JP2017126418A - Battery pack temperature control/power feed system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a battery pack temperature control/power feed system in which a battery cell can be heated or cooled in a planar configuration, the system having highly exceptional heating efficiency and cooling efficiency, stable battery performance, a small number of components, and an uncomplicated structure, while achieving reductions in size and thickness as well as cost.SOLUTION: A battery pack temperature control/power feed system 10 includes: a battery part 22 which is formed by laminating a plurality of battery cells 12 and a plate-shaped vapor chamber 16 interposed between the battery cells 12; a thermoelectric element 24 disposed so as to adhere tightly to the end surface of one end of the vapor chamber 16 (lateral vapor chamber 18); a heat sink part 26 equipped with a plurality of fins 30 formed extending at a predetermined spacing from each other such that the end surface of the heat sink part 26 adheres tightly to the thermoelectric element 24; and a fan part 32 disposed to face the fins 30 of the heat sink part 26.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a battery pack temperature control / power supply system, and includes, for example, an electric vehicle (EV), a hybrid vehicle (HV), a plug-in hybrid vehicle (PHV), etc., and a battery such as a nickel metal hydride battery or a lithium ion battery. The present invention relates to a battery pack temperature control / power supply system used in various battery-powered devices.

  In particular, the present invention relates to a battery pack temperature control / power supply system capable of heating, cooling, and charging a battery cell in such a battery pack temperature control / power supply system.

  Conventionally, a battery system disclosed in Patent Document 1 (Japanese Patent No. 5625115) has been proposed as a battery system for cooling such a battery.

  FIG. 11A is a perspective view of the battery system 100 of Patent Document 1, and FIG. 11B is a perspective view showing the structure of the cooling member 104 of the battery system 100 of Patent Document 1.

  In the battery system 100 of Patent Document 1, as shown in FIG. 11A, a plurality of plate-like battery cells 102 are stacked, and a cooling member 104 is interposed between the opposed battery cells 102. It is attached in a stacked state.

  As shown in FIG. 11B, the cooling member 104 is made of a metal material and includes a plate-like heat release fin 106. The cooling member 104 is provided with a coolant conduit 108 disposed so as to surround the heat release fin 106 and through which coolant flows.

  As a result, the battery system 100 of Patent Document 1 is configured to cool the battery cell 102 via the coolant conduit 108 and the heat release fin 106 through which the coolant flows.

  Patent Document 2 (Japanese Patent Application Laid-Open No. 2014-53276) proposes a battery system including a space through which conditioned air for heating and cooling a battery flows.

  12A is a top view of the battery system of Patent Document 2, and FIG. 12B is a cross-sectional view of the battery system of Patent Document 2.

  As shown in FIGS. 12A and 12B, the battery system 200 of Patent Document 2 includes a sealed housing 202 in which air is prevented from entering and exiting, and a front of the internal space of the sealed housing 202. Blowers 204 are respectively provided at the rear.

  In the internal space of the hermetic housing 202, a plurality of battery packs 206 are arranged between the two blowers 204 facing each other in the front-rear direction so as to be aligned in the up-down direction and the front-rear direction.

  A thermoelectric element 208 is provided at a position facing the center of the blower 204.

  As shown in FIG. 12B, each battery pack 206 is formed with a plurality of horizontal ventilation holes 210 having a certain width apart in the vertical direction so that air conditioning is performed uniformly. .

  That is, in each battery pack 206, a plurality of battery cells 212 are stacked in the vertical direction, and grooves are formed on the upper surface and the lower surface of each battery cell 212 so as to form the vent hole 210 when stacked. It has become.

  Thus, the battery system 200 of Patent Document 2 is configured to heat and cool the battery pack 206 with air through the ventilation hole 210 formed between the battery packs 206.

  Patent Document 3 (Japanese Patent Laid-Open No. 2009-152440) proposes a battery system for heating and cooling a battery.

  13A is a top view of the battery system of Patent Document 3, FIG. 13B is a partially enlarged perspective view of the battery system of Patent Document 3, and FIG. 14A is an exploded view of FIG. 13B. FIG. 14B is a perspective view of FIG. 13B.

  As shown in FIGS. 13A to 14B, the battery system 300 of Patent Document 3 includes a housing 302, and an inlet pipe 304 for introduction into the housing 302 is connected in communication. ing. A fan 306 for sending cooling air into the housing 302 is provided in the middle of the inlet pipe 304.

  The casing 302 is connected to an outlet pipe 308 for discharging the cooling air after cooling the battery module 310 to the outside of the casing 302.

  As shown in FIGS. 13B to 14B, a battery module 310, a heat receiving plate 312, a heat pipe 314, a thermoelectric element member 316, and a plurality of fins are provided in the housing 302. The heat sink 320 provided with 318 is accommodated in an assembled state. Further, the heat sink 320 is disposed in the cooling medium passage 322.

  Further, as shown in FIGS. 14A to 14B, the heat receiving plate 312 is joined to each other, and is attached to the inside of the battery modules 310a to 310f in a state of being in close contact with each other. Inner heat receiving plates 324 and 326 are provided.

  Furthermore, the heat receiving plate 312 includes outer heat receiving plates 328 and 330 assembled outside the battery modules 310a to 310f.

  Further, as shown in FIGS. 14A to 14B, the heat receiving plates 324 to 330 have grooves 332 that are recessed in the thickness direction thereof in the longitudinal direction of the respective heat receiving plates 324 to 330. It is formed over the entire length.

  And each part of battery module 310a-310f corresponding to each groove | channel 332 is assembled | attached in the state fitted.

  Further, as shown in FIGS. 14A to 14B, a semicircular cross-sectional groove 336 a for accommodating the heat pipes 314 a to 314 c is formed on the joint surface between the inner heat receiving plates 324 and 326. 336b are formed over the entire length in the longitudinal direction of the inner heat receiving plates 324 and 326, respectively. Heat pipes 314a to 314c are accommodated in these grooves 336a and 336b.

  The heat sink 320 is composed of a plurality of thin plate-like fins 318 arranged at predetermined intervals along the flow of the cooling air flowing through the cooling medium passage 322, and the base end side thereof is erected on the plate-like base portion 320a. It is provided in the state.

Thereby, when the battery modules 310 a to 310 f are cooled, in the battery system 300 of Patent Document 3, cooling air is introduced into the housing 302 from the inlet pipe 304 by the fan 306.
The battery modules 310a to 310f are cooled by the cooling action by the plurality of fins 318 of the heat sink 320 disposed in the cooling medium passage 322, the heat receiving plate 312 and the thermoelectric element member 316, and the heat pipes 314a to 314c. ing.

  Further, when the battery modules 310a to 310f are heated, the battery modules 310a to 310f are heated by changing the direction of the direct current of the thermoelectric element member 316.

  Patent Document 4 (Japanese Patent No. 5089814) proposes a battery system for heating and cooling the battery.

  FIG. 15 is a perspective view of the battery system of Patent Document 4. FIG.

  As shown in FIG. 15, in the battery system 400 of Patent Document 4, a plurality of battery cells 402 are arranged vertically and horizontally to constitute a battery 404. A plurality of heat pipes 406 are arranged between the battery cells 402 in the longitudinal direction.

  In addition, a heater (not shown) made of a thermoelectric element or the like is connected to one end of the heat pipe 406 as a heating unit, and a plurality of fins 410 are connected to the other end of the heat pipe 406.

  Thereby, when the battery cell 402 is heated, the battery cell 402 is heated via the heat pipe 406 by the heating of the heater. Further, the battery cell 402 can be heated via the heat pipe 406 by sending air (warm air) from the engine and air conditioner (heating) to the fins 410.

  Further, when the battery cell 402 is cooled, the heat of the battery cell 402 transmitted by the heat pipe 406 is radiated from the fins 410 into the air. Further, the battery cell 402 can be further cooled by exposing cold air from the air conditioner (cooling means) to the fins 410.

Japanese Patent No. 5625115 JP 2014-53276 A JP 2009-152440 A Japanese Patent No. 5089814

  However, in such a conventional battery system 100 of Patent Document 1, a coolant conduit 108 through which coolant is circulated must be disposed inside the cooling member 104 so as to surround the heat-dissipating fins 106, which is complicated. This is a configuration, which increases the size and costs.

  In addition, since the coolant conduit 108 is simply disposed, the battery cell 102 is not cooled in a planar shape, but the battery cell 102 is cooled linearly by the coolant conduit 108, and the cooling efficiency is improved. It will be inferior.

  In the battery system 100 of Patent Document 1, although cooling is possible, for example, when the temperature of the battery cell 102 is lowered in a cold district and the activity of the battery is deteriorated, the battery It is impossible to heat the cell 102.

  Further, in the battery system 200 of Patent Document 2, a plurality of battery packs 206 can be heated and cooled using the thermoelectric element 208 and the blower 204.

  However, in the battery system 200 of Patent Document 2, heating and cooling by the air from the blower 204 through the ventilation hole 210 to the last, and heating by the thermoelectric element 208 through the ventilation hole 210 by the blower 204, It is cooling and is inferior in heating and cooling efficiency.

  In addition, a groove is formed on the upper and lower surfaces of the battery cell 212 to form the ventilation hole 210 when stacked, and two blowers are opposed in the front-rear direction in the internal space of the sealed housing 202. It is necessary to dispose 204 and 204, which is a complicated configuration, increases in size, and increases costs.

  In the battery system 300 of Patent Document 3, the battery modules 310a to 310f are cooled by the cooling action of the plurality of fins 318 of the heat sink 320, the heat receiving plate 312, the heat pipes 314a to 314c, and the thermoelectric element member 316. it can.

  Further, when the battery modules 310a to 310f are heated, the battery modules 310a to 310f can be heated by changing the direction of the direct current of the thermoelectric element member 316.

  However, in the battery system 300 of Patent Document 3, the grooves 336a and 336b having semicircular cross-sections for accommodating the heat pipes 314a to 314c are formed on the joint surfaces of the inner heat receiving plates 324 and 326 with the inner heat receiving plates 324 and 326. Each of the heat pipes 314a to 314c must be arranged along the entire length in the longitudinal direction, and the structure is complicated, the size is increased, and the cost is increased.

  Furthermore, in the battery system 300 of Patent Document 3, a housing 302, an inlet pipe 304, a cooling medium passage 322, an outlet pipe 308, and the like must be provided, which has a complicated configuration, increases in size, and increases cost. It will be.

  Further, since the heat pipes 314a to 314c are simply arranged on the joint surfaces of the inner heat receiving plates 324 and 326, the battery modules 310a to 310f are not heated and cooled in a planar shape, but the heat pipes 314a. The battery modules 310a to 310f are linearly cooled by ˜314c, and the heating and cooling efficiency is inferior.

  Further, as shown in FIG. 13A, the wind introduced into the fan 306 does not directly contact the fin 318, the thermoelectric element member 316, and the heat receiving plate 312 but contacts from the lateral direction. Since it is comprised so that it may be inferior to heating and cooling efficiency.

  Further, in the battery system 400 of Patent Document 4, since the plurality of heat pipes 406 are simply arranged in the longitudinal direction between the plurality of battery cells 402 arranged in the vertical and horizontal directions, the battery cells are formed in a planar shape. The structure is such that the battery cell 402 is cooled linearly by the heat pipe 406, rather than heating and cooling 402, and the heating and cooling efficiency is inferior.

  Furthermore, in the battery system 400 of Patent Document 4, since the heater and the fin 410 are arranged at the end of the battery cell 402 on the opposite side in the longitudinal direction, the heating and cooling efficiency is inferior.

  In addition, none of the battery systems 100 to 400 of Patent Documents 1 to 2 has a function of charging the battery cell itself.

  In view of such a current situation, the present invention can heat and cool a battery cell in a planar shape, has excellent heating efficiency and cooling efficiency, stabilizes battery performance, and reduces the number of components. An object of the present invention is to provide a battery pack temperature control / power supply system that can be reduced in size and thickness, and can be reduced in cost, without a complicated configuration.

  Another object of the present invention is to provide an extremely convenient battery pack temperature control / power supply system having a function that can be used for charging a battery cell and other electrical components.

The present invention was invented in order to achieve the above-described problems and objects in the prior art, and the battery pack temperature control / power feeding system of the present invention includes:
A battery unit configured by stacking a plurality of battery cells and a plate-shaped vapor chamber interposed between the battery cells;
A thermoelectric element disposed so as to be in close contact with an end face of one end of the vapor chamber;
It is provided with.

The battery pack temperature control / power supply system of the present invention is
A heat sink portion having a plurality of fins formed so as to extend at a predetermined interval so that the end face thereof is in close contact with the thermoelectric element;
A fan part disposed to face the fins of the heat sink part;
It is provided with.

  With this configuration, since the plate-shaped vapor chamber is laminated between the battery cells, the battery cell is heated and cooled in a planar shape via the thermoelectric element and the vapor chamber. Therefore, it is possible to provide a battery pack temperature control / power supply system that is extremely excellent in heating efficiency and cooling efficiency and has stable battery performance.

  In addition, it is possible to provide a battery pack temperature control / power supply system that has a small number of parts, is not complicated, can be reduced in size and thickness, and can be reduced in cost.

  Furthermore, since the fan part is disposed to face the plurality of fins of the heat sink part, the heating and cooling air from the fan part directly contacts the end surfaces of the fins, the thermoelectric element, and the vapor chamber to heat, It is possible to provide a battery pack temperature control / power supply system that can perform cooling, has excellent heating efficiency and cooling efficiency, and has stable battery performance.

Further, according to the battery pack temperature control / power feeding system of the present invention, the battery cell can be heated and cooled in a planar shape via the thermoelectric element and the vapor chamber, and the temperature of the battery cell in the battery unit is It can control to become the range of 24-30 degreeC.
Therefore, it is possible to provide an optimum battery activity temperature, to improve the battery life, and to provide a battery pack temperature control / power supply system with stable battery performance.

The battery pack temperature control / power supply system of the present invention is
When cooling the battery unit,
A voltage is applied to the thermoelectric element to cool the end face of one end of the vapor chamber,
It is configured to drive the fan unit and cool the end surface of one end of the vapor chamber via the heat sink unit and the thermoelectric element.
The battery cell is configured to be cooled through the heat sink, the thermoelectric element, and the vapor chamber.

  With this configuration, when cooling the battery unit, it is only necessary to load the thermoelectric element with a voltage and drive the fan unit.

  As a result, the end face of one end of the vapor chamber is cooled by the thermoelectric element, and the end face of one end of the vapor chamber is cooled by the cooling air from the fan part via the heat sink part and the thermoelectric element.

  As a result, it is possible to provide a battery pack temperature control / power supply system in which the battery cell is efficiently cooled via the heat sink, the thermoelectric element, and the vapor chamber, the cooling efficiency is extremely excellent, and the battery performance is stabilized.

The battery pack temperature control / power supply system of the present invention is
When cooling the battery unit,
A voltage is applied to the thermoelectric element to cool the end face of one end of the vapor chamber,
The fan unit is driven to cool the heat sink unit and the thermoelectric element.

With this configuration, in order to cool the battery part, the other end surface of the heated thermoelectric element, that is, the surface on the heat sink part side of the thermoelectric element can be cooled with the cooling air of the fan part.
Therefore, heating of the thermoelectric element can be prevented, the thermoelectric element can be prevented from being damaged, the function of the thermoelectric element as the thermoelectric element can be maintained, and the battery performance has been stabilized. A battery pack temperature control / power supply system can be provided.

The battery pack temperature control / power supply system of the present invention is
When cooling the battery unit,
A voltage is applied to the thermoelectric element to cool the end face of one end of the vapor chamber,
Configured to stop driving of the fan unit,
The battery cell is configured to be cooled through the thermoelectric element and the vapor chamber.

  By configuring in this way, when cooling the battery part, voltage is applied to the thermoelectric element and the driving of the fan part is stopped so that the temperature of the battery cell does not increase and the performance of the battery does not deteriorate. Just do it.

  Thereby, the end surface of one end of the vapor chamber is cooled by the thermoelectric element, and the battery cell is cooled via the thermoelectric element and the vapor chamber.

  As a result, it is possible to provide a battery pack temperature control / power feeding system in which the battery cell is efficiently cooled through the thermoelectric element and the vapor chamber, the cooling efficiency is extremely excellent, and the battery performance is stabilized.

The battery pack temperature control / power supply system of the present invention is
When heating the battery part,
A voltage is applied to the thermoelectric element to heat an end face of one end of the vapor chamber, and
Configured to stop driving of the fan unit,
The battery cell is configured to be heated through the thermoelectric element and the vapor chamber.

  By configuring in this way, for example, in a cold region, when the battery cell temperature decreases and the battery activity deteriorates, a voltage is applied to the thermoelectric element when the battery unit is heated. It is only necessary to stop the driving of the fan unit (loading a direct current opposite to that during cooling).

  Thereby, the end surface of one end of the vapor chamber is heated by the thermoelectric element, and the battery cell is heated via the thermoelectric element and the vapor chamber.

  As a result, it is possible to provide a battery pack temperature control / power feeding system in which the battery cell is efficiently heated through the thermoelectric element and the vapor chamber, the heating efficiency is extremely excellent, and the battery performance is stabilized.

The battery pack temperature control / power supply system of the present invention is
When heating the battery part,
A voltage is applied to the thermoelectric element to heat an end face of one end of the vapor chamber, and
It is configured to drive the fan unit and heat the end surface of one end of the vapor chamber via the heat sink unit and the thermoelectric element.
The battery cell is configured to be heated through the heat sink, the thermoelectric element, and the vapor chamber.

  By configuring in this way, for example, in a cold region, when the battery cell temperature decreases and the battery activity deteriorates, a voltage is applied to the thermoelectric element when the battery unit is heated. (It is only necessary to drive the fan unit while loading the DC current in the direction opposite to that during cooling).

  As a result, the end surface of one end of the vapor chamber is heated by the thermoelectric element, and, for example, by using warm air from an engine or the like, the heating air from the fan part causes the battery to pass through the heat sink part, the thermoelectric element, and the vapor chamber. The cell is heated.

  As a result, it is possible to provide a battery pack temperature control / power feeding system in which the battery cell is efficiently heated through the heat sink, the thermoelectric element, and the vapor chamber, the heating efficiency is extremely excellent, and the battery performance is stabilized.

The battery pack temperature control / power supply system of the present invention is
When heating the battery part,
A voltage is applied to the thermoelectric element to heat an end face of one end of the vapor chamber, and
The fan unit is driven to heat the heat sink unit and the thermoelectric element.

  By configuring in this way, for example, in a cold region, when the battery cell temperature decreases and the battery activity deteriorates, a voltage is applied to the thermoelectric element when the battery unit is heated. In addition, it is only necessary to drive the fan unit.

  Thereby, the end surface of one end of the vapor chamber is heated by the thermoelectric element, and the battery cell is heated via the thermoelectric element and the vapor chamber.

  As a result, it is possible to provide a battery pack temperature control / power feeding system in which the battery cell is efficiently heated through the thermoelectric element and the vapor chamber, the heating efficiency is extremely excellent, and the battery performance is stabilized.

The battery pack temperature control / power supply system of the present invention is
Based on the temperature difference between the temperature on the heat sink part side of the thermoelectric element and the temperature on the side in close contact with the end face of one end of the vapor chamber of the thermoelectric element,
An electromotive force is generated in the thermoelectric element, and the electric power is used for charging a battery cell and other electric parts.

  With this configuration, an electromotive force is generated in the thermoelectric element based on the temperature difference between the temperature on the heat sink portion side of the thermoelectric element and the temperature on the side close to the end face of one end of the vapor chamber of the thermoelectric element. .

  This electric power can be used for charging the battery cell, for example, charging other electrical components such as LED headlights, and the charging efficiency of the battery cell, which is extremely convenient, is improved.

The battery pack temperature control / power supply system of the present invention is
The vapor chamber is
A side vapor chamber in close contact with the thermoelectric element side;
A plurality of vapor chamber bodies formed at a predetermined interval from the side vapor chamber and extending in the length direction of the battery cells;
It is comprised from these.

  By comprising in this way, since the side vapor chamber closely_contact | adhered to the thermoelectric element side is formed, it is excellent in the heat transfer effect between thermoelectric elements, and is excellent in heating and cooling efficiency.

  In addition, since a plurality of vapor chamber main body portions are formed at a predetermined interval from the side vapor chamber and extend in the length direction of the battery cell, the battery cells are provided in the gaps between the plurality of vapor chamber main body portions. Can be stacked, the assembly is easy, the manufacturing process is not complicated, and the cost can be reduced.

The battery pack temperature control / power supply system of the present invention is
The vapor chamber is composed of a plurality of vapor chambers having a plate shape with an L-shaped cross section.

  With this configuration, by laminating a plurality of vapor chambers having a plate shape with an L-shaped cross section, battery cells can be laminated in the gaps between the plurality of vapor chambers, and assembly is easy. The cost can be reduced without complicating the manufacturing process.

  In addition, the end surface of the vapor chamber having an L-shaped cross section can be integrated with the end face to which the thermoelectric element is in close contact, and the heat transfer effect with the thermoelectric element is excellent, and the heating and cooling efficiency is excellent.

The battery pack temperature control / power supply system of the present invention is
The vapor chamber main body is composed of a plurality of vapor chambers having a plate shape with an L-shaped cross section.

Thus, in the battery pack temperature control / power feeding system of the present invention, the vapor chamber body may be composed of a plurality of vapor chambers having a plate shape with an L-shaped cross section.
Thereby, since the cross section of the vapor chamber main body part is an L-shaped one end portion and contacts the side vapor chamber, the heat transfer effect between the thermoelectric elements is further improved, and the heating and cooling efficiency is excellent.

The battery pack temperature control / power supply system of the present invention is
The side vapor chamber is in close contact with the thermoelectric element side, and a side vapor chamber adhesion main body part;
It is formed by extending from the side vapor chamber adhesion main body portion, and is composed of a temperature difference vapor chamber extending portion extending in the length direction of the battery cell,
Thereby, based on the temperature difference between the temperature on the heat sink part side of the thermoelectric element and the temperature on the side that is in close contact with the end face of one end of the side vapor chamber of the thermoelectric element,
An electromotive force is generated in the thermoelectric element, and this electric power is used for charging a battery cell and other electric components.

  By configuring in this way, the temperature difference vapor chamber extending portion is formed extending from the side vapor chamber adhesion main body portion and extending in the length direction of the battery cell, for example, the temperature of heating or cooling by an air conditioner The temperature of the outside air such as the vehicle body is easily transmitted to the side vapor chamber.

  As a result, a higher electromotive force is generated based on the temperature difference between the temperature difference vapor chamber extending portion and the temperature of the thermoelectric element on the side close to the end surface of the side vapor chamber contact main body portion. Will occur.

  Thereby, this high electric power can be used for charging a battery cell, for example, charging other electrical components such as an LED headlight, and the charging efficiency of the battery cell, which is extremely convenient, is further improved.

  In the battery pack temperature control / power supply system according to the present invention, the heat sink portion includes a vapor chamber.

  As described above, the heat sink portion includes the vapor chamber, so that the heat transfer efficiency to the thermoelectric element, the vapor chamber, and the battery cell is improved by the vapor chamber of the heat sink portion, thereby efficiently heating and cooling. Therefore, it is possible to provide a battery pack temperature control / power supply system that can be performed, has excellent heating efficiency and cooling efficiency, and has stable battery performance.

  In addition, the battery pack temperature control / power supply system of the present invention includes a control device that controls the temperature of the battery cell of the battery unit to be in a range of 24 to 30 ° C.

  For this reason, an optimum battery activity temperature (range of 24 to 30 ° C.) can be obtained, and a battery pack temperature control / power feeding system with stable battery performance can be provided.

  According to the present invention, since the plate-shaped vapor chamber is laminated between the battery cells, the battery cell can be heated and cooled in a planar shape via the thermoelectric element and the vapor chamber. Therefore, it is possible to provide a battery pack temperature control / power supply system that is extremely excellent in heating efficiency and cooling efficiency and has stable battery performance.

  In addition, it is possible to provide a battery pack temperature control / power supply system that has a small number of parts, is not complicated, can be reduced in size and thickness, and can be reduced in cost.

  Furthermore, since the fan part is disposed to face the plurality of fins of the heat sink part, the heating and cooling air from the fan part directly contacts the end surfaces of the fins, the thermoelectric element, and the vapor chamber to heat, It is possible to provide a battery pack temperature control / power supply system that can perform cooling, has excellent heating efficiency and cooling efficiency, and has stable battery performance.

Further, according to the battery pack temperature control / power feeding system of the present invention, the battery cell can be heated and cooled in a planar shape via the thermoelectric element and the vapor chamber, and the temperature of the battery cell in the battery unit is It can control to become the range of 24-30 degreeC.
Therefore, it is possible to provide an optimum battery activity temperature, to improve the battery life, and to provide a battery pack temperature control / power supply system with stable battery performance.

FIG. 1 is an exploded perspective view conceptually showing a battery pack temperature control / power feeding system of the present invention. FIG. 2 is a cross-sectional view of the battery pack temperature control / power feeding system of FIG. FIG. 3 is a block diagram of the battery pack temperature control / power supply system for explaining an operating state when the battery unit is cooled in the battery pack temperature control / power supply system of the present invention. FIG. 4 is a block diagram of the battery pack temperature control / power supply system for explaining another operation state when the battery unit is cooled in the battery pack temperature control / power supply system of the present invention. FIG. 5 is a block diagram of the battery pack temperature control / power supply system for explaining an operating state when the battery unit is heated in the battery pack temperature control / power supply system of the present invention. FIG. 6 is a block diagram of the battery pack temperature control / power supply system for explaining another operating state when the battery unit is heated in the battery pack temperature control / power supply system of the present invention. FIG. 7 is a cross-sectional view similar to FIG. 2 of a battery pack temperature control / power feeding system 10 according to another embodiment of the present invention. FIG. 8 is a cross-sectional view similar to FIG. 2 of a battery pack temperature control / power feeding system 10 according to another embodiment of the present invention. FIG. 9 is a cross-sectional view similar to FIG. 2 of a battery pack temperature control / power feeding system 10 according to another embodiment of the present invention. 10A is an exploded cross-sectional view showing another embodiment of the heat sink portion 26 of the battery pack temperature control / power feeding system 10 of another embodiment of the present invention, and FIG. 10B is FIG. 10A. It is sectional drawing explaining the assembled state of the heat sink part 26 shown in FIG. FIG. 11A is a perspective view of the battery system 100 of Patent Document 1, and FIG. 11B is a perspective view showing the structure of the cooling member 104 of the battery system 100 of Patent Document 1. 12A is a top view of the battery system of Patent Document 2, and FIG. 12B is a cross-sectional view of the battery system of Patent Document 2. 13A is a top view of the battery system of Patent Document 3, and FIG. 13B is a partially enlarged perspective view of the battery system of Patent Document 3. 14A is an exploded perspective view of FIG. 13B, and FIG. 14B is a cross-sectional view of FIG. 13B. FIG. 15 is a perspective view of the battery system of Patent Document 4. FIG.

Hereinafter, embodiments (examples) of the present invention will be described in more detail with reference to the drawings.
Example 1

  1 is an exploded perspective view conceptually showing a battery pack temperature control / power supply system of the present invention, FIG. 2 is a sectional view of the battery pack temperature control / power supply system of FIG. 1, and FIG. 3 is a battery pack of the present invention. FIG. 5 is a block diagram of a battery pack temperature control / power supply system for explaining an operating state when the battery unit is cooled in the temperature control / power supply system. FIG. 5 is a diagram illustrating heating of the battery unit in the battery pack temperature control / power supply system of the present invention. FIG. 6 is a block diagram of a battery pack temperature control / power feeding system for explaining an operating state when the battery is heated, and FIG. 6 is a battery for explaining another operating state when the battery unit is heated in the battery pack temperature control / power feeding system of the present invention. It is a block diagram of a pack temperature control and electric power feeding system.

  1 to 5, reference numeral 10 indicates the battery pack temperature control / power feeding system of the present invention as a whole.

  1 conceptually shows the battery pack temperature control / power supply system 10 of the present invention, for convenience, there is a gap between the battery cell 12 and the vapor chamber body 20 of the vapor chamber 16. In practice, however, the battery cell 12 and the vapor chamber body 20 of the vapor chamber 16 are in close contact with each other.

  In the battery pack temperature control / power feeding system 10 of the present invention, as shown in an embodiment of FIG. 9 to be described later, the battery part 22, the thermoelectric element 24, the heat sink part 26, and the fan part 32 are provided in an outer case. 44, and may be configured so that warm air or cold air from an air conditioner or the like can be taken in from the fan unit 32.

  In such a case, a part of the outer case 44 can be configured to be detachable so that the internal battery part 22, thermoelectric element 24, heat sink part 26, and fan part 32 can be replaced.

  As shown in FIGS. 1 to 5, the battery pack temperature control / power supply system 10 of the present invention includes a plurality of rectangular battery cells 12 in a plan view. The battery cell 12 has a stacked structure.

  Further, a vapor chamber 16 is provided, and the vapor chamber 16 is provided with a rectangular side vapor chamber 18. The side vapor chamber 18 is formed at a certain distance in the vertical direction, extends in the length direction of the battery cell 12, and has a plate shape that is substantially the same shape as the battery cell 12 (a rectangular plate shape in plan view). A), a plurality of vapor chamber bodies 20 are provided.

  As shown in FIGS. 1 and 2, the battery cells 12 are interposed in the gaps S formed between the plurality of vapor chamber main bodies 20 of the vapor chamber 16, respectively. 12 are in close contact with each other.

  The vapor chamber 16 and the battery cell 12 constitute a battery unit 22.

  The vapor chamber 16 may be a conventionally known vapor chamber, and is not particularly limited. For example, the vapor chamber 16 is manufactured from a metal such as aluminum, and the inside thereof (that is, the side vapor chamber 18 and the vapor). A heat medium circulation space is formed in the chamber body 20), and the heat medium enclosed in the heat medium circulation space has a structure in which a refrigerant such as acetone or alcohol is enclosed as a refrigerant. is there.

  As shown in FIGS. 1 and 2, the end face of one end of the vapor chamber 16 of the battery unit 22, that is, the side vapor chamber 18 has a rectangular thermoelectric element 24 made of, for example, a Peltier element. , Arranged in close contact.

  Further, a heat sink portion 26 is arranged so that the end face thereof is in close contact with the thermoelectric element 24.

  That is, as shown in FIG. 1, the heat sink portion 26 is formed to have a rectangular base end portion 28 that is in close contact with the thermoelectric element 24, and to extend from the base end portion 28 at a predetermined interval. A plurality of fins 30 are provided.

  Further, the fan part 32 including the blades 32 a is arranged so as to face the plurality of fins 30 of the heat sink part 26.

  With this configuration, since the plate-shaped vapor chamber 16 (vapor chamber body 20) is laminated between the battery cells 12, the battery cell is interposed via the thermoelectric element 24 and the vapor chamber 16. As shown by the arrows in FIG. 1, the battery pack temperature control / power supply system 10 can be heated and cooled in a planar shape, has excellent heating efficiency and cooling efficiency, and has stable battery performance. can do.

  Further, it is possible to provide the battery pack temperature control / power supply system 10 that has a small number of parts, is not complicated, can be reduced in size and thickness, and can be reduced in cost.

  Further, as shown in FIGS. 1 and 2, since the fan part 32 is disposed to face the plurality of fins 30 of the heat sink part 26, the heating and cooling air from the fan part 32 is directly applied to the fins. 30, the thermoelectric element 24, and the end face (side vapor chamber 18) of the vapor chamber 16 can be heated and cooled, and the battery pack temperature is excellent in heating efficiency and cooling efficiency, and the battery performance is stabilized. The control / power supply system 10 can be provided.

  The battery pack temperature control / power feeding system 10 of the present invention configured as described above operates as follows.

  That is, as shown in FIG. 3, the battery pack temperature control / power feeding system 10 of the present invention has a battery unit 22 (battery cell 12) so that the temperature of the battery cell 12 does not increase and the performance of the battery does not deteriorate. When it is cooled, it operates as follows.

  First, under the control of the control device 34, a voltage (DC current) is applied from the power source 36 to the thermoelectric element 24, and the end surface (side vapor chamber 18) at one end of the vapor chamber 16 is cooled.

  Then, under the control of the control device 34, the blade 32 a of the fan unit 32 is driven, and the end surface (side) of one end of the vapor chamber 16 is passed through the plurality of fins 30, the base end portion 28, and the thermoelectric element 24 of the heat sink unit 26. The vapor chamber 18) is cooled.

  As a result, the battery cell passes through the plurality of fins 30 of the heat sink portion 26, the base end portion 28, and the thermoelectric element 24, and through the end face (side vapor chamber 18) of the vapor chamber 16 and the vapor chamber body 20. 12 is configured to be cooled.

  With this configuration, when cooling the battery unit 22 (battery cell 12), it is only necessary to load the thermoelectric element 24 and drive the fan unit 32.

  As a result, the end surface (side vapor chamber 18) at one end of the vapor chamber 16 is cooled by the thermoelectric element 24, and the plurality of fins 30 and the base end portion 28 of the heat sink portion 26 are cooled by the cooling air from the fan portion 32. The end surface of the vapor chamber 16 (the side vapor chamber 18) is cooled via the thermoelectric element 24.

  As a result, the battery cell passes through the plurality of fins 30 of the heat sink portion 26, the base end portion 28, and the thermoelectric element 24, and through the end surface of the vapor chamber 16 (side vapor chamber 18) and the vapor chamber body 20. Thus, the battery pack temperature control / power feeding system 10 in which the battery 12 is efficiently cooled, the cooling efficiency is extremely excellent, and the battery performance is stabilized can be provided.

  As shown in FIG. 4, the battery pack temperature control / power feeding system 10 of the present invention has a battery unit 22 (battery cell 12) so that the temperature of the battery cell 12 does not increase and the performance of the battery does not deteriorate. When it is cooled, it operates as follows.

  First, under the control of the control device 34, a voltage is applied from the power source 36 to the thermoelectric element 24, and the end surface (side vapor chamber 18) at one end of the vapor chamber 16 is cooled.

  And the drive of the fan part 32 is stopped by control of the control apparatus 34. FIG.

  Thus, the battery cell 12 is cooled via the thermoelectric element 24 and the end surface of the vapor chamber 16 (side vapor chamber 18) and the vapor chamber body 20.

  With this configuration, when the battery unit 22 (battery cell 12) is cooled so that the temperature of the battery cell 12 does not increase and the performance of the battery does not deteriorate, a voltage is applied to the thermoelectric element 24 ( It is only necessary to stop the driving of the fan unit 32 while loading a direct current in the opposite direction to that during cooling.

  As a result, the end face (side vapor chamber 18) at one end of the vapor chamber 16 is cooled by the thermoelectric element 24, and the end face (side vapor chamber 18) at one end of the vapor chamber 16 is passed through the thermoelectric element 24. The battery cell 12 is cooled via the main body 20.

  As a result, the battery cell 12 is efficiently cooled via the thermoelectric element 24 and the end surface of the vapor chamber 16 (side vapor chamber 18) and the vapor chamber body 20 and the battery cell 12 is extremely excellent in cooling efficiency. The battery pack temperature control / power feeding system 10 with stable performance can be provided.

  As shown in the embodiment of FIG. 9 to be described later, the battery part 22, the thermoelectric element 24, the heat sink part 26, and the fan part 32 are accommodated in the outer case 44, and the battery part 22 and the thermoelectric element are accommodated. The space between the 24 heat sink portion 26 and the fan portion 32 may be a sealing structure by a sealing member so that moisture does not enter the battery portion 22.

Therefore, in the case of such a sealing structure, it is possible to prevent the cooling air from the fan part 32 from directly entering the battery part 22 in the cooling operation of FIG.
That is, the cooling air from the fan unit 32 is configured to cool the heat sink unit 26 and the thermoelectric element 24, thereby cooling the battery cell 12 through the vapor chamber 16.

  However, as described above, the cooling air from the fan unit 32 can be allowed to enter the battery unit 22 to cool the battery cell 12.

  On the other hand, as shown in FIG. 5, the battery pack temperature control / power feeding system 10 of the present invention is used when, for example, in a cold district, the temperature of the battery cell 12 decreases and the battery activity deteriorates. When the battery unit 22 (battery cell 12) is heated, the operation is as follows.

  First, under the control of the control device 34, a voltage (a direct current in the direction opposite to that when cooling) is applied from the power source 36 to the thermoelectric element 24, and the end surface (side vapor chamber 18) at one end of the vapor chamber 16 is loaded. Heat.

  And the drive of the fan part 32 is stopped by control of the control apparatus 34. FIG.

  Accordingly, the battery cell 12 is heated via the thermoelectric element 24 and the end face (side vapor chamber 18) of the vapor chamber 16 and the vapor chamber body 20.

  By configuring in this way, for example, when the battery unit 22 (battery cell 12) is heated when the temperature of the battery cell is lowered in a cold region and the activity of the battery is deteriorated, It is only necessary to load the thermoelectric element 24 with a voltage (load a direct current opposite to that during cooling) and to stop driving the fan unit 32.

  As a result, the end surface (side vapor chamber 18) of one end of the vapor chamber 16 is heated by the thermoelectric element 24, and the end surface (side vapor chamber 18) of one end of the vapor chamber 16 is heated via the thermoelectric element 24. The battery cell 12 is heated via the main body 20.

  As a result, the battery cell 12 is efficiently heated through the thermoelectric element 24 through the end face (side vapor chamber 18) of the vapor chamber 16 and the vapor chamber body 20, and the battery cell 12 is extremely excellent in heating efficiency. The battery pack temperature control / power feeding system 10 with stable performance can be provided.

During the heating and cooling, the temperature of the battery cell 12 is detected by the temperature sensor 38, and the temperature of the battery cell 12 is controlled to be a predetermined temperature, for example, about 24 to 32 ° C. It has become so.
Therefore, it is possible to provide the battery pack temperature control / power feeding system 10 that can obtain the optimum battery activity temperature, improve the battery life, and stabilize the battery performance.

  Further, in the battery pack temperature control / power feeding system 10 of the present invention, as shown in FIG. 6, for example, in a cold district, when the temperature of the battery cell 12 decreases and the activity of the battery deteriorates. When the battery unit 22 (battery cell 12) is heated, it can be operated as follows.

  First, under the control of the control device 34, a voltage (a direct current in the direction opposite to that when cooling) is applied from the power source 36 to the thermoelectric element 24, and the end surface (side vapor chamber 18) at one end of the vapor chamber 16 is loaded. Heat.

  Then, under the control of the control device 34, the blades 32a of the fan unit 32 are driven, and for example, the warm air from the engine or the like is used to generate the plurality of fins 30 and the base end of the heat sink unit 26 by the heated air from the fan unit 32. The end surface (side vapor chamber 18) of one end of the vapor chamber 16 is heated via the part 28 and the thermoelectric element 24.

  As a result, the battery cell passes through the plurality of fins 30 of the heat sink portion 26, the base end portion 28, and the thermoelectric element 24, and through the end face (side vapor chamber 18) of the vapor chamber 16 and the vapor chamber body 20. 12 is configured to heat.

  With this configuration, for example, when the battery unit 22 (battery cell 12) is heated when the temperature of the battery cell 12 decreases and the battery activity deteriorates in a cold region or the like, for example. It is only necessary to load the thermoelectric element 24 with a voltage (load a direct current opposite to that during cooling) and to drive the fan unit 32.

  As a result, the end surface (side vapor chamber 18) at one end of the vapor chamber 16 is heated by the thermoelectric element 24, and the heat sink portion 26 is heated by the heated air from the fan portion 32 using, for example, warm air from an engine or the like. The battery cell 12 is heated through the plurality of fins 30, the base end portion 28, and the thermoelectric element 24, and through the end surface (side vapor chamber 18) at one end of the vapor chamber 16 and the vapor chamber body 20.

  As a result, the battery cell passes through the plurality of fins 30 of the heat sink portion 26, the base end portion 28, and the thermoelectric element 24, and through the end surface of the vapor chamber 16 (side vapor chamber 18) and the vapor chamber body 20. Thus, the battery pack temperature control / power feeding system 10 can be provided in which the battery 12 is efficiently heated, the heating efficiency is extremely excellent, and the battery performance is stabilized.

  As shown in the embodiment of FIG. 9 to be described later, the battery part 22, the thermoelectric element 24, the heat sink part 26, and the fan part 32 are accommodated in the outer case 44, and the battery part 22 and the thermoelectric element are accommodated. The space between the 24 heat sink portion 26 and the fan portion 32 may be a sealing structure by a sealing member so that moisture does not enter the battery portion 22.

Therefore, in the case of such a seal structure, in the case of the heating operation of FIG. 6, it is possible to prevent the heated air from the fan part 32 from directly entering the battery part 22.
That is, the heating air from the fan unit 32 heats the heat sink unit 26 and the thermoelectric element 24, and thereby heats the battery cell 12 through the vapor chamber 16.

  However, as described above, it is also possible to heat the battery cell 12 by allowing the heated air from the fan unit 32 to enter the battery unit 22.

  Furthermore, as shown in FIGS. 3 to 6, the battery pack temperature control / power feeding system 10 of the present invention has a temperature on the heat sink portion 26 side of the thermoelectric element 24 and an end face of one end of the vapor chamber 16 of the thermoelectric element 24 ( An electromotive force is generated in the thermoelectric element 24 based on the temperature difference between the side vapor chamber 18) and the side in close contact with the side vapor chamber 18), and this electric power is charged to the battery cell 12, for example, an LED headlight It may be configured to be used for charging other electrical components.

That is, by electrically connecting the power supply line 40 from the thermoelectric element 24 to the battery cell 12, the temperature on the heat sink portion 26 side of the thermoelectric element 24 and the end surface (sideward) of one end of the vapor chamber 16 of the thermoelectric element 24. The electromotive force generated in the thermoelectric element 24 based on the temperature difference between the vapor chamber 18) and the temperature in close contact with the vapor chamber 18) is used to charge the battery cell 12 to the battery cell 12 or other LED headlights, for example It can be used for charging electric parts and the like, which is very convenient, and the charging efficiency of the battery cell 12 is improved.
(Example 2)

  FIG. 7 is a cross-sectional view similar to FIG. 2 of a battery pack temperature control / power feeding system 10 according to another embodiment of the present invention.

  The battery pack temperature control / power supply system 10 of this embodiment has basically the same configuration as the battery pack temperature control / power supply system 10 shown in FIG. 1 to FIG. Reference numerals are assigned and detailed description thereof is omitted.

  In the battery pack temperature control / power supply system 10 of this embodiment, as shown in FIG. 7, the vapor chamber 16 is composed of a plurality of vapor chambers 14 having a plate shape with an L-shaped cross section.

That is, the vapor chamber 14 is provided with a side vapor chamber 14a constituting an end surface of one end, and a plate-like vapor chamber main body portion 14b extending in the length direction of the battery cell 12 and having substantially the same shape as the battery cell 12. Yes.
In addition, as shown in FIG. 7, the vapor chamber 14 at the upper end is a plate-shaped vapor chamber 14d.

  By configuring in this way, by stacking a plurality of vapor chambers 14 having an L-shaped cross section, the battery cells 12 can be stacked in the gaps S of the plurality of vapor chambers 14, Assembling is easy, and the manufacturing process is not complicated, and the cost can be reduced.

In addition, the end surface 14c to which the thermoelectric element 24 is in close contact can be formed integrally with one end portion (side vapor chamber 14a) having an L-shaped cross section of the vapor chamber 14, and the heat transfer effect with the thermoelectric element 24 is excellent. Excellent heating and cooling efficiency.
(Example 3)

  FIG. 8 is a cross-sectional view similar to FIG. 2 of a battery pack temperature control / power feeding system 10 according to another embodiment of the present invention.

  The battery pack temperature control / power supply system 10 of this embodiment has basically the same configuration as the battery pack temperature control / power supply system 10 shown in FIG. 1 to FIG. Reference numerals are assigned and detailed description thereof is omitted.

In the battery pack temperature control / power supply system 10 of this embodiment, as shown in FIG. 8, the vapor chamber 16 includes a plate-shaped side vapor chamber 18.
The vapor chamber body 20 is composed of a plurality of vapor chambers 42 that are separate from the side vapor chamber 18 and have a plate shape with an L-shaped cross section.

That is, the vapor chamber 42 is provided with a side vapor chamber 42 a constituting one end face, and a plate-shaped vapor chamber main body 42 b extending in the length direction of the battery cell 12 and having substantially the same shape as the battery cell 12. Yes.
As shown in FIG. 8, the vapor chamber 42 at the upper end is a plate-shaped vapor chamber 42d.

  By configuring in this way, the battery cells 12 can be stacked in the gaps S between the plurality of vapor chambers 42 by stacking the plurality of vapor chambers 42 having an L-shaped cross section. Assembling is easy, and the manufacturing process is not complicated, and the cost can be reduced.

In addition, an end surface 42c that is in close contact with the side vapor chamber 18 to which the thermoelectric element 24 is in close contact can be integrally formed with one end portion (side vapor chamber 42a) having an L-shaped cross section of the vapor chamber 42. It is further excellent in heat transfer effect during heating, and excellent in heating and cooling efficiency.
Example 4

  FIG. 9 is a cross-sectional view similar to FIG. 2 of a battery pack temperature control / power feeding system 10 according to another embodiment of the present invention.

  The battery pack temperature control / power supply system 10 of this embodiment is basically similar in configuration to the battery pack temperature control / power supply system 10 shown in FIG. 8, and the same reference numerals are given to the same components. A detailed description thereof will be omitted.

  In the battery pack temperature control / power supply system 10 of this embodiment, as shown in FIG. 9, the side vapor chamber 18 has a side vapor chamber contact main body 18a that is in close contact with the thermoelectric element 24 side, and the side vapor chamber. A temperature difference vapor chamber extending portion 18b is formed extending from the chamber contact main body portion 18a and extending in the length direction of the battery cell.

  Accordingly, the thermoelectric element 24 is based on the temperature difference between the temperature of the thermoelectric element 24 on the heat sink portion 26 side and the temperature of the thermoelectric element 24 on the side in close contact with the end surface of the side vapor chamber adhesion main body portion 18a. An electromotive force is generated, and this power is used for charging the battery cell 12 and other electrical components.

  By configuring in this way, the temperature difference vapor chamber extending portion 18b is formed extending from the side vapor chamber adhesion main body portion 18a and extending in the length direction of the battery cell 12, for example, heating by an air conditioner or The cooling temperature and the temperature of the outside air such as the vehicle body are easily transmitted to the side vapor chamber 18.

  As a result, based on the temperature difference between the temperature of the temperature difference vapor chamber extending portion 18b and the temperature of the thermoelectric element 24 on the side close to the end face of the side vapor chamber contact main body 18a. A high electromotive force is generated.

  As a result, this high power can be used for charging the battery cell 12 and for charging other electrical components such as LED headlights, and the charging efficiency of the battery cell 12 is further improved, which is extremely convenient. To do.

  In the case of this embodiment, the battery unit 22, the thermoelectric element 24, the heat sink unit 26, and the fan unit 32 are accommodated in the outer case 44, and the fan unit 32 draws outside air, warm air such as an air conditioner, and cool air. It has a configuration that can be incorporated.

The temperature difference vapor chamber extending portion 18b is configured to be exposed to the outside from the opening 44a of the outer case 44 as shown in FIG.
As a result, the temperature difference between the temperature of the temperature difference vapor chamber extending portion 18b and the temperature of the thermoelectric element 24 on the side close to the end face of the side vapor chamber adhesion main body portion 18a is increased and is high. An electromotive force is obtained.

  As a result, this high electric power can be used for charging the battery cell 12 and charging other electrical components such as LED headlights, which is extremely convenient and further improves the charging efficiency of the battery cell 12. To do.

  Although not shown, the temperature difference vapor chamber extending portion 18b is not exposed to the outside of the outer case 44 as shown in FIG. 9, but is accommodated in the outer case 44. Also good.

For example, the temperature of the temperature difference vapor chamber extending portion 18b, which is directly transmitted from the outer case 44, made of a metal material having good thermal conductivity, and the side vapor chamber adhesion body of the thermoelectric element 24 It is also possible to generate an electromotive force due to a temperature difference from the temperature on the side closely contacting the end face of one end of the portion 18a.
(Example 5)

  10A is an exploded cross-sectional view showing another embodiment of the heat sink portion 26 of the battery pack temperature control / power feeding system 10 of another embodiment of the present invention, and FIG. 10B is FIG. 10A. It is sectional drawing explaining the assembled state of the heat sink part 26 shown in FIG.

  In the battery pack temperature control / power supply system 10 of this embodiment, the heat sink portion 26 is composed of a plurality of rectangular heat sink bodies 46.

  The heat sink body 46 of this embodiment is composed of a heat sink body 46 a provided with a fitting protrusion 48 and a heat sink body 46 b provided with a fitting recess 50.

  And the one heat sink body 46 is comprised by fitting the protrusion part 48 for fitting of these heat sink bodies 46a to the recessed part 50 for fitting of the heat sink body 46b.

In this embodiment, the two heat sink bodies 46a and the heat sink bodies 46b are used. However, the number is not limited, and the heat sink bodies 46a and 46b may be appropriately combined according to the size of the battery unit 22 and the like.
Of course, a single heat sink body 46 is also possible.

  Each of the heat sink body 46a and the heat sink body 46b includes a plurality of vapor chambers 52 that are spaced apart from each other and extend in the width direction of the heat sink body 46.

  As described above, since the heat sink portion 26 includes the vapor chamber 52, the heat transfer efficiency to the thermoelectric element 24, the vapor chamber 16, and the battery cell 12 is improved by the vapor chamber 52 of the heat sink portion 26. It is possible to provide a battery pack temperature control / power supply system that can efficiently perform heating and cooling, is extremely excellent in heating efficiency and cooling efficiency, and has stable battery performance.

In this embodiment, the two heat sink bodies 46a and the heat sink bodies 46b are used. However, the number is not limited, and the heat sink bodies 46a and 46b may be appropriately combined according to the size of the battery unit 22 and the like.
Of course, a single heat sink body 46 is also possible.

  In the case of this embodiment, the heat sink part 26 is provided with the vapor chamber 52. However, although not shown, the heat sink part 26 itself can be constituted by a vapor chamber.

  The preferred embodiment of the present invention has been described above, but the present invention is not limited to this. In the battery pack temperature control / power feeding system 10 of the above-described embodiment, the battery cell 12 is viewed in plan view. A rectangular plate-shaped battery cell 12 is formed, and the vapor chamber main body 20 of the vapor chamber 16 is also formed into a rectangular plate-shaped vapor chamber main body 20 in plan view so as to correspond to the shape of the battery cell 12. .

  However, for example, a circular battery cell 12 can be used as the battery cell 12 in plan view, and the vapor chamber main body portion of the vapor chamber 16 corresponding to the shape of the battery cell 12 according to this. The shape of 20 may be selected.

  The battery pack temperature control / power supply system 10 of the present invention includes a battery such as a nickel metal hydride battery or a lithium ion battery such as an electric vehicle (EV), a hybrid vehicle (HV), and a plug-in hybrid vehicle (PHV). In addition, various modifications can be made without departing from the object of the present invention, such as being widely applicable to various other battery-driven devices.

  The present invention relates to a battery pack temperature control / power supply system, and includes, for example, an electric vehicle (EV), a hybrid vehicle (HV), a plug-in hybrid vehicle (PHV), etc., and a battery such as a nickel metal hydride battery or a lithium ion battery. The present invention can be applied to a battery pack temperature control / power supply system used in various battery-powered devices.

  Further, the present invention can be applied to a battery pack temperature control / power supply system capable of heating, cooling, and charging a battery cell, particularly in such a battery pack temperature control / power supply system.

10 Battery Pack Temperature Control / Power Supply System 12 Battery Cell 14 Vapor Chamber 14a Side Vapor Chamber 14b Vapor Chamber Body 14c End Face 16 Vapor Chamber 18 Side Vapor Chamber 18a Side Vapor Chamber Contact Body 18b Extension of Vapor Chamber for Temperature Difference Section 20 Vapor chamber body section 22 Battery section 24 Thermoelectric element 26 Heat sink section 28 Base end section 30 Fin 32 Fan section 32a Blade 34 Controller 36 Power supply 38 Temperature sensor 40 Power supply line 42 Vapor chamber 42a Side vapor chamber 42b Vapor chamber body Part 42c end face 42d vapor chamber 44 outer case 44a opening 46, 46a, 46b heat sink body 48 fitting protrusion 50 for fitting Part 52 Vapor chamber 100 Battery system 102 Battery cell 104 Cooling member 106 Heat release fin 108 Coolant conduit 200 Battery system 202 Sealed housing 204 Blower 206 Battery pack 208 Thermoelectric element 210 Vent hole 212 Battery cell 300 Battery system 302 Case 304 Inlet pipe 306 Fan 308 Exit pipe 310 Battery module 310a-310f Battery module 312 Heat receiving plate 314 Heat pipe 314a-314c Heat pipe 316 Thermoelectric element member 318 Fin 320 Heat sink 320a Base 322 Cooling medium passage 324, 326 Inner heat receiving plate 328, 330 Outer heat receiving plate 332 groove 336a, 336b groove 400 battery system 402 battery Seru 404 Battery 406 heat pipe 410 fin S clearance

Claims (9)

A battery unit configured by stacking a plurality of battery cells and a plate-shaped vapor chamber interposed between the battery cells;
A thermoelectric element disposed so as to be in close contact with an end face of one end of the vapor chamber;
A battery pack temperature control / power supply system characterized by comprising: A heat sink portion having a plurality of fins formed so as to extend at a predetermined interval so that the end face thereof is in close contact with the thermoelectric element;
A fan part disposed to face the fins of the heat sink part;
The battery pack temperature control / power feeding system according to claim 1, further comprising: Based on the temperature difference between the temperature on the heat sink part side of the thermoelectric element and the temperature on the side in close contact with the end face of one end of the vapor chamber of the thermoelectric element,
3. The battery pack temperature control / power supply according to claim 2, wherein an electromotive force is generated in the thermoelectric element, and the electric power is used for charging a battery cell and other electric parts. system. The vapor chamber is
A side vapor chamber in close contact with the thermoelectric element side;
A plurality of vapor chamber bodies formed at a predetermined interval from the side vapor chamber and extending in the length direction of the battery cells;
The battery pack temperature control / power feeding system according to any one of claims 1 to 3, wherein   3. The battery pack temperature control / power feeding system according to claim 1, wherein the vapor chamber includes a plurality of vapor chambers having a plate shape with an L-shaped cross section. 4.   5. The battery pack temperature control / power feeding system according to claim 4, wherein the vapor chamber body includes a plurality of plate-shaped vapor chambers having an L-shaped cross section. The side vapor chamber is in close contact with the thermoelectric element side, and a side vapor chamber adhesion main body part;
It is formed by extending from the side vapor chamber adhesion main body portion, and is composed of a temperature difference vapor chamber extending portion extending in the length direction of the battery cell,
Thereby, based on the temperature difference between the temperature on the heat sink part side of the thermoelectric element and the temperature on the side that is in close contact with the end face of one end of the side vapor chamber of the thermoelectric element,
5. The battery pack temperature control / feed according to claim 4, wherein an electromotive force is generated in the thermoelectric element and the electric power is used for charging a battery cell and other electric parts. 6. system.   The battery pack temperature control / power feeding system according to claim 1, wherein the heat sink portion includes a vapor chamber.   The battery pack temperature control / power feeding system according to any one of claims 1 to 8, further comprising a control device that controls the temperature of the battery cell of the battery unit to be in a range of 24 to 30 ° C.

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