RU2633109C1 - Device for liquid cooling of electric vehicle components - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: liquid cooling device of the electric vehicle components comprises a high-temperature hydraulic circuit and a low-temperature hydraulic circuit for cooling the electric vehicle components. In the high-temperature hydraulic circuit, a motor-driven pump is arranged to supply the heat transfer medium from the radiator to liquid cooling jacket of the traction motor, a heat engine and a generator of electric current having a drive from the heat engine. There are valves with electromechanical drive controlled by signals of temperature sensors are installed in hydraulic lines communicating said liquid cooling jackets with the radiator. The motor-driven pump is arranged in the low-temperature hydraulic circuit for supplying heat-transfer medium from the radiator to the liquid cooling jacket of the storage battery, an inverter and a device for charging the storage battery. There are valves with electromechanical drive controlled by signals of temperature sensors are installed in hydraulic lines communicating the liquid cooling jackets with the radiator. Each hydraulic circuit has a compensation-expansion tank communicating with hydraulic lines, and with a hydraulic line located between the radiator and the pump.

EFFECT: improvement of efficiency of cooling of electric vehicle components, improvement of their operation reliability, simplification of liquid cooling device.

2 dwg

Description

The invention relates to electric vehicles, in particular to electric vehicles. It can be used to cool the units of an electric car equipped with a device for increasing its mileage (Range Extender).

Known presented in patent JP 3292080 (B2), published on June 17, 2002 by the Japanese Patent Office, a liquid cooling device for electric vehicle assemblies containing two hydraulic circuits. In the first hydraulic circuit there is a liquid pump for supplying coolant from the radiator to the ICE cooling jacket. In the second hydraulic circuit, there is a liquid pump for supplying coolant from a separate radiator to the inverter liquid cooling jacket, to the liquid cooling jacket of the traction motor and to the liquid cooling jacket of the electric current generator. However, this device does not provide means for cooling the battery.

Closer to the claimed invention is a liquid cooling device for electric vehicle units equipped with a means of increasing its mileage, including a heat engine (ICE) and an electric current generator (see US 2015114323 A1, publ. 04/30/2015). This device contains two high temperature hydraulic circuits. In the first high-temperature hydraulic circuit there are liquid pumps for supplying coolant from the radiator to the liquid-cooling jacket of the traction motor and to the liquid-cooling jacket of the electric current generator. In the second high-temperature hydraulic circuit, there is a liquid pump for supplying coolant to the ICE liquid cooling jacket, a thermostat valve and a heat exchanger, through which heat exchange occurs between the two high-temperature circuits. However, due to the presence of a heat exchanger in the second high-temperature hydraulic circuit, washed by the coolant circulating in the first high-temperature hydraulic circuit, excessive heat losses occur during ICE cooling, which reduces the ICE cooling efficiency and, as a consequence, the durability of its parts. In addition, this leads to a complication of the cooling device of electric vehicle units as a whole. It also complicates the known device that each cooling line of the electric vehicle units is equipped with its own liquid pump. The cooling of the battery and the inverter in the known cooling device of the electric vehicle units occurs using a cooling radiator located in a separate low-temperature hydraulic circuit. However, the sequential inclusion in the circuit of the low-temperature hydraulic circuit of the battery cooling jackets and the inverter also reduces the cooling efficiency of these electric vehicle units, since the amount of heat generated during the operation of the battery and the inverter can be different, and their cooling intensity should thus be different. In addition, in the known device there are no means for the discharge of air bubbles formed in the liquid coolant, which can lead to the formation of air jams in the cooling circuits.

When creating a device for liquid cooling of electric vehicle units, the task was to ensure the optimal temperature regime of each unit, regardless of the power load of the units, electric vehicle movement modes and climatic conditions in which the vehicle is operated.

The technical result provided by the claimed invention is to improve the cooling efficiency of the electric vehicle units, increase the reliability of their operation, as well as to simplify the liquid cooling device of the electric vehicle units.

The specified technical result is achieved by the fact that the liquid cooling device of the electric vehicle units contains two hydraulic cooling circuits of the electric vehicle units. In a high-temperature hydraulic circuit there is a pump driven by an electric motor for supplying coolant from a radiator to a liquid cooling jacket of a traction electric motor, to a liquid cooling jacket of a heat engine, to a liquid cooling jacket of an electric current generator driven by a thermal engine. In the hydraulic lines communicating the said liquid cooled shirts with a radiator, valves with an electromechanical drive are installed, which are controlled by the signals of the temperature sensors of the coolant in these hydraulic lines. In the low-temperature hydraulic circuit there is a pump driven by an electric motor for supplying heat from a separate radiator to the liquid cooling jacket of the battery, to the liquid cooling jacket of the inverter, to the liquid cooling jacket of the device for charging the battery. In the hydraulic lines reporting the mentioned liquid cooling shirts of the low-temperature hydraulic circuit with a radiator, electromechanical valves are installed, controlled by the signals of the temperature sensors of the coolant in these hydraulic lines. Each hydraulic circuit has a expansion tank, connected with hydraulic lines that communicate with liquid cooling shirts with a radiator, and with a hydraulic line located between the radiator and the pump.

With this embodiment, the liquid cooling device of the electric vehicle’s units ensures the optimum temperature regime of each unit, regardless of the power load of the units, the vehicle’s driving modes and the climatic conditions in which the vehicle is operated, which improves the cooling efficiency of the electric vehicle’s units and increases their reliability.

The figure 1 shows a diagram of a high-temperature hydraulic circuit of a liquid cooling device for electric vehicle units.

Figure 2 shows a diagram of a low-temperature hydraulic circuit of a liquid cooling device for electric vehicle units.

A liquid cooling device for electric vehicle assemblies comprises a high temperature hydraulic circuit and a low temperature hydraulic circuit. In the high-temperature hydraulic cooling circuit of the electric vehicle assemblies, shown in figure 1, there is a pump 1, which is driven by an electric motor 2. Pump 1 delivers a coolant from a radiator 3, equipped with a temperature sensor 4 at the input, to the liquid cooling shirts of the traction motor 5, heat engine 6 and an electric current generator 7 driven by a heat engine 6. In the hydraulic line 8 communicating the liquid cooling jacket of the traction motor 5 with the radiator 3, a crane 9 is installed with an electromechanical drive controlled by the signals of the temperature sensor 10 in the hydraulic line 8. In the hydraulic line 11, which communicates the liquid cooling jacket of the heat engine 6 with the radiator 3, a crane 12 is installed with an electromechanical drive controlled by the signals of the temperature sensor 13 of the coolant in the hydraulic line 11. In the hydraulic line 14, communicating the liquid cooling jacket of the electric current generator 7 with the radiator 3, a crane 15 is installed with an electromechanical drive controlled by the signals of the temperature sensor 16 Ithel in hydraulic line 14. The high temperature hydraulic circuit is also included hydraulic line 17 electric heating compartment, in which is mounted an electric heater 18, the heat transfer fluid before it is fed to the electric heater 19 interior. The amount of coolant entering the hydraulic line 17 is regulated by a valve 20 with an electromechanical drive located at the outlet of the electric heater 18 and controlled by the signals of the temperature sensor 21. In the high-temperature hydraulic circuit there is a compensation-expansion tank 22, in communication with hydraulic lines 8, 11, 14, communicating liquid cooling shirts of the traction motor 5, heat engine 6, generator 7 with radiator 3, and with a hydraulic line 23 located between the radiator 3 and pump 1 .

In the low-temperature hydraulic cooling circuit of the electric vehicle assemblies, shown in figure 2, there is a pump 24, which is driven by an electric motor 25. The pump 24 delivers the coolant from the radiator 26, equipped with a temperature sensor 27 at the input, to the liquid cooling shirts of the battery 28, the inverter 29 and device 30 for charging the battery 28. In the hydraulic line 31, reporting the liquid cooling jacket of the battery 28 with a radiator 26, a crane 32 with an electromechanical drive is installed, detected by the signals of the coolant temperature sensor 33 in the hydraulic line 31. In the hydraulic line 34, which communicates the liquid cooling jacket of the inverter 29 with the radiator 26, a crane 35 is installed with an electromechanical drive controlled by the signals of the coolant temperature sensor 36 in the hydraulic line 34. In the hydraulic line 37, which communicates the liquid jacket cooling device 30 for charging a battery 28 with a radiator 26, a valve 38 is installed with an electromechanical drive controlled by the signals of the temperature sensor 39 of the coolant in the hydraulic line 37. In low temperature The hydraulic circuit has a compensating expansion tank 40 in communication with hydraulic lines 31, 34, 37, which inform the liquid cooling shirts of the battery 28, the inverter 29, the device 30 for charging the battery 28 with a radiator 26, and with a hydraulic line 41 located between the radiator 26 and pump 24.

The operation of the liquid cooling device of electric vehicle units is as follows.

When the ignition is turned on in the electric vehicle, before the start of its movement, the electric motors 2, 25 are turned on, which drive the pumps 1, 24 of the high-temperature and low-temperature hydraulic circuits, respectively. In this case, the circulation of the liquid coolant is carried out through the hydraulic lines 8, 11, 14 of the high-temperature hydraulic circuit and the hydraulic lines 31, 34, 37 of the low-temperature hydraulic circuit along the bypass sections through expansion and expansion tanks 22, 40 of these circuits. Tanks 22, 40 also serve as means for discharging air bubbles formed in the liquid coolant, which prevents the occurrence of air jams in hydraulic circuits. When the coolant temperature is reached in any of the hydraulic lines 8, 11, 14, 31, 34, 37 of the set value according to the signals of the temperature sensors 10, 13, 16, 33, 36, 39 installed in these hydraulic lines, the electromechanical actuators open the cranes 9, 12, 15, 32, 35, 38, as a result of which the flow rate and the amount of coolant passing through the liquid cooling shirts of the electric vehicle units will increase, due to which the electric vehicle units will be cooled. Thus, maintaining the required temperature of the electric vehicle units is carried out by changing the flow rate of the liquid coolant passing through the liquid cooling shirts of the electric vehicle units. During the opening of the taps 9, 12, 15, 32, 35, 38, the circulation of the coolant in the high-temperature and low-temperature hydraulic circuits is carried out through radiators 3, 26, respectively. If the temperature of the coolant measured by sensors 4, 27 installed at the inlet to the radiators 3, 26 of the high-temperature and low-temperature hydraulic circuits, respectively, is higher than the set value, the intensity of blowing the radiators 3, 26 by the fans will increase, which will increase the discharge of excess heat into the environment and lower the temperature coolant in hydraulic circuits. In the cold season, for heating the interior of the electric vehicle and heating its components before starting the movement, when the ignition is turned on, the electric heater 18 is turned on, which heats the liquid coolant in the hydraulic line 17 before it is supplied to the heater 19 of the cabin. In this case, the flow rate of the liquid coolant in the hydraulic line 17 and its amount are regulated by the valve 20 according to the signals of the temperature sensor 21.

Thus, due to the fact that in the high-temperature hydraulic circuit of the liquid cooling device of the electric vehicle units there is a pump driven by an electric motor for supplying coolant from the radiator to the liquid cooling jacket of the traction motor, to the liquid cooling jacket of the heat engine, to the liquid cooling jacket of the electric current generator having drive from a heat engine, and in hydraulic lines reporting the mentioned liquid-cooled shirts with a radiator, Lena's cranes with an electromechanical actuator controlled by signals coolant temperature sensors provided optimum operating temperature of the traction motor heat engine and electric generator. And due to the fact that in the low-temperature hydraulic circuit there is a pump driven by an electric motor for supplying coolant from a separate radiator to the liquid cooling jacket of the battery, to the liquid cooling jacket of the inverter, to the liquid cooling jacket of the device for charging the battery, and in the hydraulic lines reporting the above liquid cooling shirts of a low-temperature hydraulic circuit with a radiator; cranes with an electromechanical drive controlled by about the signals of the temperature sensors of the coolant, the required temperature regime of the battery, inverter and device for charging the battery has been reached. This ensures the optimal operating temperature of each unit of the electric vehicle, regardless of the power load of the units, the modes of movement of the electric vehicle and the climatic conditions in which the vehicle is operated. As a result, the cooling efficiency of electric vehicle aggregates improves, their reliability increases, and the liquid cooling device of electric vehicle aggregates as a whole is simplified.

Claims (1)

A device for liquid cooling of electric vehicle assemblies, comprising two hydraulic circuits for cooling electric vehicle units, characterized in that a high-temperature hydraulic circuit contains a pump driven by an electric motor for supplying heat from the radiator to the liquid cooling jacket of the traction motor, to the liquid cooling jacket of the heat engine, to the liquid jacket cooling of an electric current generator driven by a heat engine in hydraulic lines communicating with elastomeric liquid-cooled shirts with a radiator, cranes with an electromechanical drive installed, controlled by the signals of the temperature sensors of the coolant in the indicated hydraulic lines, a pump driven by an electric motor is located in the low-temperature hydraulic circuit to supply coolant from a separate radiator to the liquid cooling jacket of the battery, to the liquid cooling jacket inverter, in the liquid-cooling jacket of the device for charging the battery, in hydraulic lines reporting said liquid cooling shirts of a low-temperature hydraulic circuit with a radiator, valves with an electromechanical drive are installed, controlled by the signals of the temperature sensors of the coolant in these hydraulic lines, each hydraulic circuit has a expansion tank, connected to the hydraulic lines communicating the liquid cooling shirts with a radiator, and with a hydraulic line located between the radiator and the pump.

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