WO2024052393A1 - Coolant circulation device - Google Patents

Abstract

The invention relates to a coolant circulation device, in particular for an electric vehicle, said device comprising: at least one fluid flow control element (20); and a fluid guiding unit (22) which has fluid channels (24) in order to guide cooling fluid between connections and/or the at least one fluid flow control element (20), the fluid guiding unit (22) and the fluid flow control element (20) jointly having a connecting unit (30) which at least mechanically connects the fluid guiding unit (22) and the fluid flow control element (20) to one another. According to the invention, the connecting unit (30) is designed to connect the fluid guiding unit (22) and the fluid flow control element (20) to one another solely as a result of a movement of the fluid flow control element (20) relative to the fluid guiding unit (22).

Description

Description

Cooling circuit device

State of the art

Cooling circuit devices have already been proposed. These have pumps and/or valves that are connected to a fluid control unit by means of screws.

Disclosure of the invention

The invention is based on a cooling circuit device, in particular for an electric vehicle, with at least one fluid flow control element, and a fluid conduction unit which has fluid channels in order to guide cooling fluid between connections and/or the at least one fluid flow control element, the fluid conduction unit and the fluid flow control element together having a connection unit , which at least mechanically connects the fluid control unit and the fluid flow control element to one another.

It is proposed that the connection unit is intended to connect the fluid control unit and the fluid flow control element to one another, preferably in a form-fitting manner, solely by moving the fluid flow control element relative to the fluid control unit.

A “cooling circuit device” is intended to mean, in particular, a device that is part of at least one cooling circuit. A “cooling circuit” is intended, for example, to mean a unit that is intended to generate heat using a coolant, in particular a coolant. For example, a glycol-water mixture, from an object to be cooled, i.e. a heat source, to an object to be warmed, i.e. a heat sink. Depending on an operating state, at least one of the objects can function either as a heat source or as a heat sink. In particular, the cooling circuit has at least one heat sink, which is intended to remove heat from the cooling circuit and, for example, to release it to the surrounding air.

The fluid flow control element is intended in particular to drive a coolant flow. Alternatively or additionally, the fluid flow control element can be provided to influence a path and/or a volume flow of the coolant flow. Preferably, the fluid flow element has at least one electromechanical actuator element. The actuator element can, for example, be intended to be operated and/or positioned differently in different operating modes.

The fluid conduction unit has the connections which are intended to be connected to fluid lines, in particular hoses, which fluidly connect the fluid conduction unit to other cooling circuit components, in particular one or more motors and/or one or more battery units. Preferably, the fluid flow control element is arranged between two fluid channels of the fluid guide unit.

The connecting unit is preferably formed exclusively by connecting elements which are formed in one piece with the fluid guide unit or the fluid flow control element. Alternatively, the connection unit can have at least one intermediate element which is not formed in one piece with either the fluid conduction unit or the fluid flow unit and which is intended to be arranged between the fluid conduction unit and the fluid flow control element.

For example, at least in a connected state, at least one sealing element, in particular a sealing ring, is arranged between the fluid guide unit and the fluid flow control element. The inventive design of the cooling circuit device can, for example, achieve simple, particularly tool-free, assembly and/or a compact design. In particular, no space needs to be kept free to enable tool access.

According to a further embodiment, the movement can include at least one rotation of the fluid flow control element relative to the fluid guide unit. Alternatively or additionally, the movement may include a linear movement. For example, the movement may include a helical movement. For example, the rotation is limited to an angle of a maximum of 180°, for example a maximum of 90°, in particular a maximum of 30°, preferably a maximum of 15°. In particular, a high holding force can be achieved. Alternatively, the movement can, for example, be formed solely by a plugging movement of the fluid flow control element towards the fluid guide unit.

The connection unit is preferably designed as a latching and/or clamping connection unit. The connection unit is intended in particular to form a positive connection. In particular, simple assembly can be achieved. Alternatively, the connection unit can be intended to produce a screw connection, in particular the fluid flow control element and the fluid guide unit each having a thread which is intended to engage with one another.

The connection unit can advantageously be provided to form a bayonet connection or a bayonet-like connection. In particular, simple assembly and disassembly and/or a good hold can be achieved. For example, the connecting unit has at least one spring element, which is intended to press at least the connecting elements of the fluid flow control element and the fluid guide unit against one another in a mounted state. The spring element can be formed, for example, by the sealing ring.

Furthermore, it is proposed that the connection unit, in particular the fluid guide unit, has at least one latching and/or clamping hook, which is intended to have a corresponding fastening element, in particular the Fluid flow control element to encompass. In this way, particularly simple assembly can be achieved.

The latching and/or clamping hook can advantageously have and/or be formed by a base component which is embedded, in particular cast, in a housing of the fluid guide unit or the fluid flow control element. For example, the base component is made of a metal. In particular, the housing in which the base component is embedded is made of a plastic. In particular, a high level of durability can be achieved. Alternatively, the latching and/or clamping hook can be made of the same material as the housing.

Furthermore, it is proposed that the fluid flow control element is designed as a pump unit. For example, the pump unit itself forms a pump that has connections that are intended to correspond to connections of the fluid control unit. For example, the pump unit has at least one pump motor and an impeller, which is intended to be driven by the pump motor. Preferably, the fluid conduction unit forms a pump housing for the pump unit and the pump unit is intended to form a pump only together with the fluid conduction unit. In particular, the impeller is freely seated and is intended to be arranged in the pump housing of the fluid guide unit. In this way, a high level of integration can be achieved in particular.

According to a further embodiment, it is proposed that the fluid flow control element is designed as a valve unit. In particular, the valve unit is intended to be inserted into an intersection of fluid channels in the fluid guide unit in order to control a fluid flow between the fluid channels. In this way, a high level of integration can be achieved in particular.

Preferably, the fluid guide unit is designed as a fluid distribution unit, which is intended to divide a fluid flow into at least two fluid channels. A “fluid distribution unit” is intended to mean, in particular, a unit that is intended to divide a coolant flow into at least two partial cooling circuits. For example, the fluid distribution unit has at least one Coolant channel that has a branch. For example, the valve unit can be arranged on the branch. The valve unit can be designed as a multi-way valve. Furthermore, the fluid distribution unit can have at least three, in particular a plurality, of coolant interfaces which are intended to be connected to fluid lines, in particular coolant hoses, which lead to cooling or heating cooling circuit components. In this way, a particularly compact design can be achieved.

Furthermore, a vehicle, in particular an electric vehicle, is proposed with at least one previously described cooling circuit device. In particular, the vehicle has at least one cooling circuit which is intended to cool at least one motor, for example an electric motor. In particular, the cooling circuit is intended to cool or heat at least one battery. In particular, the cooling circuit is intended to dissipate heat to a passenger cell.

Furthermore, a method for assembling a previously described cooling circuit device is proposed.

The cooling circuit device according to the invention should not be limited to the application and embodiment described above. In particular, the cooling circuit device according to the invention can have a number of individual elements, components, units and/or method steps that deviate from the number of individual elements, components, units and/or method steps mentioned here in order to fulfill the functionality described herein. In addition, in the value ranges specified in this disclosure, values lying within the stated limits should also be considered disclosed and can be used in any way.

drawing

Further advantages result from the following drawing description. Two exemplary embodiments of the invention are shown in the drawing. The drawing, description and claims contain numerous features Combination. The person skilled in the art will also expediently consider the features individually and combine them into further sensible combinations.

Show it:

1 shows a vehicle according to the invention in a schematic representation,

2 shows a cooling circuit device according to the invention in a schematic sectional view,

Fig. 3 shows the cooling circuit device from Fig. 2 in a schematic, partially sectioned top view and

4 shows a cooling circuit device according to the invention in a schematic side view,

5 shows a basic component of the embodiment according to FIG. 4 in a schematic side sectional view and

Fig. 6 shows the basic component according to Fig. 5 in a schematic top view.

Description of the exemplary embodiments

Figure 1 shows a vehicle 10. The vehicle 10 is an electric vehicle and has an electric motor 16, alternatively a plurality of electric motors, to drive the vehicle 10. Furthermore, the vehicle 10 has a battery unit 14, also called a “battery pack”. The battery unit 14 can consist of one or more closed units. Furthermore, the vehicle 10 has a cooling circuit 11. The cooling circuit 11 has a cooling circuit device 12. Furthermore, the cooling circuit 11 has a heat exchanger 18, also called a “cooler”, which is intended to release heat from the cooling circuit 11 to the ambient air. The cooling circuit 11 has a further heat exchanger 19, which is intended to dissipate heat to a passenger compartment of the vehicle 10 in at least one operating state. The cooling circuit 11 is intended to cool the at least one electric motor 16. The cooling circuit 11 is intended to cool or warm the battery unit 14. The cooling circuit device 12, also “temperature management unit” called, is intended to connect the components of the cooling circuit 11 to one another. The cooling circuit 11 each has fluid lines that connect the cooling circuit device 12 to the electric motor 16, the battery unit 14, the heat exchangers 18, 19 and/or other components.

According to alternative embodiments, the vehicle has, alternatively or in addition to the electric motor, at least one internal combustion engine, which is part of the cooling circuit.

The cooling circuit device 12 has a fluid flow control element 20 and a fluid guide unit 22 (see FIGS. 2 and 3). The fluid guide unit 22 is designed as a fluid distribution unit, also called a “manifold”, which is intended to divide a fluid flow into at least two fluid channels (not shown in more detail).

The fluid guide unit 22 is intended to distribute a coolant flow from the heat exchanger 18 to the further cooling circuit components, such as in particular the electric motor 16, the battery unit 14 or the further heat exchanger 19.

The fluid guide unit 22 has fluid channels 24 in order to guide cooling fluid between connections (not shown in detail) and/or the at least one fluid flow control element 20. The fluid conduction unit 22 and the fluid flow control element 20 have a common connection unit 30, which at least mechanically connects the fluid conduction unit 22 and the fluid flow control element 20 to one another. The connection unit 30 also connects the fluid flow control element 20 and the fluid guide unit 22 in fluid technology. The connection unit 30 is intended to connect the fluid conduction unit 22 and the fluid flow control element 20 to one another solely by moving the fluid flow control element 20 relative to the fluid conduction unit 22.

The movement includes at least a rotation of the fluid flow control element 20 relative to the fluid guide unit 22.

The connection unit 30 is designed as a snap-in and/or clamp connection unit. The connection unit 30 is intended to form and/or produce a bayonet connection. The connection unit 30 has, in the present case four, alternatively another suitable number, latching and/or clamping hooks 32. The latching and/or clamping hooks 32 are formed on the fluid guide unit 22. The latching and/or clamping hooks 32 are made of the same material as the fluid guide unit 22. The connecting unit 30 also has corresponding fastening elements 34. The corresponding fastening elements 34 are formed on the fluid flow control element 20. The latching and/or clamping hooks 32 are each intended to grip around one of the corresponding fastening elements 34. The corresponding fastening elements 34 are designed as domes that protrude laterally from the fluid flow control element 20.

The fluid flow control element 20 is designed as a pump unit. The fluid guide unit 22 has a recess 26 which forms a pump housing. The fluid flow control element 20 forms a pump together with the pump housing. The cooling circuit device 12 has a sealing element 28 which is arranged between the fluid flow control element 20 and the fluid guide unit 22. The fluid flow control element 20 has an exposed impeller 21. The impeller 21 is arranged in the pump housing. The impeller 21 is intended to drive the cooling fluid in the cooling circuit 11.

The latching and/or clamping hooks 32 are arranged at regular intervals around the recess 26. The corresponding fastening elements 34 are also arranged at regular intervals from one another, in particular around the fluid flow control element 20. In an installed position, the latching and/or clamping hooks 32 and the corresponding fastening elements 34 are arranged congruently. According to alternative embodiments, the latching and/or clamping hooks can be arranged at irregular distances from one another, so that a clear installation position is determined in which the latching and/or clamping hooks are arranged congruently with the corresponding fastening elements.

When mounting the fluid flow control element 20, the fluid flow control element 20 is moved towards the fluid guide unit 22 in a first movement phase until the fluid flow control element 20 is arranged in the recess 26. In a second movement phase, the fluid flow control element 20 is rotated relative to the fluid guide unit 22 until the corresponding fastening elements 34 are gripped by the latching and/or clamping hooks 32. The sealing element 28 can be compressed during assembly and cause a restoring force on the connection unit 30, which increases a clamping force.

According to alternative embodiments, the fluid flow control element is designed as a valve unit.

The cooling circuit device 12 can have further fluid flow control elements, in particular further pump units and/or valve units, which are connected to the fluid guide unit 22 in the same way.

A further exemplary embodiment of the invention is shown in Figures 4 to 6. The following descriptions and the drawings are essentially limited to the differences between the exemplary embodiments, with regard to components with the same designation, in particular with regard to components with the same reference numerals, in principle also to the drawings and / or the description of the other exemplary embodiments, in particular Figures 1 to 3, can be referred to. To distinguish between the exemplary embodiments, the letter a is added to the reference numerals of the exemplary embodiment in FIG.

Figure 4 shows a further cooling circuit device 12a with a fluid guide unit 22a and a fluid flow control element 20a. A connection unit 30a of the cooling circuit device 12a is intended to produce a bayonet connection. The connection unit 30a has, in the present case, four latching and/or clamping hooks 32a. The latching and/or clamping hooks 32a have a common base component 36a (see also FIGS. 5 and 6). Alternatively, each latching and/or clamping hook can have its own base component. The base component 36a is embedded in a housing of the fluid guide unit 22a. The base component 36a is cast into the housing of the fluid guide unit 22a. The base component 36a is formed from a metal, in particular stainless steel. The base component 36a is designed as a ring plate from which the locking and/or clamping hooks 32a are made using a stamping and bending process are formed. The base component 36a surrounds a recess 26a in which the fluid flow control element 20a is arranged and/or which forms a pump housing for an impeller of the fluid flow control element 20a. The latching and/or clamping hooks 32a begin on the base component 36a and protrude from the housing. The latching and/or clamping hooks 32a have an intrinsic spring effect, which is intended to press the fluid flow control element 20a against the fluid guide unit 22a in order to increase a clamping force. Corresponding fastening elements 34a of the connection unit 30a are formed on the fluid flow control element 20a. A stop can be formed on at least one of the corresponding fastening elements 34a and/or on at least one of the latching and/or clamping hooks 32a, which limits a rotation of the fluid flow control element 20a relative to the fluid guide unit 22a.

Claims

Expectations

1. Cooling circuit device, in particular for an electric vehicle, with at least one fluid flow control element (20), and a fluid guide unit (22) which has fluid channels (24) in order to guide cooling fluid between connections and / or the at least one fluid flow control element (20), wherein the Fluid control unit (22) and the fluid flow control element (20) together have a connection unit (30) which at least mechanically connects the fluid control unit (22) and the fluid flow control element (20) to one another, characterized in that the connection unit (30) is intended to connect the fluid control unit (22) and the fluid flow control element (20) to be connected to one another solely by moving the fluid flow control element (20) relative to the fluid guide unit (22).

2. Cooling circuit device according to claim 1, characterized in that the movement comprises at least one rotation of the fluid flow control element (20) relative to the fluid guide unit (22).

3. Cooling circuit device according to claim 1 or 2, characterized in that the connection unit (30) is designed as a latching and / or clamping connection unit.

4. Cooling circuit device according to claim 3, characterized in that the connection unit (30) is intended to form a bayonet connection.

5. Cooling circuit device according to one of the preceding claims, characterized in that the connecting unit (30), in particular the fluid guide unit (22), has at least one latching and / or clamping hook (32) which is intended to have a corresponding fastening element (34). , in particular the fluid flow control element (20), to be encompassed.

6. Cooling circuit device according to claim 5, characterized in that the latching and / or clamping hook (32) has a base component (32) which is embedded, in particular cast, in a housing of the fluid guide unit (22) or the fluid flow control element (20).

7. Cooling circuit device according to one of the preceding claims, characterized in that the fluid flow control element (20) is designed as a pump unit.

8. Cooling circuit device according to one of the preceding claims, characterized in that the fluid guide unit (22) is designed as a fluid distribution unit which is intended to divide a fluid flow into at least two fluid channels (24).

9. Vehicle, in particular electric vehicle, with a cooling circuit device (12) according to one of the preceding claims.

10. Method for assembling a cooling circuit device (12) according to one of claims 1 to 8.