阅读说明：本技术 搅拌杯组件和食物料理机 (Stirring cup subassembly and food processor ) 是由 冯江平 王志锋 雷俊 马志海 区达理 刘经生 徐少承 于 2018-06-13 设计创作，主要内容包括：本发明公开一种搅拌杯组件和食物料理机,所述搅拌杯组件包括：杯体；杯座,所述杯座连接于所述杯体的下端；以及隔热消磁组件,所述隔热消磁组件位于所述杯体和杯座之间,且所述隔热消磁组件一表面与杯体的下端抵接,另一表面与所述杯座抵接。本发明技术方案旨在降低底部受热体传递到杯座的热量,防止杯座融化,方便用户使用。(The invention discloses a stirring cup assembly and a food processor, wherein the stirring cup assembly comprises: a cup body; the cup seat is connected to the lower end of the cup body; and the heat insulation and demagnetization component is positioned between the cup body and the cup seat, one surface of the heat insulation and demagnetization component is abutted against the lower end of the cup body, and the other surface of the heat insulation and demagnetization component is abutted against the cup seat. The technical scheme of the invention aims to reduce the heat transferred from the bottom heated body to the cup holder, prevent the cup holder from melting and facilitate the use of a user.)

1. The utility model provides a stirring cup subassembly, is applied to food processor, its characterized in that, stirring cup subassembly includes:

a cup body;

the cup seat is connected to the lower end of the cup body; and

the heat insulation and demagnetization component is positioned between the cup body and the cup seat, one surface of the heat insulation and demagnetization component is abutted against the lower end of the cup body, and the other surface of the heat insulation and demagnetization component is abutted against the cup seat.

2. The blender cup assembly of claim 1, wherein said thermally insulated degaussing assembly comprises a thermally insulating layer and a degaussing layer stacked with said thermally insulating layer, said thermally insulating layer being disposed adjacent said cup base, said degaussing layer being disposed adjacent said cup body;

or the demagnetizing layer is arranged close to the cup seat, and the heat insulation layer is arranged close to the cup body.

3. The stirring cup assembly of claim 2, wherein said demagnetizing layer is made of a diamagnetic material and said insulating layer is made of a heat insulating material.

4. A blender cup assembly as recited in claim 3, wherein said diamagnetic material is aluminum.

5. The blender cup assembly of claim 1 wherein said thermally insulated degaussing assembly comprises at least a degaussing layer, said degaussing layer being made of a diamagnetic material.

6. The stirring cup assembly according to any one of claims 2 to 4, wherein the thickness L of the demagnetizing layer is greater than or equal to 0.5 mm.

7. The stirring cup assembly as recited in claim 1, wherein the cup body comprises a cup body with two open ends and a cup bottom plate connected to one end of the cup body and blocking one of the two open ends, the cup body and the cup bottom plate together form a containing cavity for containing food, and one surface of the heat insulation and demagnetization assembly abuts against the cup bottom plate.

8. The blender cup assembly of claim 7, wherein said cup bottom comprises a bottom plate and a side plate disposed around said bottom plate, said bottom plate and said side plate are integrally formed, said side plate is fixedly connected to said cup body, said thermal-insulating degaussing assembly is disposed around said side plate, and a surface of said thermal-insulating degaussing assembly abuts against a portion of said side plate.

9. The blender cup assembly of claim 8, wherein said side plate further comprises a top plate segment, said top plate segment being annularly disposed and attached to said side plate, an upper surface of said adiabatic demagnetization element abutting a lower surface of said top plate segment.

10. The blender cup assembly of claim 9, wherein the sum H of the height of said side plate and the thickness of said base plate is: h is more than or equal to 1 mm.

11. A food processor comprising a main body and a stirring cup assembly connected to the upper end of the main body, wherein the main body further comprises a coil panel for heating the cup body, and the stirring cup assembly comprises the stirring cup assembly as claimed in any one of claims 1 to 10.

Technical Field

The invention relates to the technical field of stirring cup assemblies, in particular to a stirring cup assembly and a food processor with the same.

Background

The IH (Indirect Heating) technique heats by using magnetic force generated when current flows to a Heating coil, and the Heating effect is more uniform than that of the conventional Heating. The food processor is generally divided into a host machine and a cup, wherein the host machine comprises a motor, a heating wire coil, a circuit board, a shell and the like; the cup comprises a cup cover, a glass cup, a bottom heat receiver, a plastic sealing cup seat and the like. As the temperature of the bottom heated body of the wall breaking machine is higher during IH heating, the temperature of the part of the bottom heated body, which is contacted with the plastic cup seat, can reach the plastic softening temperature (260 ℃), and the cup seat melts to cause the problems of water leakage of the cup and the like, which is inconvenient for users to use.

Disclosure of Invention

The invention mainly aims to provide a stirring cup assembly, which aims to reduce the heat transferred from a bottom heated body to a cup seat, prevent the cup seat from melting and bring convenience to users.

In order to achieve the above object, the present invention provides a stirring cup assembly for a food processor, the stirring cup assembly comprising:

a cup body;

the cup seat is connected to the lower end of the cup body; and

the heat insulation and demagnetization component is positioned between the cup body and the cup seat, one surface of the heat insulation and demagnetization component is abutted against the lower end of the cup body, and the other surface of the heat insulation and demagnetization component is abutted against the cup seat.

Optionally, the insulated degaussing assembly comprises a thermal insulation layer and a degaussing layer stacked with the thermal insulation layer, the thermal insulation layer is disposed adjacent to the cup base, and the degaussing layer is disposed adjacent to the cup body;

or the demagnetizing layer is arranged close to the cup seat, and the heat insulation layer is arranged close to the cup body.

Optionally, the demagnetizing layer is made of a diamagnetic material, and the heat insulating layer is made of a heat insulating material.

Optionally, the diamagnetic material is aluminum.

Optionally, the thickness L of the demagnetizing layer is more than or equal to 0.5 mm.

Optionally, the heat-insulating degaussing assembly at least comprises a degaussing layer, and the degaussing layer is made of a diamagnetic material.

Optionally, the cup body comprises a cup body with two openings at two ends and a cup base plate which is connected to one end of the cup body and blocks one of the openings, the cup body and the cup base plate together form a containing cavity for containing food materials, and one surface of the heat insulation and demagnetization component is abutted to the cup base plate.

Optionally, the cup bottom plate includes a bottom plate and a side plate surrounding the bottom plate, the bottom plate and the side plate are of an integral structure, the side plate is fixedly connected to the cup body, the heat-insulating degaussing assembly is disposed surrounding the side plate, and one surface of the heat-insulating degaussing assembly abuts against a portion of the side plate.

Optionally, the side plate further includes a top plate segment, the top plate segment is annularly disposed and connected to the side plate, and an upper surface of the thermal insulation and demagnetization component abuts against a lower surface of the top plate segment.

Optionally, a sum H of the height of the side plate and the thickness of the bottom plate is: h is more than or equal to 1 mm.

The invention also provides a food processor, which comprises a host and a stirring cup assembly connected to the upper end of the host, wherein the host also comprises a coil panel, the coil panel heats the cup body, and the stirring cup assembly comprises:

a cup body;

the cup seat is connected to the lower end of the cup body; and

the heat insulation and demagnetization component is positioned between the cup body and the cup seat, one surface of the heat insulation and demagnetization component is abutted against the lower end of the cup body, and the other surface of the heat insulation and demagnetization component is abutted against the cup seat.

According to the technical scheme, the cup body and the cup seat are arranged, the heat insulation and demagnetization component is accommodated between the cup bottom plate and the cup seat, when the cup body is heated, the heat insulation and demagnetization component is arranged between the cup bottom plate and the cup seat, so that the cup seat is prevented from being in direct contact with the cup bottom plate, the temperature rising speed of the cup seat is reduced, and the electromagnetic wave has high energy consumption when passing through the heat insulation and demagnetization component, so that the cup body is not well heated by the electromagnetic wave when being abutted and covered by the heat insulation and demagnetization component, the temperature of the part of the cup bottom plate covered by the heat insulation and demagnetization component is lower, and the temperature rising speed of the cup seat is further reduced. Therefore, the technical scheme of the invention can reduce the heat transferred from the cup body to the cup seat, prevent the cup seat from melting and facilitate the use of a user.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a partial cross-sectional view of one embodiment of a blender cup assembly in accordance with the present invention;

FIG. 2 is a schematic structural view of an embodiment of a blender cup assembly according to the present invention;

FIG. 3 is a schematic view of another embodiment of a blender cup assembly;

FIG. 4 is a schematic structural diagram of a food processor according to an embodiment of the present invention;

FIG. 5 is a schematic structural view of an embodiment of a base plate of the blender cup assembly according to the present invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)
				100	Stirring cup assembly	40	Containing cavity
10	Cup body	50	Thermal-insulated demagnetization subassembly
				11	Cup body	51	Thermal insulation layer
111	Handle bar	53	Demagnetizing layer
				20	Stirring knife	70	Cup holder
13	Cup base plate	71	Through hole
				131	Base plate	73	Mounting table
133	Side plate	200	Food processor
				1331	Roof segment	210	Coil panel
1333	Mounting plate segment	230	Main unit

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The present invention provides a blender cup assembly 100.

Referring to fig. 1 to 5, the stirring cup assembly 100 according to the present invention is applied to a food processor 200, and the stirring cup assembly 100 includes:

a cup body 10;

a cup holder 70, wherein the cup holder 70 is connected to the lower end of the cup body 10; and

and the heat insulation and demagnetization component 50 is positioned between the cup body 10 and the cup seat 70, one surface of the heat insulation and demagnetization component 50 is abutted against the lower end of the cup body 10, and the other surface of the heat insulation and demagnetization component 50 is abutted against the cup seat 70.

According to the technical scheme, the cup body 10 and the cup seat 70 are arranged, the heat insulation and demagnetization component 50 is accommodated between the cup bottom plate 13 and the cup seat 70, when the cup body is heated, the heat insulation and demagnetization component 50 is arranged between the cup bottom plate 13 and the cup seat 70, so that the cup seat 70 is prevented from being in direct contact with the cup bottom plate 13, the temperature rise speed of the cup seat 70 is reduced, and the electromagnetic wave has high energy consumption when passing through the heat insulation and demagnetization component 50, so that the cup body is not well heated by the electromagnetic wave when being abutted and covered by the heat insulation and demagnetization component 50, the temperature of the part of the cup bottom plate 13 covered by the heat insulation and demagnetization component 50 is lower, and the temperature rise speed of the cup seat 70 is further reduced. Therefore, the technical scheme of the invention can reduce the heat transferred from the cup body to the cup seat 70, prevent the cup seat 70 from melting and facilitate the use of a user.

In an embodiment of the present application, the cup body 10 is substantially cylindrical with two openings, and the sidewall of the cup body 10 is further provided with a handle 11, and the handle 11 is provided for a user to hold conveniently; the cup body 10 can be made of glass or other materials, so long as the processing is convenient. The cup chassis 13 is fixed at one end of the cup body 10 and seals an opening at one end of the cup body 10, so that the cup body 10 can contain food materials and the like; the cup chassis 13 is made of a material having a good heat conductivity, and may be made of a metal material or other organic materials, specifically, a steel material (#304 steel). The cup chassis 13 is also provided with a stirring knife 20 at one side of the accommodating cavity 40, and the stirring knife 20 is used for stirring and breaking the wall of the food.

In this embodiment, the heat insulation and demagnetization component 50 may be disposed in a ring shape, so that the cup chassis 13 and the cup holder 70 are conveniently separated, and the coil panel 210 which is convenient to heat heats the cup chassis 13, and of course, the specific shape thereof may be a circular ring or a square ring, and may be selected according to the structures of the cup chassis 13 and the cup holder 70. The cup holder 70 is substantially cylindrical, and for the convenience of placement, its length in the radial direction increases from the cup body 10 toward a direction away from the cup body 10.

Referring to fig. 2, the cup holder 70 is further sunk to form a mounting platform 73, the through hole 71 is located in the middle of the mounting platform 73 and penetrates through the mounting platform 73, the cup bottom plate 13 is mounted on the mounting platform 73, and the adiabatic demagnetization module 50 is located between the cup bottom plate 13 and the mounting platform 73. The installation of the cup chassis 13 and the thermal insulation and demagnetization component 50 can be facilitated by the installation table 73, the distance between the cup chassis 13 and the coil panel 210 is closer, and the coil panel 210 can heat the cup chassis 13 conveniently. And when the part of the cup bottom tray 13 extends into the through hole 71, the cup bottom tray 13 and the mounting platform 73 form a closed mounting space, so that the heat insulation and demagnetization component 50 is well fixedly mounted, heat insulation and demagnetization are facilitated, and the cup holder 70 is prevented from melting.

Referring to fig. 1 to 3, further, the adiabatic demagnetization assembly 50 includes an insulation layer 51 and a demagnetization layer 53 stacked on the insulation layer 51, wherein the insulation layer 51 is disposed adjacent to the cup holder 70, and the demagnetization layer 53 is disposed adjacent to the cup 10;

alternatively, the demagnetizing layer 53 is disposed adjacent to the cup holder 70, and the thermal insulation layer 51 is disposed adjacent to the cup 10. In this embodiment, the thickness of the thermal insulation layer 51 can be set according to actual requirements, the thermal insulation layer 51 can be made of a material with thermal insulation function, such as ceramic, mica or glass, the demagnetizing layer 53 is made of a material with diamagnetism, such as aluminum, copper or lead, and the thicknesses of the thermal insulation layer 51 and the demagnetizing layer 53 are set according to the material of the selected material, as long as the thermal insulation and demagnetization effects are achieved well. The stacked heat insulation layer 51 and the demagnetizing layer 53 can provide the heat insulation and demagnetizing assembly 50 with good heat insulation and demagnetizing functions. When the heat insulation layer 51 is arranged adjacent to the cup seat 70 and the demagnetizing layer 53 is arranged adjacent to the cup body 10, the coil panel 210 generates a magnetic field after being electrified, so that electromagnetic waves pass through the through hole 71 to heat the cup body 10, the energy loss of the electromagnetic waves after passing through the demagnetizing layer 53 is large, the heating effect on the cup body 10 is poor, the part of the cup body 10 covered by the demagnetizing layer 53 can only transfer heat through the heat transfer of the cup body 10 per se, the temperature rising speed is slow, the heat insulation layer 51 separates the cup body 10 and the demagnetizing layer 53 from the cup seat 70, the contact heat transfer effect of the cup seat 70 with the cup body 10 and the demagnetizing layer 53 is lower; when the demagnetizing layer 53 is arranged adjacent to the cup seat 70 and the heat insulation layer 51 is arranged adjacent to the cup body 10, the electromagnetic wave energy can be firstly weakened through the demagnetizing layer 53 and then insulated through the heat insulation layer 51, and the effect of preventing the cup seat 70 from melting can also be better achieved. The user can set the heat insulation layer 51 and the degaussing layer 53 according to actual needs, as long as the cup holder 70 can be conveniently prevented from melting. Further, the diamagnetic material is aluminum. When an electromagnetic wave passes through a metal conductor, the attenuation intensity of the electromagnetic wave is different due to the difference in magnetic permeability of different metals. The properties of aluminium and steel are compared in this example with reference to the following table:

according to the formula of electromagnetic wave attenuation factor(f is electromagnetic wave frequency KHz, mu is magnetic permeability H/m of the metal material, and sigma is electric conductivity S/m of the metal material)

Calculated from the above table data, the attenuation factor α of aluminum is 5.06 x 10^-5The attenuation factor α of #304 steel was 369.187 ×.

The attenuation factor of aluminum is very small, based on its comparison with that of #304 steel at 25KHz frequency, so that the electromagnetic wave energy will be dissipated most in metallic aluminum.

And, according to the formula of heat energy W ═²R, the greater the same current resistance, the greater the power produced and the greater the heat produced. Under the condition of constant temperature, the formula R is rho L/s; where ρ is the resistivity, L is the length of the material, and S is the area. It can be seen that the magnitude of the electrical resistance of a material is proportional to the length of the material and inversely proportional to its cross-sectional area.

The resistivity (resistance) is a physical quantity used to represent resistance characteristics of various substances.

When the temperature is constant, the formula R is ρ L/S, and when the aluminum is the same as the #304 steel L and S according to the above table, the resistance of the #304 steel is 27.69 times greater than that of the aluminum, so that the amount of heat generated by the aluminum in the magnetic field strength of the same frequency is very small.

Referring to FIG. 3, further, the thickness L of the demagnetizing layer 53 is greater than or equal to 0.5 mm. The reduction of the effective section of the conductor due to the skin effect (when the magnetic lines of electromagnetic waves with a certain frequency cut metal to generate eddy currents, the frequency of the eddy currents is equal to that of the electromagnetic waves, and the reduction of the effective section of the conductor is equivalent to the reduction of the effective section of the conductor due to the fact that the magnetic fluxes of the interlinkage of the inner part and the edge part of the conductor are different, so that the current on the surface of the conductor is unevenly distributed, and the reduction of the effective section of the conductor can be expressed by the penetration depth, namely the radial depth which:(Δ -penetration depth (m), ω -angular frequency, ω ═ 2 pi f (rad/S), μ -permeability (H/m), γ -conductivity (S/m)). The penetration depth of aluminum is 0.513mm calculated according to the table above, the penetration depth of #304 steel is 0.238mm, the attachment effect of metal aluminum is more obvious than that of #304 steel when the unit area is the same, the heating area is thinner, and the minimum thickness of the shielding aluminum ring is 0.5 mm. The use of aluminum with a thickness of 0.5mm or more as the demagnetizing layer 53 can best shield electromagnetic waves without generating a high temperature, thereby best preventing the cup holder 70 from melting.

In an embodiment of the present application, the thermal-insulated degaussing assembly 50 at least includes a degaussing layer 53, and the degaussing layer 53 is made of a diamagnetic material. With such an arrangement, after the coil disk 210 is energized to generate a magnetic field, the electromagnetic wave passes through the through hole 71 to heat the cup body 10, and the electromagnetic wave passes through the demagnetizing layer 53 to cause a large energy loss and a poor heating effect on the cup body 10, so that the portion of the cup body 10 covered by the demagnetizing layer 53 can only transfer heat through the heat transfer of the cup body 10 itself, and the temperature rising speed is slow. And the cup body 10 and the cup seat 70 are directly isolated by the diamagnetic material, the direct contact heat transfer of the cup body 10 and the cup seat 70 is changed into indirect contact heat transfer, the heat transfer efficiency of the cup body 10 and the cup seat 70 is reduced, the cup seat 70 can be better prevented from melting, and the cost is lower.

Referring to fig. 2, 3 and 5, in an embodiment of the present application, the cup body 10 includes a cup body 11 with two open ends and a cup bottom plate 13 connected to one end of the cup body 11 and blocking one of the open ends, the cup body 11 and the cup bottom plate 13 together form a containing cavity 40 for containing food materials, and one surface of the thermal insulation and demagnetization component 50 abuts against the cup bottom plate 13. It can be appreciated that the provision of the cup bottom tray 13 facilitates heat conduction to process the food material in the receiving cavity 40, and so provides for convenient installation of the thermal and magnetic isolation assembly 50 to prevent the cup holder 70 from melting. And, in order to facilitate heating of the cup chassis 13, a portion of the cup chassis 13 may be received in the through hole 71, thereby making the main body 31 closer to the coil panel 210, thereby facilitating heat conduction.

In order to ensure the sealing connection between the cup body 10 and the cup bottom plate 13, a bottom plate sealing ring (not shown) is further disposed between the lower end of the cup body 10 and the mounting plate section 1333, and the lower end of the cup body 10 abuts against the cup bottom plate 13 sealing ring. When the cup body 10 is mounted, the lower end of the cup body 10 is pressed against the chassis seal 39, and the lower surface of the chassis seal 39 is pressed against the mounting plate section 1333, thereby sealing the joint between the cup body 10 and the cup chassis 13.

In one embodiment, the outer wall surface of the cup body 10 is provided with a first threaded section (not shown), and the cup holder 70 is provided with a second threaded section (not shown), wherein the first threaded section is in threaded connection with the second threaded section to connect the cup body 10 with the cup holder 70.

That is, the cup body 10 and the cup holder 70 are fixedly connected by a threaded connection, and it can be understood that the cup body 10 is generally made of glass, and the processing state of food in the cup body 10 can be clearly observed by using glass, and meanwhile, the glass is also convenient to clean. The cup body 10 can also be made of stainless steel or plastic. Of course, the cup body 10 is made of stainless steel to enhance the structural strength of the cup body 10, so that the cup body 10 is not easily damaged. The cup body 10 made of plastic is convenient to process and form.

Further, the cup bottom plate 13 includes a bottom plate 131 and a side plate 133 surrounding the bottom plate 131, the bottom plate 131 and the side plate 133 are an integral structure, the side plate 133 is fixedly connected to the cup body 11, the heat insulation and demagnetization component 50 is disposed surrounding the side plate 133, and a surface of the heat insulation and demagnetization component 50 abuts against a portion of the side plate 133. Set up bottom plate 131 and curb plate 133 and both can provide installation space for thermal-insulated demagnetization subassembly 50, can make the cup chassis 13 can be better heated by coil panel 210 again, and it can be understood that, in order to heat cup chassis 13, when bottom plate 131 stretches into through hole 71, bottom plate 131, curb plate 133 and mount table 73 form confined installation space, make thermal-insulated demagnetization subassembly 50 fixed mounting well to conveniently insulate against heat and the demagnetization, prevent that cup stand 70 from melting.

Referring to fig. 1 and 2, the side plate 133 further includes a top plate section 1331, the top plate section 1331 is disposed in a ring shape and connected to the side plate 133, and an upper surface of the adiabatic demagnetization module 50 abuts against a lower surface of the top plate section 1331. The extended top plate section 1331 is arranged to facilitate abutting of the heat insulation and demagnetization component 50, so that the coil panel 210 is isolated from heating the top plate section 1331, the top plate section 1331 can only be heated through heat conduction of the side plate 133, the side plate 133 also provides heat for food materials in the accommodating cavity 40, and therefore the temperature of the top plate section 1331 is low, and the cup holder 70 is prevented from melting. The bottom plate 13, the side plate 133, the top plate section 1331 and the mounting plate section 1333 of the cup tray 13 may be integrally stamped and formed.

It can be understood that a mounting plate section 1333 may also extend from the top plate section 1331, and the mounting plate section 1333 is engaged with the inner sidewall of the cup holder 70, so as to facilitate the installation of the cup body 10.

Referring to fig. 5, further, a sum H of the height of the side plate 313 and the thickness of the bottom plate 311 is: h is more than or equal to 1 mm. It can be understood that the sum of the height of the side plate 313 and the thickness of the bottom plate 311 and/or the height of the side plate 313 is the installation height of the thermal insulation degaussing assembly 50, and the specific value is set according to the material selected by the thermal insulation degaussing assembly 50 as long as thermal insulation and degaussing are facilitated.

The present invention further provides a food processor 200, wherein the food processor 200 comprises a main body 230 and a stirring cup assembly 100 connected to the upper end of the main body 230, the main body 230 further comprises a coil panel 210, the coil panel 210 heats the cup body 10, and the stirring cup assembly 100 comprises:

a cup body 10;

a cup holder 70, wherein the cup holder 70 is connected to the lower end of the cup body 10; and

and the heat insulation and demagnetization component 50 is positioned between the cup body 10 and the cup seat 70, one surface of the heat insulation and demagnetization component 50 is abutted against the lower end of the cup body 10, and the other surface of the heat insulation and demagnetization component 50 is abutted against the cup seat 70.

Since the food processor 200 adopts all the technical solutions of all the embodiments, at least all the beneficial effects brought by the technical solutions of the embodiments are achieved, and no further description is given here. The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.