KR100444064B1 - Cooling system of electric vehicles - Google Patents

Abstract

Water pumps for charging boards, motor controllers, motors, inverters, and cooling fans to provide a cooling system for electric vehicles that can improve cooling efficiency by selecting refrigerant flows differently according to battery charging and driving modes of electric vehicles. In the electric vehicle cooling system configured by connecting through the cooling pipe,

Connecting the water pump and the cooling fan to a first cooling pipe, connecting the cooling fan and the motor controller to a second cooling pipe, connecting the motor controller and the motor to a third cooling pipe, and connecting the motor and the inverter. To a fourth cooling pipe, connecting the inverter and the water pump to the fifth cooling pipe to form a driving mode cooling pipe, and a second connecting the cooling fan and the motor controller among the driving mode cooling pipes. One side of the cooling pipe and the charging board is connected to the sixth cooling pipe, and the charging board is connected to one side of the fifth cooling pipe connecting the inverter and the water pump to the seventh cooling pipe to charge mode cooling pipe And a refrigerant from the cooling fan at one side to which the second cooling pipe and the sixth cooling pipe are connected, according to a driving mode of the electric vehicle. A first switching means is configured to flow to the board selectively, and on one side to which the fifth cooling pipe and the seventh cooling pipe are connected, the refrigerant flows to the charging board and the inverter for the water pump according to the driving mode of the electric vehicle. It provides a cooling system for an electric vehicle, characterized in that for configuring a second switching means for selectively connecting.

Description

COOLING SYSTEM OF ELECTRIC VEHICLES}

The present invention relates to a cooling system for an electric vehicle, and more particularly, to a cooling system for an electric vehicle to improve the cooling efficiency by differently selecting the refrigerant flow for each battery charging mode and driving mode.

In general, electric vehicles have been developed for the purpose of preventing air pollution, which is getting worse day by day, and to replace limited fluid energy with new energy sources. It plays a role as.

In the operation of such electric vehicles, conventionally, in order to solve the most fatal heat problem, the cooling problem is applied to a motor, a CEU (control unit), an air conditioner inverter, a battery, and the like, which solves the heat problem. The batteries operate in their own cooling system, while the motors, CEUs and air-conditioning inverters cool each other through a single cooling system.

However, in the conventional electric vehicle cooling system as described above, the charging mode requires much less heat control than the driving mode. That is, the operation of the electric vehicle operates in the driving mode and the charging mode, and the heat source according to the mode is reduced. Among the components that make up the refrigerant flow in the cooling system for electric vehicles, in the charging mode, only the charging board is required, but the motor having the coil-like refrigerant flow and the tortuous refrigerant flow are required only in the charging board. Since the CEU and the inverter has substantially hindered the flow of the refrigerant for cooling substantially, there is a problem that the use of a water pump and a cooling fan to control it is made inefficient.

In addition, although the environmental requirements for noise generation and heat generation are very limited in the charging mode compared to the driving mode, in the conventional cooling system, even the elements that do not require cooling in the charging mode are included in the refrigerant flow. As a result, the high-capacity pump and the high-speed cooling fan operate to generate an enormous noise and heat when charging in a limited space, especially indoors, thereby preventing efficient vehicle charging.

Therefore, the present invention was created to solve the problems as described above, an object of the present invention is for an electric vehicle to improve the cooling efficiency by differently selecting the refrigerant flow for each battery charging mode and driving mode of the electric vehicle To provide a cooling system.

1 is a block diagram of a cooling system for an electric vehicle according to the present invention.

2 is a flow chart of a refrigerant in a driving mode of an electric vehicle cooling system according to the present invention.

3 is a refrigerant flow diagram in the charging mode of the cooling system for an electric vehicle according to the present invention.

The electric vehicle cooling system according to the present invention for achieving the above object is in the electric vehicle cooling system configured by connecting the charging board and the motor controller, motor, inverter and cooling fan through the water pump and the cooling pipe,

Connecting the water pump and the cooling fan to a first cooling pipe, connecting the cooling fan and the motor controller to a second cooling pipe, connecting the motor controller and the motor to a third cooling pipe, and connecting the motor and the inverter. To a fourth cooling pipe, connecting the inverter and the water pump to the fifth cooling pipe to form a driving mode cooling pipe, and a second connecting the cooling fan and the motor controller among the driving mode cooling pipes. One side of the cooling pipe and the charging board is connected to the sixth cooling pipe, and the charging board is connected to one side of the fifth cooling pipe connecting the inverter and the water pump to the seventh cooling pipe to charge mode cooling pipe And a refrigerant from the cooling fan at one side to which the second cooling pipe and the sixth cooling pipe are connected, according to a driving mode of the electric vehicle. A first switching means is configured to flow to the board selectively, and on one side to which the fifth cooling pipe and the seventh cooling pipe are connected, the refrigerant flows to the charging board and the inverter for the water pump according to the driving mode of the electric vehicle. Characterized in that the second switching means for selectively connecting the.

The first and second switching means are composed of a three-way solenoid valve, characterized in that for receiving an operation signal according to the driving mode from the motor controller.

Hereinafter, the preferred configuration and operation of the present invention will be described in detail with reference to the accompanying drawings.

1 is a configuration diagram of a cooling system for an electric vehicle according to the present invention, the cooling system for an electric vehicle according to the present invention is a charging board (1) and the motor controller (3), the motor (5), the inverter (7) as a heating source And a cooling fan 9 connected to the water pump 11 through the driving mode cooling pipe and the charging mode cooling pipe. First, the driving mode cooling pipe is a refrigerant discharge port and a cooling fan of the water pump 11. The refrigerant input port (9) is connected to the first cooling pipe (21).

In addition, the refrigerant discharge port of the cooling fan 9 and the refrigerant input port of the motor controller 3 are connected to the second cooling pipe 23, and the refrigerant discharge port of the motor controller 3 and the motor 5. Connect the refrigerant input port of the third cooling pipe (25).

The refrigerant discharge port of the motor 5 and the refrigerant input port of the inverter 7 are connected to the fourth cooling pipe 27, and the refrigerant discharge port of the inverter 7 and the refrigerant input port of the water pump 11 are connected to each other. It is made by connecting to the fifth cooling pipe (29).

The charging mode cooling piping is one side of the second cooling piping 23 connecting the cooling fan 9 and the motor controller 3 and the refrigerant input port of the charging board 1 of the driving mode cooling piping. To a sixth cooling pipe 31, and the refrigerant discharge port of the charging board 1 connects one side of the fifth cooling pipe 29 connecting the inverter 7 to the water pump 11. It is made by connecting to the cooling pipe (33).

In addition, at one side to which the second cooling pipe 23 and the sixth cooling pipe 31 are connected, the refrigerant from the cooling fan 9 is controlled by the motor controller 3 of the electric vehicle. 3 or the first switching 3-way solenoid valve 41 which is the first switching means to flow to the charging board 1 is configured to operate according to the operation signal of the motor controller 3.

The charging board 1 is connected to the water pump 11 according to the driving mode indicated by the motor controller 3 of the electric vehicle at one side to which the fifth cooling pipe 29 and the seventh cooling pipe 33 are connected. ) And a second switching 3-way solenoid valve 43 which is a second switching means to selectively connect the refrigerant flow to the inverter 7 to operate according to the operation signal of the motor controller 3.

The operation of each driving mode of the electric vehicle cooling system having the configuration as described above will be described with reference to FIGS. 2 and 3. First, as shown in FIG. The first switching 3-way solenoid valve 41 and the second switching 3-way solenoid valve 43 respectively output driving mode operation signals so that the first switching 3-way solenoid valve 41 is discharged from the cooling fan 9. The pipe is connected to the refrigerant flows through the second cooling pipe 23 to the motor controller 3, and the sixth cooling pipe 31 is blocked.

In addition, the second switch 3-way solenoid valve 43 connects a pipe such that the refrigerant from the inverter 7 is sucked into the water pump 11 through the fifth cooling pipe 29, and the seventh switch. The cooling pipe 33 is blocked.

Therefore, in the driving mode as described above, heat control such as heat control due to the operation of the motor 5 reaching 9000 RPM, heat control generated by the inverter 7 during air conditioning operation, and heat control by the motor 5 driving control are selectively performed. Will be performed.

In the charging mode, since only the charging board 1 is a heating source, as shown in FIG. 3, the first switching 3-way solenoid valve 41 and the second switching 3-way solenoid valve 43 are provided by the motor controller 3. Each of the first switching 3-way solenoid valves 41 outputs a charging mode operation signal to prevent the refrigerant from the cooling fan 9 from flowing to the motor controller 3 through the second cooling pipe 23. The pipe is blocked and the second cooling pipe 23 and the sixth cooling pipe 31 are connected such that the refrigerant flows through the sixth cooling pipe 31 to the charging board 1.

In addition, the second switch 3-way solenoid valve 43 connects a pipe such that the refrigerant cooling the charging board 1 is sucked into the water pump 11 through the seventh cooling pipe 33. The fifth cooling pipe 29 connecting the inverter 7 and the water pump 11 is blocked.

Therefore, in the charging mode as described above, it is possible to limit the control of the heat generated by the charging board 1 for charging the three-phase voltage power to the battery.

That is, the cooling system for an electric vehicle according to the present invention induces independent refrigerant flow according to the driving mode, thereby preventing the operation of the cooling fan 9 or the water pump 11 or more that is required, thereby minimizing noise and heat generation. The charging board can be maintained comfortably, and the battery can be reduced by minimizing the power consumption by the operation of the appropriate cooling fan 9 and the water pump 11 during charging, and above all, the charging board whose performance characteristics are easily changed by heat ( The temperature control of 1) can be achieved efficiently, improving the charging speed and performance of the charging system.

As described above, according to the cooling system for an electric vehicle according to the present invention, a cooling fan or water having a necessary specification or higher by selecting an independent refrigerant flow for each driving mode that selects a refrigerant flow differently for each battery charging mode and a driving mode of the electric vehicle. By preventing overload of the pump, it minimizes noise and heat generation, and at the same time, it minimizes power consumption for driving the cooling system, and reduces battery discharge. There is an effect of improving the charging speed and performance of the charging system.

Claims (2)

In the cooling system for an electric vehicle comprising a charging board and a motor controller, a motor, an inverter and a cooling fan are connected through a water pump and a cooling pipe, Connecting the water pump and the cooling fan to a first cooling pipe, connecting the cooling fan and the motor controller to a second cooling pipe, connecting the motor controller and the motor to a third cooling pipe, and connecting the motor and the inverter. To a fourth cooling pipe, and connect the inverter and the water pump to a fifth cooling pipe to form a driving mode cooling pipe, Of the driving mode cooling pipe, one side of the second cooling pipe connecting the cooling fan and the motor controller and the charging board is connected to the sixth cooling pipe, the charging board, the inverter and the water pump is connected again One side of the fifth cooling pipe is connected to the seventh cooling pipe to form a charge mode cooling pipe, On one side of the second cooling pipe and the sixth cooling pipe is connected to the first switching means so that the refrigerant from the cooling fan flows selectively to the motor controller or the charging board according to the driving mode of the electric vehicle, The second switching means for selectively connecting the refrigerant flow to the charging board and the inverter to the water pump according to the driving mode of the electric vehicle on one side to which the fifth cooling pipe and the seventh cooling pipe are connected. Cooling system for electric vehicles. The method according to claim 1, wherein the first and second switching means It consists of a three-way solenoid valve, the cooling system for an electric vehicle, characterized in that receiving an operation signal according to the driving mode from the motor controller.