WO2023274312A1

WO2023274312A1 - Engineering vehicle battery heat management system and method

Info

Publication number: WO2023274312A1
Application number: PCT/CN2022/102460
Authority: WO
Inventors: 阮计连; 戈超; 冯汉队; 王振清; 周辉; 张冬
Original assignee: 徐州徐工矿业机械有限公司
Priority date: 2021-06-29
Filing date: 2022-06-29
Publication date: 2023-01-05
Also published as: CN113451674A; CN113451674B

Abstract

Disclosed in the present invention are an engineering vehicle battery heat management system and a control method. The engineering vehicle battery heat management system comprises a battery pack, the battery pack is provided with a water inlet and a water outlet, the water inlet is connected to a water pump, and the system further comprises an electronic three-way valve A, an electronic three-way valve B, a radiator, a plate changer and a heater; a first end of the electronic three-way valve A is connected to the water outlet, a second end is connected to a first end of the electronic three-way valve B by means of the radiator, and a third end is connected to the first end of the electronic three-way valve B by means of the plate changer; a second end of the electronic three-way valve B is connected to the water inlet by means of the heater, and a third end is directly connected to the water inlet; the water inlet is connected to an inlet temperature sensor and the water pump, and the water outlet is connected to an outlet temperature sensor. The following advantages are as follows: 1. a battery heat dissipation mode may be automatically switched according to an ambient temperature and a battery temperature; 2, the heat management of a battery can be realized in a full temperature range; 3, the heat management system is convenient and flexible to adjust, high in applicability and high in reliability.

Description

System and method for heat management of engineering vehicle battery

technical field

The invention belongs to the technical field of new energy, and in particular relates to a heat management system and method for engineering vehicle batteries.

Background technique

With the development of motors, batteries and control technologies, more and more large-scale mining equipment is driven by electric power, including electric excavators, electric loaders and pure electric mine dump trucks. In particular, pure electric dump trucks have an absolute advantage in large-scale mine earthwork transportation. As one of the important components of a pure electric dump truck, the performance of the battery system directly affects the mileage of the vehicle. The working environment of the mine car is harsh, and the battery performance of the pure electric mine car is limited to varying degrees under low or high temperature environments. Therefore, a reliable battery heat management system is particularly important.

The traditional battery thermal management system needs to use the compressor frequently when the battery is cooled, resulting in increased system power consumption and greatly reducing the reliability of high-voltage accessories; when the battery is heated, it only relies on the heating film, the heating rate is slow and there is no battery insulation function , reducing the transport efficiency. In addition, the traditional battery thermal management system has a single heat dissipation and cooling mode, no shutdown heat preservation and self-circulation functions, and narrow coverage methods. These factors limit the performance of the vehicle to a certain extent. In order to solve this problem, the present invention proposes a battery heat management system that can control different heat dissipation methods according to the ambient temperature and battery temperature, which not only reduces the energy consumption of the vehicle but also improves the reliability of the battery system.

Contents of the invention

Aiming at the problems of large temperature differences in the operating environment of pure electric engineering vehicles and complex temperature changes in the working process, the present invention provides a battery heat management system and method for engineering vehicles, which can deal with battery heat management problems under various complex working conditions.

The technical solution adopted in the present invention: a battery heat management system for engineering vehicles, including a battery pack, the battery pack is provided with a water inlet and a water outlet, the water inlet is connected to a water pump, and also includes an electronic three-way valve A, an electronic Three-way valve B, radiator, plate changer and heater; the first end of the electronic three-way valve A is connected to the water outlet, the second end is connected to the first end of the electronic three-way valve B through the radiator, and the third The end is connected to the first end of the electronic three-way valve B through the plate changer; the second end of the electronic three-way valve B is connected to the water inlet through the heater, and the third end is directly connected to the water inlet; the water inlet is connected to the inlet A temperature sensor and a water pump, the water outlet is connected with an outlet temperature sensor.

Preferably, the plate exchanger is connected to a compressor and a condenser, the radiator and condenser are equipped with cooling fans, and the condenser is connected to the plate exchanger through an expansion valve.

Preferably, the battery pack is provided with a heating film.

Preferably, the water inlet is connected to an expansion tank.

Preferably, the heater is a water heating PTC heater.

A heat management method for an engineering vehicle battery, comprising the following methods:

Refrigeration method: detect the battery temperature and ambient temperature, when the battery temperature > 30°C and the ambient temperature > 10°C, turn on the water pump, cooling fan, compressor and condenser, the electronic three-way valve A is connected to the plate changer, and the electronic three-way valve B is directly connected to the water inlet, and the coolant enters the plate changer from the water outlet through the electronic three-way valve A, and returns to the battery pack through the electronic three-way valve B and the water inlet after being cooled by the compressor and condenser;

Air cooling method: detect the battery temperature and ambient temperature, when the battery temperature is >30°C and the ambient temperature is <10°C, turn on the water pump and cooling fan, the electronic three-way valve A is connected to the radiator, and the electronic three-way valve B is directly connected to the water inlet. The coolant enters the radiator through the electronic three-way valve A from the water outlet, and returns to the battery pack through the electronic three-way valve B and the water inlet after cooling;

Low-temperature heating method: detect the battery temperature and ambient temperature, when the battery temperature is <0°C, turn on the water pump, heater and heating film, the electronic three-way valve A is connected to the plate changer, the electronic three-way valve B is connected to the heater, and the coolant From the water outlet, it enters the heater through the electronic three-way valve A, the plate changer, and the electronic three-way valve B, and flows back to the battery pack through the water inlet after heating;

Low-temperature refrigeration method: detect the battery temperature and ambient temperature, when the battery temperature is >30°C and the ambient temperature is <-26°C, turn on the water pump, the electronic three-way valve A is connected to the radiator, the electronic three-way valve B is directly connected to the water inlet, and the cooling liquid Enter the radiator through the electronic three-way valve A from the water outlet, and return to the battery pack through the electronic three-way valve B and the water inlet after cooling;

Self-circulation method: detect the battery temperature, when the battery temperature is between 15°C and 30°C, turn on the water pump, the electronic three-way valve A is connected to the plate changer, the electronic three-way valve B is directly connected to the water inlet, and the coolant passes through the water outlet The electronic three-way valve A enters the plate changer, and then returns to the battery pack through the electronic three-way valve B and the water inlet;

Stop heat preservation method: detect the ambient temperature, when the ambient temperature is <-35°C, heat preservation through the heating film, and when the ambient temperature is <-40°C, heat preservation through the heater.

Beneficial effects of the present invention: 1. The heat dissipation mode of the battery can be automatically switched according to the ambient temperature and the battery temperature; 2. The heat management of the battery can be realized in the whole temperature range; 3. The heat dissipation system has high efficiency and low energy consumption; 4. The management system is convenient and flexible to adjust, with strong applicability and high reliability; 5. The power of the water pump can be adjusted according to the temperature of the battery.

Description of drawings

Fig. 1 is a schematic structural diagram of a battery heat management system of a pure electric mining dump truck of the present invention;

Fig. 2 is a schematic diagram of the refrigeration working condition of the heat management system of the present invention;

3 is a schematic diagram of the heat management system of the present invention in the air-cooled working condition and the low-temperature refrigeration working condition;

Fig. 4 is a schematic diagram of the low-temperature heating working condition of the heat management system of the present invention;

Fig. 5 is a schematic diagram of the self-circulation working condition of the heat management system of the present invention;

Fig. 6 is a schematic diagram of the thermal management system of the present invention in a shutdown and heat preservation working condition;

In the figure, 1. Electronic three-way water valve A; 2. Compressor; 3. Condenser; 4. Radiator; 5. Cooling fan; 6. Plate changer; 7. Expansion valve; 8. Electronic three-way water valve B; 9. Water heating PTC heater; 10. Expansion tank; 11. Water pump; 12. Inlet temperature sensor; 13. Battery pack; 14. Outlet temperature sensor.

detailed description

In order to further illustrate the technical details and advantages of the present invention, it will now be described in conjunction with the accompanying drawings.

In order to detect the ambient temperature, this embodiment is equipped with an ambient temperature sensor, and in order to realize the function of automatically switching working conditions, this embodiment is equipped with a controller, all of which are prior art.

As shown in Figure 1, a heat management system for engineering vehicle batteries includes a battery pack 13, the battery pack 13 is provided with a water inlet and a water outlet, the water inlet is connected to a water pump 11, and it is characterized in that it also includes an electronic Three-way valve A1, electronic three-way valve B8, radiator 4, plate changer 6 and heater; the first end of the electronic three-way valve A is connected to the water outlet, and the second end is connected to the electronic three-way through the radiator 4 The first end and the third end of the valve B8 are connected to the first end of the electronic three-way valve B8 through the plate changer 6; the second end of the electronic three-way valve B8 is connected to the water inlet through the heater, and the third end is directly connected to the Water inlet; the water inlet is connected to the inlet temperature sensor 12 and the water pump 11 , and the water outlet is connected to the outlet temperature sensor 14 .

In this embodiment, the plate exchanger 6 is connected to the compressor 2 and the condenser 3, the radiator 4 and the condenser 3 are equipped with a cooling fan 5, and the condenser 3 is connected to the plate exchanger through an expansion valve 7. The battery pack 13 is provided with a heating film; the water inlet is connected to the expansion tank 10; the heater is a water heating PTC heater 9

Refrigeration method: As shown in Figure 2, detect the battery temperature and ambient temperature, when the battery temperature > 30°C and the ambient temperature > 10°C, turn on the water pump 11, the cooling fan 5, the compressor 2 and the condenser 3, and the electronic three-way valve A1 is connected to the plate changer 6, and the electronic three-way valve B8 is directly connected to the water inlet. The coolant enters the plate changer 6 through the electronic three-way valve A1 from the water outlet, and passes through the electronic three-way valve B8 after being cooled by the compressor 2 and the condenser 3. and the water inlet back to the battery pack;

Air-cooling method: As shown in Figure 3, detect the battery temperature and ambient temperature. When the battery temperature is >30°C and the ambient temperature is <10°C, turn on the water pump 11 and the cooling fan 5, and the electronic three-way valve A1 is connected to the radiator 4. The three-way valve B8 is directly connected to the water inlet, and the coolant enters the radiator 4 from the water outlet through the electronic three-way valve A1, and returns to the battery pack through the electronic three-way valve B8 and the water inlet after cooling;

Low-temperature heating method: As shown in Figure 4, detect the battery temperature and ambient temperature, when the battery temperature is <0°C, turn on the water pump 11, the heater and the heating film, the electronic three-way valve A1 is connected to the plate changer 6, and the electronic three-way The valve B8 is connected to the heater, and the coolant enters the heater from the water outlet through the electronic three-way valve A1, the plate changer 6, and the electronic three-way valve B8, and flows back to the battery pack 13 through the water inlet after heating;

Low-temperature refrigeration method: detect the battery temperature and ambient temperature, when the battery temperature is >30°C and the ambient temperature is <-26°C, turn on the water pump 11, the electronic three-way valve A1 is connected to the radiator 4, and the electronic three-way valve B8 is directly connected to the water inlet. The coolant enters the radiator 4 through the electronic three-way valve A1 from the water outlet, and returns to the battery pack through the electronic three-way valve B8 and the water inlet after cooling;

Self-circulation method: As shown in Figure 5, the battery temperature is detected. When the battery temperature is between 15°C and 30°C, the water pump 11 is turned on, the electronic three-way valve A1 is connected to the plate changer 6, and the electronic three-way valve B8 is directly connected to the The water outlet, the coolant enters the plate changer 6 through the electronic three-way valve A1 from the water outlet, and then returns to the battery pack through the electronic three-way valve B8 and the water inlet to balance the temperature difference between the cells in the battery pack;

Stop heat preservation method: As shown in Figure 6, check the ambient temperature. When the ambient temperature is <-35°C, use a heating film to keep warm. When the ambient temperature is <-40°C, use a heater to keep warm.

In the above method, the power of the water pump 11 can be adjusted according to the temperature of the battery pack 13. When the battery pack is in the normal temperature range, the power of the water pump 11 is reduced. When the battery pack is in an abnormal temperature range, the power of the water pump 11 is increased. High, to speed up the circulation of the coolant, so that the battery pack can return to normal temperature as soon as possible.

Through practice, the present invention can control different heat dissipation modes according to ambient temperature and battery temperature. Energy consumption is saved, costs are reduced, and reliability of high-voltage components and the entire system is improved. For example, when the ambient temperature is low in spring, autumn and winter, there is no need to use a compressor to cool the battery, which reduces the quality risk and reduces the system power consumption by 70%. In extremely cold weather below -26°C, the battery can also be cooled when the battery temperature is high. Actively cool down to realize operation and management under all working conditions.

Claims

A battery heat management system for an engineering vehicle, comprising a battery pack (13), the battery pack (13) being provided with a water inlet and a water outlet, and the water inlet being connected to a water pump (11), characterized in that it also includes an electronic Three-way valve A (1), electronic three-way valve B (8), radiator (4), plate changer (6) and heater; the first end of the electronic three-way valve A is connected to the water outlet, and the first end of the electronic three-way valve A is connected to the water outlet. The two ends are connected to the first end of the electronic three-way valve B (8) through the radiator (4), and the third end is connected to the first end of the electronic three-way valve B (8) through the plate changer (6); The second end of the three-way valve B (8) is connected to the water inlet through the heater, and the third end is directly connected to the water inlet; the water inlet is connected to the inlet temperature sensor (12) and the water pump (11), and the water outlet is connected to Outlet temperature sensor (14).
A heat management system for engineering vehicle batteries according to claim 1, characterized in that: the plate exchanger (6) is connected to the compressor (2) and the condenser (3), and the radiator (4) A cooling fan (5) is installed on the condenser (3), and the condenser (3) is connected with the plate changer through an expansion valve (7).
A heat management system for engineering vehicle batteries according to claim 1, characterized in that: said battery pack (13) is provided with a heating film.
The heat management system for engineering vehicle batteries according to claim 1, characterized in that: the water inlet is connected to an expansion tank (10).
A heat management system for an engineering vehicle battery according to claim 1, characterized in that: the heater is a water heating PTC heater (9)
A heat management method for an engineering vehicle battery, characterized in that it includes the following methods:

Refrigeration method: detect battery temperature and ambient temperature, when battery temperature > 30°C and ambient temperature > 10°C, turn on water pump (11), cooling fan (5), compressor (2) and condenser (3), electronic three The through valve A (1) is connected to the plate changer (6), and the electronic three-way valve B (8) is directly connected to the water inlet. The coolant enters the plate changer (6) from the water outlet through the electronic three-way valve A (1), and passes After the compressor (2) and condenser (3) are cooled, they return to the battery pack through the electronic three-way valve B (8) and the water inlet;

Air-cooling method: detect the battery temperature and ambient temperature, when the battery temperature is >30°C and the ambient temperature is <10°C, turn on the water pump (11) and the cooling fan (5), and connect the electronic three-way valve A (1) to the radiator (4 ), the electronic three-way valve B (8) is directly connected to the water inlet, the coolant enters the radiator (4) from the water outlet through the electronic three-way valve A (1), and after cooling, it passes through the electronic three-way valve B (8) and the water inlet back to the battery pack;

Low-temperature heating method: detect the battery temperature and ambient temperature, when the battery temperature is <0°C, turn on the water pump (11), the heater and the heating film, the electronic three-way valve A (1) is connected to the plate changer (6), and the electronic three-way The through valve B (8) is connected to the heater, and the coolant enters the heater from the water outlet through the electronic three-way valve A (1), the plate changer (6), and the electronic three-way valve B (8), and flows through the water inlet after being heated. Back battery pack (13);

Low-temperature refrigeration method: detect the battery temperature and ambient temperature, when the battery temperature is >30°C and the ambient temperature is <-26°C, turn on the water pump (11), connect the electronic three-way valve A (1) to the radiator (4), and connect the electronic three-way Valve B (8) is directly connected to the water inlet, and the coolant enters the radiator (4) from the water outlet through the electronic three-way valve A (1), and returns to the battery pack through the electronic three-way valve B (8) and the water inlet after cooling;

Self-circulation method: detect the battery temperature, when the battery temperature is between 15°C and 30°C, turn on the water pump (11), the electronic three-way valve A (1) is connected to the plate changer (6), and the electronic three-way valve B (8 ) is directly connected to the water inlet, and the coolant enters the plate changer (6) from the water outlet through the electronic three-way valve A (1), and then returns to the battery pack through the electronic three-way valve B (8) and the water inlet;

Stop heat preservation method: detect the ambient temperature, when the ambient temperature is <-35°C, heat preservation through the heating film, and when the ambient temperature is <-40°C, heat preservation through the heater.