JP2020135957A - Power storage system - Google Patents

Abstract

To provide a highly reliable power storage system.SOLUTION: A power storage system 1 includes: a battery pack 2; and a cooling system 60. The battery pack 2 includes: a housing 3 having a lid 3b; and a battery module 4 housed in the housing 3. The cooling system 60 includes: a circulation flow path 10, connected to the housing 3, for circulating air S between the cooling system and an inside of the housing 3; an outside air flow path 20, connected to the circulation flow path 10, for supplying outside air R to the circulation flow path 10; and a dehumidifying unit 21, provided in the outside air flow path 20, for dehumidifying the outside air R.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power storage system.

Conventionally, a battery pack in which a plurality of battery modules are housed in a housing is known (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2013-122844

When the battery pack as described above is mounted on a vehicle used in a port, for example, the housing is formed in a closed type in order to suppress salt damage and dew condensation. On the other hand, even in such a battery pack, it is necessary to dissipate the heat generated in the battery module. In order to cool the battery module while maintaining the airtightness of the housing, for example, it is conceivable to connect a circulation flow path to the housing and circulate air between the inside of the housing and the circulation flow path. However, for example, when the lid of the housing is removed for maintenance, outside air flows into the housing. The outside air may contain a large amount of moisture, in which case dew condensation occurs when the temperature inside the housing drops. Condensation can cause malfunctions in the battery module, and it is necessary to suppress it in order to improve reliability.

An object of the present invention is to provide a highly reliable power storage system.

The power storage system of the present invention includes a battery pack and a cooling system, the battery pack includes a housing having a lid portion, and a battery module housed in the housing, and the cooling system is provided in the housing. A circulation flow path that is connected and circulates air between the inside of the housing, an outside air flow path that is connected to the circulation flow path and supplies outside air to the circulation flow path, and a dehumidification that is provided in the outside air flow path to dehumidify the outside air. It has a part and.

In this power storage system, the battery module can be cooled while maintaining the airtightness inside the housing by circulating air between the inside of the housing and the circulation flow path. Further, in this power storage system, the cooling system includes an outside air flow path connected to the circulation flow path to supply outside air to the circulation flow path, and a dehumidifying unit provided in the outside air flow path to dehumidify the outside air. .. As a result, even if the lid of the housing is removed for maintenance and the outside air flows into the housing and the humidity of the air inside the housing rises, the outside air dehumidified by the dehumidifying part is circulated from the outside air flow path. By supplying to the flow path, the humidity of the air circulating in the housing and the circulation flow path can be reduced. As a result, it is possible to suppress the occurrence of dew condensation in the housing and suppress the occurrence of defects in the battery module. Therefore, the reliability of this power storage system is improved.

The power storage system of the present invention further includes an open / close sensor for detecting information on opening / closing of the lid, and depending on the detection result of the open / close sensor, a non-supply state in which outside air is not supplied from the outside air flow path to the circulation flow path and a dehumidifying section The supply state in which the dehumidified outside air is supplied from the outside air flow path to the circulation flow path may be switched. In this case, the occurrence of dew condensation in the housing can be suppressed more reliably.

The power storage system of the present invention further includes a humidity sensor that detects the humidity of air, and is dehumidified by a dehumidifying unit and a non-supply state in which outside air is not supplied from the outside air flow path to the circulation flow path according to the detection result of the humidity sensor. The supply state in which the outside air is supplied from the outside air flow path to the circulation flow path may be switched. In this case, the occurrence of dew condensation in the housing can be suppressed even more reliably.

In the power storage system of the present invention, the duration of the supply state may be based on the volume of the housing and the amount of air supplied into the housing from the circulation flow path per unit time. In this case, the supply state can be continued for an appropriate time.

In the power storage system of the present invention, the dehumidifying unit may include a compression unit that compresses the outside air and a cooling unit that cools the outside air compressed by the compression unit. In this case, the outside air flowing through the outside air flow path can be suitably dehumidified.

In the power storage system of the present invention, when the pressure inside the housing is higher than the external pressure by a predetermined value or more, the air inside the housing is discharged to the outside, and the check that suppresses the inflow of outside air from the outside into the housing is suppressed. A valve may be provided. In this case, the air inside the housing can be suitably discharged to the outside, and the inflow of outside air from the outside into the housing can be suppressed.

In the power storage system of the present invention, the cooling system may further include a cooling unit provided in the circulation flow path to cool the air. In this case, the battery module can be cooled more effectively.

According to the present invention, it is possible to provide a highly reliable power storage system.

It is a schematic block diagram of the power storage system which concerns on one Embodiment.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. In the following description, the same reference numerals will be used for the same or equivalent elements, and duplicate description will be omitted.

The power storage system 1 shown in FIG. 1 includes a battery pack 2 and a cooling system 60. The battery pack 2 is mounted on a vehicle such as an AGV (automated guided vehicle) used for transferring a container in a port, and functions as a power source for the vehicle. The weight of the vehicle is, for example, about 30 tons.

The battery pack 2 includes a substantially rectangular parallelepiped housing 3 and a plurality of battery modules (battery strings) 4. The housing 3 has a main body portion 3a provided with an opening on one surface, and a flat plate-shaped lid portion 3b that closes the opening of the main body portion 3a. In this example, the lid portion 3b is provided so as to be openable and closable with respect to the main body portion 3a for maintenance and the like. When the lid 3b is closed, the housing 3 is sealed, and when the lid 3b is opened, the housing 3 is opened.

The battery module 4 is, for example, a secondary battery such as a nickel hydrogen secondary battery or a lithium ion secondary battery, or an electric double layer capacitor. The battery module 4 is housed in the housing 3. The total weight of the plurality of battery modules 4 is, for example, about 4 tons to 6 tons.

The cooling system 60 includes a circulation flow path 10 connected to the housing 3 and an outside air flow path 20 connected to the circulation flow path 10. The circulation flow path 10 is a flow path for circulating air S with and from the housing 3, and is composed of, for example, a pipe body (duct pipe) such as a pipe. The first end 10a of the circulation flow path 10 is connected to the lower part of the housing 3, and the second end 10b of the circulation flow path 10 is connected to the upper part of the housing 3. The circulation flow path 10 is provided with a blower 11 that sends the air S in the circulation flow path 10 toward the first end 10a side. As a result, the air S flows from the second end 10b toward the first end 10a in the circulation flow path 10. The blower 11 is, for example, a fan. A cooler (cooling unit) 12 for cooling the air S is provided on the downstream side of the blower 11 in the circulation flow path 10.

A first regulating member 5 and a second regulating member 6 for regulating the flow of air S are provided in the housing 3. The first regulating member 5 is, for example, a flat plate-shaped member arranged below the housing 3 in the vertical direction, and defines a first space P1 with the bottom surface of the housing 3. The first regulating member 5 is provided with a plurality of slits 5a. The second regulating member 6 is, for example, a flat plate-shaped member arranged on the upper portion of the housing 3 in the vertical direction, and defines a second space P2 with the top surface of the housing 3. The second regulating member 6 is provided with a plurality of slits 6a. The first space P1 and the second space P2 function as pressure pools.

The air S whose pressure has been increased in the blower 11 is supplied to the first space P1 from the first end 10a of the circulation flow path 10. The air S supplied to the first space P1 flows into the housing 3 through the slit 5a of the first regulating member 5 and rises in the housing 3. The air S that has risen inside the housing 3 and reached the second regulating member 6 flows into the second space P2 through the slit 6a. The air S in the second space P2 is discharged to the second end 10b of the circulation flow path 10. The slits 5a and 6a may be through holes, for example, as long as air S can pass through them.

In this way, in the power storage system 1, the air S is sent by the blower 11, and the air S circulates between the inside of the housing 3 and the circulation flow path 10. As a result, the battery module 4 can be cooled. Further, by restricting the flow of air S by using the first regulating member 5 and the second regulating member 6, the temperature inside the housing 3 can be uniformly lowered. Further, since the battery module 4 of the present embodiment has a heat radiating surface on the vertically lower side, the battery module 4 is effectively cooled by flowing air S from the bottom to the top in the housing 3. be able to.

A check valve (breezer) 7 is provided in the housing 3. The check valve 7 discharges the air S inside the housing 3 to the outside when the pressure inside the housing 3 is higher than the external pressure (pressure outside the housing 3) (atmospheric pressure) by a predetermined value or more. For example, when the outside air R is supplied to the circulation flow path 10 from the outside air flow path 20 as described later, an amount of air S corresponding to the amount of the supplied outside air R is discharged from the check valve 7. As a result, the balance of the amount of air S circulating in the circulation flow path 10 is maintained. Further, the check valve 7 suppresses the inflow of outside air from the outside into the housing 3. As a result, it is possible to prevent outside air from flowing into the housing 3 from the outside when the outside air temperature becomes low. The predetermined value (cranking pressure) related to the operation of the check valve 7 is determined, for example, according to the specifications of the blower 11. For example, the predetermined value can be set to a value obtained by adding the wind pressure of the blower 11 (for example, several hundred Pa) to the atmospheric pressure.

The outside air flow path 20 is a flow path for taking the outside air R into the circulation flow path 10, and is composed of, for example, a pipe body (tube pipe) such as a pipe. The diameter of the outside air flow path 20 is, for example, about 6 mm, which is smaller than the diameter of the circulation flow path 10. The outside air flow path 20 is connected to the circulation flow path 10 via the switching valve 14 on the upstream side of the blower 11. The outside air flow path 20 is provided with a dehumidifying portion 21 for dehumidifying the outside air R. The dehumidifying section 21 has a compressor (compressing section) 22, a cooler (cooling section) 23, and a drainage section 24 in this order from the upstream side.

The compressor 22 is, for example, a compressor. Although the compressor 22 is dedicated to the power storage system 1, it may be shared with the compressor of the vehicle on which the battery pack 2 is mounted. The outside air R introduced into the outside air flow path 20 is compressed by the compressor 22 and then cooled by the cooler 23. As a result, the moisture W contained in the outside air R is separated. The separated water W is discharged from the drainage unit 24. In this way, the outside air R introduced into the outside air flow path 20 is dehumidified by the dehumidifying unit 21. As a result, the outside air R supplied from the outside air flow path 20 to the circulation flow path 10 becomes dry air. The pressure of the outside air R supplied from the outside air flow path 20 to the circulation flow path 10 is, for example, about 2 atm, which is higher than the pressure of the air S flowing in the circulation flow path 10. Whether or not the outside air R can be supplied from the outside air flow path 20 to the circulation flow path 10 is switched by the switching valve 14. The switching valve 14 is, for example, a solenoid valve. The control of the switching valve 14 will be described later. The switching valve 14 may be arranged on the downstream side of the drainage portion 24 in the outside air flow path 20.

The power storage system 1 further includes an open / close sensor 41, a humidity sensor 42, and a control unit 50. The open / close sensor 41 detects the open / close of the lid 3b of the housing 3. The open / close sensor 41 is, for example, a mechanical or electrical sensor provided in the housing 3 and detecting the open / close of the lid portion 3b. Alternatively, the open / close sensor 41 may be provided in the housing 3 and detect the opening / closing of the lid portion 3b by detecting a change in pressure in the housing 3. That is, the open / close sensor 41 may be any sensor as long as it detects information regarding the opening / closing of the lid portion 3b, and may be arbitrarily configured.

The humidity sensor 42 detects the humidity of the air S. The humidity sensor 42 is provided in, for example, the blower 11 and detects the humidity of the air S flowing through the circulation flow path 10. That is, in this example, the humidity sensor 42 is arranged on the downstream side of the connection point (position of the switching valve 14) of the outside air flow path 20 in the circulation flow path 10.

The control unit 50 is composed of, for example, a computer including a processing unit such as a CPU and a storage unit such as a ROM and a RAM. The control unit 50 is electrically connected to the switching valve 14, the dehumidifying unit 21, the open / close sensor 41, the humidity sensor 42, and the like, and controls the operation of each unit of the power storage system 1.

Hereinafter, a control example by the control unit 50 will be described. Normally, the air S is sent by the blower 11, and the air S circulates between the inside of the housing 3 and the circulation flow path 10. The control unit 50 controls the cooler 12 so that the temperature inside the housing 3 approaches the target temperature, for example. The control unit 50 can grasp the temperature inside the housing 3 based on the detection result of the temperature sensor provided in each battery module 4 or the blower 11, for example. Here, the normal time is, for example, when the battery pack 2 is used and when the vehicle on which the battery pack 2 is mounted is driven. In the normal state, the lid 3b of the housing 3 is closed. Normally, the control unit 50 closes the switching valve 14 and stops the operation of the dehumidifying unit 21. As a result, the cooling system 60 is in a non-supply state in which the outside air R is not supplied from the outside air flow path 20 to the circulation flow path 10.

In a normal state, the control unit 50 monitors whether or not the lid portion 3b is opened based on the detection result of the open / close sensor 41. When the control unit 50 determines that the lid unit 3b is opened, the control unit 50 opens the switching valve 14 and causes the dehumidifying unit 21 to start the operation. As a result, the cooling system 60 switches from the non-supply state to a supply state in which the outside air R (dry air) dehumidified by the dehumidifying unit 21 is supplied from the outside air flow path 20 to the circulation flow path 10. In the supply state, the humidity of the air S circulating in the housing 3 and the circulation flow path 10 is lowered by supplying the dehumidified outside air R by the dehumidifying unit 21. When the internal pressure inside the housing 3 increases due to the supply of the outside air R, the air S inside the housing 3 is discharged to the outside from the check valve 7. Although the housing 3 is sealed in the supply state, the ingress of outside air from the outside into the housing 3 is suppressed by the positive pressure inside the housing 3.

The duration of the supply state is set based on the volume of the housing 3 and the amount of air S supplied from the circulation flow path 10 into the housing 3 per unit time. The duration is set to, for example, a value obtained by dividing the volume of the housing 3 by the amount of air S supplied into the housing 3 per unit time, or a value larger than the value. For example, when the volume of the housing 3 is 100 liters and the amount of air S supplied into the housing 3 is 10 liters / minute, the measurement time can be set to 10 minutes. For example, the control unit 50 switches the cooling system 60 to the non-supply state after the duration has elapsed from the time of switching to the supply state. As a result, the humidity inside the housing 3 can be sufficiently reduced. The control unit 50 may switch the cooling system 60 to the non-supply state after the above-mentioned duration has elapsed from the time when the lid portion 3b is closed.

As described above, in the power storage system 1, the battery module 4 is cooled while maintaining the airtightness inside the housing 3 by circulating the air S between the inside of the housing 3 and the circulation flow path 10. Can be done. Further, in the power storage system 1, the cooling system 60 is connected to the circulation flow path 10 to supply the outside air R to the circulation flow path 10, and is provided in the outside air flow path 20 to dehumidify the outside air R. It is provided with a unit 21 and. As a result, even if the lid 3b of the housing 3 is removed for maintenance, the outside air R flows into the housing 3, and the humidity of the air S in the housing 3 rises, the dehumidifying unit 21 dehumidifies the housing 3. By supplying the generated outside air R from the outside air flow path 20 to the circulation flow path 10, the humidity of the air S circulating in the housing 3 and the circulation flow path 10 can be reduced. As a result, it is possible to suppress the occurrence of dew condensation in the housing 3 and suppress the occurrence of defects in the battery module 4. In addition, stable humidity control is possible. Therefore, the reliability of the power storage system 1 is improved.

In the power storage system 1, depending on the detection result of the open / close sensor 41, the outside air R is not supplied from the outside air flow path 20 to the circulation flow path 10, and the outside air R dehumidified by the dehumidifying unit 21 is sent from the outside air flow path 20. The supply state supplied to the circulation flow path 10 is switched. As a result, the occurrence of dew condensation in the housing 3 can be suppressed more reliably.

In the power storage system 1, the duration of the supply state is based on the volume of the housing 3 and the amount of air S supplied from the circulation flow path 10 into the housing 3 per unit time. As a result, the supply state can be continued for an appropriate time.

In the power storage system 1, the dehumidifying unit 21 includes a compressor 22 that compresses the outside air R and a cooler 23 that cools the outside air R compressed by the compressor 22. Thereby, the outside air R flowing through the outside air flow path 20 can be suitably dehumidified.

In the power storage system 1, when the pressure inside the housing 3 is higher than the external pressure by a predetermined value or more, the housing 3 discharges the air S inside the housing 3 to the outside and the outside air from the outside to the inside of the housing 3. A check valve 7 is provided to prevent the inflow of air. As a result, the air S in the housing 3 can be suitably discharged to the outside, and the inflow of outside air from the outside into the housing 3 can be suppressed.

Although one embodiment of the present invention has been described above, the present invention is not limited to the above embodiment. The non-supply state and the supply state may be switched according to the detection result of the humidity sensor 42. For example, when the humidity of the air S becomes higher than a predetermined value, the non-supply state may be switched to the supply state. When the humidity of the air S becomes smaller than a predetermined value in the supply state, the supply state may be switched to the non-supply state. Similar to the above-described embodiment, reliability can be enhanced by such a modification. In addition, the occurrence of dew condensation inside the housing 3 can be reliably suppressed.

The cooler 12 may be omitted. Even in this case, the battery module 4 can be cooled by circulating the air S between the inside of the housing 3 and the circulation flow path 10. The humidity sensor 42 may be provided in the battery module 4 and detect the humidity of the air S in the housing 3. The lid portion 3b may be provided so as to be removable with respect to the main body portion 3a.

The dehumidifying unit 21 may be a dehumidifying agent such as zeolite or a desiccant (molecular receive), or a heatless dryer. Even in this case, the outside air R flowing through the outside air flow path 20 can be dehumidified. However, when the dehumidifying unit 21 includes the compressor 22 and the cooler 23, it is possible to eliminate the need to replace the dehumidifying agent or the desiccant.

A dehumidifying agent, a desiccant, or a heatless dryer may be provided on the downstream side of the dehumidifying portion 21 in the outside air flow path 20. In this case, the outside air R flowing through the outside air flow path 20 can be effectively dehumidified.

The outside air flow path 20 may be connected to the circulation flow path 10 on the downstream side of the blower 11. However, when the outside air flow path 20 is connected to the circulation flow path 10 on the upstream side of the blower 11, the pressure of the outside air R supplied to the circulation flow path 10 can be suitably increased.

The power storage system 1 may include a plurality of battery packs 2. In this case, the outside air flow path 20 and the dehumidifying section 21 may be shared between the plurality of battery packs 2. That is, dry air may be supplied to the plurality of battery packs 2 from one outside air flow path 20.

In the above embodiment, the non-supply state and the supply state are switched, but the cooling system 60 may always be in the supply state. In this case, for example, a small amount of dry air may be constantly supplied from the outside air flow path 20 to the circulation flow path 10. In this case, a flow rate throttle valve, a fixed orifice, or the like may be provided instead of the switching valve 14.

1 ... Power storage system, 2 ... Battery pack, 3 ... Housing, 3b ... Lid, 4 ... Battery module, 7 ... Check valve, 10 ... Circulation flow path, 12 ... Cooler (cooling part), 20 ... Outside air flow path , 21 ... Dehumidifying section, 22 ... Compressor (compressor), 23 ... Cooler (cooling section), 41 ... Open / close sensor, 42 ... Humidity sensor, 60 ... Cooling system, R ... Outside air, S ... Air.

Claims (7)

Equipped with a battery pack and a cooling system,
The battery pack
A housing with a lid and
A battery module housed in the housing and
The cooling system
A circulation flow path that is connected to the housing and circulates air between the housing and the inside of the housing.
An outside air flow path that is connected to the circulation flow path and supplies outside air to the circulation flow path,
A power storage system provided in the outside air flow path and comprising a dehumidifying unit for dehumidifying the outside air. Further provided with an open / close sensor for detecting information regarding the open / close of the lid.
Depending on the detection result of the open / close sensor, the outside air is not supplied from the outside air flow path to the circulation flow path, and the outside air dehumidified by the dehumidifying portion is transferred from the outside air flow path to the circulation flow path. The power storage system according to claim 1, wherein the supply state is switched. Further equipped with a humidity sensor for detecting the humidity of the air,
Depending on the detection result of the humidity sensor, the outside air is not supplied from the outside air flow path to the circulation flow path, and the outside air dehumidified by the dehumidifying portion is transferred from the outside air flow path to the circulation flow path. The power storage system according to claim 1 or 2, wherein the supply state to be supplied is switched. The power storage according to claim 2 or 3, wherein the duration of the supply state is based on the volume of the housing and the amount of air supplied into the housing from the circulation flow path per unit time. system. The power storage system according to any one of claims 1 to 4, wherein the dehumidifying unit includes a compression unit that compresses the outside air and a cooling unit that cools the outside air compressed by the compression unit. A check valve that discharges the air inside the housing to the outside when the pressure inside the housing is higher than an external pressure by a predetermined value or more, and suppresses the inflow of outside air from the outside into the housing. The power storage system according to any one of claims 1 to 5, wherein the power storage system is provided. The power storage system according to any one of claims 1 to 6, wherein the cooling system further includes a cooling unit provided in the circulation flow path to cool the air.

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