JP2018030514A - Battery cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery cooling device which can suppress submergence of the battery and keep cooling of the battery when water intrudes into a cabin.SOLUTION: A battery cooling device 30 supplies a battery pack 14 in which a battery 10 is stored with cooling air to cool the battery 10. The battery cooling device 30 comprises: an inlet duct 18 which guides the cooling air taken in from an inlet port 16 by suction of a cooling fan 12 into the battery pack 14; and an exhaust duct which guides the cooling air that has cooled the battery 10 from the battery pack 14 to an exhaust port 24. At least a part of the inlet duct 18 is upwardly inclined from the inlet port 16 toward the battery pack 14 side and a pressure valve 20 is arranged at a position which is a midway part of the inlet duct 18 and above the inlet port 16, from which the cooling air is taken in when a pressure in the inlet duct 18 becomes negative. The exhaust port 24 is arranged higher than the inlet port 16.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cooling device used for cooling an in-vehicle battery.

  In recent years, electric vehicles such as an electric vehicle using a motor as a drive source and a hybrid vehicle using a motor and an engine as a drive source are often used. These electric vehicles are equipped with a chargeable / dischargeable battery for supplying electric power to the motor and charging the generated electric power when the motor is operated as a generator, and a cooling device for cooling the battery. The cooling device sucks cooling air by a suction action of a cooling fan, and cools the battery by flowing the sucked cooling air through a cooling flow path around the battery.

  Patent Document 1 discloses a cooling device that cools a battery by driving a cooling fan to take cooling air into the intake duct and guiding the cooling air taken into the intake duct to the battery. In Patent Document 1, two intake ports for taking cooling air into the intake duct are provided in the vehicle interior, and when one intake port is blocked by luggage or the like, the cooling air is taken from the other intake port. .

JP 2006-188182 A

  By the way, when a vehicle crosses a river (crosses the river), or when the vehicle travels on a road where the water level is high due to flooding or the like, water may enter the vehicle interior. In that case, water may infiltrate from the intake port of the cooling device provided in the passenger compartment, and the battery may be submerged. Therefore, there is a demand for suppressing submergence of the battery.

  Therefore, an object of the present invention is to provide a battery cooling device that can suppress submergence of a battery and continue cooling of the battery even when water enters the vehicle interior.

  The battery cooling device of the present invention is a battery cooling device that cools the battery by supplying cooling air to a battery pack in which the battery is stored, and includes an air inlet provided in a vehicle interior, and the inside of the battery pack. An air intake duct that guides the cooling air taken in from the air intake port to the battery pack by the suction action of a cooling fan provided in the battery, and the air that has cooled the battery is led from the battery pack to the exhaust port. An exhaust duct, and at least a part of the intake duct is inclined upward from the intake port toward the battery pack side, and is in the middle of the intake duct and is more than the intake port A pressure valve for taking in the cooling air when the inside of the intake duct becomes negative pressure is provided at an upper position, and the exhaust port is provided above the intake port. The And butterflies.

  According to the present invention, since at least a part of the air intake duct is inclined upward from the air inlet toward the battery pack, water is prevented from flowing into the battery pack from the air inlet, and the battery is submerged. Can be prevented. In addition, a pressure valve is provided in the middle of the intake duct and above the intake port to take in cooling air when the intake duct becomes negative pressure. It is provided above. Therefore, even when the intake port is submerged, the cooling of the battery can be continued.

It is a figure which shows the arrangement | positioning in the vehicle of the battery pack and battery cooling device in embodiment of this invention, and the outline of a structure of a battery pack and a battery cooling device. It is a figure which shows the state of the battery cooling device when the inlet port in embodiment of this invention is block | closed with water. It is a perspective view which shows the state which the pressure valve in embodiment of this invention opened.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a view of the battery pack 14 and the battery cooling device 30 arranged under the trunk room 32 (luggage space) as viewed from the left side of the vehicle. The battery pack 14 and the battery cooling device 30 are drawn in a sectional view so that the outline of the configuration can be understood. In addition, the up-down, left-right, front-back display of FIGS. 1-3 demonstrated below has shown each direction of the up-down, left-right, front-back of a vehicle.

  The vehicle 40 of this embodiment is an electric vehicle such as a hybrid vehicle or an electric vehicle. As shown in FIG. 1, a battery pack 14 and a battery cooling device 30 for cooling the battery 10 stored in the battery pack 14 are arranged in the electric vehicle.

  The battery 10 is a secondary battery such as a chargeable / dischargeable lithium ion battery. The battery 10 supplies electric power for driving wheels to an electric motor generator (not shown) via an inverter (not shown), and is charged with electric power generated when the motor generator functions as a generator.

  The battery cooling device 30 of the present embodiment cools the intake port 16 provided in the vehicle interior 44, the intake duct 18 that guides the cooling air taken from the intake port 16 to the battery pack 14, and the battery 10 of the battery pack 14. And an exhaust duct 22 that guides the cooled air from the battery pack 14 to the exhaust port 24.

  As shown in FIG. 1, an intake port 16 for taking cooling air into the intake duct 18 is provided below the rear seat 34 in the passenger compartment 44. The intake duct 18 extends from the intake port 16 toward the rear of the vehicle, and a part of the intake duct 18 has a shape inclined upward from the intake port 16 toward the battery pack 14 side. . A pressure valve 20 is provided in the middle of the intake duct 18 and above the intake port 16. The pressure valve 20 is in a closed state in a normal state that is not in a state (described later) in which the intake duct 18 has a negative pressure. In FIG. 1 and FIG. 2 to be described later, the pressure valve 20 is drawn larger in order to make the position of the pressure valve 20 easier to understand. One end of the intake duct 18 opposite to the intake port 16 is connected to the battery pack 14.

  The battery pack 14 is provided with a cooling fan 12 for sucking cooling air. The battery pack 14 stores the battery 10. An exhaust duct 22 for exhausting the cooling air after cooling the battery 10 in the battery pack 14 is provided behind the battery pack 14 in the vehicle. One end of the exhaust duct 22 is connected to the battery pack 14, and the other end is connected to an exhaust port 24 provided outside the vehicle 40. The exhaust duct 22 has a shape inclined upward from the battery pack 14 toward the exhaust port 24, and the exhaust port 24 is provided above the intake port 16.

  An interior trim exists between the trunk room 32 and the battery cooling device 30, but is omitted from FIG. 1 and FIG. 2 described later.

  The intake duct 18, the battery pack 14, the exhaust duct 22, and the fitting portion (connecting portion) of these embodiments are waterproofed. In the battery cooling device 30 of this embodiment, the vehicle 40 crosses the river (crosses the river) and the like, so that water enters the passenger compartment 44 and the air intake 16 under the rear seat 34 is blocked with water. Even in this case, the cooling of the battery 10 can be continued. Here, the battery in each of a state where the intake port 16 is not blocked with water (hereinafter referred to as a normal state) and a state where the intake port 16 is blocked with water (hereinafter referred to as a flooded state). 10 cooling will be described.

  A thick black arrow in FIG. 1 indicates a flow of cooling air for cooling the battery 10 in a normal state. The battery cooling device 30 takes in the cooling air from the intake port 16 into the intake duct 18 by a suction action generated by driving the cooling fan 12. The taken-in cooling air reaches the cooling fan 12 of the battery pack 14 through the intake duct 18 and is guided from the cooling fan 12 to the battery 10 in the battery pack 14. The cooling air cools the battery 10 by passing through cooling passages (not shown) around the battery 10. The cooling air after cooling the battery 10 flows into the exhaust duct 22 from the battery pack 14, passes through the exhaust duct 22, and is exhausted from the exhaust port 24 to the outside of the vehicle 40.

  As described above, in the normal state, by taking in the cooling air from the intake port 16 below the rear seat 34, the cooling air that is cooler than that in the case of taking in the air above the passenger compartment 44 or the air in the trunk room 32. Can be taken into the intake duct 18. Further, in the normal state, by using the air inlet 16 below the rear seat 34, the noise of the cooling fan 12 leaking from the air inlet 16 can be made difficult to be transmitted to the passengers in the passenger compartment 44.

  Next, cooling of the battery 10 in the flooded state will be described. FIG. 2 shows the state of the battery cooling device 30 when the vehicle 40 crosses the river (crosses the river), for example, water enters the passenger compartment 44 and the intake port 16 is blocked with water. . In FIG. 2, the same members as those in FIG. The hatched hatching in FIG. 2 represents the water 42.

  As described above, the intake duct 18, the battery pack 14, the exhaust duct 22, and the fitting portions thereof are waterproofed, so that even if they are immersed in the water 42, these The water 42 is prevented from entering the inside of the inside. Further, a part of the intake duct 18 has a shape inclined upward from the intake port 16 toward the battery pack 14, and a pressure valve 20 provided in the intake duct 18 and an exhaust duct 22 are formed. The exhaust port 24 is located above the intake port 16. Therefore, as shown in FIG. 2, even when the intake port 16 is submerged, the water 42 is prevented from flowing into the battery pack 14, and the battery 10 is prevented from submerging. .

  A thick black arrow in FIG. 2 indicates a flow of cooling air for cooling the battery 10 in a flooded state. As shown in FIG. 2, when the intake port 16 is blocked with water, the cooling fan 12 is driven, and the intake duct 18 is in a negative pressure state. Thereby, the pressure valve 20 provided in the middle of the intake duct 18 is opened. By opening the pressure valve 20, the cooling air outside the pressure valve 20, that is, outside the intake duct 18 is taken into the intake duct 18 through the opening 39 of the pressure valve 20. In this way, even when the intake port 16 is blocked with water, the pressure valve 20 can take cooling air into the intake duct 18.

  The cooling air taken into the intake duct 18 is led from the intake duct 18 to the battery 10 of the battery pack 14 and cools the battery 10 as in the normal state described above. Then, the cooling air after cooling the battery 10 flows into the exhaust duct 22 from the battery pack 14, passes through the exhaust duct 22, and is exhausted from the exhaust port 24 to the outside of the vehicle 40.

  Next, the pressure valve 20 will be described in detail. FIG. 3 is a perspective view showing a state in which the pressure valve 20 is opened, and the inside of the intake duct 18 is drawn through. The thick black arrows in FIG. 3 indicate the flow of cooling air. As shown in FIG. 3, the pressure valve 20 includes a valve body 36, a hinge portion 38 of the valve body 36, and an opening 39. The hinge portion 38 is provided on the ceiling in the intake duct 18, and the valve body 36 can rotate and move toward the floor of the intake duct 18 with the hinge portion 38 as an axis. The hinge portion 38 is provided with a spring, and in a normal state, the valve body 36 is biased so as to come to the position of the ceiling of the intake duct 18 (the pressure valve 20 is closed).

  As shown in FIG. 3, when the pressure inside the intake duct 18 becomes negative, the valve body 36 rotates and moves toward the floor of the intake duct 18 so that the pressure valve 20 opens. Since the hinge portion 38 of the valve body 36 is provided on the vehicle front side (the intake port 16 side), when the valve body 36 rotates and moves toward the floor of the intake duct 18 around the hinge portion 38, the pressure is reduced. A cooling air flow path is formed from the opening 39 of the valve 20 toward the downstream side (battery pack 14 side) of the intake duct 18. Therefore, the cooling air flowing in from the opening 39 of the pressure valve 20 is guided to the battery 10 of the battery pack 14 through the intake duct 18 and cools the battery 10.

  In the battery cooling device 30 of the present embodiment described above, a part of the intake duct 18 has a shape inclined upward from the intake port 16 toward the battery pack 14 side. Further, the pressure valve 20 provided in the intake duct 18 and the exhaust port 24 of the exhaust duct 22 are located above the intake port 16. Therefore, even when the intake port 16 is submerged, the water 42 does not flow into the battery pack 14 and the battery 10 can be prevented from being submerged.

  Further, in the battery cooling device 30 of the present embodiment described above, when the intake port 16 is blocked with water, the inside of the intake duct 18 becomes negative pressure, and the pressure valve 20 provided in the intake duct 18 opens. Therefore, the cooling air can be taken into the intake duct 18 from the opening 39 of the pressure valve 20. Further, since the exhaust port 24 of the exhaust duct 22 is located above the intake port 16, even if the intake port 16 is submerged, the exhaust port 24 is not submerged and the cooling air can be exhausted. is there. Therefore, even when the intake port 16 is submerged and blocked with water, the cooling of the battery 10 can be continued.

  Further, the battery cooling device 30 according to the present embodiment described above has a configuration in which the pressure valve 20 is opened by the negative pressure in the intake duct 18 when the intake port 16 is blocked with water. Yes. Therefore, the configuration is simple compared to the case where the pressure valve 20 is controlled using an actuator or the like.

  In the battery cooling device 30 of the present embodiment described above, there is an interior trim between the trunk room 32 and the battery cooling device 30 as described above. That is, there is an interior trim on the intake duct 18 of the battery cooling device 30. In the interior trim, a portion of the interior trim located above the pressure valve 20 may be provided with a ventilation hole for feeding cooling air to the opening 39 of the pressure valve 20. With this air blowing hole, it becomes possible to send sufficient cooling air to the opening 39 of the pressure valve 20.

  DESCRIPTION OF SYMBOLS 10 Battery, 12 Cooling fan, 14 Battery pack, 16 Intake port, 18 Intake duct, 20 Pressure valve, 22 Exhaust duct, 24 Exhaust port, 30 Battery cooling device, 32 Trunk room, 34 Back seat, 36 Valve body, 38 Hinge part , 39 Opening, 40 Vehicles, 42 Water, 44 Car compartment.

Claims (1)

A battery cooling device that cools the battery by supplying cooling air to a battery pack in which the battery is stored,
An air inlet provided in the passenger compartment;
An intake duct for guiding the cooling air taken from the intake port to the battery pack by a suction action of a cooling fan provided in the battery pack;
An exhaust duct for guiding the cooling air after cooling the battery from the battery pack to an exhaust port,
At least a part of the intake duct is inclined upward from the intake port toward the battery pack side,
In the middle of the intake duct, a position above the intake port is provided with a pressure valve for taking in the cooling air when the inside of the intake duct becomes negative pressure,
The exhaust port is provided above the intake port,
A battery cooling device.

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