Thermal management system, method and device for automobile

文档序号:895 发布日期:2021-09-17 浏览:49次 中文

1. A thermal management system for an automobile, the thermal management system comprising: the heat pump air conditioning unit (10), the heat exchange unit (20), the electronic water pump (31) and the power battery (32);

the heat pump air conditioning unit (10) comprises a first reversing valve (11), a heating branch (10a) and a cooling branch (10 b); the heat exchange unit (20) comprises a first fluid channel (20a) and a second fluid channel (20 b);

the heating branch (10a) is connected between a first port of the first reversing valve (11) and a second port of the first reversing valve (11) after being connected with the first fluid channel (20a) in series; the refrigeration branch (10b) and the first fluid channel (20a) are connected in series and then connected between a first port of the first reversing valve (11) and a third port of the first reversing valve (11);

the first direction valve (11) has a first state and a second state, the first direction valve (11) is configured such that in the first state, a first port of the first direction valve (11) communicates with a second port of the first direction valve (11) such that the first port of the first direction valve (11), the second port of the first direction valve (11), the heating branch (10a) and the first fluid passage (20a) form a first circulation loop; or, in the second state, the first port of the first direction valve (11) is communicated with the third port of the first direction valve (11), so that the first port of the first direction valve (11), the third port of the first direction valve (11), the refrigeration branch (10b) and the first fluid passage (20a) form a second circulation loop;

the power battery (32), the electronic water pump (31) and the second fluid channel (20b) are connected in series to form a third circulation loop.

2. The thermal management system according to claim 1, wherein the heat pump air conditioning unit (10) further comprises an electric compressor (12), the heating branch (10a) comprising a condenser (13), a first electronic expansion valve (14) and a heat exchanger (15);

the output end of the first fluid channel (20a) is connected with the input end of the electric compressor (12), the output end of the electric compressor (12) is connected with the first port of the first reversing valve (11), the second port of the first reversing valve (11) is connected with the input end of the condenser (13), the output end of the condenser (13) is connected with the input end of the first electronic expansion valve (14), the output end of the first electronic expansion valve (14) is connected with the input end of the heat exchanger (15), and the output end of the heat exchanger (15) is connected with the input end of the first fluid channel (20 a).

3. The thermal management system according to claim 2, characterized in that said refrigeration branch (10b) comprises: the heat exchanger (15), a second electronic expansion valve (16) and an evaporator (17);

the third port of the first reversing valve (11) is connected with the output end of the heat exchanger (15), the input end of the heat exchanger (15) is connected with the input end of the second electronic expansion valve (16), the output end of the second electronic expansion valve (16) is connected with the input end of the evaporator (17), and the output end of the evaporator (17) is connected with the input end of the first fluid channel (20 a).

4. The thermal management system of any of claims 1 to 4, further comprising: a second direction changing valve (33), a third direction changing valve (34) and a motor (35);

a first port of the second direction valve (33) is connected to an output end of the second fluid passage (20b), a second port of the second reversing valve (33) is connected with a water inlet of the electronic water pump (31), the water outlet of the electronic water pump (31) is connected with the water inlet of the power battery (32), the water outlet of the power battery (32) is connected with the first port of the third reversing valve (34), the second port of the third reversing valve (34) is connected with the water inlet of the motor (35), the water outlet of the motor (35) is connected with the third port of the third reversing valve (34), the fourth port of the third direction changing valve (34) is connected with the third port of the second direction changing valve (33), a fourth port of the second direction valve (34) is connected with an input end of the second fluid channel (20 b);

the second direction valve (33) having a third state and a fourth state, the second direction valve (33) being configured such that in the third state the first port of the second direction valve (33) communicates with the second port of the second direction valve (33) and the third port of the second direction valve (33) communicates with the fourth port of the second direction valve (33); or, in the fourth state, the first port of the second direction valve (33) communicates with the fourth port of the second direction valve (33), and the second port of the second direction valve (33) communicates with the third port of the second direction valve (33);

the third direction valve (34) having a fifth state and a sixth state, the third direction valve (34) being configured such that in the fifth state, a first port of the third direction valve (34) communicates with a second port of the third direction valve (34), and a third port of the third direction valve (34) communicates with a fourth port of the third direction valve (34); or, in the sixth state, the first port of the third direction valve (34) communicates with the fourth port of the third direction valve (34), and the second port of the third direction valve (34) communicates with the third port of the third direction valve (34).

5. The system of claim 4, wherein the thermal management system further comprises a fourth reversing valve (36) and a low temperature radiator (37);

a first port of the fourth reversing valve (36) is connected with a third port of the second reversing valve (33), a second port of the fourth reversing valve (36) is connected with a fourth port of the third reversing valve (34), a third port of the fourth reversing valve (36) is connected with a water inlet of the low-temperature radiator (37), and a water outlet of the low-temperature radiator (37) is connected with a fourth port of the fourth reversing valve (36);

the fourth direction valve (36) having a seventh state and an eighth state, the fourth direction valve (36) being configured such that in the seventh state, the first port of the fourth direction valve (36) communicates with the second port of the fourth direction valve (36) and the third port of the fourth direction valve (36) communicates with the fourth port of the fourth direction valve (36); or, in the eighth state, the first port of the fourth direction valve (36) is in communication with the fourth port of the fourth direction valve (36), and the second port of the fourth direction valve (36) is in communication with the third port of the fourth direction valve (36).

6. A method for thermal management of a vehicle, applied to the thermal management system of claim 1, the method comprising:

receiving a thermal management request;

and controlling the state of the first reversing valve according to the heat management request, and controlling the electronic water pump to work.

7. The method of claim 6, wherein said controlling the state of the first reversing valve in accordance with the thermal management request comprises:

in response to the thermal management request being a first thermal management request for requesting simultaneous heating of the passenger compartment and the power cell, controlling the first diverter valve to be in the first state, or,

and in response to the thermal management request being a second thermal management request for requesting simultaneous cooling of the passenger compartment and the power battery, controlling the first reversing valve to be in the second state.

8. The method of claim 6, applied to the thermal management system of claim 4, further comprising:

and in response to a third thermal management request for requesting simultaneous cooling of the passenger compartment, the power battery and the motor, controlling the first reversing valve to be in the second state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state, and controlling the electronic water pump to work.

9. The method of claim 8, applied to the thermal management system of claim 5, further comprising:

and in response to a fourth thermal management request for requesting heating of a passenger cabin and a power battery and cooling of a motor, controlling the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state, and the fourth reversing valve to be in the eighth state, and controlling the electronic water pump and the low-temperature radiator to work.

10. A thermal management device for an automotive vehicle, comprising:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to perform the method of any one of claims 6 to 9.

Background

The heat management system of the automobile heats the key devices of the automobile under the low-temperature condition and cools the key devices of the automobile under the high-temperature condition, so that the key devices of the automobile work in the optimal temperature range, the environmental protection performance and the energy-saving effect of the whole automobile are optimized, and the running safety, the driving comfort and the like of the automobile are improved.

In the related art, a thermal management system of an automobile includes a heat pump air conditioning unit including an external evaporator and a battery cooling unit. The first fluid channel of the external evaporator is connected in series with the heating branch of the heat pump air conditioning unit, and the second fluid channel of the external evaporator is connected in series with the battery cooling unit. When the heat pump air conditioning unit works in a heating mode, the liquefied refrigerant flowing out of the heating branch circuit is evaporated by flowing through the first fluid channel of the external evaporator, and absorbs the heat of the cooling liquid flowing through the battery cooling unit in the second fluid channel of the external evaporator, so that the temperature of the power battery is reduced.

In the course of implementing the present disclosure, the inventors found that the prior art has at least the following problems:

the power battery needs to be heated by an additional heater, and the function of the heat pump air conditioning unit is not perfect.

Disclosure of Invention

The embodiment of the disclosure provides a thermal management system, a method, a device and a storage medium of an automobile, which can improve the functions of a heat pump air conditioning unit to a certain extent. The technical scheme is as follows:

in a first aspect, a thermal management system for an automobile is provided, the thermal management system comprising: the system comprises a heat pump air conditioning unit, a heat exchange unit, an electronic water pump and a power battery; the heat pump air conditioning unit comprises a first reversing valve, a heating branch and a refrigerating branch; the heat exchange unit includes a first fluid passage and a second fluid passage; the heating branch is connected between a first port of the first reversing valve and a second port of the first reversing valve after being connected with the first fluid channel in series; the refrigeration branch and the first fluid channel are connected in series and then are connected between a first port of the first reversing valve and a third port of the first reversing valve; the first reversing valve has a first state and a second state, the first reversing valve is configured such that in the first state, the first port of the first reversing valve is in communication with the second port of the first reversing valve such that the first port of the first reversing valve, the second port of the first reversing valve, the heating branch, and the first fluid passage form a first circulation loop; or, in the second state, the first port of the first direction changing valve is communicated with the third port of the first direction changing valve, so that the first port of the first direction changing valve, the third port of the first direction changing valve, the refrigeration branch and the first fluid passage form a second circulation loop; the power battery, the electronic water pump and the second fluid channel are connected in series to form a third circulation loop.

Optionally, the heat pump air conditioning unit further includes an electric compressor, and the heating branch includes a condenser, a first electronic expansion valve, and a heat exchanger; the output end of the first fluid channel is connected with the input end of the electric compressor, the output end of the electric compressor is connected with the first port of the first reversing valve, the second port of the first reversing valve is connected with the input end of the condenser, the output end of the condenser is connected with the input end of the first electronic expansion valve, the output end of the first electronic expansion valve is connected with the input end of the heat exchanger, and the output end of the heat exchanger is connected with the input end of the first fluid channel.

Optionally, the refrigeration branch comprises: the heat exchanger, the second electronic expansion valve and the evaporator; the third port of the first reversing valve is connected with the output end of the heat exchanger, the input end of the heat exchanger is connected with the input end of the second electronic expansion valve, the output end of the second electronic expansion valve is connected with the input end of the evaporator, and the output end of the evaporator is connected with the input end of the first fluid channel.

Optionally, the thermal management system further comprises: the second reversing valve, the third reversing valve and the motor; a first port of the second reversing valve is connected with an output end of the second fluid channel, a second port of the second reversing valve is connected with a water inlet of the electronic water pump, a water outlet of the electronic water pump is connected with a water inlet of the power battery, a water outlet of the power battery is connected with a first port of a third reversing valve, a second port of the third reversing valve is connected with a water inlet of the motor, a water outlet of the motor is connected with a third port of the third reversing valve, a fourth port of the third reversing valve is connected with a third port of the second reversing valve, and a fourth port of the second reversing valve is connected with an input end of the second fluid channel; the second direction valve having a third state and a fourth state, the second direction valve configured such that in the third state, the first port of the second direction valve is in communication with the second port of the second direction valve, and the third port of the second direction valve is in communication with the fourth port of the second direction valve; or, in the fourth state, the first port of the second direction valve is communicated with the fourth port of the second direction valve, and the second port of the second direction valve is communicated with the third port of the second direction valve; the third direction valve has a fifth state and a sixth state, the third direction valve being configured such that in the fifth state the first port of the third direction valve is in communication with the second port of the third direction valve and the third port of the third direction valve is in communication with the fourth port of the third direction valve; or, in the sixth state, the first port of the third direction valve is communicated with the fourth port of the third direction valve, and the second port of the third direction valve is communicated with the third port of the third direction valve.

Optionally, the thermal management system further comprises a fourth reversing valve and a low-temperature radiator; the first port of the fourth reversing valve is connected with the third port of the second reversing valve, the second port of the fourth reversing valve is connected with the fourth port of the third reversing valve, the third port of the fourth reversing valve is connected with the water inlet of the low-temperature radiator, and the water outlet of the low-temperature radiator is connected with the fourth port of the fourth reversing valve. The fourth direction valve has a seventh state and an eighth state, the fourth direction valve being configured such that in the seventh state the first port of the fourth direction valve is in communication with the second port of the fourth direction valve and the third port of the fourth direction valve is in communication with the fourth port of the fourth direction valve; or, in the eighth state, the first port of the fourth direction valve is communicated with the fourth port of the fourth direction valve, and the second port of the fourth direction valve is communicated with the third port of the fourth direction valve.

In a second aspect, a method for heat management of an automobile is provided, which is applied to the heat management system in the first aspect, and the method includes:

receiving a thermal management request; and controlling the state of the first reversing valve according to the heat management request, and controlling the electronic water pump to work.

Optionally, the controlling the state of the first directional valve according to the thermal management request includes: and controlling the first reversing valve to be in the first state in response to the thermal management request being a first thermal management request for requesting heating of the passenger compartment and the power battery at the same time, or controlling the first reversing valve to be in the second state in response to the thermal management request being a second thermal management request for requesting cooling of the passenger compartment and the power battery at the same time.

Optionally, the method further comprises: and in response to a third thermal management request for requesting simultaneous cooling of the passenger compartment, the power battery and the motor, controlling the first reversing valve to be in the second state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state, and controlling the electronic water pump to work.

Optionally, the method further comprises: and in response to a fourth thermal management request for requesting heating of a passenger cabin and a power battery and cooling of a motor, controlling the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state, and the fourth reversing valve to be in the eighth state, and controlling the electronic water pump and the low-temperature radiator to work.

In a third aspect, there is provided a thermal management device for an automobile, the device comprising: a receiving module for receiving a thermal management request; and the control module is used for controlling the state of the first reversing valve according to the heat management request and controlling the electronic water pump to work.

Optionally, the control module is further configured to control the first reversing valve to be in the first state in response to the thermal management request being a first thermal management request for requesting cooling of the passenger compartment and the power battery at the same time; or, in response to the thermal management request being a second thermal management request for requesting simultaneous heating of the passenger compartment and the power battery, controlling the first reversing valve to be in the second state.

Optionally, the control module is further configured to control the first reversing valve to be in the second state, the second reversing valve to be in the third state, and the third reversing valve to be in the fifth state, in response to the thermal management request being a third thermal management request for requesting simultaneous cooling of the passenger compartment, the power battery, and the motor, and control the electronic water pump to operate.

Optionally, the control module is further configured to control the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state, and the fourth reversing valve to be in the eighth state, and control the electronic water pump and the low-temperature radiator to operate in response to a fourth thermal management request for requesting heating of the passenger compartment and the power battery and cooling of the motor.

In a fourth aspect, there is provided a thermal management device for an automobile, comprising:

a processor;

a memory for storing processor-executable instructions;

wherein the processor is configured to perform the method of the second aspect.

The technical scheme provided by the embodiment of the disclosure has the following beneficial effects:

in the embodiment of the disclosure, when an automobile needs to be heated by a power battery, the first reversing valve is configured to be in the first state, so that the first port of the first reversing valve, the second port of the first reversing valve, the heating branch and the first fluid channel form a first circulation loop, and after passing through the first fluid channel of the heat exchange unit through the first circulation loop, a refrigerant heated by the heating branch exchanges heat with the second fluid channel of the heat exchange unit, so that a coolant in the third circulation loop is heated, and thus the power battery is heated. When the automobile has a power battery cooling requirement, the first reversing valve is configured to be in the second state, so that the first port of the first reversing valve, the third port of the first reversing valve, the refrigeration branch and the first fluid channel form a second circulation loop. The refrigerant cooled by the refrigeration branch passes through the first fluid channel of the heat exchange unit through the second circulation loop and then exchanges heat with the second fluid channel of the heat exchange unit, so that the cooling liquid in the third circulation loop is cooled, and the power battery is cooled. The heat pump air conditioning unit can cool the power battery and heat the power battery, and the functions of the heat pump air conditioning unit of the automobile can be perfected to a certain extent.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present disclosure, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present disclosure, and it is obvious for those skilled in the art to obtain other drawings based on the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a thermal management system of an automobile according to an embodiment of the present disclosure;

FIG. 2 is a schematic diagram of a first recirculation loop of a thermal management system of an automobile provided by an embodiment of the present disclosure;

FIG. 3 is a schematic diagram of a second recirculation loop of a thermal management system of an automobile provided by an embodiment of the present disclosure;

FIG. 4 is a schematic structural diagram of another automotive thermal management system provided by an embodiment of the present disclosure;

FIG. 5 is a schematic structural diagram of another automotive thermal management system provided by an embodiment of the present disclosure;

FIG. 6 is a flow chart of a method for thermal management of an automobile according to an embodiment of the present disclosure;

FIG. 7 is a flow chart of another method of thermal management for an automobile provided by an embodiment of the present disclosure;

FIG. 8 is a schematic structural diagram of a thermal management device for an automobile according to an embodiment of the present disclosure;

fig. 9 is a block diagram of a thermal management device of an automobile according to an embodiment of the present disclosure.

Detailed Description

To make the objects, technical solutions and advantages of the present disclosure more apparent, embodiments of the present disclosure will be described in detail with reference to the accompanying drawings.

Fig. 1 is a thermal management system of an automobile according to an embodiment of the present disclosure, configured to heat a power battery by using a heat pump air conditioning unit when the power battery requires heating; when the power battery has a cooling requirement, the heat pump air conditioning unit is used for cooling the power battery. Referring to fig. 1, the thermal management system includes a heat pump air conditioning unit 10, a heat exchange unit 20, an electric water pump 31, and a power battery 32.

The heat pump air conditioning unit 10 includes a first direction valve 11, a heating branch 10a, and a cooling branch 10 b. When the heat pump air conditioning unit 10 is in the heating operation mode, the heating branch 10a is used to heat the passenger compartment. When the heat pump air conditioning unit 10 is in the cooling operation mode, the cooling branch 10b is used to cool the passenger compartment.

The first direction valve 11 includes a first port 11a, a second port 11b, and a third port 11 c. The heat exchange unit 20 includes a first fluid passage 20a and a second fluid passage 20b, and the first fluid passage 20a may exchange heat with the second fluid passage 20 b. The heating branch 10a is connected in series with the first fluid passage 20a and then connected between a first port of the first direction valve 11 and a second port of the first direction valve 11. In some embodiments, the first port 11a of the first direction valve 11 is connected to the output end of the first fluid channel 20a, the second port 11b of the first direction valve 11 is connected to one end of the heating branch 10a, and the other end of the heating branch 10a is connected to the input end of the first fluid channel 20 a. The refrigeration branch 10b and the first fluid passage 20a are connected in series between the first port of the first direction valve 11 and the third port of the first direction valve 11. In some embodiments, the first port 11a of the first direction valve 11 is connected to the output end of the first fluid passage 20a, the third port 11c of the first direction valve 11 is connected to one end of the refrigeration branch 10b, and the other end of the refrigeration branch 10b is connected to the input end of the first fluid passage 20 a.

The first direction valve 11 has a first state and a second state, the first direction valve 11 is configured in the first state, the first port 11a of the first direction valve 11 is communicated with the second port 11b of the first direction valve 11, so that the first port 11a of the first direction valve 11, the second port 11b of the first direction valve 11, the heating branch 10a and the first fluid passage 20a form a first circulation loop; alternatively, in the second state, the first port 11a of the first direction valve 11 communicates with the third port 11c of the first direction valve 11, so that the first port 11a of the first direction valve 11, the third port 11c of the first direction valve 11, the refrigerating branch 10b and the first fluid passage 20a form a second circulation circuit.

The power battery 32, the electronic water pump 31 and the second fluid passage 20b are connected in series to form a third circulation loop.

In the embodiment of the present disclosure, the order of the series connection of the power battery 32 and the electronic water pump 31 is not limited. For example, in fig. 1, the water outlet of the power battery 32 is connected to the water inlet of the electronic water pump 31, the water outlet of the electronic water pump 31 is connected to the input end of the second fluid channel 20b, and the output end of the second fluid channel 20b is connected to the water inlet of the power battery 32. In other embodiments, the water outlet of the electronic water pump 31 is connected to the water inlet of the power battery 32, the water outlet of the power battery 32 is connected to the input end of the second fluid channel 20b, and the output end of the second fluid channel 20b is connected to the water inlet of the electronic water pump 31.

Refrigerant, illustratively R134a, flows through the first flow path 20 a. A coolant, illustratively comprising water and glycol, circulates through the second fluid passage 20 b.

When the first direction valve 11 is configured in the first state, the heat of the refrigerant flowing through the first fluid passage 20a heats the coolant in the second fluid passage 20b, and the heated coolant flows through the power battery 32 under the driving of the electronic water pump 31, so as to heat the power battery 32. When the first reversing valve 11 is configured in the second state, the cooling capacity of the refrigerant in the first fluid channel 20a cools the coolant in the second fluid channel 20b, and the cooled coolant flows through the power battery 32 under the driving of the electronic water pump 31, so that the power battery 32 is cooled.

In the embodiment of the disclosure, when an automobile needs to be heated by a power battery, the first reversing valve is configured to be in the first state, so that the first port of the first reversing valve, the second port of the first reversing valve, the heating branch and the first fluid channel form a first circulation loop, and after passing through the first fluid channel of the heat exchange unit through the first circulation loop, a refrigerant heated by the heating branch exchanges heat with the second fluid channel of the heat exchange unit, so that a coolant in the third circulation loop is heated, and thus the power battery is heated.

When the automobile has a power battery cooling requirement, the first reversing valve is configured to be in the second state, so that the first port of the first reversing valve, the third port of the first reversing valve, the refrigeration branch and the first fluid channel form a second circulation loop. The refrigerant cooled by the refrigeration branch passes through the first fluid channel of the heat exchange unit 20 via the second circulation loop, and then exchanges heat with the second fluid channel of the heat exchange unit, so that the cooling liquid in the third circulation loop is cooled, and the power battery is cooled.

Therefore, the heat pump air conditioning unit can not only cool the power battery, but also heat the power battery, and can improve the functions of the heat pump air conditioning unit of the automobile to a certain extent.

Fig. 2 is a schematic diagram of a first circulation loop of a thermal management system of an automobile according to an embodiment of the present disclosure. As shown by a thick solid line in fig. 2, the heat pump air conditioning unit 10 further includes an electric compressor 12, and the heating branch 10a includes a condenser 13, a first electronic expansion valve 14, and a heat exchanger 15.

The output end of the first fluid channel 20a is connected with the input end of the electric compressor 12, the output end of the electric compressor 12 is connected with the first port 11a of the first reversing valve 11, the second port 12b of the first reversing valve 11 is connected with the input end of the condenser 13, the output end of the condenser 13 is connected with the input end of the first electronic expansion valve 14, the output end of the first electronic expansion valve 14 is connected with the input end of the heat exchanger 15, and the output end of the heat exchanger 15 is connected with the input end of the first fluid channel 20 a.

The electric compressor 12 is configured to suck the low-temperature and low-pressure superheated gaseous refrigerant output from the output end of the heat exchanger 15, and compress the superheated gaseous refrigerant into a high-temperature and high-pressure gaseous refrigerant.

The condenser 13 is configured to condense the high-temperature and high-pressure gaseous refrigerant output from the output end of the electric compressor 12, and convert the high-temperature and high-pressure gaseous refrigerant into a low-temperature and high-pressure liquid refrigerant. The large amount of heat given off during condensation can be used for heating the passenger compartment. Illustratively, the condenser 13 is a water-cooled condenser.

The first electronic expansion valve 14 is used for converting the low-temperature high-pressure liquid refrigerant output from the output end of the condenser 13 into a low-temperature low-pressure refrigerant which is easy to evaporate.

The heat exchanger 15 is configured to exchange heat between the low-temperature low-pressure refrigerant output from the output end of the first expansion valve 14 and the outside, absorb heat from the outside, and convert the low-temperature low-pressure refrigerant entering the heat exchanger 15 into a low-temperature low-pressure superheated gaseous refrigerant.

The low-temperature and low-pressure superheated gaseous refrigerant output from the output end of the heat exchanger 15 passes through the first fluid channel 20a of the heat exchange unit 20, the heat of the superheated gaseous refrigerant heats the coolant in the second fluid channel 20b of the heat exchange unit 20, and the heated coolant flows through the power battery 32 under the driving of the electronic water pump 31, so that the power battery 32 is heated.

Fig. 3 is a schematic diagram of a second circulation loop of a thermal management system of an automobile according to an embodiment of the present disclosure. As shown by the thick solid line in fig. 3, the cooling branch 10b of the heat pump air conditioning unit 10 includes: a heat exchanger 15, a second electronic expansion valve 16 and an evaporator 17.

The first port 11a of the first directional valve 11 is connected to the output end of the electronic expansion valve 12, the third port 11c of the first directional valve 11 is connected to the output end of the heat exchanger 15, the input end of the heat exchanger 15 is connected to the input end of the second electronic expansion valve 16, the output end of the second electronic expansion valve 16 is connected to the input end of the evaporator 17, and the output end of the evaporator 17 is connected to the input end of the first fluid passage 20 a.

The electric compressor 12 is configured to suck the low-temperature and low-pressure gas refrigerant output from the output end of the evaporator 17, and compress the gas refrigerant into a high-temperature and high-pressure gas refrigerant.

The heat exchanger 15 releases heat by exchanging heat with the outside, and converts the high-temperature and high-pressure gaseous refrigerant entering the heat exchanger 13 into a low-temperature and high-pressure gaseous refrigerant.

The second electronic expansion valve 16 is used to convert the low-temperature high-pressure gaseous refrigerant into a low-temperature low-pressure refrigerant that is easily evaporated.

The evaporator 17 is used for evaporating low-temperature and low-pressure refrigerant, and absorbs a large amount of heat in the passenger compartment in the evaporation process, so that the passenger compartment is refrigerated.

The low-temperature low-pressure gaseous refrigerant output by the output end of the evaporator 17 passes through the first fluid channel 20a of the heat exchange unit 20, the cold energy of the low-temperature low-pressure gaseous refrigerant cools the cooling liquid in the second fluid channel 20b of the heat exchange unit 20, and the cooled cooling liquid flows through the power battery 32 under the driving of the electronic water pump 31, so that the power battery 32 is cooled.

As can be seen from fig. 2 and 3, by switching the operating state of the first direction valve 12, the operating mode of the heat pump air conditioning unit 10 can be switched. When the first reversing valve 12 is in the first state, the heat pump air conditioning unit 10 operates in the heating mode, and heating of the power battery 32 can be achieved. When the first reversing valve 12 is in the second state, the heat pump air conditioning unit 10 operates in the cooling mode, and the power battery 32 can be cooled.

Fig. 4 is another thermal management system of an automobile according to an embodiment of the present disclosure, and compared with the thermal management system shown in fig. 2 or fig. 3, the thermal management system of the automobile further includes: a second direction valve 33, a third direction valve 34 and a motor 35.

The second direction valve 33 includes a first port 33a, a second port 33b, a third port 33c, and a fourth port 33 d. The third directional valve 34 includes a first port 34a, a second port 34b, a third port 34c, and a fourth port 34 d.

The first port 33a of the second direction valve 33 is connected with the output end of the second fluid channel 20b, the second port 33b of the second direction valve 33 is connected with the water inlet of the electronic water pump 31, the water outlet of the electronic water pump 31 is connected with the water inlet of the power battery 32, the water outlet of the power battery 32 is connected with the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34 is connected with the water inlet of the motor 35, the water outlet of the motor 35 is connected with the third port 34c of the third direction valve 34, the fourth port 34d of the third direction valve 34 is connected with the third port 33c of the second direction valve 33, and the fourth port 34d of the second direction valve 34 is connected with the input end of the second fluid channel 20 b.

The second direction valve 33 has a third state and a fourth state, the second direction valve 33 being configured such that in the third state the first port 33a of the second direction valve 33 communicates with the second port 33b of the second direction valve 33, and the third port 33c of the second direction valve 33 communicates with the fourth port 33d of the second direction valve 33; alternatively, in the fourth state, the first port 33a of the second direction valve 33 communicates with the fourth port 33d of the second direction valve 33, and the second port 33b of the second direction valve 33 communicates with the third port 33c of the second direction valve 33.

The third direction valve 34 has a fifth state and a sixth state, the third direction valve 34 being configured such that in the fifth state the first port 34a of the third direction valve 34 communicates with the second port 34b of the third direction valve 34 and the third port 34c of the third direction valve 34 communicates with the fourth port 34d of the third direction valve 34; alternatively, in the sixth state, the first port 34a of the third direction valve 34 communicates with the fourth port 34d of the third direction valve 34, and the second port 34b of the third direction valve 34 communicates with the third port 34c of the third direction valve 34.

In fig. 4, the thermal management system of the automobile mainly includes the following operation modes:

the first mode is as follows: the passenger compartment is heated.

When the thermal management system of the automobile only heats the passenger compartment, the first reversing valve 11 is in the first state, and the electronic water pump 31 does not work. In the first state, the first direction valve 11 is configured such that the first port 11a of the first direction valve 11 communicates with the second port 11b of the first direction valve 11.

The motor-driven compressor 12, the first port 11a of the first direction valve 11, the second port 11b of the first direction valve 11, the condenser 13, the first electronic expansion valve 14, the heat exchanger 15, and the first circulation passage 20a of the heat exchange unit 20 form a first circulation circuit. The high-temperature and high-pressure gaseous refrigerant is liquefied in the condenser 13, and a large amount of energy is released, so that the passenger compartment is heated.

And a second mode: and cooling the passenger compartment.

When the heat management system of the automobile only cools the passenger compartment, the first reversing valve 11 is in the second state, and the electronic water pump 31 does not work. In the second state, the first direction valve 11 is configured such that the first port 11a of the first direction valve 11 communicates with the third port 11c of the first direction valve 11.

The motor-driven compressor 12, the first port 11a of the first direction valve 11, the third port 11c of the first direction valve 11, the heat exchanger 15, the second electronic expansion valve 16, the evaporator 17, and the first circulation passage 20a of the heat exchange unit 20 form a second circulation circuit. The low-temperature and low-pressure gaseous refrigerant is evaporated in the evaporator 17 to absorb a large amount of energy, thereby cooling the passenger compartment.

And a third mode: the passenger compartment and the power battery are heated simultaneously.

When the passenger compartment and the power battery have heating requirements at the same time, the first reversing valve 11 is in the first state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the sixth state, and the electronic water pump 31 works.

At this time, the circuit for achieving the heating of the passenger compartment is the same as the first circulation circuit in the mode one. The second flow passage 20b of the heat exchange unit 20, the first port 33a of the second direction valve 33, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the fourth port 34d of the third direction valve 34, the third port 33c of the second direction valve 33, and the fourth port 33d of the second direction valve 33 form a fourth circulation circuit.

The refrigerant in the first circulation circuit is liquefied in the condenser 13 to release a large amount of heat, thereby heating the passenger compartment. Meanwhile, the heat of the refrigerant in the first fluid channel 20a of the heat exchange unit 20 heats the coolant in the second fluid channel 20b, and the heated coolant flows through the power battery 32 under the driving of the electronic water pump 31 in the fourth circulation loop, so that the power battery 32 is heated.

And a fourth mode: the passenger compartment and the power battery are cooled simultaneously.

When the passenger compartment and the power battery have cooling requirements at the same time, the first reversing valve 11 is in the second state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the sixth state, and the electronic water pump 31 works.

At this time, the circuit for cooling the passenger compartment is the same as the second circulation circuit in the second mode, and the circuit for cooling the power battery 32 is the same as the fourth circulation circuit in the third mode.

The refrigerant in the second circulation loop evaporates in the evaporator 17 to absorb a large amount of heat, thereby cooling the passenger compartment. Meanwhile, the cooling capacity of the refrigerant in the first fluid channel 20a cools the coolant in the second fluid channel 20b, and the cooled coolant flows through the power battery 32 under the driving of the electronic water pump 31 in the fourth circulation loop, so that the power battery 32 is cooled.

And a fifth mode: cooling the passenger compartment, cooling the power battery and cooling the motor.

When the passenger compartment, the power battery and the motor simultaneously have a cooling requirement, the first reversing valve 11 is in the first state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the fifth state, and the electronic water pump 31 works.

At this time, the circuit for achieving the passenger compartment cooling is the same as the second circulation circuit in the mode two. The first port 33a of the second direction valve 33, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34, the motor 35, the third port 34c of the third direction valve 34, the fourth stage port 34d of the third direction valve 34, the third port 33c of the second direction valve 33, the fourth port 33d of the second direction valve 33, and the second fluid passage 20b form a fifth circulation circuit.

In the second circulation loop, the refrigerant evaporates and absorbs a large amount of heat in the evaporator 17, so that the temperature of the passenger compartment is reduced. Meanwhile, the cooling capacity of the refrigerant in the first fluid channel 20a in the second circulation loop cools the coolant in the second channel 20b in the fifth circulation loop, and the cooled coolant in the second fluid channel 20b flows through the power battery 32 and the motor 35 under the driving of the electronic water pump 31, so that the cooling of the power battery 32 and the cooling of the motor 35 are realized.

Mode six: and heating by a power battery.

When the passenger compartment has no cooling demand, the power battery 32 has a heating demand, and the temperature of the motor 35 is higher than that of the power battery 32, the second reversing valve 33 is in the fourth state, the third reversing valve 34 is in the fifth state, and the electronic water pump 31 operates. The second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34, the motor 35, the third port 34c of the third direction valve 34, the fourth port 34d of the third direction valve 34, and the third port 33c of the second direction valve 33 form a sixth circulation circuit.

At this time, in the sixth circulation circuit, the coolant heated by the residual heat of the motor 35 flows through the power battery 32 under the driving of the electronic water pump 31, and the residual heat of the motor 35 heats the power battery 32.

Fig. 5 is another thermal management system for an automobile according to an embodiment of the present disclosure, and compared with the thermal management system shown in fig. 4, the thermal management system for an automobile further includes a fourth direction valve 36 and a low-temperature radiator 37.

The fourth directional valve 36 includes a first port 36a, a second port 36b, a third port 36c, and a fourth port 36 d. The first port 36a of the fourth direction valve 36 is connected to the third port 33c of the second direction valve 33, the second port 36b of the fourth direction valve 36 is connected to the fourth port 34d of the third direction valve 34, the third port 36c of the fourth direction valve 36 is connected to the inlet of the low temperature radiator 37, and the outlet of the low temperature radiator 37 is connected to the fourth port 36d of the fourth direction valve 36.

The water-cooled condenser can pass

The fourth direction valve 36 has a seventh state and an eighth state, the fourth direction valve 36 being configured such that in the seventh state the first port 36a of the fourth direction valve 36 communicates with the second port 36b of the fourth direction valve 36 and the third port 36c of the fourth direction valve 36 communicates with the fourth port 36d of the fourth direction valve 36; alternatively, in the eighth state, the first port 36a of the fourth direction valve 36 communicates with the fourth port 36d of the fourth direction valve 36, and the second port 36b of the fourth direction valve 36 communicates with the third port 36c of the fourth direction valve 36.

In fig. 5, the thermal management system of the vehicle includes the following operation modes:

the first mode is as follows: the passenger compartment is heated.

The first mode refers to the first mode in fig. 4, and a detailed description thereof is omitted.

And a second mode: and cooling the passenger compartment.

The second mode refers to the second mode in fig. 4, and a detailed description thereof is omitted.

And a third mode: the passenger compartment and the power battery are heated simultaneously.

When the passenger compartment and the power battery have heating requirements at the same time, the first reversing valve 11 is in the first state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the sixth state, the fourth reversing valve 36 is in the seventh state, the electronic water pump 31 works, and the low-temperature radiator 37 does not work.

At this time, the circuit for achieving the heating of the passenger compartment is the same as the first circulation circuit in the mode one. The second flow passage 20b of the heat exchange unit 20, the first port 33a of the second direction valve 33, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the fourth port 34d of the third direction valve 34, the second port 36b of the fourth direction valve 36, the first port 36a of the fourth direction valve 36, the third port 33c of the second direction valve 33, and the fourth port 33d of the second direction valve 33 form a seventh circulation circuit.

The refrigerant in the first circulation circuit is liquefied in the condenser 13 to release a large amount of heat, thereby heating the passenger compartment. Meanwhile, the heat of the refrigerant in the first fluid channel 20a of the heat exchange unit 20 heats the coolant in the second fluid channel 20b, and the heated coolant flows through the power battery 32 under the driving of the electronic water pump 31 in the seventh circulation loop, so that the power battery 32 is heated.

And a fourth mode: the passenger compartment and the power battery are cooled simultaneously.

When the passenger compartment and the power battery have cooling requirements at the same time and the cooling requirement of the power battery is smaller, the first reversing valve 11 is in the second state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the sixth state, the fourth reversing valve 36 is in the seventh state, the electronic water pump 31 works, and the low-temperature radiator 37 does not work.

At this time, the circuit for cooling the passenger compartment is the same as the second circulation circuit in the second mode, and the circuit for cooling the power battery 32 is the same as the seventh circulation circuit in the third mode.

The refrigerant in the second circulation loop evaporates in the evaporator 17 to absorb a large amount of heat, thereby cooling the passenger compartment. Meanwhile, the cooling capacity of the refrigerant in the first fluid channel 20a cools the coolant in the second fluid channel 20b, and the cooled coolant flows through the power battery 32 under the driving of the electronic water pump 31 in the seventh circulation loop, so that the power battery 32 is cooled.

When the passenger compartment and the power battery have cooling requirements at the same time, and the cooling requirement of the power battery is large, that is, the cooling requirement of the power battery cannot be met only through the heat pump air conditioning unit 10 or only through the low-temperature radiator 37, the first reversing valve 11 is in the second state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the sixth state, the fourth reversing valve 36 is in the eighth state, and the electronic water pump 31 and the low-temperature radiator 37 work.

At this time, the circuit for achieving the passenger compartment cooling is the same as the second circulation circuit in the mode two. The first port 33a of the second direction valve 33, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the fourth port 34d of the third direction valve 34, the second port 36b of the fourth direction valve 36, the third port 36c of the fourth direction valve 36, the low temperature radiator 37, the fourth port 36d of the fourth direction valve 36, the first port 36a of the fourth direction valve 36, the third port 33c of the second direction valve 33, the fourth port 33d of the second direction valve 33, and the second fluid passage 20b form an eighth circulation circuit.

In the second circulation circuit, the refrigerant evaporates in the evaporator 37 to absorb a large amount of heat, thereby cooling the passenger compartment. Meanwhile, in the eighth circulation circuit, under the driving of the electronic water pump 31, the coolant passes through the low-temperature radiator 37 and is cooled by the low-temperature radiator 37, and the coolant passes through the second circulation passage 20b of the heat exchange unit 20 and is subjected to heat exchange with the refrigerant in the first circulation passage 20a in the second circulation circuit and is cooled. The cooling liquid is cooled under the combined action of the refrigerant and the low-temperature radiator 37, and then the power battery 32 with a large cooling requirement is cooled.

And a fifth mode: cooling the passenger compartment, cooling the power battery and cooling the motor.

When the passenger compartment, the power battery 32 and the motor 35 have cooling requirements at the same time, and the cooling requirements of the power battery 32 and the motor 35 are smaller, the first reversing valve 11 is in the first state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the fifth state, the fourth reversing valve 36 is in the seventh state, the electronic water pump 31 is operated, and the low-temperature radiator 37 is not operated.

At this time, the circuit for achieving the passenger compartment cooling is the same as the second circulation circuit in the mode two. The first port 33a of the second direction valve 33, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34, the motor 35, the third port 34c of the third direction valve 34, the fourth stage port 34d of the third direction valve 34, the second port of the fourth direction valve 36, the first port of the fourth direction valve 36, the third port 33c of the second direction valve 33, the fourth port 33d of the second direction valve 33, and the second fluid passage 20b form a ninth circulation circuit.

In the second circulation loop, the refrigerant evaporates and absorbs a large amount of heat in the evaporator 17, so that the temperature of the passenger compartment is reduced. Meanwhile, the cooling capacity of the refrigerant in the first fluid channel 20a in the second circulation loop cools the coolant in the second channel 20b in the ninth circulation loop, and the cooled coolant in the second fluid channel 20b flows through the power battery 32 and the motor 35 under the driving of the electronic water pump 31, so that the cooling of the power battery 32 and the cooling of the motor 35 are realized.

When the passenger compartment, the power battery 32 and the motor 35 have cooling requirements at the same time, and the cooling requirements of the power battery 32 and the motor 35 are large, that is, the cooling requirements of the power battery 32 and the motor 35 cannot be met only by the heat pump air conditioning unit 10 or the low-temperature radiator 37, the first reversing valve 11 is in the second state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the fifth state, the fourth reversing valve 36 is in the eighth state, and the electronic water pump 31 and the low-temperature radiator 37 operate.

At this time, the circuit for achieving the passenger compartment cooling is the same as the second circulation circuit in the mode two. The first port 33a of the second direction valve 33, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34, the motor 35, the third port 34c of the third direction valve 34, the fourth port 34d of the third direction valve 34, the second port 36b of the fourth direction valve 36, the third port 36c of the fourth direction valve 36, the low-temperature radiator 37, the fourth port 36d of the fourth direction valve 36, the first port 36a of the fourth direction valve 36, the third port 33c of the second direction valve 33, the fourth port 33d of the second direction valve 33, and the second fluid passage 20b of the heat exchanger unit 20 form a tenth circulation circuit.

In the second circulation loop, the refrigerant evaporates and absorbs a large amount of heat in the evaporator 17, so that the temperature of the passenger compartment is reduced. Meanwhile, in the tenth circulation circuit, under the driving of the electronic water pump 31, the coolant passes through the low-temperature radiator 37 and is cooled by the low-temperature radiator 37, and the coolant passes through the second circulation passage 20b of the heat exchange unit 20 to exchange heat with the refrigerant in the first circulation passage 20a and is cooled. The cooling liquid is cooled under the combined action of the refrigerant and the low-temperature radiator 37, and then the power battery 32 and the motor 35 which have large cooling requirements are cooled.

Mode six: and heating by a power battery.

When the passenger compartment does not need cooling, the power battery 32 needs heating and the temperature of the motor 35 is higher than the temperature of the power battery 32, the second reversing valve 33 is in the fourth state, the third reversing valve 34 is in the fifth state, the fourth reversing valve 36 is in the seventh state, the electronic water pump 31 is operated, and the low-temperature radiator 37 is not operated.

The second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34, the motor 35, the third port 34c of the third direction valve 34, the fourth port 34d of the third direction valve 34, the second port 36b of the fourth direction valve 36, the first port 36a of the fourth direction valve 36, and the third port 33c of the second direction valve 33 form an eleventh circulation circuit.

At this time, in the eleventh circulation circuit, the coolant heated by the residual heat of the motor 35 flows through the power battery 32 under the driving of the electronic water pump 31, and the residual heat of the motor 35 heats the power battery 32.

Mode seven: and cooling the power battery.

When the passenger compartment has no cooling requirement and the power battery has the cooling requirement, the second reversing valve 33 is in the fourth state, the third reversing valve 34 is in the sixth state, the fourth reversing valve 36 is in the eighth state, and the electronic water pump 31 and the low-temperature radiator 37 work.

At this time, the second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the fourth port 34d of the third direction valve 34, the second port 36b of the fourth direction valve 36, the third port 36c of the fourth direction valve 36, the low temperature radiator 37, the second port 36b of the fourth direction valve 36, the first port 36a of the fourth direction valve 36, and the third port 33c of the second direction valve 33 form a twelfth circulation circuit.

In the twelfth circulation loop, under the driving of the electronic water pump 31, the cooling liquid cooled by the low-temperature radiator 37 flows through the power battery 32, so that the power battery 32 is cooled.

And a mode eight: and simultaneously cooling the power battery and the motor.

When the passenger compartment has no cooling requirement and the power battery 32 and the motor 35 both have cooling requirements, the second reversing valve 33 is in the second state, the third reversing valve 34 is in the fifth state, the fourth reversing valve 36 is in the eighth state, and the electronic water pump 31 and the low-temperature radiator 37 work.

The second port 33b of the second direction valve 33, the electronic water pump 31, the power battery 32, the first port 34a of the third direction valve 34, the second port 34b of the third direction valve 34, the motor 35, the third port 34c of the third direction valve 34, the fourth port 34d of the third direction valve 34, the second port 36b of the fourth direction valve 36, the third port 36c of the fourth direction valve 36, the low temperature radiator 37, the fourth port 36d of the fourth direction valve 36, the first port 36a of the fourth direction valve 36, and the third port 33c of the second direction valve 33 form a thirteenth circulation circuit.

At this time, in the thirteenth circulation loop, under the driving of the electronic water pump 31, the coolant cooled by the low-temperature radiator 37 flows through the power battery 32 and the motor 35, so as to cool the power battery 32 and the motor 35.

The mode nine: heating by a power battery and cooling by a motor.

When the passenger compartment has no heating request, the power battery has a heating requirement, the motor has a cooling requirement, and the temperature of the motor is high, the second reversing valve 33 is in the fourth state, the third reversing valve 34 is in the fifth state, the fourth reversing valve 36 is in the eighth state, and the electronic water pump 31 operates. The circuit for achieving this requirement is the same as the thirteenth circulation circuit in mode eight.

At this time, under the driving of the electronic water pump 31, after the coolant cooled by the low temperature radiator 37 flows through the motor 35, the motor 35 is cooled, and the temperature of the coolant flowing through the motor 35 is increased, so that the power battery 32 is heated.

And a tenth mode: heating the passenger compartment, heating the power battery, and cooling the motor (the low-temperature radiator 37 works).

When the passenger compartment and the power battery 32 have a heating requirement, the motor 35 has a cooling requirement, and the temperature of the motor 35 is high, the first reversing valve 11 is in the first state, the second reversing valve 33 is in the third state, the third reversing valve 34 is in the fifth state, the fourth reversing valve 36 is in the eighth state, and the electronic water pump 31 and the low-temperature radiator 37 operate.

The loop for heating the passenger compartment is the same as the first loop in the first mode, and the loop for heating the power battery 32 and cooling the motor 35 is the same as the tenth loop in the fifth mode.

In the first circulation loop, the refrigerant is liquefied in the condenser to release a large amount of heat, so that the passenger compartment is heated. Meanwhile, in the eleventh circulation loop, under the driving of the electronic water pump 31, the coolant cooled by the low-temperature radiator 37 is heated after heat exchange is performed between the coolant in the second fluid passage 20b and the refrigerant in the first fluid passage 20a, the heated coolant passes through the power battery 32, the power battery 32 can be heated, and the temperature of the motor 35 is high, so that the temperature of the motor 35 can be reduced when the coolant passes through the motor 35.

Optionally, as shown in fig. 5, in an embodiment of the present disclosure, the thermal management system of the automobile further includes: a gas-liquid separator 18. An input end of the gas-liquid separator 18 is connected to an output end of the first fluid passage 20a, and an output end of the gas-liquid separator 18 is connected to an input end of the electric compressor 12. The gas-liquid separator 18 is used to separate the gas-liquid mixture from the evaporator 17 or the heat exchanger 15, so that the gas enters the electric compressor 12, and the liquid coolant is prevented from directly entering the cylinder of the electric compressor 12, resulting in wet compression or liquid impact accidents.

Optionally, as shown in fig. 5, in the embodiment of the present disclosure, the thermal management system of the automobile further includes a plurality of check valves 19. Check valves 19 are arranged between the first electronic expansion valve 14 and the heat exchanger 15, between the second electronic expansion valve 16 and the heat exchanger 15, between the first reversing valve 11 and the condenser 13, between the first reversing valve 11 and the heat exchanger 15, and between the heat exchanger 15 and the heat exchange unit 20. The plurality of check valves 19 serve to prevent the reverse flow of the refrigerant when the flow direction of the refrigerant is regulated by the first direction changing valve 11.

Fig. 6 is a thermal management method of an automobile according to an embodiment of the present disclosure, which is applied to the thermal management system of the automobile shown in fig. 1, 2, 3, 4, or 5. The method may be performed by an automotive controller. Referring to fig. 6, the method includes:

in step 601, a thermal management request is received.

In some examples, a user may send a thermal management request to an automobile controller by clicking a function button on a terminal interface. The terminal can be a smart phone, a computer, a tablet, a vehicle-mounted terminal and the like.

In step 602, the state of the first reversing valve is controlled according to the thermal management request, and the electronic water pump is controlled to work.

In some embodiments, the thermal management request comprises a first thermal management request and a second thermal management request. The first thermal management request is used for requesting heating of the passenger cabin and the power battery at the same time, and the second thermal management request is used for requesting cooling of the passenger cabin and the power battery at the same time.

This step 602 includes: and controlling the first reversing valve to be in a first state in response to a first thermal management request for requesting heating of the passenger compartment and the power battery at the same time, or controlling the first reversing valve to be in a second state in response to a second thermal management request for requesting cooling of the passenger compartment and the power battery at the same time.

The first direction valve is configured such that in a first state, the first port of the first direction valve communicates with the second port of the first direction valve; in a second state, the first port of the first reversing valve is in communication with the third port of the first reversing valve.

The heat exchange unit and the electronic water pump are related to the embodiment shown in fig. 1, and a detailed description thereof is omitted.

In the embodiment of the disclosure, when the automobile has a passenger compartment heating requirement and a power battery heating requirement, the first port of the first reversing valve, the second port of the first reversing valve, the heating branch and the first fluid channel form a first circulation loop by configuring the first reversing valve to the first state. The heating branch circuit heats the passenger compartment, and meanwhile, after flowing through the first fluid channel of the heat exchange unit through the first circulation loop, the refrigerant heated by the heating branch circuit exchanges heat with the second fluid channel of the heat exchange unit, so that the temperature of the cooling liquid in the third circulation loop is increased, and the power battery is heated. When the automobile has the requirement of cooling the passenger compartment and the power battery, the first reversing valve is configured to be in the second state, so that the first port of the first reversing valve, the third port of the first reversing valve, the refrigeration branch and the first fluid channel form a second circulation loop. The refrigeration branch is cooled down to the passenger cabin, and simultaneously, the refrigerant of being cooled down by the refrigeration branch exchanges heat with the second fluid passage of heat exchange unit after the second circulation circuit flows through the first fluid passage of heat exchange unit for the coolant liquid cooling in the third circulation circuit, thereby realize cooling down power battery. The heat pump air conditioning unit can cool the power battery while cooling the passenger compartment, and can also heat the power battery while heating the passenger compartment, thereby perfecting the functions of the heat pump air conditioning unit of the automobile to a certain extent.

Optionally, in this disclosed embodiment, the thermal management request further includes a third thermal management request, where the third thermal management request is used to request that the passenger compartment, the power battery, and the motor are cooled simultaneously. The method of thermal management of an automobile further comprises: and responding to a third thermal management request for requesting simultaneous cooling of the passenger compartment, the power battery and the motor in the thermal management request, controlling the first reversing valve to be in the second state, the second reversing valve to be in the third state, and the third reversing valve to be in the fifth state, and controlling the electronic water pump to work.

Optionally, in the embodiment of the present disclosure, the thermal management request further includes a fourth thermal management request, where the fourth thermal management request is used to request heating of the passenger cabin and the power battery, and cooling of the motor. The method of thermal management of an automobile further comprises: responding to a fourth heat management request for requesting heating of the passenger compartment and the power battery and cooling of the motor in response to the heat management request, controlling the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state and the fourth reversing valve to be in the eighth state, and controlling the electronic water pump to operate; and controlling the electronic water pump and the water-cooled condenser to work.

Fig. 7 is another method for thermal management of an automobile according to an embodiment of the present disclosure, which is applied to the thermal management system of the automobile shown in fig. 5. The method may be performed by an automotive controller. Referring to fig. 7, the method includes:

in step 701, a thermal management request is received.

The thermal management request includes: a first thermal management request, a second thermal management request, a third thermal management request, a fourth thermal management request, a fifth thermal management request, a sixth thermal management request, a seventh thermal management request, an eighth thermal management request, a ninth thermal management request, and a tenth thermal management request.

The first thermal management request is a request for heating the passenger compartment and the power battery simultaneously; the second heat management request is a request for cooling the passenger compartment and the power battery simultaneously; the third heat management request is a request for cooling the passenger compartment, the power battery and the motor simultaneously; the fourth heat management request is a request for heating the passenger compartment and the power battery and cooling the motor; the fifth thermal management request is a passenger compartment heating request; the sixth thermal management request is a passenger compartment cooling request; the seventh thermal management request is a power battery heating request; the eighth thermal management request is a power battery cooling request; the ninth thermal management request is a request for cooling the power battery and the motor at the same time; the tenth thermal management request is a power battery heating and motor cooling request.

The user can send the thermal management request to the automobile controller by clicking a function button on the terminal interface. The interface function buttons may correspond to different thermal management functions.

The automobile heat management function comprises a passenger cabin and power battery simultaneous heating function, a passenger cabin and power battery simultaneous cooling function, a passenger cabin, power battery and motor simultaneous cooling function, a passenger cabin and power battery heating and motor cooling function, a passenger cabin heating function, a passenger cabin cooling function, a power battery heating function, a power battery cooling function, a power battery and motor simultaneous cooling function, a power battery heating function and a motor cooling function.

In step 702, based on the thermal management request, the thermal management system is controlled to perform a corresponding thermal management function.

And the automobile controller controls the thermal management system to execute the following corresponding thermal management functions according to the received different thermal management requests.

(1) The passenger compartment and the power battery are heated simultaneously.

The thermal management request is the first thermal management request, i.e., the passenger compartment and the power battery have heating requirements at the same time.

The automobile controller controls the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the sixth state, and the fourth reversing valve to be in the seventh state, and controls the electronic water pump to work and the low-temperature radiator to not work.

At this time, the thermal management system of the automobile forms a first circulation loop and a seventh circulation loop. In the first circulation loop, the refrigerant is liquefied in the condenser to release a large amount of heat, so that the passenger compartment is heated. Meanwhile, the heat of the refrigerant in the first fluid channel of the heat exchange unit heats the cooling liquid in the second fluid channel, and the heated cooling liquid flows through the power battery under the driving of the electronic water pump in the seventh circulation loop, so that the power battery is heated.

(2) And the passenger compartment and the power battery have the function of cooling simultaneously.

The thermal management request is a second thermal management request, i.e., the passenger compartment and the power battery have a cooling requirement at the same time.

If the cooling requirement of the power battery is small, the automobile controller controls the first reversing valve to be in the second state, the second reversing valve to be in the third state, the third reversing valve to be in the sixth state, and the fourth reversing valve to be in the seventh state, and controls the electronic water pump to work and the low-temperature radiator to not work.

At this time, the thermal management system forms a second circulation loop and a seventh circulation loop. In the second circulation loop, the refrigerant evaporates in the evaporator to absorb a large amount of heat, thereby realizing the cooling of the passenger compartment. Meanwhile, the cooling capacity of the refrigerant in the first fluid channel cools the cooling liquid in the second fluid channel, and the cooled cooling liquid flows through the power battery under the driving of the electronic water pump in the seventh circulation loop, so that the power battery is cooled.

If the cooling requirement of the power battery is large, the automobile controller controls the first reversing valve to be in the second state, the second reversing valve to be in the third state, the third reversing valve to be in the sixth state and the fourth reversing valve to be in the eighth state, and controls the electronic water pump and the low-temperature radiator to work.

At this time, the thermal management system of the automobile forms a second circulation loop and an eighth circulation loop. In the second circulation loop, the refrigerant is evaporated in the evaporator to absorb a large amount of heat, so that the temperature of the passenger compartment is reduced. Meanwhile, in the eighth circulation loop, under the driving of the electronic water pump, the cooling liquid is cooled by the low-temperature radiator after passing through the low-temperature radiator, and is cooled after being subjected to heat exchange with the refrigerant of the first circulation channel in the second circulation loop after passing through the second circulation channel of the heat exchange unit. The cooling liquid is cooled under the combined action of the refrigerant and the low-temperature radiator, and then the power battery with large cooling demand is cooled.

(3) And the passenger compartment, the power battery and the motor are cooled simultaneously.

The thermal management request is a third thermal management request, that is, the passenger compartment and the power battery have cooling requirements at the same time.

If the cooling requirements of the power battery and the motor are smaller, the automobile controller controls the first reversing valve to be in the second state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state and the fourth reversing valve to be in the seventh state, and controls the electronic water pump to work and the low-temperature radiator to not work.

At this time, the thermal management system of the automobile forms a second circulation loop and a ninth circulation loop. In the second circulation loop, the refrigerant is evaporated in the evaporator to absorb a large amount of heat, so that the temperature of the passenger compartment is reduced. Meanwhile, the refrigerant in the first fluid channel in the second circulation loop cools the cooling liquid in the second channel in the ninth circulation loop, and the cooled cooling liquid in the second fluid channel flows through the power battery and the motor under the driving of the electronic water pump, so that the cooling of the power battery and the cooling of the motor are realized.

If the cooling requirements of the power battery and the motor are large, the automobile controller controls the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state and the fourth reversing valve to be in the eighth state, and controls the electronic water pump and the low-temperature radiator to work.

At this time, the thermal management system of the automobile forms a second circulation loop and a tenth circulation loop. In the second circulation loop, the refrigerant is evaporated in the evaporator to absorb a large amount of heat, so that the temperature of the passenger compartment is reduced. Meanwhile, in the tenth circulation loop, under the driving of the electronic water pump, the cooling liquid is cooled by the low-temperature radiator after passing through the low-temperature radiator, and the cooling liquid is cooled after passing through the second circulation channel of the heat exchange unit to exchange heat with the refrigerant in the first circulation channel. The cooling liquid is cooled under the combined action of the refrigerant and the low-temperature radiator, so that the power battery and the motor which are high in cooling requirement are cooled.

(4) Passenger cabin and power battery heating and motor cooling functions.

The heat management request is a fourth heat management request, namely that the passenger compartment and the power battery have heating requirements at the same time, the motor has cooling requirements, and the temperature of the motor is higher.

The automobile controller controls the first reversing valve to be in the first state, the second reversing valve to be in the third state, the third reversing valve to be in the fifth state and the fourth reversing valve to be in the eighth state, and controls the electronic water pump and the low-temperature radiator to work.

At this time, the thermal management system of the automobile forms a first circulation loop and a tenth circulation loop. In the first circulation loop, the refrigerant is liquefied in the condenser to release a large amount of heat, so that the passenger compartment is heated. Meanwhile, in the tenth circulation loop, under the driving of the electronic water pump, the cooling liquid cooled by the low-temperature radiator is heated after heat exchange is carried out between the cooling liquid in the second fluid channel and the refrigerant in the first circulation channel, the heated cooling liquid passes through the power battery and can heat the power battery, and the temperature of the motor is high, so that the cooling liquid can cool the motor when flowing through the motor.

(5) Passenger compartment heating function.

The thermal management request is a fifth thermal management request, i.e., the passenger compartment has a heating demand.

The automobile controller controls the first reversing valve to be in a first state.

At this point, the thermal management system forms a first circulation loop. The refrigerant in the first circulation loop is liquefied in the condenser to release a large amount of heat, so that the passenger compartment is heated.

(6) And a passenger compartment cooling function.

The thermal management request is a sixth thermal management request, that is, the passenger compartment has a cooling demand.

And the automobile controller controls the first reversing valve to be in the second state.

At this point, the thermal management system forms a second circulation loop. And the refrigerant in the second circulation loop evaporates in the evaporator to absorb a large amount of heat, so that the passenger compartment is cooled.

(7) And (4) a power battery heating function.

The thermal management request is a seventh thermal management request, that is, the power battery has a heating requirement.

The automobile controller controls the second reversing valve to be in the fourth state, the third reversing valve to be in the fifth state and the fourth reversing valve to be in the seventh state, and controls the low-temperature radiator to be out of work and the electronic water pump to work.

At this time, the thermal management system of the automobile forms an eleventh circulation loop. In the eleventh circulation loop, the cooling liquid heated by the waste heat of the motor flows through the power battery under the driving of the electronic water pump, so that the waste heat of the motor heats the power battery.

(8) And (5) cooling the power battery.

The thermal management request is an eighth thermal management request, that is, the power battery has a cooling requirement.

The automobile controller controls the second reversing valve to be in the fourth state, the third reversing valve to be in the sixth state and the fourth reversing valve to be in the eighth state, and controls the electronic water pump and the low-temperature radiator to work.

At this time, the thermal management system of the automobile forms a twelfth circulation loop. In the twelfth circulation loop, under the driving of the electronic water pump, the cooling liquid cooled by the low-temperature radiator flows through the power battery, so that the power battery is cooled.

(9) And the power battery and the motor simultaneously have a cooling function.

The thermal management request is an eighth thermal management request, that is, the power battery and the motor have cooling requirements at the same time.

The automobile controller controls the second reversing valve to be in the fourth state, the third reversing valve to be in the fifth state and the fourth reversing valve to be in the eighth state, and controls the electronic water pump and the low-temperature radiator to work.

At this time, the thermal management system of the automobile forms a thirteenth circulation loop. In the thirteenth circulation loop, under the driving of the electronic water pump, the cooling liquid cooled by the low-temperature radiator flows through the power battery and the motor, so that the power battery and the motor are cooled.

(10) Power battery heating and motor cooling functions.

The heat management request is a tenth heat management request, that is, the power battery has a heating requirement, and the motor has a cooling requirement.

The automobile controller controls the second reversing valve to be in the fourth state, the third reversing valve to be in the fifth state, the fourth reversing valve to be in the eighth state, and the electronic water pump and the low-temperature radiator work.

At this time, the thermal management system of the automobile forms a thirteenth circulation loop. In the thirteenth circulation loop, under the driving of the electronic water pump, the cooling liquid cooled by the low-temperature radiator cools the motor after flowing through the motor, and the temperature of the cooling liquid flowing through the motor is increased, so that the power battery is heated.

In the embodiment of the disclosure, the thermal management function corresponding to the thermal management request can be realized for different thermal management requests, and the vehicle use experience of a user is enhanced to a certain extent.

Fig. 8 is a block diagram of a thermal management apparatus 800 of an automobile according to an embodiment of the present disclosure. As shown at 800, the apparatus includes: a receiving module 801 and a control module 802.

A receiving module 801, configured to receive a thermal management request; and the control module 802 is configured to control the state of the first reversing valve according to the thermal management request, and control the electronic water pump to operate.

Optionally, the control module 802 is further configured to control the first reversing valve to be in the first state in response to the thermal management request being a first thermal management request for requesting cooling of the passenger compartment and the power battery at the same time; or, in response to the thermal management request being a second thermal management request for requesting simultaneous heating of the passenger compartment and the power battery, controlling the first reversing valve to be in the second state.

Optionally, the control module 802 is further configured to, in response to the thermal management request being a third thermal management request for requesting to cool down the passenger compartment, the power battery, and the motor at the same time, control the first directional valve to be in the second state, the second directional valve to be in the third state, and the third directional valve to be in the fifth state, and control the electronic water pump to operate.

Optionally, the control module 802 is further configured to, in response to the thermal management request being a fourth thermal management request for requesting heating of the passenger compartment and the power battery and cooling of the motor, control the first directional valve to be in the first state, the second directional valve to be in the third state, the third directional valve to be in the fifth state, and the fourth directional valve to be in the eighth state, and control the electronic water pump and the low-temperature radiator to operate.

It should be noted that: in the thermal management apparatus 800 for an automobile according to the above embodiment, when performing thermal management on an automobile, only the above-mentioned division of the functional modules is taken as an example, and in practical applications, the above-mentioned function distribution may be completed by different functional modules according to needs, that is, the internal structure of the device may be divided into different functional modules to complete all or part of the above-mentioned functions. In addition, the automobile thermal management device 800 provided in the above embodiment and the embodiment of the thermal management method of the automobile belong to the same concept, and specific implementation processes thereof are described in the embodiment of the method for details, and are not described herein again.

Fig. 9 is a block diagram of a thermal management device of an automobile according to an embodiment of the present disclosure. As shown in fig. 9, the computer apparatus 900 may be a vehicle-mounted computer or the like. The computer device 900 comprises: a processor 901 and a memory 902.

Processor 901 may include one or more processing cores, such as a 4-core processor, a 9-core processor, and so forth. The processor 901 may be implemented in at least one hardware form of a DSP (Digital Signal Processing), an FPGA (Field-Programmable Gate Array), and a PLA (Programmable Logic Array). The processor 901 may also include a main processor and a coprocessor, where the main processor is a processor for Processing data in an awake state, and is also called a Central Processing Unit (CPU); a coprocessor is a low power processor for processing data in a standby state. In some embodiments, the processor 901 may be integrated with a GPU (Graphics Processing Unit), which is responsible for rendering and drawing the content required to be displayed on the display screen. In some embodiments, the processor 901 may further include an AI (Artificial Intelligence) processor for processing computing operations related to machine learning.

Memory 902 may include one or more computer-readable storage media, which may be non-transitory. The memory 902 may also include high-speed random access memory, as well as non-volatile memory, such as one or more magnetic disk storage devices, flash memory storage devices. In some embodiments, a non-transitory computer readable storage medium in the memory 902 is used to store at least one instruction for execution by the processor 901 to implement the thermal management method of the automobile provided in the embodiments of the present application.

Those skilled in the art will appreciate that the configuration shown in FIG. 9 does not constitute a limitation of computer devices, and may include more or fewer components than those shown, or some components may be combined, or a different arrangement of components may be employed.

An embodiment of the present invention further provides a non-transitory computer-readable storage medium, and when instructions in the storage medium are executed by a processor 901 of a computer device 900, the computer device is enabled to implement the thermal management method for an automobile provided in the embodiment of the present application.

A computer program product comprising instructions which, when run on a computer, cause the computer device 900 to perform the method for thermal management of an automobile according to an embodiment of the present application.

The above description is intended to be exemplary only and not to limit the present disclosure, and any modification, equivalent replacement, or improvement made without departing from the spirit and scope of the present disclosure is to be considered as the same as the present disclosure.

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