DE20121116U1 - Electric heating device for heating a liquid in a motor vehicle - Google Patents

Description

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pO/ta Patent Attorneys

Dipl. Phys. Ulrich Twelmeier Dr. techn. Waldemar Leitner Dr. phil. not. Rudolf Bauer-1990 Dipl./ng. Helmut Hubbuch-J 99 J European Patent Attorneys

EA01 E009DEU/MS01S137/TW-Dr.Mm/ms/21.12.2001 Fritz Eichenauer GmbH & Co. KG, Georg-Todt-Straße 1-3, D-76870 Kandel

Electric heating device for heating a liquid in a motor vehicle Description:

The invention relates to an electric heating device for heating a liquid in a motor vehicle.

In known heating devices for heating a liquid in a motor vehicle, for example for heating diesel fuel, a PTC heating element is directly surrounded by the fuel, as disclosed, for example, in DE 195 42 317.

This type of heating is very effective due to the favorable heat coupling of the heating element to the fuel, but can only be used with electrically non-conductive liquids, such as diesel fuel. For other liquids to be heated in the vehicle, in particular water or urea solution, which are electrically conductive and corrosive, this direct open electrical heating is not possible. DE 100 14 011 describes a heating device specifically for heating cooling water, in which the heat generated by PTC heating elements is transferred from a

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good heat-conducting material, such as aluminum, is transferred to the liquid to be heated. The disadvantage of such a heating device, which is modeled on a continuous flow heater, is that it is limited to heating coolant.

The object of the invention is therefore to provide a heating device for heating a liquid in a motor vehicle, which can be installed in a motor vehicle with only minor modifications to heat a wide variety of liquids at different locations.

This object is achieved by an electric heating device having the features specified in claim 1. Advantageous further developments of the invention are the subject of the subclaims.

A heating device with a metal housing that tightly encloses the heating element can be used as a compact heating cartridge for heating diesel fuel, as well as for heating cooling water or urea, which is required as an ammonia supplier for a catalyst. The tight metal housing protects the heating element from corrosion caused by the liquid. In order to ensure sufficient heat coupling of the heating element(s) contained in the heating element, the one or more heating elements are clamped into the housing, which has been compressed for this purpose, i.e. pressed in after the heating element has been inserted.

The one or more heating elements have two connection surfaces and are preferably designed as plates. One of these connection surfaces is in electrically conductive connection with the housing, while the other connection surface is electrically contacted by a connection which leads out of the housing and is connected to potential as intended. The connection is electrically connected to the housing, which is connected to ground as intended.

insulated. It can be designed, for example, as a ceramic plate which is provided with an electrically conductive layer on one side, or as a connecting fork or preferably as a connecting plate. Due to its flat connection with the heating element, a connecting plate advantageously leads to the best possible heat dissipation to the housing and thus to the liquid to be heated, even on the potential side of the heating element.

Electric heating devices in which a heating insert is pressed into a housing are known for heating water, for example for household appliances such as window cleaners as steam jets and are disclosed in DE 38 15 306 A1. In the heating device described in DE 38 15 306 A1, PTC heating elements are inserted in a frame made of electrically insulating material between two connecting plates bent outwards in the shape of a segment of a circle, and are covered with a plastic film which both electrically insulates the connections from the housing and holds the described structure together when it is inserted into the housing. After the heating insert consisting of PTC modules, frame and connecting plates and wrapped in the plastic film has been inserted into the housing, the housing is pressed in order to ensure better thermal coupling of the heating elements to the housing and thus to the liquid to be heated. The heating devices described in DE 38 15 306 A1 ensure sufficient heat coupling when operated with a mains voltage of 230V, but an even better heat coupling is required for operation with a vehicle voltage of 12V to 24V. In a heating device according to the invention, improved heat coupling is achieved by the housing being electrically connected to the heating element and the connecting plate being electrically insulated from the housing. Instead of covering the heating insert all around with a plastic film, which not only provides electrical insulation but also thermal insulation, in a heating device according to the invention the housing is connected to ground potential as intended. The advantage of the

Electrical contact between the heating element and the housing also ensures excellent thermal coupling.

The heating insert preferably has a frame which accommodates the heating element and fixes it in position. Such a frame makes it considerably easier to insert the heating insert into the housing and thus simplifies production. The frame preferably locks into the metal connecting plate in a form-fitting manner, so that the heating insert is advantageously easy to handle.

The heating insert is held together by the positive connection between the frame and the metal connecting plate and can therefore be inserted into the housing without any effort, without the parts slipping against each other. While a heating insert according to the state of the art, as described in DE 38 15 306 A1, is only held together by a covering made of plastic film, so that when inserting the heating insert into the housing, care must be taken to ensure that parts of the heating insert do not slide against each other, this problem is eliminated with a heating device according to the invention.

In order to insulate the connection plate, which is intended to be at a higher electrical potential than ground potential during operation, from the housing, the latter is preferably covered with an insulating layer on the side facing away from the heating element. This insulating layer can be designed as a varnish, for example, or, more cost-effectively, as a thin plate or film that is placed on the connection plate. The frame preferably has side walls that position and hold an insulating layer designed as a plate or film. The insulating layer is preferably made of ceramic, in particular aluminum oxide, since this has a relatively high thermal conductivity for an electrically insulating material. A plate offers the particular advantage of also being able to be locked to the frame, which further simplifies the stability of the heating insert.

Preferably, the frame is positively connected to a metallic contact plate. Such a metallic contact plate can be used advantageously to ensure a flat connection between the heating element and the housing, which ensures both electrical contact with low resistance and good thermal coupling of the heating elements to the housing.

To protect against corrosive liquids, such as urea solution, the housing is preferably coated with a layer. Particularly suitable are inorganic, non-metallic layers, which can be applied, for example, as glass-like layers made of polycondensed silanes in a sol-gel process, or carbon or SiO ₂ layers, which can be applied by means of deposition from the gas phase, in particular Plasma Enhanced Chemical Vapour Deposition, PACVD.

Further details and advantages of the invention are explained using an embodiment with reference to the accompanying drawings. They show:

Figure 1 shows an embodiment of a heating device according to the invention,

Figure 2 a heating insert of the heating device shown in Figure 1,

Figure 2a shows the heating insert shown in Figure 2 in an exploded view,

Figure 3 shows the heating device shown in Figure 1 in a side view, and

Figure 4 shows the heating device shown in Figures 1 and 3 along the section line A-A.

The housing 6 of the heating device shown in Figure 1 is an extruded part made of a material with good heat conduction, such as aluminum. The heating insert 20 shown in Figures 2 and 2a is arranged inside the housing 6. The housing 6 tightly encloses the heating insert 20 so that the penetration of liquid is prevented.

The housing 6 is coated with a layer 19 which prevents corrosion by a corrosive liquid, such as urea solution, which is required for a catalyst provided in the motor vehicle. However, such a layer 19 is not required for heating less corrosive liquids, such as water or diesel fuel in particular, and is preferably omitted for such applications. The layer 19 is an organically modified silicon oxide coating deposited by means of PACVD with a thickness of 3 pm to 5 pm. This transparent coating is a mixed structure of silicon oxide particles and organic structural components. These organic structural components give the layer 19 a high degree of elasticity, so that even in the event of thermal expansion of the housing 6, which inevitably occurs during operation of the heating device, a reliable adhesion of the layer 19 is ensured and in particular cracking is avoided.

Figure 2a shows the structure of the heating insert 20 in an exploded drawing in detail. The heating insert 20 has two heating elements 3 as a central component, although it is of course also possible to provide a larger or smaller number of heating elements, which are fixed in position by a frame 2 made of plastic. The heating elements 3 are in conductive connection with the contact plate 1, which is designed as an aluminum profile and has at least one, preferably two wire connections 7, which preferably represent the ground connection. The contact plate 1, designed as an aluminum profile, has longitudinal grooves 8 for receiving the wire connections 7. A connection plate 4, which is designed, for example, as a brass sheet, with molded connection elements 12 covers the heating elements 3 as a potential connection.

Between the connecting plate 4 and the surrounding housing 6 there is a final insulating strip as an insulating layer 5 made of aluminum oxide, which is designed as a plate and preferably locks into the side walls of the frame 2.

As can be seen in particular in Figure 2, the frame 2 holds the individual components together before they are inserted into the housing 6. The frame 2 has a hook-shaped nose 10 on its front side, which points downwards in the direction of the contact plate 1. When inserted into the frame 2, the contact plate 1 locks positively with the latter and is gripped by the nose 10. In the rear area, the frame 2 has knobs 11, which engage in the longitudinal grooves 8 provided in the contact plate 1, which is designed as an aluminum profile, so that the contact plate 1 is reliably connected to the frame 2. The frame 2 also has two opposing noses 13 in the front side area, which lock positively with the connection plate 4 and hold it in position. The side walls of the frame 2 are so high that they not only provide support for the heating element 3, but also form a lateral guide for the contact plate 1, the connection plate 4 and the insulating layer 5 designed as an insulating strip. The frame 2 is dimensioned in such a way that the contact plate 1, the connection plate 4 and the insulating layer 5 designed as an insulating strip are held in it in a force-fitting and/or form-fitting manner and are thus held together until the heating insert 20 is inserted into the housing 6. This makes assembly much easier.

After inserting the heating insert 20 into the housing 6, the housing 6 is pressed so that the housing clamps around the heating insert 20. Pressing the housing 6 creates good thermal contact between the heating elements 3 and the housing 6. The heating elements 3 are PTC heating elements, which advantageously have an intrinsic temperature limitation.

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so that complex additional measures for limiting the temperature of the heating elements 3 can be dispensed with.

In the heating device described, the heating elements 3 are only electrically insulated from the housing 6 on one side, namely by the insulating layer 5 designed as an insulating strip. On the one hand, this means that the housing 6 is at the potential of one of the connections, in the example shown the ground connection, but on the other hand it also advantageously leads to a much better thermal coupling of the housing 6 to the heating elements 3. This not only advantageously results in a particularly simple construction of the heating device, but also a high heat flow density from the heating element 3 to the liquid to be heated is achieved even with small temperature gradients. This measure makes a decisive contribution to ensuring that heating elements 3, whose maximum surface temperature is limited to a safe value by their PTC characteristics, ensure rapid and safe heating even at temperatures well below the freezing point of the liquid to be heated.

As can be seen in particular in Figure 4, the housing 6 is formed by a flat tube with a slightly concave top 6a and bottom 6b. The side parts 6c and 6d are convexly curved outwards. The housing 6 is closed at the rear end 6e. A bayonet-like flange 6f is formed on the front end, which allows a connection cap (not shown) to be attached in a simple and secure manner. Such a connection cap has an opening for the connections and is filled with plastic after being placed on the heating device.

The contact plate 1 with the wire connections 7, the frame 2 and the connection plate 4 with the molded connection elements 12 protrude beyond the flange 6f. The wire connections 7 are preferably connected to a control electronics (not shown). If such a control electronics contains power semiconductors, the negative connection with the good heat conducting

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Wire connections 7 and the contact plate 1 simultaneously for heat dissipation for the power semiconductors and thus for additional heating of the liquid. The control electronics (not shown) are preferably arranged at a distance from the connection plate 4, since the connection plate 4 is less able to dissipate heat generated by the heating elements 3 than the contact plate 1 due to the insulating layer 5 and therefore heats up the most. In order to keep undesirable heat dissipation in the direction of the connection element 12 provided on the connection plate 4 and thus also thermal stress on the control electronics, if present, as low as possible, the connection plate 4 has a narrow point 14 in front of the connection element 12. Additional thermal insulation of the control electronics can be achieved by filling the inside of a connection cap (not shown) with plastic.

Claims (21)

1. Electric heating device for heating a liquid in a motor vehicle, which has a heating insert ( 20 ) which is tightly enclosed by a metallic housing ( 6 ) which is immersed in the liquid during operation and which has one or more heating elements ( 3 ) and a connection ( 4 ) for electrically contacting the one or more heating elements ( 3 ), wherein the one or more heating elements ( 3 ) are clamped in the housing ( 6 ), which is compressed for this purpose and is electrically conductively connected to the one or more heating elements ( 3 ), while the connection ( 4 ) is electrically insulated from the housing ( 6 ). 2. Heating device according to claim 1, characterized in that the heating insert ( 20 ) has a frame ( 2 ) which receives the one or more heating elements ( 3 ) and fixes them in their position. 3. Heating device according to claim 2, characterized in that the frame ( 2 ) accommodates several heating elements ( 3 ) arranged in a row. 4. Heating device according to one of the preceding claims, characterized in that the heating elements ( 3 ) are plate- or disc-shaped. 5. Heating device according to one of the preceding claims, characterized in that the connection ( 4 ) is designed as a connecting plate. 6. Heating device according to one of the preceding claims, characterized in that the frame ( 2 ) is positively locked to the metallic connecting plate ( 4 ). 7. Heating device according to one of the preceding claims, characterized in that the connecting plate ( 4 ) is covered by an insulating layer ( 5 ) on its side facing away from the heating element ( 3 ). 8. Heating device according to claim 7, characterized in that the insulating layer ( 5 ) is designed as a plate or foil. 9. Heating device according to claim 8, characterized in that the frame ( 2 ) has side walls which position the insulating layer ( 5 ). 10. Heating device according to one of claims 7 to 9, characterized in that the insulating layer ( 5 ) is made of ceramic, in particular aluminum oxide. 11. Heating device according to one of the preceding claims, characterized in that the frame ( 2 ) is positively connected to a metallic contact plate ( 1 ). 12. Heating device according to claim 11, characterized in that the contact plate ( 1 ) is made of aluminum or an aluminum alloy. 13. Heating device according to claim 11 or 12, characterized in that the contact plate ( 1 ) is an extruded profile. 14. Heating device according to one of claims 11 to 12, characterized in that the contact plate ( 1 ) has at least one groove ( 8 ) for receiving a wire connection ( 7 ). 15. Heating device according to claim 14, characterized in that the wire connection ( 7 ) and the contact plate ( 1 ) serve to dissipate heat from a power semiconductor of a control electronics. 16. Heating device according to one of the preceding claims, characterized in that the frame ( 2 ) is made of plastic. 17. Heating device according to one of the preceding claims, characterized in that the housing ( 6 ) has a flange ( 6f ) for connection to a connection cap. 18. Heating device according to claim 17, characterized in that the flange ( 6f ) has projections ( 6g ) on its edge which run in a flange plane and enable a positive connection with the connection cap. 19. Heating device according to one of the preceding claims, characterized in that the connecting plate ( 4 ) is made of copper or a copper alloy. 20. Heating device according to one of the preceding claims, characterized in that the connecting plate ( 4 ) has a constriction ( 14 ) in front of a connecting element ( 12 ) for thermal decoupling of the connecting element ( 12 ). 21. Heating device according to one of the preceding claims, characterized in that the housing ( 6 ) is coated with a layer ( 19 ).