阅读说明：本技术 Ptc加热装置及其制造方法 (PTC heating device and method for manufacturing same ) 是由 安德雷斯·克林格比尔 迪特马尔·温斯多夫 卡尔斯滕·鲍尔茨 于 2021-05-14 设计创作，主要内容包括：本发明涉及一种具有加热单元的PTC加热装置,该加热单元包括PTC元件和与PTC元件电连接的导体元件,导体元件被容纳在加热器壳体中。为了减少装配步骤并简化装配过程,本发明提出,相比于加热单元,将加热器壳体尺寸偏小地制造,使得加热单元在引入加热器壳体中之后在预紧力下被保持加热器壳体的彼此相对的壁部之间。在根据本发明的方法中,当将加热单元引入到加热器壳体中时,加热器壳体相应弹性地扩宽。(The present invention relates to a PTC heating device having a heating unit including a PTC element and a conductor element electrically connected to the PTC element, the conductor element being accommodated in a heater case. In order to reduce the number of assembly steps and simplify the assembly process, the invention proposes that the heater housing be made smaller in size than the heating unit, so that the heating unit is held under pretension between the mutually opposite wall sections of the heater housing after introduction into the heater housing. In the method according to the invention, the heater housing is correspondingly elastically widened when the heating unit is introduced into the heater housing.)

1. A PTC heating device with a heating unit (22), comprising a PTC element (6) and a conductor element (12) which is in electrically conductive abutment with the PTC element and which is accommodated in a heater housing (20), characterized in that the heater housing (20) is made undersized with respect to the heating unit (22) such that the heating unit is held under pretension between mutually opposed wall sections (34) of the heater housing (20) after introduction into the heater housing (20).

2. PTC heating device according to claim 1, wherein mutually opposing wall sections (34) of the heater housing (20) are provided with an electrically insulating coating.

3. PTC heating device according to claim 1, wherein the heating unit (22) is provided on its outside with an electrically insulating layer (18) which is connected to the PTC element (6) and/or the corresponding conductor element (12).

4. PTC heating device according to claim 1, wherein the heater housing is formed from a flat tube (20) closed on one side, the inner faces (34) of the heater housing which are opposite one another and bear against the heating unit (22) in a heat-conducting manner being at a smaller distance from one another than the thickness of the heating unit (22).

5. PTC heating device according to claim 4, wherein the lead-in openings (32) of the flat tubes (20) have a clear width which is greater than the distance between the inner faces (34).

6. PTC heating device according to claim 4, wherein the heating unit (22) has a frame-shaped housing (2) which joins the at least one PTC element (6), the conductor strip (12) and optionally an insulating layer (18) provided against the PTC element (6) into one unit and which is projected by contact tongues (14), the contact tongues (14) being connected to the conductor strip (12) in an electrically conductive manner with different polarities in order to energize the PTC element (6), and the frame-shaped housing (2) has wedge-shaped, preceding frame beams (26) which can be introduced first into the introduction opening (32) and which are configured in a manner suitable for spreading apart the inner face (34).

7. PTC heating device according to claim 6, wherein the frame shaped housing (2) has a rear frame beam (28) which is inserted as a plug into the flat tube (20).

8. PTC heating device according to claim 7, further comprising a sealing flange (24) which seals the flat tube (20) at least on the periphery in the region of the introduction opening (32).

9. PTC heating device according to claim 8, wherein the sealing flange (24) is arranged at the height of the rear frame beam (28).

10. A method for manufacturing a PTC heating device with a heater housing (40), in which method a heating unit (22) comprising a PTC element (6) and a conductor element (12) in electrically conductive abutment with the PTC element is accommodated, characterized in that the heater housing (40) is elastically widened upon introduction of the heating unit (22) into the heater housing (40) such that mutually opposing wall sections of the heater housing (40) abut against the heating unit (22) under pretension after introduction of the heating unit (22) into the heater housing (40).

11. Method according to claim 10, wherein the heater housing (40) is formed by a flat tube (20) closed on one side, the inner faces (34) of the heater housing which lie opposite one another and bear against the heating unit (22) in a thermally conductive manner being at a smaller distance from one another than the thickness of the heating unit (22), the insertion opening (32) of the flat tube (20) having a clear width which is greater than the inner face (34), and the heating unit being introduced with a certain clearance into the insertion opening (32) and being pressed elastically outwards with increasing extent of the insertion movement, so that, in the mounted position, the heating unit (22) bears against the inner face (34) under pretension.

Technical Field

The present invention relates to a PTC (positive temperature coefficient) heating device having a heating unit that is accommodated in a heater case. The heater housing typically forms a heat dissipating surface that surrounds the PTC element and is isolated from the surrounding environment. The heater housing typically circumferentially surrounds the PTC element. The heater housing may be formed by a heating tube or a heating sleeve accommodating the heating unit.

Background

Such PTC heating devices are known from EP 2724086B 1, EP 2685784 a1, EP 1768457a1 or EP 2127924 a 1.

PTC heating devices of the aforementioned type are commonly used in heating devices for motor vehicles. The corresponding heating device has the task of generating heat and dissipating it as efficiently as possible onto the medium to be heated. The PTC heating device comprises a PTC element which is arranged in electrical contact in the heater housing. If the heater housing is made of metal, an insulation in the form of a film or a ceramic layer or a combination of both is provided between the PTC element and/or the contact metal plate placed thereon. In the present invention and in the prior art according to EP 1768457a1, the PTC elements are usually accommodated in a gas-tight or liquid-tight manner together with the conductor tracks in a heater housing which should have a relatively thin wall thickness in view of achieving good heat dissipation. Sometimes, the heater case should also be made of metal in view of electromagnetic shielding.

It is essential for good efficiency that the PTC element is connected in a good heat-conducting manner to the heat-dissipating outer side of the heater housing.

There are various possibilities that can achieve this.

According to EP 1768457a1, the PTC element is accommodated in a positioning frame which is shaped with a receptacle for the PTC element, which circumferentially surrounds the PTC element. The recess is covered on both sides with contact metal plates which directly contact the PTC element in an electrically conductive manner. On the side of the contact metal plate opposite the PTC element, there is an insulating layer made of a ceramic plate with a synthetic material film, which is supported against the positioning frame by means of an elastic seal, so that the pressing force acting from the outside acts at right angles to the main sides of the PTC element at the location of the above-mentioned configuration, and the pressing forces acting from the outside can be applied to one another, so that heat from the PTC element can be dissipated on the outer surface of the insulating layer with a low thermal resistance.

This configuration requires various components of the heating unit and therefore a large number of manufacturing steps and a function-dependent defect-free seal, in particular a permanent elasticity of the elastic seal. Furthermore, the elastic pretensioning force must be applied continuously from the outside.

Motor vehicles are exposed to severe vibrations. Motor vehicles are also used in areas with significantly different climates, and therefore the components are exposed to different temperatures. In this condition, a PTC heating device of the type described above must also be able to operate. Thus, the PTC heating device of a motor vehicle and the heating device to be further developed in particular according to the invention comprising the PTC heating device must operate without failure under such conditions, that is to say without failure during the expected driving time of the vehicle.

In an alternative embodiment known from EP 2127924 a1, the heating unit is first preassembled and then inserted into a U-shaped bag. Then, a wedge is also inserted into the U-shaped bag, by means of which the heat-dissipating main side of the PTC heating device abuts on the one hand against the inner face of the bag and on the other hand against the wedge, which in turn is formed of a material which conducts heat well and is in contact with the opposite inner face of the receiving bag. The receiving bag is formed inside the heating rib exposed in the heating chamber/circulating chamber.

This design also requires a large number of initially separately manufactured components which must be assembled and joined in a suitable manner in order to be able to dissipate heat well from the PTC element. The one-sided arrangement of the wedge-shaped element breaks the inherently ideal symmetrical dissipation of heat to the two main sides of the PTC element.

In an alternative solution known from EP 2428747 a1, the heating unit is inserted into a tubular heater housing, which is then filled with potting compound in order to achieve good heat dissipation from the PTC element to the outside of the heating tube.

This design also requires precise method guidance during the production of the heating device. The casting compound must also be hardened, so that a hardening time or a drying time must be inserted within the scope of the production process.

Disclosure of Invention

The present invention provides a PTC heating device which can be manufactured through several process steps. The PTC heating device and the method which can be used for manufacturing the same should be suitable for mass production of manufactured PTC heating devices with constant quality.

In view of this, the invention proposes a PTC heating device having the features of claim 1. In a manner known per se, a PTC heating device has a heating unit with a PTC element and a conductor element which is electrically connected to the PTC element. The conductor element can be covered with an external insulation, so that the current-carrying element of the PTC heating device does not directly abut in an electrically conductive manner against the heater housing accommodating the heating unit. The heating unit may comprise a positioning frame which circumferentially surrounds the PTC element and positions the contact metal plate and in an electrically conductive manner against the PTC element. The positioning frame can also hold and position electrical terminal tabs that open into the PTC element with different polarities to energize the PTC element and extend beyond the actual heating unit so that the electrical terminal tabs can electrically connect the heating unit. This connection is usually made by means of plug contacts on the terminal strip.

The heating unit is typically manufactured as a preassembled unit and assembly. Accordingly, the PTC element, the conductor strip and the usual terminal webs on the PTC element and, if appropriate, the positioning frame and the insulating layer, for example in the form of two insulating layers on opposite main sides, are joined to form a unit, for example by gluing or welding or by overmolding of a synthetic material which can form the positioning frame.

The heater case is made smaller in size than the heating unit. In particular, the heater housing has a thickness smaller than the heating unit. This thickness is typically the smallest extension thickness in a cross-sectional view through the heater housing, which is designed as a heating tube or heating sleeve. The other two extended thicknesses, i.e. the length and width of the heating unit, extend at right angles to the direction of extension of the thickness, the width and thickness being transverse to the cross-sectional view, and the length extending at right angles to the cross-sectional view. This length generally corresponds to the extension of the heating unit in the insertion direction into the heating tube or heating sleeve. Thus, prior to assembly, the main sides of the heating unit are further away from each other than the distance between the thermally conductive inner faces of the heating tube or heating sleeve to be contacted.

Therefore, when the heating unit is introduced into the heater case, the heater case is elastically widened. The mutually opposite wall portions of the heater housing, which are thus elastically spaced apart from one another, i.e. widened, abut in a heat-conducting manner against the main side of the heating unit. Thus, after the introduction of the heating unit and only as a result of the introduction of the heating unit into the heater housing, the wall of the heater housing abuts against the heating unit under pretension. As a result, the individual positions of the heating unit are pressed against one another, which improves the coupling of the power current into the PTC element and the dissipation of heat from the PTC element.

It goes without saying that the individual positions of the heating unit can also bear against one another with an externally acting pressure during the production of the heating unit, for example can be connected to one another in a cohesive manner by means of an adhesive. The heating unit used in the electric heating apparatus according to the present invention may be manufactured using a method generally known in the art. Due to the pretensioning force introduced by the heater housing, the individual positions of the heating unit are also only temporarily connected to one another, for example by means of wax or adhesive which softens under heat, so that the heating unit is provided as a unit in a manner which enables preassembly. However, the connection between the various positions of the heating unit does not remain continuous during operation of the heating device.

Subsequently, no further measures need to be taken, for example deformation of the heater housing after introduction of the heating unit according to EP 2724086B 1 and/or casting according to EP 2428747 a1, in order to transfer the heat from the heating unit to the outer surface of the PTC heating device with good heat conduction. Due to the pretensioning force caused solely by the introduction, the heating unit rests against the inner surface of the heater housing. After joining the inner face and the heating unit, the inner face directly contacts the heating unit. In particular, a binder or a thermally conductive potting compound is absent between the inner surface of the elastically widened wall and the corresponding main side of the heating unit.

The above-mentioned main side of the heating unit is the largest surface of the PTC element, which is generally in the shape of a rectangular parallelepiped. The main side faces are typically at least 5 times larger than each of the edge faces extending at right angles to the main side faces, which edge faces connect the main side faces to one another and define the circumference of the PTC element.

By the proposal according to the invention, a PTC heating device is proposed which can be produced with less weight and with fewer components in a reproducible and economical manner.

The aforementioned insulating portion may be provided as a coating on the inner sides of the wall portions opposed to each other. Alternatively or additionally, the insulation can surround the main side of the heating unit as an outer layer and directly abut on the inner sides of the mutually opposite wall sections of the PTC element or of the mutually opposite wall sections of the contact metal plates for energizing the PTC element.

The invention also enables the manufacture of PTC heating devices according to the modular principle. The heater housing may be inserted into the structure of the previous stage first and then the components of the heating device are joined into the heater housing by pressing the heating unit, or the entire PTC heating device may be preassembled and inserted into the construction of the structure of the previous stage.

The invention can be realized in particular by a thin-walled heater housing made of sheet metal or other material with good heat conductivity, which can permanently store and maintain a certain elastic pretension.

According to a preferred refinement of the invention, the heater housing is formed from a flat tube closed on one side, the inner faces of which that are opposite one another and which contact the heating unit in a heat-conducting manner having a distance to one another which is smaller than the thickness of the heating unit. The inner face may be designed to be electrically insulating. The inner face is usually formed from the flat tube itself and is made of metal. The flat tubes are closed from the underside and are typically exposed to a heating chamber depending on the type of heating rib. The flat tubes are usually produced in advance with small dimensions, so that when the heating unit is introduced, the heater housing widens and the inner face of the heater housing bears with a certain pretension against the heat dissipation surface of the heating unit. The widening of the flat tube takes place in the elastic region. The elastic deformation thus acts as a permanent pretension on the free plane or outer surface of the heat sink.

The heater housing or the flat tube can be provided with the heating unit and then connected to the partition wall of the PTC heating device. Alternatively, the heater housing or the flat tube may be first connected to the partition wall, and then the heating unit may be inserted into the receiving bag formed by the heater housing or the flat tube from the side of the connection chamber. The last-mentioned variant is particularly suitable when the heater housing is connected to the partition wall in a material-locking manner, for example by soldering or welding, or when the partition wall is formed integrally with the heater housing to form heating ribs which project from the partition wall into the heating chamber. The partition wall and/or the heater housing are preferably formed from metal, in particular preferably from sheet metal.

In view of the simplified assembly, a preferred development of the invention provides that the inlet openings of the flat tubes are designed with a larger clear width than the distance between the inner faces. The introduction inlet is usually larger than the thickness of the heating unit, so that, for example, the heating unit can be introduced into the introduction inlet with play. In the scope of the assembly, the heating unit can be easily introduced into the introduction inlet due to the larger size of the introduction inlet. Only when the insertion movement continues, an elastic pretensioning force of the inner surface is generated, which in the assembled state rests in a thermally conductive manner against the heating unit.

According to a further preferred embodiment of the invention, the heating unit has a frame-shaped housing. The frame-shaped housing is usually composed of a synthetic material. The housing forms an accommodation space which itself accommodates at least one PTC element. The conductor track is connected to the PTC element in an electrically conductive manner. Usually, the main sides of the PTC elements are covered with an insulating layer, which is joined by a frame-shaped housing. Therefore, the heating unit is formed as a unit that can be processed by heating. The contact tongues project from the frame-shaped housing and are connected to the conductor strip in an electrically conductive manner with different polarities in order to energize the PTC elements.

According to a preferred refinement, the frame-shaped housing is preferably provided with wedge-shaped, front frame beams. The preceding frame bar is the frame bar which is first introduced into the flat tube when the heating unit is introduced into the flat tube. According to the development discussed here, the preceding frame beam is configured in a wedge shape, so that the inner surface widens elastically when the heating unit is introduced into the flat tube. The wedge shape of the preceding frame beam is typically chosen such that the maximum thickness of the frame beam corresponds to the distance between the outer surfaces of the heating units. If the heating unit has an insulating layer at its outer side, for example in the form of a ceramic plate, the maximum thickness of the preceding frame beam corresponds to the distance between the outer surfaces of the free planes of the formed heating unit of the insulating layer.

Therefore, when the heating unit is introduced into the flat tube, the preceding frame beam can elastically widen the flat tube. The mechanical work required here therefore does not have to be performed by the functional elements of the heating unit for heat generation and dissipation.

The frame-shaped housing preferably has a rear frame bar, which is inserted as a plug into the flat tube. The plug reinforces the flat tube in the region of the inlet opening. The sealing effect of the sealing flanges, which are usually made of a flexible synthetic material and are provided on the outer peripheral surfaces of the flat tubes to seal the flat tubes on the outer peripheries, is thereby improved. The sealing sleeve flange is therefore preferably arranged at the level of the rear frame beam. The frame beam at the back may be thicker to form a plug than the frame beam at the front.

Drawings

Further details and advantages of the invention emerge from the following description of an embodiment in conjunction with the accompanying drawings. In the drawings:

FIG. 1 shows a perspective exploded view of an embodiment of a heating unit;

fig. 2 shows a perspective side view of the PTC heating apparatus of the embodiment shown in fig. 1 before engagement with the flat tubes;

fig. 3 shows the representation according to fig. 2 in a longitudinal sectional view;

fig. 4 shows the view according to fig. 3 after engagement;

fig. 5 shows a perspective side view of an embodiment of a PTC heating device.

Detailed Description

The exemplary embodiment according to fig. 1 shows a housing 2 made of a synthetic material, which is designed in the shape of a frame and forms an accommodating space 4 for accommodating a PTC element 6. The two PTC elements 6 are each designed in the form of a cuboid and have mutually opposite surfaces 8 which form the main side of the PTC element 6, which primarily emits heat, and are connected to one another by circumferential end sides 10. Opposite the surface 8, conductor strips in the form of contact metal plates 12 are shown, each having a contact tongue 14 formed from a plate-shaped material by stamping and bending. Corresponding to these contact tongues 14, a support 16 is provided on the housing 2, which support itself accommodates the respective contact tongue 14 such that the free end of the contact tongue 14 protrudes out of the housing 2. These free ends of the contact tongues 14 serve to energize the PTC element 6 in the housing 2. After the insertion of the contact tongues 14, the support 16 is covered by a cover 17, which cover 17 is fastened to the housing by means of thermal caulking of pins projecting from the housing 2 through holes in the cover.

An insulating layer in the form of an alumina plate is shown by reference numeral 18, which has a base area that is larger than the base area of the contact metal plate 12 (without the contact tongues 14) and which at least partially covers the frame-shaped housing 2 in the joined state.

The unit discussed above is first prefabricated and then inserted into a metal housing 20 formed from a plate-shaped material, through which a sealing flange 22 made of a flexible synthetic material is drawn off from the end side in order to introduce a heating element designated by reference numeral 24 into a receiving pocket of a partition wall as described, for example, in DE 102016224296a 1.

The housing 2 has a front frame beam, which is designated by reference numeral 26 and tapers towards the front and is thus configured in a wedge shape. The tapered ends point in the direction of the flat tubes 20 in fig. 1. The rear frame beam, which is arranged opposite the front frame beam 26 and projects only beyond the support 16, is characterized in fig. 1 by the reference numeral 28. The widened end of the preceding frame beam 26 runs without steps around the heat-dissipating free plane 30. In the present case, this free plane 30 is formed by the outer surface of the respective alumina plate 18.

The wedge shape of the preceding frame beams 26 allows the heating unit 22 to be centered with insertion into the receiving pocket 31 formed by the flattened tube 20. This centering is shown in fig. 3. It is apparent that the central longitudinal axis of the heating unit 22 is aligned with the central longitudinal axis of the flat tube 20. The preceding frame beam 26 is located with little play in an inlet opening 32 of the flat tube 20, which opens into the receiving pocket 31.

The flat tubes 20 are generally formed by deep drawing an initially cylindrical blank whose major sides are reformed so that the inner faces 34 are reformed toward one another. Starting from the previous embodiment shown in fig. 1, in which the frame beams 26 are already located in the insertion openings 32, the heating units 22 are pushed into the flat tubes 20. The preceding frame beam 26 presses the inner surface 34, which delimits the receiving pocket 31 and which, according to the sectional view of fig. 3, has a spacing that is smaller than the thickness of the heating unit 22, outward. The inner face 34 is elastically pretensioned. With continued insertion movement, the inner face 34 rests against the free plane 30. The introduction movement ends when the preceding frame beam 26 hits the lower closed end of the receiving pocket 31 or the widened flange of the following frame beam 28 abuts from the end side onto the introduction opening 32. As can be seen in fig. 4, the inner face 34 then bears against the free plane 30 over its full face as a result of the elastic deformation. Therefore, good heat dissipation from the heat generated by the PTC elements 6 up to the outer surfaces of the flat tubes 20 is ensured. After this engagement, the sealing flange 24 is pushed onto the flat tube 20. The sealing flange 24 then bears circumferentially against the flat tube 20 at the level of the trailing frame beam 28.

Before the introduction of the heating unit 22, the inner face 34 can be shaped slightly convex, that is to say convex in the direction of the receiving bag 31.

Fig. 5 shows a perspective top view of the heating device housing designated by reference numeral 40 of an electric heating device designed as a water heater. The heating device housing 40 has a housing slot element 42 made of a synthetic material. The heating device housing 40 is designed with an inlet support 44 and an outlet support 46, which in the present case are integrally formed on the housing slot element 42. The supports 44, 46 are designed as hose connection supports and form an inlet opening 48 or an outlet opening 50 to the heating chamber, which is identified by reference numeral 52.

The heating chamber 52 is separated from the connection chamber 54 and isolated from it by a partition wall 56 made of a synthetic material. The partition walls 56 form female insertion element receptacles 58 for the PTC heating units 22, which are each sealingly inserted into the female insertion element receptacles 58 by means of a sealing ring 24 and are supported on a bottom 62 of the housing trough element 4. Reference numeral 64 designates a control housing which is described in further detail in DE 102019205848.

Alternatively, instead of the sealing ring, the flat tube 20 can also be connected directly to the partition wall 56 in a material-locking manner, for example by gluing or soldering. The partition wall 56 may be formed of metal. It is only important that the flat tubes 20 are connected to the partition wall 56 in a fluid-tight manner, but the flat tubes 20 can also be formed integrally with the partition wall 56.

List of reference numerals

2 casing

4 accommodation space

6 PTC element

8 surface of

10 end side surface

12 contact metal plate/conductor strip

14 contact tongue

16 support piece

17 cover (casing cover 24 in EP 125965)

18 alumina plate

20 flat tube

22 heating unit

24 sealing flange

26 preceding frame beam

28 rear frame beam

30 free plane

31 receiving bag

32 introduction opening

34 inner face

40 heating device housing

42 housing trough member

44 entrance support

46 outlet support

48 inlet opening

50 outlet opening

52 heating chamber

54 connecting chamber

56 dividing wall

58 recessed insert element receptacle

62 top part

64 control device shell