

The through hole d is formed to penetrate the support wall b, and may be formed in a form cut from an upper side end of the support wall b to the coupling hole c. Such a through hole d is formed to penetrate the support wall b with a width corresponding to the length of the short side of the key shape part 425, thereby forming a passage connecting the outside of the support wall b and the coupling hole c to each other.

The through-holes d may be formed in a width corresponding to the length of the short sides of the key shapes 425, in other words, in a width corresponding to the thickness of the key shapes 425. The width is greater than or equal to the thickness of the key shape portion and smaller than the width of the pupil.

Any one of the first and second link ends 420 and 430 may be inserted into the coupling hole c through the through hole d in a state where the first heating part 400 is in the first posture. Here, the first posture is defined as a posture in which the first heating section 400 is arranged such that a surface parallel to the thickness direction of the key-shaped section 425 (i.e., the second surface 427) is parallel to the width direction of the through hole d (see fig. 36)

In addition, an extension hole e may be formed in the support wall b. The extension hole e is formed to penetrate the support wall b similarly to the through hole d, and may be formed in a shape in which the through hole d formed at the top of the coupling hole c extends to the lower portion of the coupling hole c through the coupling hole c.

When the connection end is in the first posture, the key shape portion 425 protrudes further upward and downward than the cylindrical portion 421. In addition, when the connection end is in the first posture, in order for the cylindrical portion 421 to be in a state of being able to be inserted into the inside of the coupling hole c, it is necessary to locate the cylindrical portion 421 and the coupling hole c at the same height. However, in order for the cylindrical portion 421 and the coupling hole c to be located at the same height, the lower protruding portion of the key shape portion 425 must be located at a lower position than the coupling hole c.

For this, an extended hole e is formed at a lower portion of the coupling hole c, and a lower protruding portion of the key shape portion 425 may be inserted into such an extended hole e. That is, the extension hole e may provide a passage enabling the lower protrusion part inserted into the key shape part 425 of the coupling hole c in the first posture to pass downward through the coupling hole c.

Additionally, the connection end may further include an extension 422. The extended portion 422 may be formed by extending the cylindrical portion 421 to the key shape portion 425 side. Such an extension 422 is formed to protrude outward from the first face 426 of the key shape portion 425 in the thickness direction of the key shape portion 425 to form a step 423 between the extension 422 and a surface (i.e., the first face 426) parallel to the width direction of the key shape portion 425. According to the extending portion 422 formed in the above-described manner, in a part of the key shape portion 425 adjacent to the cylindrical portion 421, an area where the extending portion 422 and the key shape portion 425 overlap is formed.

In this region, it is shown a shape that the extending portion 422 protrudes further in the thickness direction of the key shape portion 425 than the first face 426 of the key shape portion 425, and the second face 427 of the key shape portion 425 protrudes further in the width direction of the key shape portion 425 than the extending portion 422.

The strength of the joint portion between the cylindrical portion 421 and the key shape portion 425 can be further enhanced by forming the extension portion 422 in the above-described manner. If the extension 422 is not present, the junction between the cylindrical portion 421 and the key shape portion 425 is defined only by the lateral end of the key shape portion 425. However, since the extended portion 422 is formed at the connecting end, the joint portion between the cylindrical portion 421 and the key shape portion 425 can be expanded to the overlapping position of the extended portion 422 and the key shape portion 425, and therefore, the strength of the joint portion between the cylindrical portion 421 and the key shape portion 425 can be further enhanced.

In addition, the step 423 formed due to the extension 422 may serve to guide the position where the key shape portion 425 is inserted into the through hole d when the connection end and the support wall b are engaged in the sandwiching. The detailed description thereof will be described later.

On the other hand, each of the first and second connection end fixing parts 326 and 327 may further include an outer wall f. The outer walls f are respectively disposed outside the support walls b in the longitudinal direction of the heating element 410, and may be respectively connected to the inner side surfaces of the coupling portions 321. Such an outer wall f forms the outermost walls of the first and second connection end fixing parts 326 and 327 in the longitudinal direction of the heating element 410.

The first and second connection end fixing portions 326 and 327 each have a space surrounded by the cover a, the support wall b, the outer wall f, and the shielding plate 328 formed therein. The space is a space whose side portions are surrounded by the cover a, the support wall b, the outer wall f, and the shielding plate 328 and whose lower portion is surrounded by the cover a, and at least a part of the cylindrical portion 421 fixed to the fixed end of the first connection end fixing portion 326 or the second connection end fixing portion 327 is inserted into such a space.

In the space, the cylindrical portion 421 may be connected with a cable. The cable connected to the cylindrical portion 421 may be a signal cable that transmits a control signal generated from the first control substrate 500 (see fig. 7) to the first heating unit 400, may be a power supply cable that supplies power to the first heating unit 400, or may be both of the signal cable and the power supply cable.

As shown in fig. 7, the signal cable and the power cable may be provided in cable mounting parts 340, 345 provided in the door top face part 310. The coupling between the door top surface 310 and the door frame 320 forms a state in which the coupling portion 321 covers the portion where the cable attachment portions 340 and 345 are disposed.

The plurality of coupling protrusions 341, 346 are disposed in the cable attachment portions 340, 345, and the plurality of coupling holes 320a are disposed in the door frame 320 so as to correspond to the coupling protrusions 341, 346. After the positions of the door top surface portion 310 and the door frame 320 are matched so that the positions of the coupling hole 320a and the coupling protrusions 341 and 346 are matched, the portions where the coupling hole 320a and the coupling protrusions 341 and 346 are formed are coupled by the coupling member, whereby the coupling between the door top surface portion 310 and the door frame 320 can be configured. At this time, the portions where the cable attachment portions 340 and 345 are disposed are covered with the coupling portion 321.

The glasses 330 and 335 do not cover the portions where the cable attachment portions 340 and 345 are disposed, but the first heating unit 400 and the heater attachment portion 325 are disposed at the lower portion of the region covered with the glass 335. Therefore, in order to connect the cables provided at the cable mounting parts 340, 345 to the connection terminals, as shown in fig. 32 to 35, it is necessary to form a passage between the region of the bonding part 321 not covered with the glass 335 and the region of the heater mounting part 325 covered with the glass 335.

In view of these points, in the present embodiment, the groove g is provided at the connecting portion of the outer wall f and the joint 321. The groove g is formed at a connection site of the outer wall f and the combining portion 321, in which a surface recessed compared to the top face of the combining portion 321 (more specifically, the seating face 322 of the combining portion 321) is formed. The groove g formed in the above manner forms a gap allowing a cable to pass through at a lower portion of the glass 335 placed on the seating surface 322, so that a passage allowing the cable to pass through can be formed between the space in which the cylindrical portion a of the connection terminal is accommodated and the cable mounting portions 340 and 345 (refer to fig. 7).

On the other hand, the unnumbered 320b in the drawing is a hole formed through the door frame 320 to form a passage on the door frame 320 through which the hinge portion 810 (refer to fig. 2) passes through the door frame 320.

On the other hand, the cooking apparatus of the present embodiment may further include an emitter 440 and a protective grill 450.

The emitter 440 is provided to reflect heat of the first heating part 400 so that the heat of the first heating part 400 can be concentrated to the tray 200 (refer to fig. 2) side. In the present embodiment, the transmitter 440 may be configured to transmit the signal to the receiverThe shape connecting the reflection surface formed parallel to the plane of the shield plate 328 and the reflection surface formed parallel to the plane of the glass 335 is exemplifiedAnd (6) discharging. Such a transmitter 440 may be provided on the door frame 320 by being combined with the shielding plate 328.

The emitter 400 disposed in the above-described manner may be laterally blocked between the first heating part 400 and the shielding plate 328 and between the first heating part 400 and the glass 335 to reflect heat of the first heating part 400, thereby helping to concentrate the heat of the first heating part 400 to the tray 200 side.

The protective grill 450 can transfer heat of the first heating part 400 to the tray 200 side, and is provided in a structure for protecting the first heating part 400. Such a protective grill 450 is disposed to be spaced apart from the shielding plate 328 with the first heating part 400 interposed therebetween.

The protective grating 450 may include a plurality of steel wires 451 and a plurality of fixing members 453. Each of the wires 451 has a length extending in a longitudinal direction of the first heating part 400, and is provided in a length substantially corresponding to the length of the first heating part 400 or a length slightly longer than the length of the first heating part 400.

The plurality of wires 451 are arranged so as to surround the circumference of the first heating section 400 at the outer side in the circumferential direction of the first heating section 400. Such a plurality of steel wires 451 may be arranged at predetermined intervals in the circumferential direction of the first heating section 400.

According to the present embodiment, the circumference of the first heating part 400 is surrounded by the emitter 440 and the protective grill 450. That is, one side of the first heating part 400 in the front-rear direction and the top of the heating part 400 are surrounded by the emitter 440, and the remaining direction, that is, the other side of the first heating part 400 in the front-rear direction and the lower part of the heating part 400 are surrounded by the protective grill 450.

Therefore, the plurality of wires 451 are arranged so as to surround the other side of the first heating section 400 in the front-rear direction and the lower portion of the heating section 400 on the outer side in the circumferential direction of the first heating section 400. The fixing member 453 is formed in a shape extending in the arrangement direction of the wires 451. The plurality of fixing members 453 may be disposed at predetermined intervals along the length direction of the wire 451.

The protective grill 450 may be disposed on the door frame 320 by fixing both end portions thereof in a length direction to the first and second connection end fixing portions 326 and 327, respectively.

For this, a grill fixing portion may be provided in each of the first and second connection end fixing portions 326 and 327. The grill fixing part is provided as means for fixing the steel wire 451 of the protection grill 450 to the heater installation part 325, and may include a plurality of fixing ribs h.

The plurality of fixing ribs h are configured to be spaced apart at predetermined intervals along the arrangement direction of the plurality of steel wires 451. And, each fixing rib h is formed to protrude from the cover a toward the first heating part 400. Accordingly, fixing grooves may be formed between each of the fixing ribs h. Preferably, the spaced interval between each fixing rib h is determined such that the fixing groove can be formed to a width corresponding to the thickness of the steel wire 451.

As described above, the sandwiching coupling between the protection grill 450 and the grill fixing portion may be achieved by sandwiching and fixing the steel wire 451 to the respective fixing grooves formed between the plurality of fixing ribs h. Thereby, the protective grill 450 can be simply and rapidly disposed in the door frame 320 only by a simple operation of sandwiching and fixing both side ends of the protective grill 450 to the grill fixing portion formed at each of the first and second connection end fixing portions 326 and 327.

In addition, as described above, a plurality of fixing ribs h formed to protrude from the cover a may be used as a reinforcing structure to increase the strength of the cover a.

Fig. 35 to 39 are views showing a process of installing the first heating part in the door frame.

Hereinafter, a process in which the first heating part 400 is provided in the door frame 320 will be described with reference to fig. 35 to 39.

Referring to fig. 35, before the first heating part 400 is installed on the door frame 320, a protective grill 450 may be installed. The protective grill 450 may be provided in such a manner that both end portions of the protective grill 450 in the length direction are fixed to the first and second connection end fixing portions 326 and 327, respectively. In this case, the fixing of each end of the protection grill 450 may be configured such that the steel wire 451 sandwiches the fixing grooves formed between the plurality of fixing ribs h to form a sandwiched connection between the protection grill 450 and the grill fixing portion.

When the setting of the protective grill 450 is completed, the setting of the first heating part 400 may be performed. In order to install the first heating unit 400 on the door frame 320, first, the first heating unit 400 is brought into a first posture. At this time, the first and second link ends 420 and 430 are in a state where the pair of first faces 426 face forward and backward, respectively, and the pair of second faces 427 facing each other of the two pairs of second faces 427 face top and bottom.

In this state, as shown in fig. 36, either one of the first link end 420 and the second link end 430 is sandwiched into the support wall b. In the present embodiment, an example is shown in which the first connection terminals 420 are sandwiched in the support walls b provided in the first connection terminal fixing portions 326.

The first connection terminals 420 need to be inserted into the through holes d formed in the support wall b in order to be clamped into the support wall b. For this reason, the first connection end 420 is inserted into the through hole d in a state where the position of the key shape portion 425 and the position of the through hole d coincide. In this process, the key shape part 425 is inserted into the through hole d through the upper end of the cut support wall b and inserted into the coupling hole c through the through hole d.

At this time, the second connection end 430 remains in a state where the second connection end fixing portion 327 is not sandwiched. That is, even if the first heating part 400 is moved downward in a state where the key-shaped parts 425 of the first connection ends 420 are inserted into the coupling holes c, the second connection ends 430 are not sandwiched by the support wall b and are maintained in a state of being positioned at the right side of the support wall b.

The position of the first connection end 420 in the longitudinal direction thereof for sandwiching the support wall b may be guided to a position where a region between the end of the heat-generating body 410 in the longitudinal direction and the extension 422 (hereinafter, referred to as a "recess region") can overlap the through-hole d. That is, the portion of the first connection end 420 that can pass through the through-hole d is limited to a recessed region in which the recessed region can be clearly distinguished due to the shape characteristics of the recess between the end of the heat-generating body 410 in the length direction and the extension 422.

When the length of the recessed area is about equal to or slightly greater than the thickness of the support wall b, the first link ends 420 are sandwiched into the support wall b of the first link end fixing part 326, and the position of the first heating part 400 can be easily guided so that the second link ends 430 are not sandwiched into the support wall b of the second link end fixing part 327.

For this purpose, a distance L between the supporting wall b of the first connection end fixing portion 420 and the supporting wall b of the second connection end fixing portion 430₁The following relationship is satisfied.

L_H＝L_H1+2L_H2+2L_H3

L₁＝L_H－L_H2－L_H3

Here, L_HIs the total length of the first heating section, L_H1Length of heat-generating body, L_H2Distance between one side end of the heating element and the step, L_H3Is the distance between the step and the outermost end of the cylindrical portion, in addition, L_H2The length of the recessed region can be considered as the distance between the one end of the heat-generating body and the step.

That is, a distance L between the supporting wall b of the first connection end fixing portion 326 and the supporting wall b of the second connection end fixing portion 327₁The length is set to be equal to the length obtained by subtracting one connection end from the one heating element 410 and the pair of connection ends 420 and 430 constituting the first heating unit 400.

If the interval L between the supporting wall b of the first connection end fixing portion 326 and the supporting wall b of the second connection end fixing portion 327 is set in the above-described manner₁When the recessed area of the first connection terminal 420 is inserted into the through hole d to be clamped into the support wall b of the first connection terminal fixing portion 326, the second connection terminal 430 is not clamped into the support wall b of the second connection terminal fixing portion 327.

On the other hand, as shown in fig. 37, the depressed area of the key shape portion 425 is inserted into the coupling hole c through the through hole d, and therefore, when the cylindrical portion 421 is located at the same height as the coupling hole c, the lower protruding portion of the key shape portion 425 is sandwiched into the extension hole e, and the first connection end 420 is in a state of being unable to move further downward.

In this state, as shown in fig. 38, the entire first heating part 400 is moved in the longitudinal direction of the first heating part 400, and the heating element 410 is moved in a direction away from the support wall b of the first connection terminal fixing part 326. Accordingly, the key shape portion 425 of the first connection end 420 and the support wall b are separated. That is, the key-shaped portion 425 of the first connection end 420 is separated from the coupling hole c, the through hole d, and the extension hole e, and the cylindrical portion 421 is inserted into the coupling hole c, and constitutes a sandwiching coupling between the cylindrical portion 421 of the first connection end 420 and the support wall b of the first connection end fixing portion 326.

Meanwhile, in the second connection end fixing portion 327, the cylindrical portion 421 of the second connection end 420 is inserted into the coupling hole c, and thus the cylindrical portion 421 of the second connection end 430 and the support wall b of the second connection end fixing portion 327 are coupled by being sandwiched. At this time, the second connection end fixing portion 327 also holds the state in which the key-shaped portion 425 of the second connection end 420 is separated from the support wall b, that is, the state in which the key-shaped portion 425 of the second connection end 420 is not inserted into the coupling hole c, the through hole d, and the extension hole e.

For this purpose, a distance L between the supporting wall b of the first connection end fixing portion 420 and the supporting wall b of the second connection end fixing portion 430₁The following relationship is satisfied.

L₁＝L_H1+2L_H4

Here, L_H4Is the length of the key shape 425.

That is, a distance L between the supporting wall b of the first connection end fixing portion 326 and the supporting wall b of the second connection end fixing portion 327₁The length is set to be equal to the length including the heating element 410 and the pair of key-shaped portions 425.

If the interval L between the supporting wall b of the first connection end fixing portion 326 and the supporting wall b of the second connection end fixing portion 327 is set in the above-described manner₁When the cylindrical portion 421 of the first connection end 420 and the cylindrical portion 421 of the second connection end 430 are sandwiched by the support wall b, both the key-shaped portion 425 of the first connection end 420 and the key-shaped portion 425 of the second connection end 430 will be maintained in a state of not being sandwiched by the support wall b.

In this state, as shown in fig. 39, when the posture of the first heating part 400 is changed to the second posture, the setting of the first heating part 400 is completed. Here, the second posture is defined as a posture in which the first heating part 400 is disposed in parallel with the width direction of the through hole d on the first surface 426 of the key-shaped part 425. The second posture of the first heating part 400 may be a state in which the first heating part 400 is rotated by 90 ° about an axis in the longitudinal direction of the first heating part 400 from the state in which the first heating part 400 is in the first posture.

As described above, as the posture of the first heating part 400 is changed, each of the key shape parts 425 disposed at both side end parts of the first heating part 400 is closely attached to the support wall b, and thus the first heating part 400 can be fixed to the heater mounting part 325 in a state where the movement in the longitudinal direction thereof is restricted.

This corresponds to designing the shapes of the first heating part 400 and the heater installation part 325 such that the interval L between the supporting wall b of the first connection end fixing part 420 and the supporting wall b of the second connection end fixing part 430₁Satisfy L₁＝L_H1+2L_H4The relationship (c) to (d).

In addition, a spacing L between support wall b and outer wall f₂The following relationship is satisfied.

L₂≥L_H3

I.e. the spacing L between the support wall b and the outer wall f₂Is set to have a length longer than a length between the step 423 and the outermost end of the cylindrical portion 421.

When the interval L between the support wall b and the outer wall f is set in the above-described manner₂Between the supporting wall b and the outer wall f, a spacing L is formed₂The extension 422 and the cylindrical portion 421 are inserted into the space formed between the support wall b and the outer wall f in the above-described manner, and in this space, the connection between the cable and the connection end can be established, that is, when the interval L between the support wall b and the outer wall f is set in the above-described manner₂When this is done, sufficient space for inserting the extension 422 and the cylindrical portion 421 and connecting the cable and the connection end can be provided.

As described above, when the setting of the first heating part 400 is completed, the setting of the emitter 440 may be performed. The transmitter 440 arrangement may be implemented in a form such that the transmitter 440 is coupled to the shield 328.

Then, the glass 335 (refer to fig. 31) is seated on the seating surface 332 of the door frame 330 and fixed by the stopper 324 and the restricting rib 323, thereby completing the setting of the glass 335.

The connection work of the connection terminal and the cable may be performed before or after the glass 335 is disposed. When these processes are all completed, a unit body in which the door frame 320, the first heating part 400, the emitter 440, the protective grill 450, and the glass 335 are assembled into one unit may be provided. As described above, if the door frame 320 in which the first heating part 400, the emitter 440, the protective grill 450, and the glass 335 are assembled is coupled to the door top surface part 310 (see fig. 1), the first heating part 400, the emitter 440, the protective grill 450, the glass 335, and the like may be assembled to the door 300 at one time.

Although not shown, when the setting work of the first heating part 400 and the connection work of the connection terminals to the cables are completed, covers may be covered on the top opened in the first and second connection terminal fixing parts 326 and 327 (refer to fig. 31) to protect the connection terminals. In order to achieve the coupling between the first and second link end fixing parts 326 and 327 and the cover, a coupling protrusion i may be provided at the top of the cover a to protrude therefrom.

The door frame 320 of the present embodiment having the above-described configuration can provide the following effects.

First, the door frame 320 may be coupled to a lower portion of the door top surface part 310 to cover the lower portion of the door top surface part 310 such that the cable installation parts 340 and 345 (refer to fig. 7) disposed inside the door top surface part 310 and the cables provided at the cable installation parts 340 and 345 are not exposed to the outside.

The door frame 320 can be coupled to a lower portion of the door top surface portion 310 by coupling members to the cable attachment portions 340 and 345 and the like in a state where portions where the cable attachment portions 340 and 345 are disposed are covered with the coupling portions 321. As described above, the door frame 320 coupled to the lower portion of the door top surface portion 310 can cover the cable installation portions 340 and 345 (see fig. 7) disposed inside the door top surface portion 310 and the cables provided in the cable installation portions 340 and 345, so that the cable installation portions 340 and 345 and the cables are not exposed to the outside and can be easily separated from the door 300 when necessary. Such a door frame 320 can safely protect various components inside the door top surface part 310 and can be easily separated when needed, and thus, can contribute to that maintenance work of the cooking apparatus can be easily and quickly performed.

Second, the door frame 320 provides a frame that can assemble the first heating part 400, the respective components associated with the first heating part 400, and the glass 335 into a single unit, thereby contributing to more efficient component management and manufacturing management.

In the door frame 320, structures for fixing the first heating part 400, the emitter 440, and the protective grill 450 to the door frame 320 are provided in addition to the structures for fixing the glass 335 to the door frame 320.

Accordingly, one unit for coupling the glass 335, the first heating part 440, the emitter 440, and the protective grill 450 to the door frame 320 may be provided, and the glass 335, the first heating part 440, the emitter 440, and the protective grill 450 may be coupled to the door at one time by coupling the door frame 320 to the lower portion of the door top surface part 310.

Third, the door frame 320 provides a structure that allows the first heating part 400 to be easily and rapidly installed at the door frame 320, and thus, it can contribute to more efficient installation work of the first heating part 400.

According to the present embodiment, first, one side end portion of the first heating part 400 is sandwiched between any one of the first and second connection end fixing portions 326 and 327, and the first heating part 400 is moved in the longitudinal direction thereof to sandwich both side end portions of the first heating part 400 between the first and second connection end fixing portions 326 and 327, respectively, and then, the installation of the first heating part 400 can be completed only by a simple and easy operation of rotating the first heating part 400.

At this time, the first and second connection end fixing portions 326 and 327 are not provided to have directionality, and therefore, even if one end portion of the first heating unit 400 is first sandwiched between one of the first and second connection end fixing portions 326 and 327, the first heating unit 400 can be provided without any trouble.

As described above, the door frame 320 enables the first heating part 400 setting work to be more efficiently performed, and thus it can contribute to easier and faster performing the manufacturing work of the cooking apparatus and the maintenance work performed to replace the first heating part 400.

While the invention has been described with reference to the embodiments shown in the drawings, which are intended to be exemplary only, it will be understood that various modifications and other equivalent embodiments may be made from the described embodiments by those skilled in the art. Therefore, the true technical scope of the present invention will be defined by the appended claims.