DE102022005121A1 - Tempering device, assembly with such a tempering device, and vehicle with such a tempering device or such an assembly - Google Patents

Abstract

The invention relates to a temperature control device (3) having a heater (6) and a temperature control device housing, wherein the temperature control device housing comprises a receiving space with a coolant inlet (41a) and a coolant outlet (41b), wherein the coolant inlet (41a) and the coolant outlet (41b) are fluidically connected to one another by means of a coolant channel (41). The coolant channel (41) is formed by a component (5) which is arranged in the receiving space. The invention further relates to an assembly (2) with such a temperature control device (3) and to a vehicle (1) with such a temperature control device (3) or such an assembly (2).

Description

Technical area

The invention relates to a temperature control device, an assembly with such a temperature control device, and a vehicle with such a temperature control device or such an assembly.

State of the art

Such a temperature control device can be used to heat components that must be operated within a specific temperature range.

The publication EN 10 2011 082 991 A1 discloses a temperature control device integrated into a battery housing.

A particular disadvantage of the prior art devices is that the formation of a cooling channel is extremely complex.

Description of the invention, task, solution, advantages

It is the object of the present invention to create an alternative temperature control device which is characterized in particular by its simple and cost-effective manufacture. A further object is to provide an assembly with such a temperature control device. In addition, a further object is to provide a vehicle with such a temperature control device or such an assembly.

The object with regard to the tempering device is achieved by the device having the features of claim 1.

One embodiment of the invention relates to a temperature control device, comprising a heater and a temperature control device housing, wherein the temperature control device housing comprises a receiving space with a coolant inlet and a coolant outlet, wherein the coolant inlet and the coolant outlet are fluidically connected to one another by means of a coolant channel, wherein the coolant channel is formed by a component which is arranged in the receiving space.

This allows the coolant channel to be formed using an additional component, which is particularly simple and cost-effective to manufacture.

It is particularly advantageous if the heater is an electric heater. The heater is preferably coupled to the coolant channel in a heat-transfer manner. This ensures that the heater heats up the coolant that can be conveyed through the coolant channel to the maximum. The heater is advantageously designed to be operated with 12 volts, 48 volts or at least 600 volts of electrical voltage. This takes into account different performance classes and requirements for heating performance.

Furthermore, it is advantageous if the receiving space is limited by the temperature control device housing. Furthermore, it is expedient if the receiving space is located within the temperature control device housing.

Furthermore, it is advantageous if the tempering device is designed such that it can be used both as a heating device and as a cooling device.

In addition, it is expedient if the temperature control device housing is designed in at least two parts. It is particularly preferable if the receiving space is limited by the two parts of the temperature control device housing or by more than two parts of the temperature control device housing. Alternatively or additionally, a variant is conceivable in which the receiving space is located in both a first and a second temperature control device housing part.

It is also preferred if the temperature control device housing, at least one, two or all of the temperature control device housing parts are designed as sheet metal and/or deep-drawn parts. This makes the corresponding parts extremely simple and cost-effective to manufacture. In particular, series production is particularly easy as a result.

It is also advantageous if the coolant channel runs through the receiving space in a meandering shape. This ensures that the coolant channel extends as far as possible through the receiving space. As a result, a coolant flow that can be conveyed through the coolant channel remains in heat-transferring contact with the heater for as long as possible, which increases the outlet temperature, i.e. the temperature at the coolant outlet, of the coolant to be heated.

A preferred embodiment is characterized in that the component is a sheet metal part, deep-drawn part and/or a stamped part. This makes the component extremely simple and cost-effective to manufacture. In particular, series production is particularly easy as a result.

It is further preferred if the component has strip-shaped and/or band-shaped sections These sections are preferably bent and/or punched. Preferably, at least one of the sections has a free end, which in particular protrudes from the component. Such a section with a free end is preferably arranged on the edge of the component. Alternatively or additionally, it is conceivable to provide sections that do not have a free end. In other words, such sections are formed integrally with the component at their front ends. Regardless of the design of the sections, it is preferred if the sections extend transversely to the flow direction of the coolant flow that can be conveyed through the coolant channel. The coolant channel is preferably delimited by the sections and/or a temperature control device housing part. In particular, several sections are arranged adjacent to one another, it being expedient if these sections are bent differently from one another. Furthermore, it is preferred if the sections form a meandering coolant channel course. Preferably, the sections, particularly preferably their shape, are decisive for the conduction of the coolant, for the course of the coolant channel, for the heat transfer of the component with the coolant and/or turbulence of the coolant flow. Such turbulence increases the heat transfer between the component and the coolant.

It is also preferable if the component is clamped between two parts of the temperature control device housing. In this way, if this is intended, there is no need to fasten the component in order to fix it in place.

A further preferred embodiment is characterized in that the component is designed as a coolant guide element. In other words, the coolant channel is at least partially delimited by the component. The delimitation preferably extends transversely to the flow direction of a coolant that can be conveyed through the coolant channel.

It is also preferable if the coolant channel is additionally limited by the temperature control device housing or at least by a temperature control device housing part.

A further preferred embodiment is characterized in that the component is designed as a heat-conducting element which is coupled to the heater in a heat-transferring manner. In this way, the heat from the heater is transferred particularly effectively to a coolant that can be conveyed through the coolant channel. For this purpose, it is particularly expedient if the component is made from a material that has a high thermal conductivity. An example of this is aluminum or an aluminum alloy. Alternatively, it is conceivable to use a material that has at least a higher thermal conductivity than the temperature control device housing or at least one temperature control device housing part.

A further preferred embodiment is characterized in that the component is designed as a fastening element for the temperature control device housing. In other words, the component gives the temperature control device housing greater stability and strength.

It is also preferable if the component is attached to the temperature control device housing. This is preferably a force-transmitting connection. A force-locking, form-locking and/or material-locking connection or attachment is conceivable.

Furthermore, it is advantageous if at least one fastening or connection of the component is formed with a temperature control device housing part or several temperature control device housing parts. The various temperature control device housing parts are thus connected or fastened to one another by means of the component in a force-transmitting manner. The temperature control device housing parts that are fastened to one another by the component are preferably the temperature control device housing parts that delimit the receiving space.

A further preferred embodiment is characterized in that the component is designed as a turbulator for a coolant that can be conveyed through the coolant channel. This increases heat transfer from the heater to the coolant that can be conveyed through the coolant channel. In particular, if the component is simultaneously designed as a heat conducting element and/or as a coolant conducting element, it is advantageous to increase heat transfer from the heat conducting element to the coolant that can be conveyed through the coolant channel.

A turbulator is preferably understood to be a component which, due to its geometry, shape and/or surface, in particular a surface disturbance, converts a laminar coolant flow into a turbulent coolant flow, which results in an increased heat exchange.

Preferably, the geometry, shape and/or surface, in particular surface defect, which gives the component its property as a turbulator, is formed by means of deep drawing, punching or bending.

A further preferred embodiment is characterized in that the component is designed as an electrical conductor. In this way, it is conceivable to use the component for supplying the electric heater with electrical energy. It is also conceivable to use the component as a ground connection or as an earthing connection.

It is also preferable if the component is electrically connected to the electric heater.

A further preferred embodiment is characterized in that the temperature control device comprises a temperature sensor, a power supply interface, a signal interface and/or a control unit. The temperature sensor is preferably designed to measure the temperature of a coolant that can be conveyed through the coolant channel. The temperature sensor is expediently arranged at the coolant inlet or at the coolant outlet. It is also expedient for the temperature control device to comprise a second temperature sensor that is designed to measure the temperature of a coolant that can be conveyed through the coolant channel. If the temperature control device comprises two temperature sensors, one of the two temperature sensors is arranged at the coolant inlet of the coolant channel, while the other of the two temperature sensors is arranged at the coolant outlet of the coolant channel. In addition, it is expedient, regardless of the number of temperature sensors, for the temperature sensor(s) to be connected to the control unit in a signal-transmitting manner.

Alternatively or additionally, it is conceivable that a temperature sensor is provided to measure the temperature of the heater. This can be used to limit or control the heating output of the heater.

It is also expedient if the control unit is designed to operate the electric heater. It is particularly preferred if the control unit is designed to operate the electric heater depending on the temperature signal from the temperature sensor or depending on the temperature signals from the temperature sensors. The operation of the electric heater is to be understood in particular as regulating and/or controlling the electric heater. In other words, the heating power of the electric heater is controlled or regulated depending on the temperature of the coolant that can be conveyed through the coolant channel. Alternatively or additionally, it is conceivable to operate the electric heater depending on the temperature of the electric heater.

The power supply interface means in particular a connection for an electrical power line, which can preferably connect the control unit and/or the electric heater in an electrically conductive manner to an electrical power source.

The signal interface is preferably an interface by means of which signals from the temperature sensor, the temperature sensors or the control unit can be forwarded. For example, the signal interface can be coupled to a data bus to transmit signals and forward the signals to other control units.

A further preferred embodiment is characterized in that the temperature control device or the temperature control device housing can be connected to an assembly to be temperature controlled. More precisely, the coolant outlet of the temperature control device can be fluidically connected to a coolant inlet of a coolant channel of an assembly to be temperature controlled.

Furthermore, it is expedient if the temperature control device or the temperature control device housing can be connected or fastened, in particular directly, to the assembly to be temperature controlled. In other words, the temperature control device or the temperature control device housing can be adapted to an assembly to be temperature controlled.

It is also preferable if the component to be tempered is a power electronics unit, an inverter, an electric drive axle, an electric drive motor or a battery housing.

A further preferred embodiment is characterized in that the temperature control device housing is partially open and that the temperature control device housing is designed such that it is closed when it is connected to the assembly to be temperature controlled, or an opening of the assembly to be temperature controlled is closed by the temperature control device.

In other words, the two housings complement each other, which brings cost advantages.

The object with regard to the assembly is achieved by an assembly with a tempering device according to the invention, wherein the coolant outlet of the tempering device is fluidically connected to a coolant inlet of a coolant channel of the assembly.

It is also preferable if this connection is made directly. In other words, there is no other coolant-carrying component between the coolant outlet of the temperature control device and the coolant inlet of the assembly.

Furthermore, it is expedient if the temperature control device is attached to the assembly and/or forms part of the assembly.

A further preferred embodiment is characterized in that the assembly is a power electronics unit, an inverter, an electric drive axle, an electric drive motor or a battery housing.

The battery housing in particular must be heated at low ambient temperatures in order to prevent damage to the battery arranged in the battery housing, which is why such a temperature control device is particularly suitable.

The object with regard to the vehicle is achieved by a vehicle with a temperature control device according to the invention or an assembly according to the invention. The vehicle is preferably a motor vehicle which expediently has an electric drive.

Since the temperature control device is a particularly effective and cost-effective temperature control device, it provides a vehicle which has a particularly low energy consumption and is cost-effective.

Advantageous further developments of the present invention are described in the subclaims and in the following description of the figures.

Short description of the drawings

• 1 ein Fahrzeug,
• 2 eine Temperiervorrichtung,
• 3 eine weitere Ansicht der Temperiervorrichtung, und
• 4 ein Bauteil der Temperiervorrichtung.

In the following, the invention is explained in detail using exemplary embodiments with reference to the drawings. In the drawings:

• 1 a vehicle,
• 2 a tempering device,
• 3 another view of the tempering device, and
• 4 a component of the temperature control device.

Preferred embodiment of the invention

The 1 shows a vehicle 1 which is designed as a motor vehicle with an electric drive. It comprises an assembly 2 to be tempered, which is a battery housing with batteries located therein. The batteries serve to supply energy to the electric drive. In order to prevent premature aging of the costly batteries, which would lead to a reduction in the range of the vehicle 1, a tempering device 3 according to the invention is provided which is able to heat a coolant that can be conveyed through the tempering device 3 and thus prevent the temperature of the batteries from dropping. For this purpose, the tempering device 3 comprises a coolant channel 41 which has a coolant inlet 41a and a coolant outlet 41b. The coolant outlet 41b of the tempering device 3 is fluidically connected to a coolant inlet 42a of a coolant channel 42 of the assembly 2. The coolant channel 42 further comprises a coolant outlet 42b. The two coolant channels 41, 42 can be part of a coolant circuit (not shown in detail), which can include bypass valves, heat exchangers or a coolant pump. The temperature control device 3 is also attached to the assembly 2. The representation of the 1 , in particular the course of the cooling channels 41, 42 is greatly simplified.

The 2 shows the tempering device 3 from 1 The temperature control device 3 comprises a first temperature control device housing part 31, which forms a cover as a deep-drawn part, wherein the first temperature control device housing part 31 is fastened to a further temperature control device housing part by means of fastening means 33, for example screws. The temperature control device 3 also comprises a power supply interface 81 and a signal interface 82.

The 3 shows another view of the tempering device 3 from the 1 and 2 . In addition to the first temperature control device housing part 31, the further temperature control device housing part 32, which is designed as a base plate, can be seen. Between the first temperature control device housing part 31 and the further temperature control device housing part 32, a component 5 is arranged, which consists of a deep-drawn and punched sheet metal that is designed as a single piece. The component 5 is designed simultaneously as a heat conducting element, a coolant conducting element and a fastening element. It serves as a heat conducting element because it is coupled to a heater 6 of the temperature control device 3 in a heat-transferring manner and can transfer this heat to the coolant. It also serves as a coolant conducting element because it forms the coolant channel of the temperature control device 3 from forms, i.e. limits the coolant channel of the temperature control device 3. In addition, it serves as a fastening element, since it is fastened to both temperature control device housing parts and thus gives the temperature control device housing stability. The heater 6 is an electric heater that is regulated or controlled by a control unit 8. The control unit 8 is designed as a circuit board and comprises a power supply interface 81 through which the control unit 8 and the heater 6 can be supplied with electrical energy. The control unit 8 also comprises a signal interface 82 by means of which the control unit 8 can output and/or receive signals. The temperature control device also comprises temperature sensors 7 that can determine a coolant temperature or a heater temperature, depending on which the heater 6 can be operated.

The 4 shows component 5 from 3 It comprises strip-shaped and band-shaped sections 51, 52. These sections 51, 52 are preferably bent and punched. Several of the sections 51 have a free end and are arranged on the edge of the component 5. The component 5 is designed as a sheet metal. The component 5 also comprises sections 52 that do not have free ends. All sections 51, 52 are formed in one piece with the component. The sections 51, 52 extend transversely to the flow direction of the coolant flow that can be conveyed through the coolant channel. The coolant channel is delimited by the sections 51, 52 and, if the component is installed in the temperature control device, a temperature control device housing part. In particular, several sections 52 are arranged adjacent to one another, with the sections 52 being bent differently from one another. The sections 51, 52 form a meandering coolant channel course. As a result, the coolant is conveyed through the temperature control device for a long time and is thus heated up considerably.

In particular, the embodiments are not restrictive in nature and serve to clarify the inventive concept.

List of reference symbols

1

vehicle

2

module

3

Tempering device

31

Tempering device housing part

32

Tempering device housing part

33

Fasteners

41

Coolant channel

41a

Coolant inlet

41b

Coolant outlet

42

Coolant channel

42a

Coolant inlet

42b

Coolant outlet

5

Component

51

Sections

52

Sections

6

Heater

7

Temperature sensor

8th

Control unit

81

Power supply interface

82

Signal interface

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA accepts no liability for any errors or omissions.

Cited patent literature

• DE 102011082991 A1 [0003]

Claims (13)

Temperature control device (3) comprising a heater (6) and a temperature control device housing, wherein the temperature control device housing comprises a receiving space with a coolant inlet (41a) and a coolant outlet (41b), wherein the coolant inlet (41a) and the coolant outlet (41b) are fluidically connected to one another by means of a coolant channel (41), characterized in that the coolant channel (41) is formed by a component (5) which is arranged in the receiving space. Tempering device (3) according to Claim 1 , characterized in that the component (5) is a sheet metal part, deep-drawn part and/or a stamped part. Tempering device (3) according to one of the preceding claims, characterized in that the component (5) is designed as a coolant conducting element. Tempering device (3) according to one of the preceding claims, characterized in that the component (5) is designed as a heat-conducting element which is coupled to the heater in a heat-transferring manner. Tempering device (3) according to one of the preceding claims, characterized in that the component (5) is designed as a fastening element for the tempering device housing. Tempering device (3) according to one of the preceding claims, characterized in that the component (5) is designed as a turbulator for a coolant that can be conveyed through the coolant channel. Tempering device (3) according to one of the preceding claims, characterized in that the component (5) is designed as an electrical conductor. Tempering device (3) according to one of the preceding claims, characterized in that the tempering device (3) comprises a temperature sensor (7), a power supply interface (81), a signal interface (82) and/or a control device (8). Tempering device (3) according to one of the preceding claims, characterized in that the tempering device (3) can be connected to an assembly (2) to be tempered. Tempering device (3) according to Claim 9 , characterized in that the temperature control device housing is partially open and that the temperature control device housing is designed such that, when it is connected to the assembly (2) to be temperature controlled, it is closed, or an opening of the assembly (2) to be temperature controlled is closed by the temperature control device (3). Assembly (2) with a temperature control device (3) according to one of the preceding claims, wherein the coolant outlet (41b) of the temperature control device (3) is fluidically connected to a coolant inlet (42a) of a coolant channel (42) of the assembly (2). Assembly (2) according to Claim 11 , wherein the assembly (2) is a power electronics unit, an inverter, an electric drive axle, an electric drive motor or a battery housing. Vehicle (1) with a temperature control device (3) according to one of the Claims 1 until 10 or an assembly (2) according to one of the Claims 11 or 12 .

Images