JP2012094313A - Battery unit cooling structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery unit cooling structure which can prevent dew condensation on the outer surface of a battery.SOLUTION: In the cooling structure of a battery unit 1 having a battery pack 11 formed by disposing a plurality of batteries 10, with insulation quality separators 52 put in between, and provided with a cooling plate 12 on the side of a cooling surface 11A of the battery pack 11, the cooling plate 12 is equipped with a dehumidification accelerating body 33, and a duct 40 for collecting condensed water, getting condensed in the dehumidification accelerating body 33 and flowing out of it, is provided beneath the dehumidification accelerating body 33, with a drainage unit 45 disposed in the duct 40.

Description

  The present invention relates to a cooling structure for a battery device for driving a vehicle mounted on a vehicle.

  Conventionally, a driving battery device mounted on a vehicle includes an assembled battery in which a plurality of rectangular batteries are arranged. This type of battery pack needs to be cooled in order to prevent a decrease in battery performance due to temperature rise. Therefore, even when the outside air temperature is high, in order to efficiently cool the assembled battery, the heat absorbing part is thermally connected to the assembled battery, and a refrigerant is flowed inside the heat absorbing part so that the heat absorbing part becomes a refrigerant. It is known that the assembled battery can be cooled by cooling at (for example, see Patent Document 1).

JP 2008-62875 A

However, when the heat absorption part is cooled with the refrigerant, the heat absorption part can be cooled to the dew point temperature or lower, so that the battery outer surface of the rectangular battery is cooled to the dew point temperature or less as the heat absorption part is cooled. There is. In this case, the water part in the air condenses at the part lower than the outdoor temperature, and condensation occurs. There is a problem that the condensed water generated in this manner adheres to the outer surface of the prismatic battery and may adversely affect the insulation performance of the battery device.
An object of the present invention is to provide a cooling structure for a battery device that solves the problems of the conventional techniques described above and can prevent the occurrence of condensation on the outer surface of the battery.

  In order to achieve the above object, the present invention provides a battery device in which a plurality of batteries are arranged to form an assembled battery with an insulating separator interposed therebetween, and a cooling plate is provided on the cooling surface side of the assembled battery. In this cooling structure, the cooling plate is provided with a dehumidification promoting body, and a duct is provided below the dehumidification promoting body for collecting condensed water that is condensed and flows out by the dehumidification promoting body, and a drainage device is disposed in this duct. It was set up.

  In this configuration, an air blower that blows air into the duct, cools the dehumidification promoting body, and blows dry air around the assembled battery may be provided. Moreover, the said cooling plate is set vertically and it is good also as a structure provided with the said dehumidification promotion body in the lower end of the said cooling plate. Further, the cooling plate may be installed vertically, and the dehumidification promoting body may be provided on the surface opposite to the cooling surface of the cooling plate. The cooling plate may be flat and the dehumidification promoting body may be provided on the lower surface of the cooling plate. Moreover, it is good also as a structure which provided the several heat-transfer fin integrally in the said dehumidification promotion body.

  According to the present invention, the cooling plate is provided with a dehumidification promoting body, the dew condensation water that is condensed and flows out by the dehumidification promotion body is collected by the duct, and the drainage device that drains the dew condensation water collected by the duct is disposed. Therefore, the moisture in the air around the battery device is effectively condensed by the dehumidification promoting body, and the air around the battery device is dried by lowering the dew point temperature of the air to prevent the formation of condensation on the outer surface of the prismatic battery. There is an effect that can be done.

It is a figure which shows typically the structure of the battery apparatus of 1st embodiment. It is a disassembled perspective view of a battery apparatus. It is a disassembled perspective view of an assembled battery. It is a disassembled perspective view of a cooling structure. It is a disassembled perspective view of the dehumidification part of a cooling structure. It is a disassembled perspective view which shows the cooling structure of 2nd embodiment. It is a disassembled perspective view which shows the cooling structure of 3rd embodiment. It is the disassembled perspective view which looked at the cooling structure from the downward direction. It is a disassembled perspective view of an assembled battery. It is a perspective view of a battery device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
<First embodiment>
FIG. 1 is a diagram schematically showing a configuration of a battery device 1 according to an embodiment to which the present invention is applied.
The battery device 1 according to the present embodiment is an in-vehicle battery device mounted on a hybrid vehicle or an electric vehicle using an electric motor as a drive source. As shown in FIG. 1, the battery device 1 includes an assembled battery 11 configured by arranging a plurality of rectangular batteries (batteries) 10, and a cooling plate 12 for cooling the assembled battery 11. The assembled battery 11 and the cooling plate 12 roughly constitute a cooling structure 13 of the battery device 1. The cooling plate 12 is connected to the battery cooling cycle 18 constituted by the radiator 8, the brine pump 9, and the heat exchanger 7 through the refrigerant pipe 15 </ b> A, and the cooling plate 12 is transported by the brine pump 9. Cooled by.

The heat exchanger 7 also has a refrigeration cycle 19 constituted by the compressor 3, the condenser 4, the first pressure reducer 5a, and the evaporator 6 via the on-off valve 17 and the second pressure reducer 5b. Connected with. The refrigeration cycle 19 is a car air conditioner cycle of a vehicle on which the battery device 1 is mounted. If it is determined that the cooling capacity of the battery cooling cycle 18 is insufficient, the on-off valve 17 is opened, and the refrigerant flowing through the refrigeration cycle 19 is decompressed by the second decompressor 5b, and then the heat exchanger 7 Flow into. The refrigerant flowing into the heat exchanger 7 exchanges heat with the brine flowing through the battery cooling cycle 18 in the heat exchanger 7, and the brine is cooled.
The cooling plate 12 is arranged in a state of being thermally connected to the cooling surface side of the assembled battery 11. The cooling plate 12 is formed in a thin plate shape, and a surface facing the assembled battery 11 is formed as a heat exchange surface (cooling surface) 12A. When the assembled battery 11 is cooled, the cooling plate 12 is cooled by circulating the brine in the battery cooling cycle 18, and the cooling plate 12 functions as a heat exchanger for cooling the assembled battery 11. Heat is exchanged with the cooled cooling plate 12 and cooled.

  As the cooling plate 12, for example, a flat multi-hole type (microchannel type) cooling plate in which a plurality of tubes (not shown) through which refrigerant flows is arranged in parallel in the front-rear direction can be suitably used. If such a flat multi-hole type (microchannel type) cooling plate is used, the thickness of the cooling plate 12 can be reduced even when the area of the heat exchange surface 12A is large. The thin plate-like cooling plate 12 may have a configuration in which both surfaces are formed as a heat exchange surface 12A.

FIG. 2 is an exploded perspective view of the battery device 1. In the following description, front and rear, top and bottom, and left and right are based on front and rear, top and bottom, and left and right shown in FIG.
The battery device 1 includes a substantially rectangular parallelepiped battery case 60. The battery case 60 includes a case main body 60A formed in a substantially box shape and a case lid 60B that covers the upper opening of the case main body 60A and simply seals the battery case 60. Inside the battery case 60, an assembled battery 11 in which a plurality of rectangular batteries 10 are arranged and assembled is provided. A plurality of the assembled batteries 11 may be arranged side by side in the battery case 60. In this embodiment, the battery unit 26 formed by arranging the assembled batteries 11 in two right and left rows is accommodated in the battery case 60. The

  The assembled battery 11 is arranged inside a fixed block 64 formed in a substantially rectangular parallelepiped frame shape. The fixed block 64 includes fixed plates 65 provided before and after the assembled battery 11, and extending portions 66 provided along the arrangement direction of the assembled battery 11 above and below the side surfaces provided on the left and right sides of the assembled battery 11. . The fixed plate 65 is a thin plate-like member having a surface having substantially the same shape as the facing surface of the prismatic battery 10. The extending portion 66 is fixed to the fixing plate 65 with a screw 67. In this way, the assembled battery 11 is held in a state of being sandwiched between the fixing plates 65 and 65 arranged in the front-rear direction with respect to the arrangement direction of the rectangular batteries 10 of the assembled battery 11.

As shown in FIG. 3, the assembled battery 11 includes a plurality of rectangular batteries 10 arranged in a predetermined direction, and a separator 52 is provided between the adjacent rectangular batteries 10.
Each of the rectangular batteries 10 constituting the assembled battery 11 has a rectangular parallelepiped shape with a width in the left-right direction wider than a width in the front-rear direction, and an output terminal 23 is provided on the upper surface. In the rectangular battery 10 according to the present embodiment, a non-aqueous electrolyte secondary battery including a power generation element in which a positive electrode and a negative electrode are wound via a separator is provided in a rectangular flat case 10c made of aluminum or an aluminum alloy. It is housed and configured. For example, a lithium ion secondary battery is preferably used as the nonaqueous electrolyte secondary battery.

  On the upper surface 10b of the prismatic battery 10, a pair of output terminals 23 provided so as to protrude from the case 10c are provided. The separator 52 is a member for electrically insulating the rectangular batteries 10 adjacent to each other in the assembled battery 11, and is formed of an insulating material. When the assembled battery 11 is configured by combining the prismatic battery 10 and the separator 52, the separator 52 is adjacent to the upper surface holding portion 53 that holds the upper surface 10 b of the rectangular battery 10 and the lower surface holding portion 54 that holds the lower surface. A flat plate-shaped insulating portion 55 interposed between the rectangular batteries 10 and the side surface holding portions 56 and 58 for holding the side surfaces of the rectangular battery 10. The side surface holding part 56 is notched in the vertical direction leaving a pair of corner parts 59, 59 to form a notch part 57, from which the cooling surface 10A of the prismatic battery 10 is exposed. Configured. When the assembled battery 11 is assembled, the cooling surface 10A exposed from the notch 57 is arranged in the front-rear direction of the assembled battery, and the cooling surface 11A is formed.

As shown in FIG. 4, the battery unit 26 is composed of assembled batteries 11 and 11 arranged in two rows side by side on the left and right, and between the assembled batteries 11 and 11, the side surfaces facing the assembled batteries 11 and 11. A cooling plate 12 whose both surfaces are heat exchange surfaces 12A is arranged vertically. Between the cooling surface 11 </ b> A of the assembled battery 11 and the heat exchange surface 12 </ b> A of the cooling plate 12, a heat conductive sheet 51 for maintaining insulation is disposed. The heat conductive sheet 51 is in contact with the cooling surface 11 </ b> A of the assembled battery 11 through the notch 57 and is in contact with the heat exchange surface 12 </ b> A of the cooling plate 12. The heat conductive sheet 51 is formed from a material excellent in insulation and heat conductivity, has elasticity, and is provided in a state of being pressed toward the cooling surface 11A. Therefore, even when vibration occurs as the vehicle travels, the cooling surface 11A is connected to the cooling plate 12 via the heat conductive sheet 51 while maintaining the insulation between the assembled battery 11 and the cooling plate 12 with the heat conductive sheet 51. It can be made to contact uniformly, and the thermal resistance between the cooling surface 11A and the cooling plate 12 can be reduced.
Further, in order to maintain the insulation between the cooling surface 11A and the heat exchange surface 12A of the cooling plate 12, not only the configuration in which the heat conductive sheet 51 is disposed but also the heat exchange surface 12A of the cooling plate 12 is directly insulated. It is good also as a structure which insulates the cooling surface 11A and the heat exchange surface 12A by surface-coating a material.

  A duct 40 is provided below the cooling plate 12 across the assembled battery 11. An air inlet 41 is provided at the front end of the duct 40, and the air inlet 41 is provided with a blower 21 that circulates air in the duct 40. An exhaust port 42 is provided at the rear end of the duct 40. The blower 21 sucks air in the battery case 60 and blows air from the air inlet 41 into the duct 40. The air introduced into the duct 40 from the intake port 41 is again discharged into the battery case 60 from the exhaust port 42. As shown in FIG. 2, the duct 40 and the blower 21 are accommodated together with the battery unit 26 in a battery case 60 that is simply sealed.

As shown in FIG. 5, the cooling plate 12 arranged vertically is provided with an inlet 12 </ b> B through which the refrigerant circulating in the refrigeration cycle 19 (see FIG. 1) flows into the cooling plate 12, and the inside of the cooling plate 12. And an outlet 12C through which the refrigerant flowing through the cooling plate 12 flows out. The inlet 12B and the outlet 12C are provided on the same surface of the cooling plate 12, and the refrigerant pipes connected to the inlet 12B and the outlet 12C are piped in the same direction. The cooling plate 12 is provided such that the inlet 12B and the outlet 12C are arranged on the exhaust port 42 side of the duct 40.
A dehumidification promoting body 33 is provided at the lower end of the cooling plate 12. The dehumidification promoting body 33 and the duct 40 constitute a dehumidifying portion 13A of the cooling structure 13. The dehumidification promoting body 33 is formed from a material having high thermal conductivity such as aluminum or an aluminum alloy. The cooling plate 12 is mounted and provided on an upper surface 33A formed on a substantially flat surface of the dehumidification promoting body 33, and the cooling plate 12 and the dehumidification promoting body 33 are thermally connected. A plurality of fins 33 </ b> C are formed integrally with the dehumidification promoting body 33 on the lower surface 33 </ b> B opposite to the upper surface 33 </ b> A on which the cooling plate 12 of the dehumidification promoting body 33 is stacked.

  The duct 40 includes a water receiving portion 43 formed in a substantially box shape, and the dehumidification promoting body 33 is disposed inside the water receiving portion 43. Projecting portions 44 that protrude upward from the water receiving portion 43 are formed at front and rear ends of the water receiving portion 43, respectively. The protrusion 44 is formed in a substantially rectangular parallelepiped frame shape, and the above-described intake port 41 and exhaust port 42 are formed at the tip of the protrusion 44. The fins 33 </ b> C are formed substantially straight from the front to the rear of the dehumidification promoting body 33 so that the air circulating in the duct 40 flows from the lower surface 33 </ b> B side of the dehumidification promoting body 33 through the fins 33 </ b> C. It has been. According to this configuration, the dehumidification promoting body 33 is cooled by heat conduction with the cooling plate 12 and is air-cooled by the air flowing in the duct 40. Moreover, since the dehumidification promoting body 33 includes a plurality of fins 33C on the lower surface thereof, cooling by the air cooling of the dehumidification promoting body 33 is promoted by the fins 33C.

  Since the dehumidification promoting body 33 is directly and thermally connected to the cooling plate 12, the cooling plate 12 is cooled at the same time as being cooled, and is cooled to a temperature lower than the dew point temperature of the battery ambient air of the assembled battery 11. Moisture in the air circulating in the duct 40 is condensed by the dehumidification promoting body 33 cooled by the dew point temperature of the battery ambient air, and the lower surface 33B or the fin 33C of the dehumidification promoting body 33 is condensed by the moisture in the air. Condensed water flows out. This condensed water is collected by the duct 40 provided under the dehumidification promoting body 33 by its own weight. The air whose dew point temperature has been lowered by the dehumidification promoting body 33 through the duct 40 is discharged again from the exhaust port 42 of the duct 40 into the battery case 60, blown around the assembled battery 11, and into the battery case 60. Full of dry air.

  A drainage device 45 is provided near the lower end of the exhaust port 42 at the rear end of the duct 40. The drainage device 45 includes a drainage pipe 45 </ b> A provided substantially vertically downward from the water receiving portion 43. Although not shown, the drainage device 45 is provided with a one-way valve opening / closing mechanism (open / close valve) such as a spring at the connecting portion between the water receiving portion 43 and the drain pipe 45 </ b> A. It opens and closes due to its own weight of condensed water. Therefore, it is possible to block the flow of gas with the outside air through this open / close mechanism and to discharge condensed water. The drain pipe 45A passes through a hole (not shown) provided on the lower surface of the case body 60A of the battery case 60, extends outside the battery case 60, and the dew condensation water drained through the drain pipe 45A is stored in the battery case. 60 is discharged outside.

  According to these configurations, the air in the battery case 60 circulates in the battery case 60 through the duct 40. Moisture in the air flowing in the duct 40 condenses on the lower surface 33B side of the dehumidification promoting body 33 that has been cooled below the dew point temperature of the battery ambient air. The condensed condensed water is discharged out of the battery case 60 via the drain pipe 45A. The air discharged from the duct 40 to the battery case 60 becomes dry air whose dew point temperature is lowered by the dehumidification promoting body 33. Therefore, it is possible to effectively cause dew condensation on the lower surface 33B side of the dehumidification promoting body 33 in the battery case 60 and to reduce the dew point temperature of the air circulating in the battery case 60. The air whose dew point temperature has been lowered by the dehumidification promoting body 33 is blown around the assembled battery 11 and is filled in the battery case 60, so that condensation is formed on the battery outer surface of each rectangular battery 10 constituting the assembled battery 11 by cooling. Can be prevented.

  As described above, the cooling structure 13 of the battery device 1 according to this embodiment includes the dehumidification promoting body 33 below the cooling plate 12, and the dehumidification promoting body 33 condenses and flows out below the dehumidification promoting body 33. And a drainage device 45 for discharging the condensed water collected by the duct 40 out of the battery case 60 that is simply sealed. Therefore, moisture in the air in the battery case 60 is condensed by the dehumidification promoting body 33 and the dew point temperature is lowered, so that it is possible to prevent dew condensation on the outer surface of the prismatic battery 10. Moreover, since the dew condensation water is discharged out of the battery case 60, the air in the battery case 60 can be kept dry. Furthermore, since the dew condensation water is drained from the duct 40 provided below the dehumidification promoting body 33, the dew condensation water can be prevented from adhering to the battery during drainage.

  Further, according to the present embodiment, the air is blown into the duct 40 to cool the dehumidification promoting body 33, and the air with the dew point temperature lowered is blown around the assembled battery 11, and the dry air is fed into the battery case 60. Therefore, the dry air heavier than the moisture-rich air can be efficiently exhausted from the duct 40, blown around the assembled battery 11, and filled into the battery case 60. Further, the dehumidification promoting body 33 is directly connected to the cooling plate 12 and is cooled simultaneously with the cooling plate 12 and can be air-cooled with air blown into the duct 40. The battery can be quickly cooled below the dew point temperature of the ambient air. Therefore, the moisture contained in the air in the battery case 60 can be efficiently condensed by the dehumidification promoting body 33 to dehumidify the air in the battery case 60, and condensation on the outer surface of the prismatic battery 10 can be prevented. Can be prevented.

  Further, according to the present embodiment, the cooling plate 12 is placed vertically, the battery pack 11 arranged on both sides of the cooling plate 12 is sandwiched between the cooling plates 12, and the cooling plate 12 is placed below the cooling plate 12. A dehumidification promoting body 33 that is directly thermally connected is provided. Therefore, it is possible to cool the assembled batteries 11 arranged in two rows on the left and right sides using both surfaces of the cooling plate 12, to reduce the size of the battery device 1, and to reduce the inside of the battery case 60 with the dehumidification promoting body 33. The air can be dehumidified to prevent condensation on the outer surface of the prismatic battery 10.

  Further, according to the present embodiment, since the fins 33C are provided integrally with the dehumidification promoting body 33, air cooling by the air flowing in the duct 40 of the dehumidification promoting body 33 can be promoted, and the dehumidification promoting body 33 can be further promptly made. The air in the battery case 60 can be dehumidified by cooling to the dew point temperature or lower.

<Second Embodiment>
Next, a second embodiment will be described. In addition, about the following description, about the component same as 1st Embodiment mentioned above, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
As shown in FIG. 6, a cooling plate 12 arranged vertically is in contact with the cooling surface 11 </ b> A of the assembled battery 11 via a heat conductive sheet 51. On the surface of the cooling plate 12 opposite to the heat exchange surface 12 </ b> A, a plurality of dehumidification promoting bodies 63 are provided in direct thermal connection with the cooling plate 12. The dehumidification promoting body 63 is formed in a thin plate shape, and is provided substantially at right angles to the heat exchange surface 12A of the cooling plate 12. Further, each dehumidification promoting body 63 is arranged substantially vertically over the upper and lower sides of the cooling plate 12, and is configured so that the dehumidification promoting body 63 itself functions as a fin. The dehumidification promoting body 63 may be formed from a material having high thermal conductivity such as aluminum or an aluminum alloy, and may be formed integrally with the cooling plate 12.

  A duct 40 is provided below the cooling plate 12 across the assembled battery 11. Although not shown, the air inlet 41 of the duct 40 is provided with a blower 21 that blows air into the duct 40 through the air inlet 41. The air blown into the duct 40 flows from the intake port 41 toward the exhaust port 42 and flows between the dehumidification promoting body 63 and from the lower side to the upper side of the cooling plate 12. The dehumidification promoting body 63 that is directly and thermally connected to the cooling plate 12 is cooled simultaneously with the cooling plate 12 and cooled to a temperature lower than the dew point temperature of the battery ambient air. Further, the dehumidification promoting body 63 cools the air blown by the blower 21.

  When the dehumidification promoting body 63 reaches a temperature lower than the dew point temperature of the battery ambient air, the air in the air blown around the dehumidification promoting body 63 is condensed by the dehumidification promoting body 63 by the blower 21, and the dehumidification promoting body 63 Dew condensation water due to condensation of moisture in the air. The condensed water is collected by the dead weight in the duct 40 provided below the dehumidification promoting body 63, and the air flowing between the duct 40 and the dehumidification promoting body 63 is the air with the dew point temperature lowered. Become. This air is blown around the assembled battery 11 to become dry air and fills the battery case 60. Thereby, it is possible to prevent dew condensation from occurring on the battery outer surface of each rectangular battery 10 constituting the assembled battery 11 due to cooling.

  As described above, according to the present embodiment, the cooling plate 12 is placed vertically, and one surface of the cooling plate 12 is brought into contact with the cooling surface 11A of the assembled battery 11 as a heat exchange surface (cooling surface) 12A. The dehumidification promoting body 63 is provided on the opposite surface. Therefore, the dew condensation water that is condensed and flows out by the dehumidification promoting body 63 does not flow to the assembled battery 11 side and can be discharged to the outside of the battery case 60. The air in the battery case 60 is efficiently dehumidified, It is possible to prevent the condensed water from adhering to the outer surface of the prismatic battery 10.

In addition, according to the present embodiment, the dehumidification promoting body 63 is formed in a thin plate shape and plays the role of a fin. Therefore, the dehumidification promoting body 63 is efficiently cooled by air cooling, and the dehumidification promoting body 63 is quickly replaced with a battery. The air in the battery case 60 can be dehumidified by cooling to the dew point temperature of the ambient air or less, and condensation can be prevented from occurring on the outer surface of the prismatic battery 10.
Further, since the thin plate-like dehumidification promoting body 63 is disposed substantially vertically over the upper and lower sides of the heat exchange surface 12A, it is possible to quickly collect condensed water in the duct 40 provided below the dehumidification promoting body 63. Become.

<Third Embodiment>
Next, a third embodiment will be described. In addition, about the following description, about the component same as 1st Embodiment mentioned above, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
As shown in FIG. 7, the battery unit 260 includes a battery pack 110 in which a plurality of prismatic batteries 10 are arranged in a predetermined direction, and separators 70 described later are arranged between the prismatic batteries 10 adjacent to each other. Multiple columns are arranged on the left and right. The two assembled batteries 110, 110 arranged side by side are integrally fixed by a fixing plate 65 provided at the front and rear of the assembled battery 110 and an extending portion 66 provided at the left and right. The assembled battery 110 is placed on the heat exchange surface 12A on the upper surface side of the cooling plate 12 placed flat. The cooling plate 12 is fixed to the fixing plate 65 by screwing from below with screws.

  A duct 140 is disposed below the cooling plate 12. The duct 140 is formed larger than the cooling plate 12 so that the cooling plate 12 is accommodated inside the water receiving portion 43. The duct 140 includes an exhaust port 42 provided on the side of the cooling plate 12 on which the refrigerant inlet 12B and the outlet 12C are provided, and an intake port 41 provided on the opposite side of the exhaust port 42. The air inlet 41 is provided with the blower 21, and air is blown into the duct 140 through the air inlet 41 by the air blower 21.

As shown in FIG. 8, a dehumidification promoting body 83 is provided on the lower surface of the cooling plate 12 so as to be directly thermally connected. A plurality of grooves 84 formed in a channel shape are formed on the lower surface of the dehumidification promoting body 83, and the heat exchange area of the dehumidification promoting body 83 is expanded. Although not shown, a plurality of fins may be formed inside the groove 84, and the heat exchange area of the dehumidification promoting body 83 may be further expanded. The dehumidification promoting body 83 may be formed integrally with the cooling plate 12 or may be formed of a material having high thermal conductivity such as aluminum or aluminum alloy and thermally connected to the cooling plate 12. It is good also as composition which has.
A cooling surface 11A is formed on the lower surface of the assembled battery 11, and when the assembled battery 11 is placed on the cooling plate 12, the cooling surface 11A is brought into contact with the cooling plate 12 via a heat conductive sheet 51 (not shown). Make contact.

  As shown in FIG. 9, the lower surface holding portion 54 that holds the lower surface of the prismatic battery 10 is formed with a cutout portion 72 that is largely cut out in the left-right direction, leaving a pair of corner portions 71. . When the separator 70 and the prismatic battery 10 are combined, the cooling surface 10 </ b> A of the prismatic battery 10 is exposed from the notch 72. When the assembled battery 11 is assembled, the cooling surface 10A of the prismatic battery 10 exposed from the notch 72 is aligned in the front-rear direction of the assembled battery 11, and the cooling surface 11A is formed.

  As shown in FIG. 10, the battery unit 260, the cooling plate 12, the duct 140, and the blower 21 are accommodated in the battery case 60, and the battery case 60 is simply sealed. When the cooling plate 12 is cooled, the dehumidification promoting body 83 that is directly and thermally connected to the cooling plate 12 is cooled at the same time as the cooling plate 12 and is cooled to a temperature lower than the dew point temperature of the battery ambient air. Further, the dehumidification promoting body 83 is guided into the duct 140 by the blower 21. When the dehumidification promoting body 83 is cooled below the dew point temperature of the battery ambient air, the moisture in the air of the air guided by the blower 21 into the duct 140 is condensed by the dehumidification promoting body 83.

  Condensed water due to condensation of moisture in the air flows out to the dehumidification promoting body 83. The condensed water is collected by the own weight in a duct 140 provided below the dehumidification promoting body 83 and discharged from the drainage device 45 provided in the duct 140 to the outside of the battery case 60. The dew point temperature of the air passing through the duct 140 is lowered by the dehumidification promoting body 83. The air whose dew point temperature has been lowered by the dehumidification promoting body 83 is blown from the exhaust port 42 of the duct 40 around the assembled battery 11, and the battery case 60 is filled with dry air. In this way, dry air having a low dew point temperature is circulated around the assembled battery 11, and it is possible to prevent dew condensation due to cooling from occurring on the outer surface of each rectangular battery 10 constituting the assembled battery 11.

  As described above, according to this embodiment, the cooling plate 12 is placed flat, the assembled battery 110 is placed on the heat exchange surface 12A on the upper surface side of the cooling plate 12, and the dehumidification promoting body 83 is provided on the lower surface side. It was. Therefore, the assembled battery 110 can be cooled on the upper surface side of the cooling plate 12, and the air in the battery case 60 can be dehumidified by the dehumidification promoting body 83 on the lower surface side of the cooling plate 12. In addition, it is possible to prevent the condensation water that has been condensed and discharged by the dehumidification promoting body 83 from flowing to the assembled battery 110 side.

1 Battery device 10 Square battery (battery)
11, 110 Battery pack 11A Cooling surface 12 Cooling plate 12A Heat exchange surface (cooling surface)
13 Cooling structure 21 Blower 33, 63, 83 Dehumidification promoting body 33C Fin 40, 140 Duct 45 Drainage device 51 Thermal conductive sheet 52, 70 Separator

Claims (6)

In the cooling structure of the battery device in which a plurality of batteries are arranged with an insulating separator in between to form an assembled battery, and a cooling plate is provided on the cooling surface side of the assembled battery,
The cooling plate is provided with a dehumidification promoting body, and below the dehumidification promoting body, is provided with a duct for collecting dew condensation water condensed and flowing out by the dehumidification promoting body, and a drainage device is provided in this duct. Battery device cooling structure.   The cooling structure for a battery device according to claim 1, further comprising a blower that blows air into the duct to cool the dehumidification promoting body and blows dry air around the assembled battery.   The cooling structure for a battery device according to claim 1 or 2, wherein the cooling plate is vertically placed, and the dehumidification promoting body is provided at a lower end of the cooling plate.   The cooling structure for a battery device according to claim 1 or 2, wherein the cooling plate is vertically placed, and the dehumidification promoting body is provided on a surface opposite to the cooling surface of the cooling plate.   3. The cooling structure for a battery device according to claim 1, wherein the cooling plate is flat and the dehumidification promoting body is provided on a lower surface of the cooling plate.   The cooling structure for a battery device according to any one of claims 1 to 5, wherein a plurality of heat transfer fins are integrally provided on the dehumidification promoting body.