A multi-functional vehicle-mounted system

By separating the refrigerant-side integrated mechanism from the water cooler and the refrigeration unit, and using electronic expansion valves and sensors for high-precision control, the problem of overlapping refrigerant and water-side wiring in the vehicle thermal management system is solved, achieving simple and safe thermal management.

CN224490591UActive Publication Date: 2026-07-14SUZHOU ZHONGCHENG NEW ENERGY TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SUZHOU ZHONGCHENG NEW ENERGY TECH CO LTD
Filing Date
2025-08-11
Publication Date
2026-07-14

Smart Images

  • Figure CN224490591U_ABST
    Figure CN224490591U_ABST
Patent Text Reader

Abstract

The utility model relates to a kind of multifunctional vehicle-mounted system, including water cooler, water cooler has first condensate path and first water cooling passage;Refrigerating device, refrigerating device has second condensate path and second water cooling passage;At least two functional elements with heat exchange function;Agent side integration mechanism, agent side integration mechanism includes compressor, expansion valve, gas-liquid separator;Compressor, water cooler's first condensate path, expansion valve, refrigerating device's second condensate path, gas-liquid separator are connected in series;Expansion valve is set to electronic expansion valve, the suction side of compressor is connected with first sensor, the exhaust side of compressor is connected with second sensor, water cooler temperature sensor is connected between water cooler and electronic expansion valve;First, second water cooling passage is communicated with at least one functional element with heat exchange function by waterway.This utility model can be integrated by refrigerant side, pipeline organization is simple and safe, and the setting of electronic expansion valve and corresponding valve body, control stability is high.
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Description

Technical Field

[0001] This utility model relates to a thermal management system, and more particularly to a multi-functional vehicle-mounted system. Background Technology

[0002] The description in this section provides only background information related to the disclosure of this utility model and does not constitute prior art.

[0003] In vehicle-mounted thermal management systems, the main functions generally consist of refrigerant compression, cooling / cooling, and heating / cooling. In some scenarios, a water-cooled LCC (liquid cooler) acts as the condenser, and a water-cooled chiller acts as the evaporator. By intelligently controlling the circulation paths of the refrigerant and coolant, efficient cooling, heating, and energy recovery are achieved, making it particularly suitable for electric and hybrid vehicles. However, because the water cooler and chiller require simultaneous connection to both refrigerant and water lines, the intersection of these two different lines leads to a complex system structure, making low-cost and rapid installation difficult. Furthermore, to achieve rapid temperature regulation in the passenger compartment, refrigerant may be introduced into the passenger compartment, which carries lower safety risks, especially when using R290 refrigerant. Excessively long refrigerant pipes increase the risk of leakage, affecting thermal management efficiency and posing safety hazards. Therefore, it is necessary to isolate the refrigerant side from the water side.

[0004] By isolating the refrigerant side from the water side, it is expected that the refrigerant path will be shortened. The various devices in the path have a greater impact on the refrigerant, so more precise control of the refrigerant is required. There is currently no control solution for this scenario in the existing technology.

[0005] It should be noted that the above introduction to the technical background is only for the purpose of providing a clear and complete explanation of the technical solutions of this utility model and facilitating understanding by those skilled in the art. It should not be assumed that these technical solutions are known to those skilled in the art simply because they have been described in the background section of this utility model. Utility Model Content

[0006] The purpose of this invention is to provide a multi-functional vehicle system that integrates the refrigerant side, resulting in a simple and safe pipeline structure, and achieves high control stability through the use of an electronic expansion valve and corresponding valve body.

[0007] To achieve the above objectives, this utility model discloses a multi-functional vehicle-mounted system, which includes:

[0008] A water cooler having a first condensate path and a first water cooling path;

[0009] The refrigerator has a second condensate passage and a second water cooling passage;

[0010] At least two functional components with heat exchange capabilities;

[0011] The agent-side integrated mechanism includes a compressor, an expansion valve, and a gas-liquid separator; the compressor, the first condensate circuit of the water cooler, the expansion valve, the second condensate circuit of the refrigerator, and the gas-liquid separator are connected in series; the expansion valve is configured as an electronic expansion valve; a first sensor is connected to the suction side of the compressor, a second sensor is connected to the discharge side of the compressor, and a water cooler temperature sensor is connected between the water cooler and the electronic expansion valve;

[0012] The first water-cooling passage is connected to at least one of the aforementioned functional components with heat exchange function via a water passage;

[0013] The second water-cooling passage is connected to at least one of the aforementioned functional components with heat exchange function via a water path;

[0014] The functional component with heat exchange function is any one of a cooler, heater, fan heat exchange unit, battery heat exchange unit, or drive motor heat exchange unit.

[0015] As a further description of the above technical solution, the first sensor and the second sensor are configured as temperature sensors for a pressure water cooler.

[0016] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler.

[0017] The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

[0018] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant flows through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The first water-cooling passage is also connected in series with the outlet of the water cooler, the heater, and the inlet of the water cooler. The coolant flows through the outlet of the water cooler and the heater in sequence and then returns to the inlet of the water cooler.

[0019] The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

[0020] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the heater, and the inlet of the water cooler, and the coolant flows through the outlet of the water cooler and the heater in sequence before returning to the inlet of the water cooler;

[0021] The second water-cooling passage is connected in series with the cooler outlet, the fan heat exchange unit, the drive motor heat exchange unit, and the cooler inlet. The coolant flows through the cooler outlet, the fan heat exchange unit, and the drive motor heat exchange unit in sequence before returning to the cooler inlet.

[0022] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler.

[0023] The second water-cooling passage is connected in series with the cooler outlet, the battery heat exchange unit, and the cooler inlet. The coolant passes through the cooler outlet and the battery heat exchange unit in sequence and then returns to the cooler inlet.

[0024] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the battery heat exchange unit, and the inlet of the water cooler, and the coolant passes through the outlet of the water cooler and the battery heat exchange unit in sequence and then returns to the inlet of the water cooler.

[0025] The second water-cooling passage is connected in series with the cooler outlet, the fan heat exchange unit, the drive motor heat exchange unit, and the cooler inlet. The coolant flows through the cooler outlet, the fan heat exchange unit, and the drive motor heat exchange unit in sequence before returning to the cooler inlet.

[0026] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler.

[0027] The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet. The second water-cooling passage is also connected in series with the refrigerator outlet, the battery heat exchange unit, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the battery heat exchange unit in sequence and then returns to the refrigerator inlet.

[0028] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant flows sequentially through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit before returning to the inlet of the water cooler. The first water-cooling passage is also connected in series with the outlet of the water cooler, the battery heat exchange unit, and the inlet of the water cooler. The coolant flows sequentially through the outlet of the water cooler and the battery heat exchange unit before returning to the inlet of the water cooler.

[0029] The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

[0030] As a further description of the above technical solution, the first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The first water-cooling passage is also connected in series with the outlet of the water cooler, the heater, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler and the heater in sequence and then returns to the inlet of the water cooler.

[0031] The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

[0032] Based on the above technical solution, the beneficial effects of this utility model are as follows:

[0033] This utility model's multi-functional vehicle-mounted system integrates the refrigerant side, resulting in a simple and safe pipeline structure. In this utility model, the entire refrigerant operating mechanism is integrated into the refrigerant-side integrated mechanism, separate from other mechanisms and not introduced into locations such as the passenger compartment, thus providing high safety. Simultaneously, the operation of the heat exchange water circuit is connected according to the corresponding functional requirements. Heat exchange in the passenger compartment and fan heat exchange mechanisms relies entirely on water temperature control, resulting in lower costs, easier pipeline organization, and enhanced safety.

[0034] Meanwhile, the electronic expansion valve in this invention, in conjunction with the corresponding sensor, is more flexible and responsive than the existing thermostatic expansion valve that relies solely on mechanical thermal control.

[0035] To further understand the features and technical content of this utility model, please refer to the following detailed description and drawings of this utility model. However, the drawings provided are for reference and illustration only and are not intended to limit this utility model. Attached Figure Description

[0036] To more clearly illustrate the technical solutions in the embodiments or prior art of this specification, the drawings used in the description of the embodiments or prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this specification. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0037] Figure 1 This is a schematic diagram of the cooling system of a multi-functional vehicle-mounted system provided in the embodiments of this specification;

[0038] Figure 2 This is a schematic diagram of a dehumidification system for a multi-functional vehicle-mounted system provided in the embodiments of this specification;

[0039] Figure 3 This is a schematic diagram of the heating system of a multi-functional vehicle-mounted system provided in the embodiments of this specification;

[0040] Figure 4 This is a schematic diagram of the cooling of a battery heat exchange unit in a multi-functional vehicle system provided in the embodiments of this specification;

[0041] Figure 5 This is a schematic diagram of the battery heat exchange unit of a multi-functional vehicle system provided in the embodiments of this specification;

[0042] Figure 6 This is a schematic diagram of the cooling system and the cooling of the battery heat exchange unit of a multi-functional vehicle system provided in the embodiments of this specification;

[0043] Figure 7 This is a schematic diagram of the cooling and heating of the battery heat exchange unit of a multi-functional vehicle system provided in the embodiments of this specification;

[0044] Figure 8 This is a schematic diagram of the dehumidification and battery heat exchange unit shutdown of a multi-functional vehicle system provided in the embodiments of this specification;

[0045] Figure 9 This is a schematic diagram of the fourteen valve ports of the water-side valve island of a multi-functional vehicle-mounted system provided in the embodiments of this specification;

[0046] In the picture:

[0047] 1. Water-side valve island; 11. First valve port; 12. Second valve port; 13. Third valve port; 14. Fourth valve port; 15. Fifth valve port; 16. Sixth valve port; 17. Seventh valve port; 18. Eighth valve port; 19. Ninth valve port; 110. Tenth valve port; 111. Eleventh valve port; 112. Twelfth valve port; 113. Thirteenth valve port; 114. Fourteenth valve port;

[0048] 2. Agent-side integrated mechanism; 21. Compressor; 22. Water cooler; 23. Expansion valve; 24. Refrigerator; 25. Gas-liquid separator; 26. First sensor; 27. Second sensor; 28. Water cooler temperature sensor;

[0049] 3. Passenger cabin mechanism; 31. Cooler; 32. Heater; 33. Blower;

[0050] 4. Fan heat exchange mechanism; 41. Fan heat exchange unit; 42. Heat exchange fan;

[0051] 5. Electric heater; 51. First pump body;

[0052] 6. Water tank; 61. Second pump body;

[0053] 7. Battery heat exchange unit; 71. Third pump body;

[0054] 8. Drive motor heat exchange unit;

[0055] In the diagram, blue represents cold water, red and orange represent hot water, and black represents refrigerant. Detailed Implementation

[0056] To enable those skilled in the art to better understand the technical solutions in this specification, the technical solutions in the embodiments of this specification will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this specification, and not all embodiments. Based on the embodiments in this specification, all other embodiments obtained by those skilled in the art without creative effort should fall within the scope of protection of this specification.

[0057] The following specific embodiments illustrate the implementation of this utility model. Those skilled in the art can understand the advantages and effects of this utility model from the content disclosed in this specification. This utility model can be implemented or applied through other different specific embodiments, and various details in this specification can also be modified and changed based on different viewpoints and applications without departing from the concept of this utility model. Furthermore, the accompanying drawings of this utility model are for simple illustration only and are not depictions of actual dimensions, as stated in advance. The following embodiments will further describe the relevant technical content of this utility model in detail, but the disclosed content is not intended to limit the scope of protection of this utility model.

[0058] It should be understood that while terms such as "first," "second," and "third" may be used in this document to describe various components or signals, these components or signals should not be limited by these terms. These terms are primarily used to distinguish one component from another, or one signal from another. Furthermore, the term "or" as used herein should, as appropriate, include any combination of one or more of the related listed items.

[0059] Please see Figure 1 This embodiment provides a multi-functional vehicle-mounted system, which includes:

[0060] Water cooler 22, water cooler 22 has a first condensate passage and a first water cooling passage;

[0061] Refrigerator 24, refrigerator 24 has a second condensate passage and a second water cooling passage;

[0062] At least two functional components with heat exchange capabilities;

[0063] The agent-side integrated mechanism 2 includes a compressor 21, an expansion valve 22, and a gas-liquid separator 25; the compressor 21, the first condensate path of the water cooler 22, the expansion valve 23, the second condensate path of the refrigerator 24, and the gas-liquid separator 25 are connected in series; a first sensor 26 is connected to the suction side of the compressor 21, a second sensor 27 is connected to the discharge side of the compressor 21, a water cooler temperature sensor 28 is connected between the water cooler 22 and the expansion valve 23, and the expansion valve 23 is set as an electronic expansion valve;

[0064] The first water-cooling passage is connected to at least one functional component with heat exchange function via a water channel;

[0065] The second water-cooling passage is connected to at least one functional component with heat exchange function via a water channel;

[0066] The functional component with heat exchange function is not limited to, but can be any one of the following: cooler 31, heater 32, fan heat exchange unit 41, battery heat exchange unit 7, or drive motor heat exchange unit 8.

[0067] Specifically, in the above structure, the corresponding water passage can be mixed or heat exchanged through the water-side valve island 1.

[0068] In the above structure, the water-side valve island 1 is mainly used to collect and exchange heat from water flows of different temperatures introduced from the agent-side integrated mechanism 2, passenger cabin mechanism 3, and fan heat exchange mechanism 4. It can mix cold and hot water flows according to actual needs to achieve temperature control. The water-side valve island 1 can switch between different flow channels through electronic control. In this embodiment, the water-side valve island 1 is a conventional multi-way valve body, such as a disc valve.

[0069] In actual operation, compressor 21 compresses the low-temperature, low-pressure refrigerant into a high-temperature, high-pressure refrigerant, which then enters the downstream water cooler 22. The high-temperature, high-pressure refrigerant heats the water flow in water cooler 22 and flows to expansion valve 23. After expansion and pressure reduction, it becomes a low-temperature, low-pressure refrigerant and enters the downstream refrigerator 24. The low-temperature, low-pressure refrigerant cools the water flow in refrigerator 24 and flows to gas-liquid separator 25. After gas-liquid separation, at least a portion of the refrigerant returns to compressor 21 from the suction port for the next cycle. Simultaneously, the heated water flow in water cooler 22 provides hot water to water-side valve island 1, and the cooled water flow in refrigerator 24 provides cold water to water-side valve island 1.

[0070] The cooler 22 in the agent-side integrated mechanism 2 is mainly used to directly supply high-temperature water to the water-side valve island 1, and the cooler 24 is mainly used to supply low-temperature water to the water-side valve island 1. The high-temperature water flows through the water-side valve island 1 through the corresponding functional element with heat exchange function, and is heated or used to dissipate heat from the water flow. Similarly, the low-temperature water flows through the water-side valve island 1 through the corresponding functional element with heat exchange function, and is cooled or used to heat the water flow. Under specific conditions, it is connected in series with the preset mechanism water circuit in the passenger cabin mechanism 3 and the fan heat exchange mechanism 4 to achieve the final thermal management function.

[0071] like Figure 1 As shown, by setting up the above system, the refrigerant side can be integrated (that is... Figure 1 The refrigerant-side integration mechanism 2 is located in the center of the system, resulting in a simple and highly safe pipeline organization. The entire refrigerant operation is integrated into the refrigerant-side integration mechanism 2, separate from other parts of the air conditioning system, and is not introduced into the passenger compartment. Figure 1The passenger cabin mechanism 3 is located in a central position, which provides high safety. At the same time, the operation of the heat exchange water circuit is adjusted entirely through the water-side valve island 1. In the passenger cabin mechanism 3 and the fan heat exchange mechanism 4, heat control and distribution are achieved entirely by controlling the temperature of the water. This results in lower cost, easier pipeline organization, and higher safety.

[0072] In one embodiment, the electric heater 5 and the first water cooling passage of the water cooler 22 are connected in series to provide auxiliary heating for the water flow of the water cooler 22 when the heat source is insufficient. In this embodiment, the electric heater can be set to a power of 7 kW.

[0073] like Figure 1-8 As shown, in this embodiment, the expansion valve 23 is set as an electronic expansion valve. Through the cooperation of the electronic expansion valve and multiple sets of sensors, high-precision monitoring of subcooling is achieved. This, combined with the gas-liquid separator 25, enables gas-liquid separation control, resulting in stable and highly accurate operation. In this embodiment, a first sensor 26 is connected in series between the compressor 21 and the gas-liquid separator 25. A second sensor 27 is connected in series between the compressor 25 and the water cooler 22. A water cooler temperature sensor 28 is connected in series between the water cooler 22 and the refrigerator 24. The first sensor 26 and the second sensor 27 are configured as pressure water cooler temperature sensors. In this embodiment, the expansion valve 23 is set as an electronic expansion valve. The first sensor 26 upstream of the compressor 21 is used to monitor the temperature and pressure of the refrigerant at the suction port to maintain equivalent operation. Similarly, from a safety perspective, a second sensor 27 is also set at the discharge port downstream of the compressor 21 for temperature and pressure monitoring, which is applicable to compressor structures without a pressure relief valve. The water cooler temperature sensor 28 upstream of the expansion valve 23 is mainly used for monitoring subcooling and coordinating with the electronic expansion valve to adjust the switch size. The gas-liquid separator 25 in this invention is mainly used to monitor subcooling. In conjunction with the corresponding sensors mentioned above, the monitoring results of subcooling are used to control the opening of the electronic expansion valve, so as to ensure the smooth flow of refrigerant.

[0074] Please see Figure 1 In one operating mode, the system cools the passenger cabin, maintains the temperature of the battery heat exchange unit 7, and dissipates heat from the drive motor heat exchange unit 8. Temperature control refers to keeping the temperature within a certain range, such as 20℃-30℃.

[0075] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. In this embodiment, the high-temperature fluid that absorbs heat from the water cooler 22 and the drive motor heat exchange unit 8 sequentially is transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed.

[0076] The second water-cooling passage is connected in series with the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Cooling fluid flows sequentially through the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Similarly, in this embodiment, the low-temperature fluid cooled by the refrigerator 24 is transported to the cooler 31, and then blown by the blower 33 through the cooler 31 to cool the passenger cabin.

[0077] Simultaneously, the water path of the battery heat exchange unit 7 and the high-temperature fluid from the water cooler 22 and the low-temperature fluid from the refrigerator 24 are mixed in the water-side valve island 1. After flowing into the water-side valve island 1 through the tenth valve port 110, it flows back to the battery heat exchange unit 7 through the eleventh valve port 111. Therefore, the temperature of the battery heat exchange unit 7 can be controlled.

[0078] Please see Figure 2 In one of the operating modes, the system dehumidifies the passenger cabin, maintains and controls the temperature of the battery heat exchange unit 7, and dissipates heat from the drive motor heat exchange unit 8. Temperature control refers to keeping the temperature within a certain range, such as 20℃-30℃.

[0079] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The first water-cooling passage is also connected in series with the outlet of the water cooler 22, the first valve port 11, the third valve port 13, the heater 32, the fourth valve port 14, the fourteenth valve port 114, the eighth valve port 18, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler and the heater 32 before returning to the inlet of the water cooler. In this embodiment, the high-temperature fluid that absorbs heat from the water cooler 22 and the drive motor heat exchange unit 8 sequentially is transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed. At the same time, in this embodiment, the high-temperature fluid heated by the water cooler 22 is also transported to the heater 32, and then the blower 33 blows it through the heater 32 to heat the passenger cabin.

[0080] The second water-cooling passage is connected in series with the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Cooling fluid flows sequentially through the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. In this embodiment, the low-temperature fluid cooled by the refrigerator 24 is transported to the cooler 31, and then blown by the blower 33 through the cooler 31 to cool the passenger cabin.

[0081] Simultaneously, the water path of the battery heat exchange unit 7 and the high-temperature fluid from the water cooler 22 and the low-temperature fluid from the refrigerator 24 are mixed in the water-side valve island 1. After flowing into the water-side valve island 1 through the tenth valve port 110, it flows back to the battery heat exchange unit 7 through the eleventh valve port 111. Therefore, the temperature of the battery heat exchange unit 7 can be controlled.

[0082] Specifically, the cooler 31 and the electric heater 32 in the passenger cabin mechanism 3 can be operated intermittently, so that the cooler 31 plays a condensing role, and water in the air condenses in the cooler 31 and is discharged to achieve dehumidification. Then, the heater 32 is used to heat the air that is blown out by the blower 33, so as to maintain the stability of the passenger cabin temperature while ensuring dehumidification, so as to achieve the purpose of regulating humidity without excessive temperature regulation, and avoiding cooling the passenger cabin in environments where cooling is not required.

[0083] Please see Figure 3 In one of the operating modes, the system heats the passenger cabin, maintains and controls the temperature of the battery heat exchange unit 7, and dissipates heat from the drive motor heat exchange unit 8. Temperature control refers to keeping the temperature within a certain range, such as 20℃-30℃.

[0084] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the third valve port 13, the heater 32, the fourth valve port 14, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows through the outlet of the water cooler and the heater 32 in sequence and then returns to the inlet of the water cooler. It is then transported to the heater 32 by means of the high-temperature fluid heated by the water cooler 22, and then blown by the blower 33 through the heater 32 to heat the passenger cabin.

[0085] The second water-cooling passage is connected in series with the outlet of the cooler 24, the thirteenth valve port 113, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the ninth valve port 19, the drive motor heat exchange unit 8, the eighth valve port 18, and the inlet of the cooler 24. The coolant flows sequentially through the outlet of the cooler 24, the thirteenth valve port 113, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the ninth valve port 19, the drive motor heat exchange unit 8, the eighth valve port 18, and the inlet of the cooler 24. In this embodiment, the low-temperature water output from the cooler 24 absorbs heat in the drive motor heat exchange unit 8 and is then transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed.

[0086] Simultaneously, the water path of the battery heat exchange unit 7 and the high-temperature fluid from the water cooler 22 and the low-temperature fluid from the refrigerator 24 are mixed in the water-side valve island 1. After flowing into the water-side valve island 1 through the tenth valve port 110, it flows back to the battery heat exchange unit 7 through the eleventh valve port 111. Therefore, the temperature of the battery heat exchange unit 7 can be controlled.

[0087] Please see Figure 4 In one of the operating modes, the passenger cabin is ventilated, the battery heat exchange unit 7 is cooled, and the drive motor heat exchange unit 8 is cooled.

[0088] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. In this embodiment, the high-temperature fluid that absorbs heat from the water cooler 22 and the drive motor heat exchange unit 8 sequentially is transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed.

[0089] The second water-cooling passage is connected in series with the outlet of the cooler 24, the thirteenth valve port 113, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the cooler 24. The coolant flows sequentially through the outlet of the cooler 24, the thirteenth valve port 113, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the cooler 24, and cools the battery heat exchange unit 7 by the low-temperature water flow output by the cooler 24.

[0090] Please see Figure 5 In one of the operating modes, the system heats the passenger cabin, heats the battery heat exchange unit 7, and dissipates heat from the drive motor heat exchange unit 8.

[0091] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the water cooler 22. In this embodiment, the high-temperature water flow output from the water cooler 22 is input to the battery heat exchange unit 7 and heats the battery heat exchange unit 7.

[0092] The second water-cooling passage is connected in series with the outlet of the cooler 24, the thirteenth valve port 113, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the ninth valve port 19, the drive motor heat exchange unit 8, the eighth valve port 18, and the inlet of the cooler 24. The coolant flows sequentially through the outlet of the cooler 24, the thirteenth valve port 113, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the ninth valve port 19, the drive motor heat exchange unit 8, the eighth valve port 18, and the inlet of the cooler 24. In this embodiment, the low-temperature water output from the cooler 24 absorbs heat in the drive motor heat exchange unit 8 and is then transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed.

[0093] In this embodiment, the passenger cabin mechanism 3 may not participate in operation, thus maintaining ventilation in the passenger cabin.

[0094] Please see Figure 6 In one operating mode, the system cools the passenger cabin, cools the battery heat exchange unit 7, and dissipates heat from the drive motor heat exchange unit 8. Temperature control refers to keeping the temperature within a certain range, such as 20℃-30℃.

[0095] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. In this embodiment, the high-temperature fluid that absorbs heat from the water cooler 22 and the drive motor heat exchange unit 8 sequentially is transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed.

[0096] The second water-cooling passage is connected in series with the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Cooling fluid flows sequentially through the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Similarly, in this embodiment, the low-temperature fluid cooled by the refrigerator 24 is transported to the cooler 31, and then blown by the blower 33 through the cooler 31 to cool the passenger cabin. Meanwhile, the second water-cooling passage is connected in series with the outlet of the cooler 24, the thirteenth valve port 113, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the cooler 24. The coolant flows sequentially through the outlet of the cooler 24, the thirteenth valve port 113, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the cooler 24. The low-temperature water flow output by the cooler 24 cools the battery heat exchange unit 7.

[0097] Please see Figure 7 In one operating mode, it cools the passenger cabin, heats the battery heat exchange unit 7, and dissipates heat from the drive motor heat exchange unit 8. Temperature control refers to keeping the temperature within a certain range, such as 20℃-30℃.

[0098] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. In this embodiment, the high-temperature fluid that absorbs heat from the water cooler 22 and the drive motor heat exchange unit 8 sequentially is transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed.

[0099] Meanwhile, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the eleventh valve port 111, the battery heat exchange unit 7, the tenth valve port 110, and the inlet of the water cooler 22. In this embodiment, the high-temperature water flow output from the water cooler 22 is input to the battery heat exchange unit 7 and heats the battery heat exchange unit 7.

[0100] The second water-cooling passage is connected in series with the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Cooling fluid flows sequentially through the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. In this embodiment, the low-temperature fluid cooled by the refrigerator 24 is transported to the cooler 31, and then blown by the blower 33 through the cooler 31 to cool the passenger cabin.

[0101] Please see Figure 8 In one operating mode, the passenger cabin is dehumidified, battery heat exchange unit 7 is shut down, and drive motor heat exchange unit 8 is cooled. Temperature control refers to keeping the temperature within a certain range, such as 20℃-30℃.

[0102] In this mode, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows sequentially through the outlet of the water cooler 22, the first valve port 11, the seventh valve port 17, the fan heat exchange unit 41, the sixth valve port 16, the eighth valve port 18, the drive motor heat exchange unit 8, the eighth valve port 18, the fourteenth valve port 114, and the inlet of the water cooler 22. In this embodiment, the high-temperature fluid that absorbs heat from the water cooler 22 and the drive motor heat exchange unit 8 sequentially is transported to the fan heat exchange unit 41 in the fan heat exchange mechanism 4 for external heat dissipation. During the heat dissipation process, the heat exchange fan 42 can be used to accelerate the heat dissipation speed. Meanwhile, the first water-cooling passage is connected in series with the outlet of the water cooler 22, the first valve port 11, the third valve port 13, the heater 32, the fourth valve port 14, the fourteenth valve port 114, and the inlet of the water cooler 22. The coolant flows through the outlet of the water cooler and the heater 32 in sequence and then returns to the inlet of the water cooler. It is then transported to the heater 32 by means of the high-temperature fluid heated by the water cooler 22, and then blown by the blower 33 through the heater 32 to heat the passenger cabin.

[0103] The second water-cooling passage is connected in series with the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. Cooling fluid flows sequentially through the outlet of the refrigerator 24, the thirteenth valve port 113, the second valve port 12, the cooler 31, the fifth valve port 15, the twelfth valve port 112, and the inlet of the refrigerator 24. In this embodiment, the low-temperature fluid cooled by the refrigerator 24 is transported to the cooler 31, and then blown by the blower 33 through the cooler 31 to cool the passenger cabin.

[0104] In another embodiment, the first pump body 51 is connected in series to the pipe connecting the water cooler 22 and the water-side valve island 1, in order to pump the hot water output from the water cooler 22.

[0105] Similarly, the second pump body 61 is connected in series to the pipe connecting the chiller 24 and the water-side valve island 1, with the purpose of pumping the chilled water output from the chiller 24. It is worth noting that a water tank 6 is also connected in series in the above-mentioned pipe to control the water volume in the pipeline.

[0106] Similarly, the third pump body 71 is connected in series to the pipeline connecting the battery heat exchange unit 7 and the water-side valve island 1. Its purpose is to deliver corresponding cold or hot water to the battery heat exchange unit 7 in order to achieve temperature control of the battery heat exchange unit 7.

[0107] In the above embodiment, the blower 33 is oriented towards the passenger compartment to directly introduce warm or cold air into the passenger compartment, while the heat exchange fan 42 is oriented towards the outside of the vehicle to reduce the temperature difference between the fan heat exchange unit 41 and the outside air.

[0108] In another embodiment, the water cooler 22, the expansion valve 23, the refrigerator 24, and the gas-liquid separator 25 are mounted on the compressor 21. That is, the refrigerant-side structure in this embodiment is actually a precisely integrated structure centered on and supported by the compressor 21, achieving clear separation between the refrigerant and water sides, high safety, and high integration.

[0109] The above-disclosed content is only a preferred and feasible embodiment of the present utility model, and is not intended to limit the scope of the patent application of the present utility model. Therefore, all equivalent technical changes made using the contents of the present utility model specification and drawings are included in the scope of the patent application of the present utility model.

[0110] The various embodiments in this specification are described in a progressive manner. The same or similar parts between the various embodiments can be referred to each other. Each embodiment focuses on describing the differences from other embodiments.

[0111] Although this application has been described by way of examples, those skilled in the art will know that this application has many modifications and variations without departing from the spirit of this application, and it is intended that the appended embodiments include these modifications and variations without departing from this application.

Claims

1. A multi-functional vehicle-mounted system, characterized in that, The multi-functional vehicle system includes: A water cooler having a first condensate path and a first water cooling path; The refrigerator has a second condensate passage and a second water cooling passage; At least two functional components with heat exchange capabilities; The agent-side integrated mechanism includes a compressor, an expansion valve, and a gas-liquid separator; the compressor, the first condensate circuit of the water cooler, the expansion valve, the second condensate circuit of the refrigerator, and the gas-liquid separator are connected in series; the expansion valve is configured as an electronic expansion valve; a first sensor is connected to the suction side of the compressor, a second sensor is connected to the discharge side of the compressor, and a water cooler temperature sensor is connected between the water cooler and the electronic expansion valve; The first water-cooling passage is connected to at least one of the aforementioned functional components with heat exchange function via a water passage; The second water-cooling passage is connected to at least one of the aforementioned functional components with heat exchange function via a water path; The functional component with heat exchange function is any one of a cooler, heater, fan heat exchange unit, battery heat exchange unit, or drive motor heat exchange unit.

2. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first sensor and the second sensor are configured as temperature sensors for a pressure water cooler.

3. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

4. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant flows through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The first water-cooling passage is also connected in series with the outlet of the water cooler, the heater, and the inlet of the water cooler. The coolant flows through the outlet of the water cooler and the heater in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

5. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the heater, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler and the heater in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the cooler outlet, the fan heat exchange unit, the drive motor heat exchange unit, and the cooler inlet. The coolant flows through the cooler outlet, the fan heat exchange unit, and the drive motor heat exchange unit in sequence before returning to the cooler inlet.

6. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the cooler outlet, the battery heat exchange unit, and the cooler inlet. The coolant passes through the cooler outlet and the battery heat exchange unit in sequence and then returns to the cooler inlet.

7. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the battery heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler and the battery heat exchange unit in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the cooler outlet, the fan heat exchange unit, the drive motor heat exchange unit, and the cooler inlet. The coolant flows through the cooler outlet, the fan heat exchange unit, and the drive motor heat exchange unit in sequence before returning to the cooler inlet.

8. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant passes through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet. The second water-cooling passage is also connected in series with the refrigerator outlet, the battery heat exchange unit, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the battery heat exchange unit in sequence and then returns to the refrigerator inlet.

9. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant flows sequentially through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit before returning to the inlet of the water cooler. The first water-cooling passage is also connected in series with the outlet of the water cooler, the battery heat exchange unit, and the inlet of the water cooler. The coolant flows sequentially through the outlet of the water cooler and the battery heat exchange unit before returning to the inlet of the water cooler. The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.

10. The multi-functional vehicle-mounted system according to claim 1, characterized in that: The first water-cooling passage is connected in series with the outlet of the water cooler, the fan heat exchange unit, the drive motor heat exchange unit, and the inlet of the water cooler. The coolant flows through the outlet of the water cooler, the fan heat exchange unit, and the drive motor heat exchange unit in sequence and then returns to the inlet of the water cooler. The first water-cooling passage is also connected in series with the outlet of the water cooler, the heater, and the inlet of the water cooler. The coolant flows through the outlet of the water cooler and the heater in sequence and then returns to the inlet of the water cooler. The second water-cooling passage is connected in series with the refrigerator outlet, the cooler, and the refrigerator inlet. The coolant flows through the refrigerator outlet and the cooler in sequence and then returns to the refrigerator inlet.