JP6784281B2 - Equipment temperature controller - Google Patents

Description

The present invention relates to a device temperature control device for adjusting the temperature of a target device.

Conventionally, a device temperature control device that adjusts the temperature of a target device by a loop type thermosiphon method has been known.

The equipment temperature control device described in Patent Document 1 includes a heat exchanger for equipment that exchanges heat between a battery as a target equipment and a working fluid, and a condenser arranged on the upper side in the direction of gravity with respect to the heat exchanger for the equipment. It is equipped with a gas phase passage and a liquid phase passage that connect the heat exchanger for equipment and the condenser. In addition, this device temperature control device includes a heating member capable of heating the working fluid inside the heat exchanger for the device.

In the device temperature control device described in Patent Document 1, when the battery is cooled, the working fluid inside the device heat exchanger absorbs heat from the battery and evaporates, and flows into the condenser through the gas phase passage. The liquid phase working fluid condensed by the condenser flows into the equipment heat exchanger through the liquid phase passage. In this way, the equipment temperature control device is configured to cool the battery by the phase change of the working fluid circulating in the thermosiphon circuit.

JP-A-2015-41418

The inventors have found the following problems with respect to the thermosiphon type device temperature control device as described in Patent Document 1. That is, as shown in FIG. 42, when the device temperature control device 100 is mounted on a vehicle or the like, the device temperature control device 100 may be tilted together with the vehicle. In the state shown in FIG. 42, in the device heat exchanger 110 included in the device temperature control device 100, the connection portion 201 connected to the device heat exchanger 110 in the gas phase passage 200 is on the lower side in the gravity direction. It is leaning. Therefore, the liquid level FL of the working fluid of the liquid phase in the heat exchanger 110 for equipment is located above the connection portion 201 of the gas phase passage 200. That is, the connection portion 201 of the gas phase passage 200 is submerged in the working fluid of the liquid phase. In this case, the working fluid evaporated in the equipment heat exchanger 110 when the battery generates heat does not flow into the gas phase passage 200, but accumulates in the upper space 120 in the equipment heat exchanger 110. Therefore, the working fluid does not circulate in the thermosiphon circuit including the heat exchanger 110 for the device, the gas phase passage 200, the condenser 500, and the liquid phase passage 550, and the device temperature control device 100 cannot cool the battery.

The target device for which the device temperature control device 100 adjusts the temperature can be a battery pack mounted on an electric vehicle such as an electric vehicle or a hybrid vehicle. In that case, the battery pack is composed of a large number of battery cells and is arranged under the floor of the electric vehicle, so that the physique in the horizontal direction is large. Therefore, along with the battery pack, the length of the device heat exchanger 110 in the horizontal direction also increases. Therefore, even when the inclination angle of the electric vehicle is small, there is a high possibility that the connecting portion 210 of the gas phase passage 200 is submerged in the working fluid of the liquid phase. That is, when the target device is a battery pack of an electric vehicle, the inclination of the electric vehicle has a great influence on the battery cooling capacity of the device temperature control device 100.

In view of the above points, it is an object of the present invention to provide an equipment temperature control device capable of adjusting the temperature of the target device even when the device is tilted.

In order to achieve the above object, the invention according to claim 1 is an equipment temperature control device that adjusts the temperature of the target equipment (2) by a phase change between the liquid phase and the gas phase of the working fluid.
Equipment temperature adjusting unit having multiple heat exchanger equipment to the target device and the working fluid is thermally exchangeably configured working fluid when the target device cooling is evaporated (11-14) and (10),
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit,
It is provided with a plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) through which the working fluid of the gas phase flows between the device temperature control unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the connection part (221) .
The equipment temperature control unit is a first connection unit and a second connection unit provided in one of a plurality of equipment heat exchangers provided at positions separated from each other in the front-rear direction of the vehicle and a plurality of equipment heat exchangers. It has a connecting passage (61, 62) for connecting the above.
The invention according to claim 7 is an equipment temperature control device that adjusts the temperature of the target equipment (2) by changing the phase between the liquid phase and the gas phase of the working fluid.
A device temperature control unit (10) having a plurality of device heat exchangers (11 to 14) configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled.
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit,
It is provided with a plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) through which the working fluid of the gas phase flows between the device temperature control unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the connection part (221).
Flow path area adjustment provided in the first gas phase passage or the second gas phase passage to regulate the flow of the working fluid of the liquid phase from the first connection side or the second connection side of the gas phase passage to the condenser side. With valves (80, 83, 86),
Further equipped with a tilt sensor (82) that detects the tilt of the device temperature control unit,
When the tilt of the equipment temperature control unit is detected by the tilt sensor, the flow path area control valve moves the working fluid of the liquid phase from the first connection side or the second connection side of the gas phase passage to the condenser side. To regulate.
The invention according to claim 8 is an equipment temperature control device that adjusts the temperature of the target equipment (2) by changing the phase between the liquid phase and the gas phase of the working fluid.
A device temperature control unit (10) having a plurality of device heat exchangers (11 to 14) configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled.
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit,
It is provided with a plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) through which the working fluid of the gas phase flows between the device temperature control unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the connection part (221).
Flow path area adjustment provided in the first gas phase passage or the second gas phase passage to regulate the flow of the working fluid of the liquid phase from the first connection side or the second connection side of the gas phase passage to the condenser side. Further equipped with valves (80, 83, 86),
The flow path area adjusting valve (83)
A valve seat (84) provided on the inner wall of the gas phase passage and
When the first connection part or the second connection part of the gas phase passage is on the upper side in the gravity direction from the valve seat, it is seated on the valve seat by its own weight, and the first connection part or the second connection part of the gas phase passage is gravity from the valve seat. It has a valve body (85) that separates from the valve seat when it is on the lower side in the direction.
The invention according to claim 9 is an equipment temperature control device that adjusts the temperature of the target equipment (2) by changing the phase between the liquid phase and the gas phase of the working fluid.
A device temperature control unit (10) having a plurality of device heat exchangers (11 to 14) configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled.
A condenser (50) that dissipates heat from the working fluid in the gas phase and causes the working fluid in the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit,
It is provided with a plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) through which the working fluid of the gas phase flows between the device temperature control unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the connection part (221).
Flow path area adjustment provided in the first gas phase passage or the second gas phase passage to regulate the flow of the working fluid of the liquid phase from the first connection portion side or the second connection portion side of the gas phase passage to the condenser side. Further equipped with valves (80, 83, 86),
The flow path area adjusting valve (86) is
A valve seat (87) provided on the inner wall of the gas phase passage and
It has a valve body (88) that is seated on the valve seat by buoyancy when the working fluid of the liquid phase flows in the gas phase passage and is separated from the valve seat when the working fluid of the gas phase flows in the gas phase passage.

According to this, when the device temperature adjusting part is tilted, one of the first connection part and the second connection part is located on the upper side in the gravity direction, and the other of the first connection part and the second connection part is on the lower side in the gravity direction. To position. Therefore, the working fluid evaporated in the equipment heat exchanger of the equipment temperature control unit is at least from the first connection part or the second connection part located on the upper side in the direction of gravity to the first gas phase passage or the second gas phase passage. It flows on one side and flows into the condenser. The working fluid condensed by the condenser flows through the liquid phase passage and flows into the heat exchanger for equipment. By such circulation of the working fluid, the equipment temperature control device can cool the target equipment even when the equipment temperature adjusting unit is tilted.

The reference numerals in parentheses attached to each of the above configurations indicate an example of the correspondence with the specific configurations described in the embodiments described later.

It is a schematic block diagram of the equipment temperature control device which concerns on 1st Embodiment. It is a perspective view of the heat exchanger for the device and the battery module provided in the device temperature control device. It is sectional drawing of the heat exchanger and the battery module for a device provided in the device temperature control device. It is explanatory drawing which shows the flow of the working fluid at the time of battery cooling of an apparatus temperature control device. It is explanatory drawing which shows the flow of the working fluid when the equipment temperature control device is tilted. It is explanatory drawing which shows the flow of the working fluid when the equipment temperature control device is tilted. As a modification 1 with respect to the first embodiment, it is a schematic block diagram which shows the state which changed the encapsulation amount of the working fluid. As a second modification with respect to the first embodiment, it is a schematic configuration diagram showing a state in which the encapsulation amount of the working fluid is changed. It is a schematic block diagram of the equipment temperature control device which concerns on 2nd Embodiment. As a modification 3 with respect to the second embodiment, it is the schematic block diagram which shows the state which changed the encapsulation amount of the working fluid. It is a schematic block diagram of the equipment temperature control device which concerns on 3rd Embodiment. It is a schematic block diagram of the equipment temperature control device which concerns on 4th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 5th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 6th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 7th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 8th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 9th Embodiment. It is a perspective view of the equipment temperature control device which concerns on tenth embodiment. It is a perspective view of the equipment temperature control device which concerns on 11th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 12th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 13th Embodiment. It is a perspective view of the equipment temperature control device which concerns on 14th Embodiment. It is a perspective view of the heat exchanger for equipment and the battery module included in the equipment temperature control device which concerns on 15th Embodiment. It is a perspective view of the heat exchanger for equipment and the battery module included in the equipment temperature control device which concerns on 16th Embodiment. It is a schematic block diagram of the equipment temperature control device which concerns on 17th Embodiment. It is an enlarged view of the XXVI part of FIG. It is a schematic block diagram of the equipment temperature control device which concerns on 18th Embodiment. It is an enlarged view of the XXVIII part of FIG. 27. It is an enlarged view of the XXIX part of FIG. 27. It is a schematic block diagram of the equipment temperature control device which concerns on 19th Embodiment. It is a schematic block diagram of the equipment temperature control device which concerns on 19th Embodiment. It is sectional drawing of the flow path area adjustment valve provided in the apparatus temperature control device which concerns on 20th Embodiment. It is sectional drawing of the flow path area adjustment valve provided in the apparatus temperature control device which concerns on 20th Embodiment. It is sectional drawing of the flow path area adjustment valve provided in the equipment temperature control device which concerns on 21st Embodiment. It is sectional drawing of the flow path area adjustment valve provided in the equipment temperature control device which concerns on 21st Embodiment. It is a schematic block diagram of the equipment temperature control device which concerns on 22nd Embodiment. It is an enlarged view of the XXXVII part of FIG. It is an enlarged view of the XXXVIII part of FIG. It is a schematic block diagram of the equipment temperature control device which concerns on 23rd Embodiment. It is an enlarged view of the XL part of FIG. It is an enlarged view of the XLI part of FIG. 39. It is a schematic block diagram of the conventional equipment temperature control device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In each of the following embodiments, the same or equal parts are designated by the same reference numerals, and the description thereof will be omitted. Further, in the description of each embodiment, the terms such as first, second, and third are for convenience of explanation, and do not limit the number, arrangement, shape, and the like of each constituent member.

(First Embodiment)
The first embodiment will be described with reference to FIGS. 1 to 6. The device temperature control device 1 of the first embodiment is mounted on an electric vehicle (hereinafter, simply referred to as "vehicle") such as an electric vehicle, a plug-in hybrid vehicle, or a hybrid vehicle. The device temperature control device 1 (hereinafter, may be referred to as “this device 1”) of the first embodiment cools or warms a secondary battery (hereinafter, “battery”) mounted on a vehicle, and heats the battery. Is to adjust.

First, the battery 2 as the target device for which the device temperature control device 1 adjusts the temperature will be described. The large battery 2 installed in the vehicle is mounted under the seat of the vehicle or under the trunk room as a battery pack (that is, a power storage device) in which a plurality of battery modules in which a plurality of battery cells 3 are combined are stored. The electric power stored in the battery 2 is supplied to the vehicle traveling motor via an inverter or the like. The battery 2 self-heats when power is supplied while the vehicle is running. When the temperature of the battery 2 becomes high, not only does it not exhibit sufficient functions, but it also accelerates deterioration. Therefore, it is necessary to limit the output and input so that self-heating is reduced. Therefore, in order to secure the output and input of the battery 2, a cooling device for maintaining the battery 2 at a predetermined temperature or lower is required.

Further, in a season when the outside temperature is high such as summer, the temperature of the battery 2 rises not only while the vehicle is running but also when the vehicle is left parked. Further, the battery 2 is often arranged under the floor of the vehicle, under the trunk room, or the like, and although the amount of heat given to the battery 2 per unit time is small, the temperature of the battery 2 gradually rises when left for a long time. If the battery 2 is left in a high temperature state, the life of the battery 2 is shortened. Therefore, it is desired to keep the temperature of the battery 2 below a predetermined temperature even while the vehicle is parked.

Further, the battery 2 is composed of a plurality of battery cells 3. If the temperature of each battery cell 3 of the battery 2 varies, the deterioration of the battery cell 3 is biased, and the storage performance of the battery 2 deteriorates. This is because the battery 2 is configured to include a series connection of a plurality of battery cells 3, so that the input / output characteristics of the battery 2 are determined according to the characteristics of the most deteriorated battery cell 3. Therefore, in order for the battery 2 to exhibit the desired performance over a long period of time, it is important to equalize the temperature by reducing the temperature variation between the plurality of battery cells 3.

Further, as another cooling device for cooling the battery 2, an air-cooled cooling means using a blower and a cooling means using the cold heat of a vapor compression refrigerating cycle are generally used. However, the air-cooled cooling means by the blower only blows the air in the vehicle interior, so the cooling capacity is low. Further, since the air blown by the blower cools the battery 2 by the sensible heat of the air, the temperature difference between the upstream and the downstream of the air flow becomes large, and the temperature variation between the plurality of battery cells 3 cannot be sufficiently suppressed. Further, although the cooling means using the cold heat of the refrigeration cycle has a high cooling capacity, it is necessary to drive a compressor or the like that consumes a large amount of electricity while the vehicle is parked. This is not preferable because it causes an increase in power consumption, an increase in noise, and the like.

Therefore, the device temperature control device 1 of the present embodiment employs a thermosiphon system in which the temperature of the battery 2 is adjusted by the natural circulation of the working fluid without forcibly circulating the working fluid by the compressor.

Next, the configuration of the device temperature control device 1 will be described. As shown in FIG. 1, in the equipment temperature control device 1, a fluid in which an equipment temperature adjusting unit 10, a plurality of gas phase passages 21, 22, 40, a condenser 50, a liquid phase passage 55, and the like are connected to each other and sealed. It is configured as a circuit. The equipment temperature control device 1 constitutes a loop-type thermosiphon circuit in which the flow path through which the working fluid in the gas phase flows and the flow path through which the working fluid in the liquid phase flows are separated. A predetermined amount of working fluid is sealed in the thermosiphon circuit in a state where the inside is evacuated. As the working fluid, for example, a chlorofluorocarbon-based refrigerant such as HFO-1234yf or HFC-134a is used. The filling amount of the working fluid is adjusted so that the liquid level FL of the working fluid is located in the middle of the heat exchanger for equipment in the height direction. In the drawing, an example of the height of the liquid level FL of the working fluid is shown by a chain line. The upper and lower sides indicated by the double-headed arrows in the drawing show the upper side and the lower side in the direction of gravity when the device temperature control device 1 is mounted on a vehicle or the like.

As shown in FIGS. 1 to 3, the equipment temperature adjusting unit 10 of the first embodiment is composed of one equipment heat exchanger 11. The device heat exchanger 11 has a shape having a longitudinal direction and a lateral direction when viewed from the direction of gravity. The equipment heat exchanger 11 is composed of a tubular upper header tank 111, a tubular lower header tank 112, and a heat exchange unit 113. The upper header tank 111 is provided at a position on the upper side of the heat exchanger 11 for equipment in the direction of gravity. The lower header tank 112 is provided at a position on the lower side of the heat exchanger 11 for equipment in the direction of gravity. The plurality of heat exchange units 113 have a plurality of tubes that communicate the flow path in the upper header tank 111 and the flow path in the lower header tank 112. The heat exchange unit 113 may have a plurality of flow paths formed inside the plate-shaped member. Each component of the device heat exchanger 11 is made of a metal having high thermal conductivity such as aluminum and copper. It should be noted that each component of the device heat exchanger 11 can be made of a material having high thermal conductivity other than metal.

A battery 2 is installed on the outside of the heat exchange unit 113 via an electrically insulating heat conductive sheet 114. The heat conductive sheet 114 guarantees insulation between the heat exchange unit 113 and the battery 2, and reduces the thermal resistance between the heat exchange unit 113 and the battery 2. In the present embodiment, in the battery 2, the surface 6 on the side opposite to the surface 5 on which the terminal 4 is provided is installed in the heat exchange portion 113 via the heat conductive sheet 114. It is also possible to omit the heat conductive sheet 114 and directly connect the battery 2 and the heat exchange unit 113.

The plurality of battery cells 3 constituting the battery 2 are arranged in a direction intersecting in the direction of gravity. The installation method of the battery 2 is not limited to that shown in FIGS. 1 to 3, and any installation method can be adopted as described in the 15th and 16th embodiments described later. The number, shape, and the like of each battery cell 3 constituting the battery 2 are not limited to those shown in FIGS. 1 to 3, and any battery cell 3 can be adopted.

The battery 2 can exchange heat with the working fluid inside the heat exchanger 11 for equipment. When the battery 2 generates heat, the working fluid of the liquid phase in the heat exchanger 11 for equipment evaporates. As a result, the plurality of battery cells 3 are uniformly cooled by the latent heat of vaporization of the working fluid.

Outlets 111a and 111b are provided on the left and right sides of the upper header tank 111 of the heat exchanger 11 for equipment in the longitudinal direction, respectively. The lower header tank 112 is provided with an inflow port 112a. The outlets 111a and 111b are pipe connection portions for connecting the end portions of the gas pipes constituting the gas phase passages 21, 22 and 40. The inflow port 112a is a pipe connection portion for connecting the end portions of the liquid pipes constituting the liquid phase passage 55.

The plurality of gas phase passages 21, 22, and 40 are passages for flowing the working fluid of the gas phase evaporated inside the heat exchanger 11 for equipment to the condenser 50. In the present embodiment, the plurality of gas phase passages 21, 22, and 40 include a first gas phase passage 21, a second gas phase passage 22, and a confluence passage 40. One end of the first gas phase passage 21 is connected to an outlet 111a provided on one side of the upper header tank 111 of the equipment heat exchanger 11 in the longitudinal direction. The end of the first gas phase passage 21 that connects to the equipment heat exchanger 11 is referred to as the first connection portion 211. One end of the second gas phase passage 22 is connected to an outflow port 111b provided on the other end in the longitudinal direction of the upper header tank 111 of the equipment heat exchanger 11. The end of the second gas phase passage 22 that connects to the equipment heat exchanger 11 is referred to as the second connection portion 221. The first connection portion 211 of the first gas phase passage 21 and the second connection portion 221 of the second gas phase passage 22 are provided at positions apart from each other in the horizontal direction in the heat exchanger 11 for one device. .. Specifically, the first connection portion 211 of the first gas phase passage 21 and the second connection portion 221 of the second gas phase passage 22 are located outside the heat exchange portion 113 of the equipment heat exchanger 11 in the longitudinal direction. It is provided in.

The first connection portion 211 is provided on the vehicle front side of the heat exchanger 11 for equipment with respect to the heat exchange portion 113. Further, the second connection portion 221 is provided on the rear side of the vehicle from the heat exchange portion 113 of the heat exchanger 11 for equipment. That is, the first connection portion 211 and the second connection portion 221 are provided at locations separated in the front-rear direction of the vehicle. The first gas phase passage 21 has a portion 21a extending from the first connection portion 211 to the front of the vehicle. The second gas phase passage 22 has a portion 22a extending rearward from the second connecting portion 221. The first gas phase passage 21 may extend upward from the first connecting portion 211, or may extend upward and diagonally forward. Further, the second gas phase passage 22 may extend upward from the second connecting portion 221 or may extend upward and diagonally backward.

The following can be said as the effect of the first gas phase passage 21 having the portion 21a extending from the first connection portion 211 to the front of the vehicle. That is, as shown in FIG. 5, the portion 21a of the first gas phase passage 21 extending from the first connection portion 211 to the front of the vehicle is a pipe for dealing with the inclination when the position of the condenser 50 is raised. Here, since there is a portion 21a of the first gas phase passage 21 extending from the first connection portion 211 to the front of the vehicle, when the portion 21a is inclined as shown in FIG. 5, the heat exchange portion 113 of the equipment heat exchanger 11 However, the first gas phase passage 21 does not go down relatively. Therefore, the vapor-phase refrigerant evaporated in the heat exchange unit 113 is likely to be guided to the first vapor-phase passage 21 at the time of inclination.

Further, the following can be said as an effect that the second gas phase passage 22 has a portion 22a extending from the second connecting portion 221 to the rear of the vehicle. That is, as shown in FIG. 6, the portion 22a of the second gas phase passage 22 extending from the second connecting portion 221 to the rear of the vehicle is a pipe for dealing with the inclination when the position of the condenser 50 is lowered. Here, since there is a portion 22a of the second gas phase passage 22 extending from the first connection portion 221 to the rear of the vehicle, when the portion 22a is inclined as shown in FIG. 6, the heat exchange portion 113 of the equipment heat exchanger 11 However, the second gas phase passage 22 does not go down relatively. Therefore, the vapor phase refrigerant evaporated in the heat exchange section 113 is likely to be guided to the second vapor phase passage 22 at the time of inclination.

The end of the first gas phase passage 21 on the opposite side of the equipment heat exchanger 11 and the end of the second gas phase passage 22 on the side opposite to the equipment heat exchanger 11 are the confluence 30. It is connected with. A merging passage 40 is connected between the merging portion 30 and the condenser 50. The merging portion 30 is provided above the first connecting portion 211 and the second connecting portion 221 in the direction of gravity. The working fluid flowing through the first gas phase passage 21 and the working fluid flowing through the second gas phase passage 22 merge at the merging portion 30. The working fluid merged at the merging portion 30 flows to the condenser 50 through the merging passage 40.

The condenser 50 is arranged above the heat exchanger 11 for equipment in the direction of gravity. The condenser 50 is a heat exchanger for exchanging heat between the working fluid of the gas phase that has flowed into the inside of the condenser 50 through the gas phase passages 21, 22, and 40 and a predetermined heat receiving medium. As the predetermined heat receiving medium that exchanges heat with the working fluid flowing through the condenser 50, various heat media such as a refrigerant that circulates in the refrigeration cycle, cooling water that circulates in the cooling water circuit, or air may be adopted. It is possible. For example, when air is adopted as a predetermined heat receiving medium that exchanges heat with the working fluid flowing through the condenser 50, the condenser 50 uses air or running wind blown by a fan (not shown) and a gas phase working fluid. It is configured as an air-cooled heat exchanger that exchanges heat with and. In that case, the working fluid of the gas phase flowing through the condenser 50 is condensed by dissipating heat to the air passing through the condenser 50. The condenser 50 is generally provided in the engine room in front of the vehicle.

The condenser 50 is not limited to a position above the liquid level FL of the working fluid as shown in the drawing, and may be provided at a position straddling the liquid level FL of the working fluid in the height direction.

The liquid phase passage 55 is a passage for flowing the working fluid of the liquid phase condensed inside the condenser 50 to the heat exchanger 11 for equipment. The end of the liquid phase passage 55 on the opposite side of the condenser 50 is connected to an inflow port 112a provided in the lower header tank 112 of the equipment heat exchanger 11. As a result, the working fluid condensed by the condenser 50 to become a liquid phase flows down the liquid phase passage 55 due to its own weight and flows into the heat exchanger 11 for equipment.

The gas phase passages 21, 22, 40 and the liquid phase passage 55 are names for convenience, and do not mean a passage through which only the working fluid of the gas phase or the liquid phase flows. That is, both the gas phase and the liquid phase working fluids may flow in any of the gas phase passages 21, 22, 40 and the liquid phase passage 55. Further, the shapes of the gas phase passages 21, 22, 40 and the liquid phase passage 55 can be appropriately changed in consideration of the mountability on the vehicle.

Subsequently, the flow of the working fluid when the device temperature control device 1 cools the battery 2 will be described. <Horizontal state>
FIG. 4 shows a case where the device temperature adjusting unit 10 is in a horizontal state. In the present embodiment, the amount of the working fluid filled is such that when the device temperature control device 1 is inactive and the device temperature adjusting unit 10 is in the horizontal state, the liquid level FL of the working fluid is in the height direction of the heat exchange unit 113. It is located in the middle and is adjusted so that the first connection portion 211 and the second connection portion 221 are above the liquid level FL of the working fluid.

When the equipment temperature control device 1 is activated and the battery 2 is cooled, the condenser 50 exchanges heat between the working fluid of the gas phase and a predetermined heat receiving medium. Specifically, when the vehicle is stopped, a fan (not shown) for blowing air to the condenser 50 is driven, and the fan blows air. When the vehicle is running, the running wind flows to the condenser 50, so that it is not necessary to drive the fan. Alternatively, a compressor of a refrigeration cycle (not shown) for exchanging heat with the working fluid flowing through the condenser 50 is driven, and the refrigerant circulates in the refrigeration cycle. Alternatively, a pump of a cooling water circuit (not shown) for exchanging heat with the working fluid flowing through the condenser 50 is driven, and the cooling water circulates in the cooling water circuit.

As a result, the working fluid of the liquid phase condensed by the condenser 50 flows through the liquid phase passage 55 due to its own weight, and flows into the lower header tank 112 of the heat exchanger 11 for equipment from the inflow port. The working fluid flowing into the lower header tank 112 is diverted into a plurality of flow paths included in the heat exchange unit 113. Here, in the present embodiment, the filling amount of the working fluid is adjusted so that the liquid level FL of the working fluid is located in the middle of the heat exchange section 113 when the device temperature adjusting section 10 is in the horizontal state. Therefore, the first connection portion 211 and the second connection portion 221 are located above the liquid level FL of the working fluid in the equipment temperature adjusting unit 10.

The liquid phase working fluid flowing through the plurality of flow paths of the heat exchange unit 113 evaporates by exchanging heat with the battery 2. In this process, the battery 2 is cooled by the latent heat of vaporization of the working fluid. After that, the working fluids in the gas phase merge at the upper header tank 111, and the first air from the first connection portion 211 and the second connection portion 221 connected to one and the other in the longitudinal direction of the upper header tank 111, respectively. It flows through the phase passage 21, the second gas phase passage 22, and the confluence passage 40 to the condenser 50.

As described above, the flow of the working fluid when the battery 2 is cooled is as follows: condenser 50 → liquid phase passage 55 → lower header tank 112 → heat exchange unit 113 → upper header tank 111 → first gas phase passage 21, second air. The order is phase passage 22 → merging passage 40 → condenser 50. That is, a loop-shaped flow path including the heat exchanger 11 for equipment and the condenser 50 is formed.

<Inclined state>
Next, a case where the device temperature control device 1 is in an inclined state will be described. 5 and 6 show a state in which the device temperature control device 1 is tilted at a predetermined angle. As for the filling amount of the working fluid, when the equipment temperature adjusting portion 10 is tilted at a predetermined angle, the liquid level FL of the working fluid is on one upper side of the first connecting portion 211 or the second connecting portion 221 and the first connecting portion 211. Alternatively, it is adjusted so that it is below the other side of the second connection portion 221. Further, the filling amount of the working fluid is adjusted so that the liquid level FL of the working fluid is below the confluence portion 30 when the equipment temperature adjusting portion 10 is tilted at a predetermined angle.

The predetermined angle as a reference for adjusting the filling amount of the working fluid is appropriately set according to the usage environment of the vehicle on which the equipment temperature control device 1 is mounted. In the present embodiment, the predetermined angle is set as, for example, 25 °. The predetermined angle can be appropriately set, for example, between 5 ° and 25 °. By the way, it is desirable that the device temperature control device 1 has a configuration corresponding to the inclination of the vehicle in the front-rear direction rather than the left-right direction of the vehicle. A running vehicle tends to maintain its inclination in the front-rear direction of the vehicle for a long time as when climbing a slope, while the inclination in the left-right direction of the vehicle is not maintained for a long time. Therefore, there is a high need for the equipment temperature control device 1 to support the vehicle in the front-rear direction. In addition, the device temperature control device 1 is also effective with respect to the inertial force acting on the vehicle. At this time, in a scene such as acceleration or deceleration, the state in which the inertial force acts in the front-rear direction of the vehicle is likely to be maintained for a long time. On the other hand, the state in which the inertial force acts in the left-right direction of the vehicle due to a curve or the like is not maintained for a long time. It is more necessary for the equipment temperature control device 1 to correspond in the front-rear direction of the vehicle.

FIG. 5 shows a state in which the heat exchanger 11 for equipment is tilted so that the condenser 50 side is upward. In this state, for example, when the condenser 50 is installed in front of the vehicle, it is tilted so that the front of the vehicle is upward. At this time, the first connection portion 211 of the first gas phase passage 21 connected to one of the upper header tanks 111 in the longitudinal direction is above the liquid level FL of the working fluid and is connected to the other in the longitudinal direction of the upper header tank 111. The second connection portion 221 of the second gas phase passage 22 is below the liquid level FL of the working fluid.

When the device temperature control device 1 is in the operating state and the battery 2 is cooled, as shown by the arrow in FIG. 5, the working fluid of the liquid phase condensed by the condenser 50 flows through the liquid phase passage 55 to exchange heat for the device. It flows into the lower header tank 112 of the vessel 11. The working fluid flowing into the lower header tank 112 is diverted into a plurality of flow paths included in the heat exchange unit 113, and evaporates by heat exchange with the battery 2. In the case of FIG. 5, the working fluid of the gas phase evaporated in the heat exchange part 113 passes through the first gas phase passage 21 and the merging passage 40 from the first connecting part 211 above the liquid level FL of the working fluid and is condensed. It flows into the vessel 50.

On the other hand, FIG. 6 shows a state in which the condenser 50 side of the equipment heat exchanger 11 is tilted downward. In this state, the first connection portion 211 of the first gas phase passage 21 connected to one of the upper header tanks 111 in the longitudinal direction is below the liquid level FL of the working fluid, and is located on the other side of the upper header tank 111 in the longitudinal direction. The second connection portion 221 of the second gas phase passage 22 to be connected is above the liquid level FL of the working fluid.

When the equipment temperature control device 1 is in the operating state and the battery 2 is cooled, as shown by the arrow in FIG. 6, when the battery 2 is cooled, the working fluid of the liquid phase condensed by the condenser 50 passes through the liquid phase passage 55. It flows and flows into the lower header tank 112 of the equipment heat exchanger 11. The working fluid flowing into the lower header tank 112 is diverted into a plurality of flow paths included in the heat exchange unit 113, and evaporates by heat exchange with the battery 2. In the case of FIG. 6, the working fluid of the gas phase evaporated in the heat exchange unit 113 passes through the second gas phase passage 22 and the merging passage 40 from the second connecting part 221 above the liquid level FL of the working fluid and is condensed. It flows into the vessel 50. As described above, in the first embodiment, it is possible to cool the battery 2 regardless of which side of the longitudinal direction the heat exchanger 11 for equipment is inclined.

Next, the liquid level FL of the working fluid will be described in detail.
When the apparatus 1 is in operation, that is, when evaporation occurs in the device temperature adjusting unit 10 and condensation occurs in the condenser 50, the liquid level changes slightly up and down due to the pressure balance during evaporation. As described above, in the present embodiment, the filling amount of the working fluid is adjusted so that the first connecting portion 211 and the second connecting portion 221 are located above the liquid level of the working fluid. If the liquid level of the working fluid is not adjusted in this way, the working fluid of the gas phase cannot escape stably and the performance cannot be ensured, or the gas phase is only when the liquid level moves slightly downward. Performance cannot be ensured stably because the working fluid of is not drained.

When the apparatus 1 is not operating, that is, when evaporation does not occur in the device temperature adjusting unit 10 and condensation does not occur in the condenser 50, the liquid level is stationary. In this state, if the relationship that the first connection portion 211 and the second connection portion 221 are located above the liquid level of the working fluid is not satisfied, a cold heat source is provided in the condenser 50 in order to operate the present device 1. Even if it is supplied, there is no path for the vaporized gas phase working fluid to escape from the equipment temperature adjusting unit 10. That is, the stable operation of the present device 1 cannot be started.

Here, the operating principle of the present device 1 will be described. The working fluid evaporates in the equipment temperature control unit 10 to become a gas phase, and the working fluid of the gas phase condenses in the condenser 50 to become a liquid phase working fluid, and the liquid phase working fluid becomes a liquid phase passage. Accumulate. At this time, the liquid level difference between the equipment temperature adjusting unit 10 and the liquid phase passage 55 serves as a driving source for operation. In other words, a part of the liquid phase refrigerant of the equipment temperature adjusting unit 10 moves to the liquid phase passage 55 via the condenser 50 after evaporation, so that a liquid level difference occurs and the working fluid circulates.

Next, the liquid level during operation and the liquid level during non-operation are compared. As described above, since the apparatus 1 operates when a part of the liquid phase refrigerant of the equipment temperature adjusting unit 10 moves to the liquid phase passage 55 via the condenser 50 after evaporation, the equipment temperature adjusting unit 10 does not operate. The liquid level during operation and the liquid level during operation are higher than those during non-operation. Due to the pressure balance, the liquid level during operation rises and falls slightly, causing an event in which the liquid level during operation temporarily becomes higher than the liquid level during non-operation, but in general, the liquid level during non-operation occurs. It can be considered that the liquid level at the time of operation is higher than the liquid level at the time of non-operation.

From the above, regarding the relationship that the first connection portion 211 and the second connection portion 221 are located above the liquid level of the working fluid, if the relationship is satisfied at the liquid level when the apparatus 1 is not operating. Cooling performance can be ensured in almost all situations of the present device 1.

The device temperature control device 1 of the first embodiment described above has the following effects.
(1) In the first embodiment, the first connection portion 211 in which the first gas phase passage 21 is connected to the heat exchanger 11 for equipment and the second connection portion 211 in which the second gas phase passage 22 is connected to the heat exchanger 11 for equipment. The connecting portion 221 is located at a location separated from the connecting portion 221 in the horizontal direction. As a result, when the heat exchanger 11 for equipment is tilted, one of the first connection portion 211 and the second connection portion 221 is located on the upper side in the gravity direction, and the other of the first connection portion 211 and the second connection portion 221 is gravity. Located on the lower side of the direction. Therefore, the working fluid evaporated in the heat exchanger 11 for equipment is at least one of the first gas phase passage 21 or the second gas phase passage 22 from the first connection portion 211 or the second connection portion 221 located on the upper side in the gravity direction. Flows into the condenser 50. The working fluid condensed by the condenser 50 flows through the liquid phase passage 55 and flows into the heat exchanger 11 for equipment. By such circulation of the working fluid, the device temperature control device 1 can cool the battery 2 regardless of which side of the longitudinal direction the device heat exchanger 11 is tilted.

(2) In the first embodiment, the amount of the working fluid sealed is such that when the device temperature control device 1 is inactive and the device heat exchanger 11 is in the horizontal state, the liquid level FL of the working fluid is the device heat. It is adjusted to be located in the middle of the exchanger 11. Further, the amount of the working fluid sealed is such that when the device temperature control device 1 is inactive and the device heat exchanger 11 is in the horizontal state, the first connection portion 211 and the second connection portion 221 are the fluids of the working fluid. It is adjusted so that it is located above the surface FL. As a result, the gas release property of the first connection portion 211 or the second connection portion 221 is improved. That is, the pressure loss of the working fluid of the gas phase flowing from the heat exchanger 11 for equipment to the first gas phase passage 21 or the second gas phase passage 22 via the first connection portion 211 or the second connection portion 221 is reduced. To. Therefore, the device temperature control device 1 can improve the cooling performance of the battery 2 by improving the circulation of the working fluid of the thermosiphon circuit.

(3) In the first embodiment, the amount of the working fluid sealed is such that when the heat exchanger 11 for equipment is tilted at a predetermined angle, the liquid level FL of the working fluid is the first connection portion 211 or the second connection portion 221. It is on one side and the liquid level FL of the working fluid is adjusted to be on the other side of the first connection 211 or the second connection 221. As a result, when the equipment heat exchanger 11 is tilted, the working fluid evaporated inside the equipment heat exchanger 11 is the first connection portion 211 or the second connection portion 211 or the second on the side where the working fluid of the liquid phase is not submerged. It flows from the connection portion 221 to the first vapor phase passage 21 or the second vapor phase passage 22. Therefore, the device temperature control device 1 can improve the cooling performance of the battery 2 by improving the circulation of the working fluid of the thermosiphon circuit.

(4) In the first embodiment, the equipment temperature control device 1 further includes a merging portion 30 and a merging passage 40. The merging portion 30 is provided above the first connecting portion 211 and the second connecting portion 221 in the direction of gravity. The merging passage 40 allows the working fluid of the gas phase to flow between the merging portion 30 and the condenser 50. According to this, the equipment temperature control device 1 is configured to connect the merging portion 30 and the condenser 50 with a merging passage 40, so that the entire space between the equipment heat exchanger 11 and the condenser 50 is connected. The number of pipes can be reduced as compared with the configuration in which the first gas phase passage and the second vapor phase passage are connected.

Further, by providing the merging portion 30 above the first connecting portion 211 and the second connecting portion 221 in the direction of gravity, it is possible to prevent the merging portion 30 from being submerged when the heat exchanger 11 for equipment is tilted. Can be done. If the confluence portion 30 is submerged and the equipment heat exchanger 11 is tilted, the working fluid of the gas phase flowing through the first gas phase passage 21 or the second gas phase passage 22 passes through the confluence portion 30. Can be difficult. On the other hand, if the confluence portion 30 is not submerged when the heat exchanger 11 for equipment is tilted, the working fluid of the gas phase flowing through the first gas phase passage 21 or the second gas phase passage 22 is the confluence portion. It easily passes through 30 and flows into the condenser 50. Therefore, the device temperature control device 1 can improve the cooling performance of the battery 2 by improving the circulation of the working fluid of the thermosiphon circuit.

(5) In the first embodiment, the filling amount of the working fluid is adjusted so that the liquid level FL of the working fluid is below the merging portion 30 when the heat exchanger 11 for equipment is tilted at a predetermined angle. There is. As a result, it is possible to prevent the confluence portion 30 from submerging when the heat exchanger 11 for equipment is tilted.

(6) In the first embodiment, the first connection portion 211 and the second connection portion 221 are provided at positions apart from each other in the horizontal direction in the heat exchanger 11 for one device. As a result, when the equipment heat exchanger 11 is tilted, the working fluid evaporated in the equipment heat exchanger 11 is the first gas phase from the first connection portion 211 or the second connection portion 221 located on the upper side in the gravity direction. It flows through the passage 21 or the second vapor phase passage 22 and flows into the condenser 50. Therefore, the device temperature control device 1 can cool the battery 2 even when the device heat exchanger 11 is tilted.

(7) In the first embodiment, the first connection portion 211 and the second connection portion 221 are provided outside the heat exchange portion 113 of the equipment heat exchanger 11 in the longitudinal direction. As a result, the first connection portion 211 and the second connection portion 221 are provided at positions far apart in the horizontal direction in the heat exchanger 11 for one device. Therefore, even when the equipment heat exchanger 11 is greatly tilted, the working fluid of the gas phase evaporated in the equipment heat exchanger 11 is transferred from the first connection portion 211 or the second connection portion 221 to the first gas phase passage 21 or It can be discharged to the second gas phase passage 22.

(Modification example 1)
A modified example 1 with respect to the first embodiment will be described with reference to FIG. In the first modification, the amount of the working fluid to be sealed in the thermosiphon circuit of the device temperature control device 1 is changed with respect to the first embodiment, and the other parts are the same as those of the first embodiment. Only the part different from the first embodiment will be described.

FIG. 7 shows a state in which the device temperature control device 1 is tilted at a predetermined angle. In the first modification, the amount of the working fluid filled is the first gas phase passage 21 and the second gas phase passage 21 and the second even when the equipment temperature adjusting unit 10 is in the horizontal state and the equipment temperature adjusting unit 10 is tilted at a predetermined angle. The liquid level FL of the working fluid is adjusted to be located in the middle of the gas phase passage 22. Further, the amount of the working fluid filled is the liquid level of the working fluid below the confluence 30 even when the device temperature adjusting section 10 is in a horizontal state and when the device temperature adjusting section 10 is tilted at a predetermined angle. It is adjusted to have FL.

When the battery 2 is cooled, the working fluid of the liquid phase condensed in the condenser 50 flows through the liquid phase passage 55 and flows into the lower header tank 112 of the heat exchanger 11 for equipment. The working fluid flowing into the lower header tank 112 is diverted into a plurality of flow paths included in the heat exchange unit 113, and evaporates by heat exchange with the battery 2. In FIG. 7, the second connection portion 221 of the second gas phase passage 22 is located above the first connection portion 211 of the first gas phase passage 21. Therefore, the working fluid of the gas phase evaporated in the heat exchange unit 113 flows through the upper header tank 111 to the second connection portion 221 side, passes from the second connection portion 221 to the second gas phase passage 22 and the merging passage 40, and is condensed. It flows into the vessel 50. Depending on how the pipes constituting the second gas phase passage 22 are routed, it is conceivable that a fluid pool of the working fluid may be formed in the middle of the second gas phase passage 22. Therefore, as shown by the broken line P1 in FIG. 7, it is preferable that the piping forming the second gas phase passage 22 has a layout in which the inclination in the vertical direction is gentle within the limitation of the vehicle mounting space. Furthermore, it is even better if the pipe has a layout in which the height increases toward the confluence 30.

(Modification 2)
The second modification with respect to the first embodiment will be described with reference to FIG. The second modification is also different from the first embodiment in that the amount of the working fluid to be sealed in the thermosiphon circuit of the device temperature control device 1 is changed, and the other parts are the same as those in the first embodiment.

FIG. 8 shows a state in which the device temperature control device 1 is tilted at a predetermined angle. In the second modification, the liquid level FL of the working fluid is located above the merging portion 30 and in the middle of the merging passage 40. That is, the merging portion 30 is submerged in the working fluid of the liquid phase. In this case, when the battery 2 is cooled, the working fluid evaporated by the heat exchange with the battery 2 in the heat exchange section 113 of the equipment heat exchanger 11 merges with the first gas phase passage 21, the second vapor phase passage 22, and the battery 2. It may be difficult to pass through the portion 30. Therefore, as shown by the broken line P2 in FIG. 8, the piping constituting the first gas phase passage 21 or the second gas phase passage 22 should be laid out so as to be gently inclined in the vertical direction within the limitation of the vehicle mounting space. Is preferable. Furthermore, it is even better if the pipe has a layout in which the height increases toward the confluence 30.

(Second Embodiment)
The second embodiment will be described with reference to FIG. The second embodiment is the same as the first embodiment in that a part of the configuration of the second gas phase passage 22 and the amount of the working fluid filled therein are changed with respect to the first embodiment. ..

FIG. 9 shows a state in which the device temperature control device 1 is tilted at a predetermined angle. In the second embodiment, the vertical distance between the upper header tank 111 of the equipment heat exchanger 11 and the second vapor phase passage 22 is the upper header tank 111 and the second vapor phase passage 22 represented by the first embodiment. It is larger than the vertical distance to.

In the second embodiment, the filling amount of the working fluid is such that the second vapor phase passage 22 is horizontal even when the equipment temperature adjusting unit 10 is in the horizontal state and when the equipment temperature adjusting unit 10 is tilted at a predetermined angle. The liquid level FL of the working fluid is adjusted so as to be located below the portion extending to.

Further, in the second embodiment, the amount of the working fluid sealed is the first gas phase passage 21 even when the equipment temperature adjusting unit 10 is in the horizontal state and when the equipment temperature adjusting unit 10 is tilted at a predetermined angle. And the liquid level FL of the working fluid is adjusted to be located in the middle of the second gas phase passage 22. Further, the amount of the working fluid filled is the liquid level of the working fluid below the confluence 30 even when the device temperature adjusting section 10 is in a horizontal state and when the device temperature adjusting section 10 is tilted at a predetermined angle. It is adjusted to have FL.

When the battery 2 is cooled, the working fluid of the liquid phase condensed in the condenser 50 flows through the liquid phase passage 55 and flows into the lower header tank 112 of the heat exchanger 11 for equipment. The working fluid flowing into the lower header tank 112 is diverted into a plurality of flow paths included in the heat exchange unit 113, and evaporates by heat exchange with the battery 2. In FIG. 9, the second connection portion 221 of the second gas phase passage 22 is located above the first connection portion 211 of the first gas phase passage 21. Therefore, the working fluid of the gas phase evaporated in the heat exchange unit 113 flows through the upper header tank 111 to the second connection portion 221 side, passes from the second connection portion 221 to the second gas phase passage 22 and the merging passage 40, and is condensed. It flows into the vessel 50.

Also in the second embodiment, when the heat exchanger 11 for equipment is tilted, one of the first connection portion 211 and the second connection portion 221 is located on the upper side in the direction of gravity, and the first connection portion 211 and the second connection portion 221 are also located. The other is located below the direction of gravity. Therefore, the working fluid evaporated in the heat exchanger 11 for equipment is at least one of the first gas phase passage 21 or the second gas phase passage 22 from the first connection portion 211 or the second connection portion 221 located on the upper side in the gravity direction. Flows into the condenser 50. Therefore, the device temperature control device 1 can cool the battery 2 regardless of which side of the longitudinal direction the device heat exchanger 11 is tilted.

(Modification 3)
A modified example 3 with respect to the second embodiment will be described with reference to FIG. The third modification is the same as that of the second embodiment in that the amount of the working fluid sealed is changed with respect to the second embodiment.

FIG. 10 shows a state in which the device temperature control device 1 is tilted at a predetermined angle. In the third modification, the liquid level FL of the working fluid is located above the merging portion 30 and in the middle of the merging passage 40. That is, the merging portion 30 is submerged in the working fluid of the liquid phase. In this case, when the battery 2 is cooled, the working fluid evaporated by the heat exchange with the battery 2 in the heat exchange section 113 of the equipment heat exchanger 11 merges with the first gas phase passage 21, the second vapor phase passage 22, and the battery 2. It may be difficult to pass through the portion 30. Therefore, as shown by the broken line P3 in FIG. 10, the pipes constituting the first gas phase passage 21 or the second gas phase passage 22 should be laid out so as to be gently inclined in the vertical direction within the limitation of the vehicle mounting space. Is preferable. Furthermore, it is even better if the pipe has a layout in which the height increases toward the confluence 30.

(Third Embodiment)
The third embodiment will be described with reference to FIG. The third embodiment is a modification of the first embodiment with a part of the configuration of the first gas phase passage 21 and the second gas phase passage 22, and the other parts are the same as those of the first embodiment. ..

In the third embodiment, the first connection portion 211 of the first gas phase passage 21 and the second connection portion 221 of the second gas phase passage 22 are connected in the middle of the upper header tank 111, respectively. Also in the third embodiment, the first connection portion 211 of the first gas phase passage 21 and the second connection portion 221 of the second gas phase passage 22 are separated from each other in the horizontal direction in the heat exchanger 11 for one device. It is provided at the above position. Therefore, the device temperature control device 1 can cool the battery 2 regardless of which side of the longitudinal direction the device heat exchanger 11 is tilted.

(Fourth Embodiment)
A fourth embodiment will be described with reference to FIG. The fourth embodiment is the same as the third embodiment in that the gas phase passage is added to the third embodiment.

In the fourth embodiment, the plurality of gas phase passages are configured to include a first gas phase passage 21, a second gas phase passage 22, a third gas phase passage 23, and a confluence passage 40. The first connection portion 211 of the first gas phase passage 21, the second connection portion 221 of the second gas phase passage 22, and the third connection portion 231 of the third gas phase passage 23 are all heat exchangers 11 for equipment. It is connected in the middle of the upper header tank 111. The end of the first gas phase passage 21 opposite to the heat exchanger 11 for equipment and the end of the third gas phase passage 23 opposite to the heat exchanger 11 for equipment are first merged. It is connected by unit 31. The end of the second gas phase passage 22 opposite to the heat exchanger 11 for equipment and the end of the first gas phase passage 21 opposite to the heat exchanger 11 for equipment are secondly merged. It is connected by a unit 32. As described above, the number of gas phase passages and the number of confluences are not limited, and can be arbitrarily set according to the layout on the vehicle.

Also in the fourth embodiment, the first connection portion 211 of the first gas phase passage 21, the second connection portion 221 of the second gas phase passage 22, and the third connection portion 231 of the third gas phase passage 23 are It is provided at a position separated in the horizontal direction from the heat exchanger 11 for one device. Therefore, the device temperature control device 1 can cool the battery 2 regardless of which side of the longitudinal direction the device heat exchanger 11 is tilted.

(Fifth Embodiment)
A fifth embodiment will be described with reference to FIG. In the fifth to fourth embodiments described below, the device temperature adjusting unit 10 included in the device temperature control device 1 is composed of a plurality of heat exchangers for devices. The device temperature adjusting unit 10 can be stored together with the battery 2 in the case of the battery pack. In addition, in FIGS. 13 to 22 referred to in the description of the 5th to 14th embodiments, the illustration of the condenser is omitted. Further, the range of the device temperature adjusting unit 10 is shown by a broken line.

In the fifth embodiment, the device temperature adjusting unit 10 is composed of the heat exchanger 11 for the first device and the heat exchanger 12 for the second device. The heat exchanger 11 for the first device and the heat exchanger 12 for the second device are provided at positions separated in the horizontal direction. Although not shown, in the fifth embodiment, the amount of the working fluid filled is adjusted so that the liquid level of the working fluid is located in the middle of the heat exchange part when the device temperature adjusting part 10 is in the horizontal state. Has been done. Therefore, the first connection portion 211 and the second connection portion 221 are provided in a portion of the heat exchanger 11 for the first device above the liquid level of the working fluid, and are among the heat exchanger 12 for the second device. It is provided at a portion above the liquid level of the working fluid.

In the fifth embodiment, the first gas phase passage 21 and the second gas phase passage 22 are merged at the merging portion 30. A merging passage 40 is connected between the merging portion 30 and the condenser. The first gas phase passage 21 branches from the confluence portion 30 to one first gas phase passage 21c and the other first gas phase passage 21d via the branch portion 21b. On the other hand, the first connection portion 211a of the first gas phase passage 21c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the front side of the vehicle. The first connection portion 211b of the other first gas phase passage 21d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the front side of the vehicle.

The second gas phase passage 22 branches from the confluence portion 30 to one second gas phase passage 22c and the other second gas phase passage 22d via the branch portion 22b. The second connection portion 221a of the second gas phase passage 22c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the rear side of the vehicle. The second connection portion 221b of the other second gas phase passage 22d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the rear side of the vehicle.

The first gas phase passages 21c and 21d and the second gas phase passages 22c and 22d also function as connecting passages for connecting the heat exchanger 11 for the first device and the heat exchanger 12 for the second device. There is. The lower header tank 112 of the heat exchanger 11 for the first device and the lower header tank 122 of the heat exchanger 12 for the second device are connected by a liquid phase passage 55.

Also in the fifth embodiment, when the device temperature adjusting unit 10 is tilted in the vehicle front-rear direction, one of the first connection unit 211 and the second connection unit 221 is located on the upper side in the gravity direction, and the other is located on the lower side in the gravity direction. To do. Therefore, the working fluid evaporated in the heat exchangers 11 and 12 for a plurality of devices is sent from either the first connection portion 211 or the second connection portion 221 located on the upper side in the gravity direction to the first gas phase passage 21 or the first gas phase passage 21 or the first 2 Flows through the vapor phase passage 22 and flows into the condenser. The working fluid condensed by the condenser flows through the liquid phase passage 55 and flows into the heat exchangers 11 and 12 for a plurality of devices. By such circulation of the working fluid, the device temperature control device 1 of the fifth embodiment can cool the battery 2 even when the plurality of device heat exchangers 11 and 12 are tilted.

(Sixth Embodiment)
A sixth embodiment will be described with reference to FIG. The sixth embodiment is a modification of the fifth embodiment with a part of the configuration of the gas phase passage.

Also in the sixth embodiment, the first gas phase passage 21 branches from the merging portion 30 to the one first vapor phase passage 21c and the other first gas phase passage 21d via the branch portion 21b. On the other hand, the first connection portion 211a of the first gas phase passage 21c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the front side of the vehicle. The first connection portion 211b of the other first gas phase passage 21d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the front side of the vehicle.

On the other hand, in the sixth embodiment, the second gas phase passage 22 branches from the confluence portion 30 into one second gas phase passage 22c and the other second gas phase passage 22d. The second connection portion 221a of the second gas phase passage 22c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the rear side of the vehicle. The second connection portion 221b of the other second gas phase passage 22d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the rear side of the vehicle.

The sixth embodiment can also exhibit the same effects as those of the first to fifth embodiments.

(7th Embodiment)
A seventh embodiment will be described with reference to FIG. The seventh embodiment is a modification of the fifth embodiment with a part of the configuration of the gas phase passage.

Also in the seventh embodiment, the first gas phase passage 21 branches from the merging portion 30 to the one first gas phase passage 21c and the other first gas phase passage 21d via the branch portion 21b. On the other hand, the first connection portion 211a of the first gas phase passage 21c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the front side of the vehicle. The first connection portion 211b of the other first gas phase passage 21d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the front side of the vehicle.

The second gas phase passage 22 branches from the confluence portion 30 to one second gas phase passage 22c and the other second gas phase passage 22d via the branch portion 22b. The second connection portion 221a of the second gas phase passage 22c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the rear side of the vehicle. The second connection portion 221b of the other second gas phase passage 22d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the rear side of the vehicle.

The seventh embodiment can also exhibit the same effects as those of the first to sixth embodiments.

(8th Embodiment)
The eighth embodiment will be described with reference to FIG. In the eighth embodiment, the arrangement of the plurality of heat exchangers 11 and 12 for the equipment constituting the equipment temperature adjusting unit 10 is different from that in the fifth embodiment. The heat exchangers 11 and 12 for a plurality of devices are all arranged so that the longitudinal direction is along the vehicle width direction. The plurality of heat exchangers 11 and 12 for equipment are arranged so as to be arranged in the front-rear direction of the vehicle. Of the plurality of heat exchangers 11 and 12 for equipment, the one arranged on the front side of the vehicle is called the heat exchanger 11 for the first equipment, and the one arranged on the rear side of the vehicle is the heat exchanger 12 for the second equipment. I will call it.

In the eighth embodiment, the first gas phase passage 21 connects the merging portion 30 and the heat exchanger 11 for the first device. The first connection portion 211 of the first gas phase passage 21 is connected to the upper header tank 111 of the heat exchanger 11 for the first equipment arranged on the front side of the vehicle. The first gas phase passage 21 has a portion 21a extending from the first connection portion 211 to the front of the vehicle.

The second gas phase passage 22 connects the merging portion 30 and the heat exchanger 12 for the second device. The second connection portion 221 of the second gas phase passage 22 is connected to the upper header tank 121 of the heat exchanger 12 for the second equipment arranged on the rear side of the vehicle. The first gas phase passage 21 and the second gas phase passage 22 merge at the merging portion 30. A merging passage 40 is connected between the merging portion 30 and the condenser.

Further, in the eighth embodiment, the equipment temperature adjusting unit 10 has a plurality of heat exchangers 11 and 12 for equipment provided at positions separated in the vehicle front-rear direction, and a connecting passage 61. The connecting passage 61 connects the first connecting portion 211 provided in the heat exchanger 11 for the first device and the second connecting portion 221 provided in the heat exchanger 12 for the second device.

In the eighth embodiment, when the device temperature adjusting unit 10 is tilted in the vehicle front-rear direction, one of the first connection unit 211 and the second connection unit 221 is located on the upper side in the gravity direction, and the other is located on the lower side in the gravity direction. .. Therefore, the working fluid evaporated in the heat exchangers 11 and 12 for a plurality of devices is from the first connection portion 211 or the second connection portion 221 to the first gas phase passage 21 located on the upper side in the gravity direction via the connection passage 61. Alternatively, it flows through at least one of the second vapor phase passages 22 and flows into the condenser. The working fluid condensed by the condenser flows through the liquid phase passage 55 and flows into the heat exchangers 11 and 12 for a plurality of devices. Therefore, the eighth embodiment can also exhibit the same effects as those of the first to seventh embodiments.

(9th Embodiment)
A ninth embodiment will be described with reference to FIG. The ninth embodiment is obtained by changing the number of heat exchangers for equipment and the like from the eighth embodiment.

In the ninth embodiment, the equipment temperature adjusting unit 10 is composed of three or more heat exchangers 11, 12, 13 for equipment and a connecting passage 61. Also in the ninth embodiment, the device heat exchanger arranged at the frontmost portion in the direction in which the plurality of device heat exchangers 11, 12 and 13 are arranged is called the first device heat exchanger 11 and is arranged at the rearmost portion. The heat exchanger for equipment is called the heat exchanger 12 for second equipment. Further, a plurality of heat exchangers for equipment arranged between the heat exchanger 11 for the first equipment and the heat exchanger 12 for the second equipment are all referred to as heat exchangers 13 for the third equipment.

The connecting passage 61 connects one ends of the upper header tanks 111, 121, 131 of the heat exchangers 11, 12, and 13 for the first to third devices. Specifically, the connecting passage 61 includes a first connection portion 211 provided in the heat exchanger 11 for the first device, a second connection portion 221 provided in the heat exchanger 12 for the second device, and a third. A third connection portion 231 provided in the heat exchanger 13 for equipment is connected.

In the ninth embodiment, the first connection portion 211 to which the first gas phase passage 21 is connected to the equipment temperature adjusting unit 10 is connected to the upper header tank 111 of the first equipment heat exchanger 11 arranged on the front side of the vehicle. doing. The first gas phase passage 21 has a portion 21a extending from the first connection portion 211 to the front of the vehicle. Further, the second connection portion 221 in which the second gas phase passage 22 is connected to the equipment temperature adjusting portion 10 is connected to the upper header tank 121 of the second equipment heat exchanger 12 arranged on the rear side of the vehicle. That is, the first connection portion 211 and the second connection portion 221 are provided at positions as far as possible in the horizontal direction from each other. The first gas phase passage 21 and the second gas phase passage 22 are merged at the confluence portion 30. A merging passage 40 is connected between the merging portion 30 and the condenser.

Also in the ninth embodiment, when the device temperature adjusting unit 10 is tilted in the vehicle front-rear direction, one of the first connection unit 211 and the second connection unit 221 is located on the upper side in the gravity direction and the other is located on the lower side in the gravity direction. .. Therefore, the working fluid evaporated in the heat exchangers 11, 12, and 13 for a plurality of devices is the first gas phase from the first connection portion 211 or the second connection portion 221 located on the upper side in the gravity direction via the connecting passage 61. It flows through at least one of the passage 21 or the second vapor phase passage 22 and flows into the condenser. The working fluid condensed by the condenser flows through the liquid phase passage 55 and flows into the heat exchangers 11, 12, and 13 for a plurality of devices. Therefore, the ninth embodiment can also exhibit the same effects as those of the first to eighth embodiments.

(10th Embodiment)
The tenth embodiment will be described with reference to FIG. The tenth embodiment is a modification of the eighth embodiment in which a part of the configuration of the gas phase passage and the connecting passage is changed.

In the tenth embodiment, the connecting passage includes a first connecting passage 61 and a second connecting passage 62. The first connecting passage 61 is the right end of the upper header tank 111 of the first equipment heat exchanger 11 in the vehicle width direction and the right end of the upper header tank 121 of the second equipment heat exchanger 12 in the vehicle width direction. And are connected. The second connecting passage 62 is the left end portion of the upper header tank 111 of the first equipment heat exchanger 11 in the vehicle width direction and the left end portion of the upper header tank 121 of the second equipment heat exchanger 12 in the vehicle width direction. And are connected.

In the tenth embodiment, the first gas phase passage 21 includes a first gas phase passage 21e on the right side in the vehicle width direction and a first gas phase passage 21f on the left side in the vehicle width direction.

The first gas phase passage 21e on the right side in the vehicle width direction connects the first merging portion 31 and the heat exchanger 11 for the first device arranged on the front side of the vehicle. The first connection portion 211a of the first gas phase passage 21e on the right side in the vehicle width direction is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the right side in the vehicle width direction.

The first gas phase passage 21f on the left side in the vehicle width direction connects the second merging portion 32 and the heat exchanger 11 for the first device arranged on the front side of the vehicle. The first connection portion 211b of the first gas phase passage 21f on the left side in the vehicle width direction is connected to the portion on the left side in the vehicle width direction of the upper header tank 111 of the heat exchanger 11 for the first device.

The second gas phase passage 22 includes a second gas phase passage 22e on the right side in the vehicle width direction and a second gas phase passage 22f on the left side in the vehicle width direction.

The second gas phase passage 22e on the right side in the vehicle width direction connects the second merging portion 32 and the heat exchanger 12 for the second device arranged on the rear side of the vehicle. The second connection portion 211a of the second gas phase passage 21f on the left side in the vehicle width direction is connected to the portion on the right side in the vehicle width direction of the upper header tank 121 of the heat exchanger 12 for the second device.

The second gas phase passage 22f on the left side in the vehicle width direction connects the second merging portion 32 and the heat exchanger 12 for the first device arranged on the rear side of the vehicle. The second connection portion 221b of the second gas phase passage 22f on the left side in the vehicle width direction is connected to the portion on the left side in the vehicle width direction of the upper header tank 121 of the heat exchanger 12 for the second device.

The first gas phase passage 21e and the second gas phase passage 22e on the right side in the vehicle width direction meet at the first merging portion 31. The first gas phase passage 21f and the second gas phase passage 22f on the left side in the vehicle width direction meet at the second merging portion 32. The first merging portion 31 and the second merging portion 32 are connected by a first merging passage 41. The middle of the first merging passage 41 and the condenser are connected by a second merging passage 42.

One end of the lower header tank 112 of the first equipment heat exchanger 11 and one end of the lower header tank 122 of the second equipment heat exchanger 12 are connected by the first lower connecting passage 71. The other end of the lower header tank 112 of the first equipment heat exchanger 11 and the other end of the lower header tank 122 of the second equipment heat exchanger 12 are connected by a second lower connecting passage 72. The liquid phase passage 55 branches in the middle and is connected to the first lower connecting passage 71 and the second lower connecting passage 72.

In the tenth embodiment, when the device temperature adjusting unit 10 is tilted in the vehicle front-rear direction, one of the first connecting portions 211a and 211b or the second connecting portions 221a and 221b is located on the upper side in the gravity direction and the other is located on the lower side in the gravity direction. Located on the side.

Further, in the tenth embodiment, when the device temperature adjusting unit 10 is inclined in the vehicle width direction, one of the connecting portions 211a and 221a on the right side of the vehicle or the connecting portions 211b and 221b on the left side of the vehicle is located on the upper side in the gravity direction and the other. Is located on the lower side in the direction of gravity. Therefore, the tenth embodiment can also exhibit the same effects as those of the first to ninth embodiments. Further, in the tenth embodiment, the first connection portions 211a and 211b and the second connection portions 221a and 221b are provided at the four corners of the device temperature adjusting unit 10, respectively, so that the vehicle can be in any of the front, rear, left and right directions. It can also handle the inclination of.

(11th Embodiment)
The eleventh embodiment will be described with reference to FIG. The eleventh embodiment is a modification of the tenth embodiment in which the number of heat exchangers 11 for equipment and the like are changed.

In the eleventh embodiment, the equipment temperature adjusting unit 10 is composed of three or more heat exchangers for equipment and connecting passages 61 and 62. In the description of the eleventh embodiment, the heat exchanger for equipment arranged at the frontmost portion in the direction in which the heat exchangers 11, 12, and 13 for a plurality of equipment are arranged is referred to as the heat exchanger 11 for first equipment, and is at the rearmost portion. The heat exchanger for the equipment to be arranged is called the heat exchanger 12 for the second equipment. Further, a plurality of heat exchangers for equipment arranged between the heat exchanger 11 for the first equipment and the heat exchanger 12 for the second equipment are all referred to as heat exchangers 13 for the third equipment.

The first connecting passage 61 connects the ends on the right side in the vehicle width direction of the upper header tanks 111, 121, 131 of the heat exchangers 11, 12, and 13 for the first to third devices. The second connecting passage 62 connects the left ends of the upper header tanks 111, 121, 131 for the first to third equipment heat exchangers 11, 12, and 13 in the vehicle width direction.

Also in the eleventh embodiment, the first gas phase passage 21 is configured to include the first gas phase passage 21e on the right side in the vehicle width direction and the first gas phase passage 21f on the left side in the vehicle width direction.

The first gas phase passage 21e on the right side in the vehicle width direction connects the first merging portion 31 and the heat exchanger 11 for the first device arranged on the front side of the vehicle. The first connection portion 211a of the first gas phase passage 21e on the right side in the vehicle width direction is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the right side in the vehicle width direction.

The first gas phase passage 21f on the left side in the vehicle width direction connects the second merging portion 32 and the heat exchanger 11 for the first device arranged on the front side of the vehicle. The first connection portion 211b of the first gas phase passage 21f on the left side in the vehicle width direction is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the left side in the vehicle width direction.

The second gas phase passage 22 includes a second gas phase passage 22e on the right side in the vehicle width direction and a second gas phase passage 22f on the left side in the vehicle width direction.

The second gas phase passage 22e on the right side in the vehicle width direction connects the first confluence portion 31 and the heat exchanger 12 for the second device arranged on the rear side of the vehicle. The second connection portion 211a of the second gas phase passage 22e on the right side in the vehicle width direction is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the right side in the vehicle width direction.

The second gas phase passage 22f on the left side in the vehicle width direction connects the second merging portion 32 and the heat exchanger 12 for the first device arranged on the rear side of the vehicle. The second connection portion 221b of the second gas phase passage 22f on the left side in the vehicle width direction is connected to the portion on the left side in the vehicle width direction of the upper header tank 121 of the heat exchanger 12 for the second device. Therefore, the first connection portions 211a and 211b and the second connection portions 221a and 221b are provided at positions as far as possible in the vehicle front-rear direction in the direction in which the plurality of equipment heat exchangers 11, 12, and 13 are arranged. ..

The first gas phase passage 21e and the second gas phase passage 22e on the right side in the vehicle width direction meet at the first merging portion 31. The first gas phase passage 21f and the second gas phase passage 22f on the left side in the vehicle width direction meet at the second merging portion 32. The first merging portion 31 and the second merging portion 32 are connected by a first merging passage 41. The middle of the first merging passage 41 and the condenser are connected by a second merging passage 42.

The ends of the lower header tanks 112, 122, and 132 of the heat exchangers 11, 12, and 13 for the first to third devices on the right side in the vehicle width direction are connected by the first lower connecting passage 71. The left ends of the lower header tanks 112, 122, 132 of the heat exchangers 11, 12, and 13 for the first to third devices in the vehicle width direction are connected to each other by the second lower connecting passage 72. The liquid phase passage 55 branches in the middle and is connected to the first lower connecting passage 71 and the second lower connecting passage 72.

The eleventh embodiment can also exhibit the same effects as those of the first to tenth embodiments. Further, in the eleventh embodiment, the first and second connection portions 211a, 211b, 211a and 221b of the first and second vapor phase passages 21 and 22 are provided at the four corners of the equipment temperature adjusting unit 10, respectively. Therefore, it is possible to cope with the inclination of the vehicle in any direction of front, rear, left and right.

(12th Embodiment)
A twelfth embodiment will be described with reference to FIG. The twelfth embodiment is different from the eighth embodiment in that the directions in which the heat exchangers 11 and 12 for a plurality of devices are arranged are changed.

In the twelfth embodiment, a plurality of heat exchangers 11 and 12 for equipment are arranged in the longitudinal direction of the heat exchangers 11 and 12 for the equipment. Further, the plurality of heat exchangers 11 and 12 for equipment are arranged along the vehicle front-rear direction. The connecting passage 61 includes the end of the upper header tank 111 of the heat exchanger 11 for the first device on the rear side of the vehicle and the end of the upper header tank 121 of the heat exchanger 12 for the second device on the front side of the vehicle. Are connected.

In the twelfth embodiment, the first gas phase passage 21 connects the merging portion 30 and the heat exchanger 11 for the first device arranged on the front side of the vehicle. The first connection portion 211 of the first gas phase passage 21 is provided at the end portion of the upper header tank 111 of the heat exchanger 11 for the first device on the front side of the vehicle.

The second gas phase passage 22 connects the merging portion 30 and the heat exchanger 12 for the second device arranged on the rear side of the vehicle. The second connection portion 221 of the second gas phase passage 22 is provided at the rear end of the upper header tank 121 of the heat exchanger 12 for the second device on the rear side of the vehicle. Therefore, the first connection portion 211 and the second connection portion 221 are provided at positions as far as possible in the vehicle front-rear direction in the direction in which the plurality of device heat exchangers 11 and 12 are arranged. The third gas phase passage 23 connects the end portion of the upper header tank 111 of the heat exchanger 11 for the first device on the rear side of the vehicle to the second gas phase passage 22. The third gas phase passage 23 may be omitted.

The first gas phase passage 21 and the second gas phase passage 22 merge at the merging portion 30. A merging passage 40 is connected between the merging portion 30 and the condenser.

The other end of the lower header tank 112 of the first device heat exchanger 11 and one end of the lower header tank 122 of the second device heat exchanger 12 are connected by a lower connecting passage 70. The liquid phase passage 55 is connected to one end of the lower header tank 112 of the heat exchanger 11 for the first device.

Also in the twelfth embodiment, when the device temperature adjusting unit 10 is tilted toward the heat exchanger 11 side for the first device or the heat exchanger 12 side for the second device, one of the first connection unit 211 and the second connection unit 221 It is located above the direction of gravity and the other is located below the direction of gravity. Therefore, the twelfth embodiment can also exhibit the same effects as those of the first to eleventh embodiments.

(13th Embodiment)
The thirteenth embodiment will be described with reference to FIG. The thirteenth embodiment is a modification of the eighth embodiment and the like in which the number and arrangement of heat exchangers for equipment are changed.

In the thirteenth embodiment, the equipment temperature adjusting unit 10 is composed of four equipment heat exchangers 11 to 14 and a connecting passage 61. In the description of the thirteenth embodiment, among the heat exchangers for a plurality of devices, the heat exchangers for two devices arranged on the front side of the vehicle are the heat exchangers for the first device 11 and the heat exchangers for the second device. Call it 12. The two heat exchangers for equipment arranged on the rear side of the vehicle are called the heat exchanger 13 for the third equipment and the heat exchanger 14 for the fourth equipment.

In the thirteenth embodiment, in the first gas phase passage 21, the portion 21a extending from the confluence portion 30 is branched into one first gas phase passage 21c and the other first gas phase passage 21d via the branch portion 21b. .. The first connection portion 211a of the first gas phase passage 21c is connected to the upper header tank 111 of the heat exchanger 11 for the first device. The first connection portion 211b of the other first gas phase passage 21d is connected to the upper header tank 121 of the heat exchanger 12 for the second device.

Further, the second gas phase passage 22 branches from the merging portion 30 to one second gas phase passage 22c and the other second gas phase passage 22d via the branch portion 22b. The second connection portion 221a of the second gas phase passage 22c is connected to the upper header tank 131 of the heat exchanger 13 for the third device. The second connection portion 221b of the other second gas phase passage 22d is connected to the upper header tank 141 of the heat exchanger 14 for the fourth device.

The connecting passage 61 connects the branch portion 21b of the first gas phase passage 21 and the branch portion 22b of the second gas phase passage 22.

The liquid phase passage 55 is connected to the lower header tanks 112, 122, 132, 142 of the heat exchangers 11 to 14 for the first to fourth devices.

Also in the thirteenth embodiment, when the device temperature adjusting unit 10 is tilted toward the heat exchanger 11 side for the first device or the heat exchanger 13 side for the third device, the first connecting parts 211a and 211b and the second connecting part 221a, One of the 221b is located above the gravity direction and the other is located below the gravity direction. Therefore, the thirteenth embodiment can also exhibit the same effects as those of the first to twelfth embodiments.

(14th Embodiment)
The 14th embodiment will be described with reference to FIG. The 14th embodiment is different from the 13th embodiment in that the directions in which the heat exchangers 11 to 14 for a plurality of devices are arranged are changed.

Also in the 14th embodiment, the device temperature adjusting unit 10 is composed of four device heat exchangers 11 to 14. The heat exchangers 11 to 14 for a plurality of devices are all arranged so that the longitudinal direction is along the vehicle front-rear direction. Also in the description of the fourteenth embodiment, among the heat exchangers for a plurality of devices, the heat exchangers for two devices arranged on the front side of the vehicle are the heat exchangers for the first device 11 and the heat exchangers for the second device. Call it 12. The two heat exchangers for equipment arranged on the rear side of the vehicle are called the heat exchanger 13 for the third equipment and the heat exchanger 14 for the fourth equipment.

In the 14th embodiment, the first gas phase passage 21 connects the merging portion 30 and a portion of the heat exchangers 11 to 14 for the first to fourth devices on the front side of the vehicle. In the first gas phase passage 21a, the portion 21a extending from the confluence portion 30 is branched into three first gas phase passages 21c, 21d, 21e via the branch portion 21b. The first connection portion 211a of the one first gas phase passage 21c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first device on the front side of the vehicle. The first connection portion 211b of another first gas phase passage 21d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the front side of the vehicle.

Yet another first gas phase passage 21e is branched into two first gas phase passages 21g and 21h via a branch portion 21f. The first connection portion 211c of the first gas phase passage 21g is connected to a portion of the upper header tank 121 of the heat exchanger 13 for the third device on the front side of the vehicle. The first connection portion 211d of another first gas phase passage 21h is connected to a portion of the upper header tank 141 of the heat exchanger 14 for the fourth device on the front side of the vehicle.

The second gas phase passage 21 connects the merging portion 30 and a portion of the heat exchangers 11 to 14 for the first to fourth devices on the rear side of the vehicle. In the second gas phase passage 22a, the portion 22a extending from the confluence portion 30 is branched into three second gas phase passages 22c, 22d, 22e via the branch portion 22b. The second connection portion 221a of the one second gas phase passage 22c is connected to a portion of the upper header tank 111 of the heat exchanger 11 for the first equipment on the rear side of the vehicle. The second connection portion 221b of another second gas phase passage 22d is connected to a portion of the upper header tank 121 of the heat exchanger 12 for the second device on the rear side of the vehicle.

Yet another second gas phase passage 22e is branched into two second gas phase passages 22g and 21h via the branch portion 22f. The second connection portion 221c of the one second gas phase passage 22g is connected to a portion of the upper header tank 131 of the heat exchanger 13 for the third device on the rear side of the vehicle. The second connection portion 221d of another second gas phase passage 22h is connected to a portion of the upper header tank 141 of the heat exchanger 14 for the fourth device on the rear side of the vehicle.

The first gas phase passage 21 and the second gas phase passage 22 are connected by a confluence portion 30. The merging portion 30 and the condenser are connected by a merging passage 40.

The liquid phase passage 55 is connected to the lower header tanks 112, 122, 132, 142 of the heat exchangers 11 to 14 for the first to fourth devices.

Also in the fourteenth embodiment, when the device temperature adjusting unit 10 is tilted in either the front-back or left-right direction, either the first connection unit 211 or the second connection unit 221 is located on the upper side in the gravity direction. Therefore, the 14th embodiment can also exhibit the same effects as those of the 1st to 13th embodiments.

(15th Embodiment)
The fifteenth embodiment will be described with reference to FIG. The fifteenth embodiment describes an example of a method of installing the battery 2 in the heat exchanger 11 for equipment. In the fifteenth embodiment, the battery 2 is installed so that the surface 5 on which the terminal 4 is provided faces upward in the direction of gravity. The battery 2 has a surface perpendicular to the surface 5 on which the terminal 4 is provided, which is installed in the heat exchange unit 113 via the heat conductive sheet 114. As described above, the installation method of the battery 2 can be arbitrarily set.

(16th Embodiment)
The sixteenth embodiment will be described with reference to FIG. The sixteenth embodiment describes an example of how to install the heat exchanger 11 for equipment and the battery 2. In the 16th embodiment, a plurality of heat exchangers 11 for equipment are installed so as to sandwich both sides of the battery 2. Therefore, the area of the battery 2 that comes into thermal contact with the heat exchange unit 113 via the heat conductive sheet 114 becomes large. Therefore, according to the method of installing the device heat exchanger 11 and the battery 2 of the 16th embodiment, it is possible to increase the cooling capacity of the battery 2.

(17th Embodiment)
The 17th embodiment will be described with reference to FIGS. 25 and 26. The seventeenth embodiment describes an example of the arrangement of the first gas phase passage 21 and the second gas phase passage 22. The second gas phase passage 22 extends along the upper header tank 111 in contact with or adjacent to the upper header tank 111, and further extends along the first gas phase passage 21 so as to form the first gas phase. It extends in contact with or adjacent to the passage 21. A part of the first gas phase passage 21 and at least a part of the second gas phase passage 22 form a parallel portion 25 extending in contact with or adjacent to each other. The upper header tank 111 and a part of the second vapor phase passage 22 also form a parallel portion 251 extending in contact with or adjacent to each other. As a result, the area occupied by the first gas phase passage 21 and the second gas phase passage 22 becomes smaller. It is also possible to assemble the first gas phase passage 21 and the second gas phase passage 22 together with the vehicle or the like. For example, the gas pipe forming the first gas phase passage 21 and the gas pipe forming the second gas phase passage 22 can be attached to the vehicle body by using a common mounting bracket. Alternatively, it is also possible to form two flow paths in one piping member, and use one of the flow paths as the first gas phase passage 21 and the other flow path as the second gas phase passage 22. Therefore, the device temperature control device 1 can improve the mountability and assembling property to a vehicle or the like.

(18th Embodiment)
The eighteenth embodiment will be described with reference to FIGS. 27 to 29. The eighteenth embodiment also describes an example of the arrangement of the first gas phase passage 21 and the second gas phase passage 22. The pipes constituting the second gas phase passage 22 are provided inside the upper header tank 111, and further provided inside the pipes forming the first vapor phase passage 21. A part of the first gas phase passage 21 and at least a part of the second gas phase passage 22 have a double piping structure 26 in which the other pipe is provided inside one pipe. A part of the upper header tank 111 and the second gas phase passage 22 also has a double piping structure 261 in which the second vapor phase passage 22 is provided inside the upper header tank 111. As a result, the area occupied by the first gas phase passage 21 and the second gas phase passage 22 becomes smaller. It is also possible to assemble the first gas phase passage 21 and the second gas phase passage 22 having the double piping structure 26 together with the vehicle or the like. Therefore, the device temperature control device 1 can improve the mountability and assembling property to a vehicle or the like.

(19th Embodiment)
The nineteenth embodiment will be described with reference to FIGS. 30 and 31. In the 19th embodiment, the flow path area adjusting valve 80 is provided in the gas phase passage. The flow path area adjusting valve 80 is a member that regulates the flow of the working fluid of the liquid phase from the connecting portion side of the gas phase passage to the merging portion 30 side. In the 19th embodiment, the flow path area adjusting valve 80 is provided in the first gas phase passage 21. The flow path area adjusting valve 80 regulates the flow of the working fluid of the liquid phase from the first connecting portion 211 side of the first gas phase passage 21 to the merging portion 30 side.

When the flow path area adjusting valve 80 is provided in the second gas phase passage 22, the flow path area adjusting valve 80 causes the flow of the working fluid of the liquid phase from the second connecting portion 221 side to the merging portion 30 side. regulate.

The flow path area adjusting valve 80 of the 19th embodiment is a solenoid valve driven by a drive signal transmitted from the control device 81. When the tilt sensor 82 that detects the tilt of the device temperature adjusting unit 10 detects the tilt of the device temperature adjusting unit 10, the control device 81 transmits a drive signal to the flow path area adjusting valve 80. Specifically, as shown in FIG. 31, when the device temperature control device 1 is tilted so that the first connection portion 211 is lower than the second connection portion 221, the control device 81 is relative to the flow path area adjusting valve 80. Transmit the drive signal. When the drive signal is transmitted to the flow path area adjusting valve 80, the flow path area adjusting valve 80 causes the flow of the working fluid of the liquid phase from the first connection portion 211 side of the first gas phase passage 21 to the condenser 50 side. To regulate. In FIG. 31, when the flow path area adjusting valve 80 is activated, the device temperature control device 1 is hatched in a region filled with the working fluid of the liquid phase. As shown in FIG. 31, the flow path area adjusting valve 80 regulates the flow of the working fluid in the liquid phase, so that the merging portion 30 is prevented from being submerged. Therefore, the flow of the working fluid of the gas phase from the second gas phase passage 22 to the merging passage 40 via the merging portion 30 is secured. Therefore, the device temperature control device 1 can improve the mountability on a vehicle or the like by lowering the position of the merging portion 30.

Further, when the equipment temperature control device 1 is tilted, the flow path area adjusting valve 80 regulates the flow of the working fluid in the liquid phase, so that the liquid flowing out from the equipment heat exchanger 11 to the first gas phase passage 21. The amount of working fluid in the phase is reduced. When the device temperature control device 1 is tilted, the decrease in the working fluid of the liquid phase inside the device heat exchanger 11 is suppressed. Therefore, the device temperature control device 1 can improve the cooling performance of the battery 2 and prevent the temperature distribution between the battery cells 3 from becoming large.

Further, the flow path area adjusting valve 80 of the 19th embodiment is configured to operate in response to a control signal of the control device 81 when the tilt sensor 82 detects the tilt of the device temperature control device 1. Therefore, the flow path area adjusting valve 80 operates reliably in response to the inclination of the equipment temperature control device 1. Therefore, the flow path area adjusting valve 80 can reliably regulate the flow of the working fluid of the liquid phase from the connecting portion side of the gas phase passage to the merging portion 30 side.

(20th Embodiment)
A twentieth embodiment will be described with reference to FIGS. 32 and 33. The 20th embodiment is a modification of the flow path area adjusting valve described in the 19th embodiment.
The flow path area adjusting valve 83 of the 20th embodiment has a valve seat 84 and a valve body 85. The valve seat 84 is provided on the inner wall of the gas phase passage 21. The valve body 85 is a ball valve arranged in the flow path on the connection portion side of the valve seat 84. The ball valve leaves the valve seat 84 when the connecting portion 211 of the gas phase passage 21 is below the valve seat 84 in the direction of gravity. Further, as shown in FIG. 33, the ball valve is seated on the valve seat 84 by its own weight when the connecting portion 211 of the gas phase passage 21 is above the valve seat 84 in the direction of gravity. Even with this configuration, when the merging portion 30 side of the flow path area adjusting valve 83 is lower than the connecting portion side of the gas phase passage, the flow of the working fluid of the liquid phase from the connecting portion side of the gas phase passage to the merging portion 30 side. It is possible to regulate. Therefore, in the twentieth embodiment, the configuration of the flow path area adjusting valve 83 can be simplified.

(21st Embodiment)
The 21st embodiment will be described with reference to FIGS. 34 and 35. The 21st embodiment is also a modification of the flow path area adjusting valve described in the 19th embodiment.

The flow path area adjusting valve 86 of the 21st embodiment also has a valve seat 87 and a valve body 88. The valve seat 87 is provided on the inner wall of the gas phase passage. The valve body 88 is a float valve made of a material having a mass smaller than that of the working fluid of the liquid phase. As shown in FIG. 34, the float valve separates from the valve seat 87 due to its own weight when the working fluid of the gas phase flows through the gas phase passage 21. Further, as shown in FIG. 35, the float valve is seated on the valve seat 87 by buoyancy when the working fluid of the liquid phase flows through the gas phase passage 21. In FIG. 35, a broken line hatch is attached to the region filled with the working fluid of the liquid phase. With this configuration, the flow path area adjusting valve 86 can regulate the flow of the working fluid of the liquid phase from the connecting portion 211 side of the gas phase passage 21 to the merging portion 30 side. Therefore, in the 21st embodiment, the configuration of the flow path area adjusting valve 86 can be simplified.

(22nd Embodiment)
The 22nd embodiment will be described with reference to FIGS. 36 to 38. The 22nd embodiment is a combination of the 8th embodiment and the 17th embodiment.

In the 22nd embodiment, the first gas phase passage 21 and the second gas phase passage 22 extend in contact with each other or adjacent to each other. Further, the connecting passage 61 and the second gas phase passage 22 also extend in contact with each other or adjacent to each other.

The first gas phase passage 21 and the second gas phase passage 22 form a parallel portion 25 extending in contact with or adjacent to each other. Further, the connecting passage 61 and the second gas phase passage 22 also form a parallel portion 251 extending in a state of being in contact with or adjacent to each other. As a result, the area occupied by the first gas phase passage 21, the second gas phase passage 22, and the connecting passage 61 becomes smaller. It is also possible to assemble the first gas phase passage 21, the second gas phase passage 22, and the connecting passage 61 together with the vehicle or the like.

It is also possible to form two flow paths in one piping member, one of which is the first gas phase passage 21 or the connecting passage 61, and the other flow path is the second gas phase passage 22. Is. As a result, the device temperature control device 1 can be improved in mountability and assembling property to a vehicle or the like.

(23rd Embodiment)
The 23rd embodiment will be described with reference to FIGS. 39 to 41. The 23rd embodiment is a combination of the 8th embodiment and the 18th embodiment.

In the 23rd embodiment, the pipes constituting the second gas phase passage 22 are provided inside the pipes constituting the first gas phase passage 21 and the connecting passage 61. The first gas phase passage 21, the connecting passage 61, and the second gas phase passage 22 have a double piping structure 26 in which the other pipe is provided inside one pipe. As a result, the area occupied by the first gas phase passage 21, the connecting passage 61, and the second gas phase passage 22 becomes smaller. Further, it is also possible to assemble the first gas phase passage 21, the connecting passage 61, and the second gas phase passage 22 having the double piping structure 26 together with the vehicle or the like. Therefore, the device temperature control device 1 can improve the mountability and assembling property to a vehicle or the like.

(Other embodiments)
The present invention is not limited to the above-described embodiment, and can be appropriately modified within the scope of the claims. Further, the above-described embodiments are not unrelated to each other, and can be appropriately combined unless the combination is clearly impossible. Further, in each of the above embodiments, it goes without saying that the elements constituting the embodiment are not necessarily essential except when it is clearly stated that they are essential and when they are clearly considered to be essential in principle. No. Further, in each of the above embodiments, when numerical values such as the number, numerical values, amounts, and ranges of the constituent elements of the embodiment are mentioned, when it is clearly stated that they are particularly essential, and in principle, they are clearly limited to a specific number. It is not limited to the specific number except when it is done. In addition, in each of the above embodiments, when referring to the shape, positional relationship, etc. of a component or the like, the shape, unless otherwise specified or limited in principle to a specific shape, positional relationship, etc. It is not limited to the positional relationship.

(1) In each of the above embodiments, the battery 2 has been described as an example of the target device for which the device temperature control device 1 adjusts the temperature. On the other hand, in another embodiment, the target device for which the device temperature control device 1 adjusts the temperature may be another device that requires cooling or warming up, such as a motor, an inverter, or a charger.

(2) In each of the above embodiments, the configuration in which the device temperature control device 1 has a function of cooling the target device has been described. On the other hand, in another embodiment, the device temperature control device 1 may have a function of warming up the target device. In that case, it is possible to provide a heating mechanism for heating the working fluid in the middle of the gas phase passage and the liquid phase passage connecting the inflow portion and the outflow portion provided in the heat exchanger for equipment. The working fluid heated and evaporated by the heating mechanism flows into the heat exchanger for equipment from the outflow portion through the gas phase passage. The working fluid that radiates heat to the battery 2 and condenses in the heat exchanger for equipment flows into the heating mechanism from the inflow portion through the liquid phase passage due to the head difference. By such circulation of the working fluid, the device temperature control device 1 can warm up the target device.

(3) In the above-described embodiment, an example in which a fluorocarbon-based refrigerant is used as the working fluid has been described, but the present invention is not limited to this. As the working fluid, other fluids such as propane and carbon dioxide may be adopted.

(4) In the above-described embodiment, the plurality of gas phase passages 21 and 22 are connected by the merging section 30, and the merging section 30 and the condenser 50 are connected by the merging passage 40. On the other hand, in another embodiment, the device temperature adjusting unit 10 and the condenser 50 may be connected by a plurality of gas phase passages 21 and 22 without providing the merging unit 30 and the merging passage 40. ..

(5) In the above-described embodiment, when the device temperature adjusting unit 10 is in the horizontal state, the amount of the working fluid sealed is adjusted so that the liquid level FL of the working fluid is located in the middle of the heat exchanger 11 for the device. .. On the other hand, in another embodiment, when the device temperature adjusting unit 10 is in the horizontal state, even if the filling amount of the working fluid is adjusted so that the liquid level FL of the working fluid is located in the middle of the gas phase passage. Good.

(Summary)
According to the first aspect shown in part or all of the above-described embodiment, the device temperature control device that adjusts the temperature of the target device by the phase change between the liquid phase and the gas phase of the working fluid is the device temperature control device. It includes a section, a condenser, a liquid phase passage, and a plurality of gas phase passages. The equipment temperature control unit has one or more heat exchangers for equipment configured so that the target equipment and the working fluid can exchange heat so that the working fluid evaporates when the target equipment is cooled. The condenser dissipates the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out. The liquid phase passage allows the working fluid of the liquid phase to flow between the condenser and the equipment temperature control unit. The plurality of gas phase passages allow the working fluid of the gas phase to flow between the device temperature controller and the condenser. Of the plurality of gas phase passages, the first connection portion in which the first gas phase passage connects to the equipment temperature adjusting portion and the second connecting portion in which the second gas phase passage connects to the equipment temperature adjusting portion are separated in the horizontal direction. It is located in the same place.

According to the second aspect, the equipment temperature control device is mounted on the vehicle, and the first connection portion and the second connection portion are located at locations separated in the front-rear direction of the vehicle.
According to this, the equipment temperature control device corresponds to the inclination in the front-rear direction of the vehicle. The inclination of the vehicle in the front-rear direction, such as when climbing a slope, is likely to be maintained for a long time. In addition, the state in which the inertial force in the front-rear direction of the vehicle acts, such as the scenes of acceleration and deceleration, is likely to be maintained for a long time. The equipment temperature control device can continue to operate even in such a scene, and can continuously cool the battery.

According to the third viewpoint, when the equipment temperature adjusting portion is in the horizontal state, the liquid level of the working fluid is located in the middle of the height direction of the equipment heat exchanger, and the first connection portion and the second connection portion are located. The amount of the working fluid filled is adjusted so that it is located above the liquid level of the working fluid in the equipment temperature adjusting part.
According to this, the gas release property of the first connection portion or the second connection portion is improved. That is, the pressure loss of the working fluid of the gas phase flowing from the equipment temperature adjusting unit to the first gas phase passage or the second gas phase passage via the first connecting portion or the second connecting portion is reduced. Therefore, the device temperature control device can improve the cooling performance of the target device by improving the circulation of the working fluid of the thermosiphon circuit.

According to the fourth aspect, when the equipment temperature adjusting part is tilted at a predetermined angle, the liquid level of the working fluid is on the upper side of one of the first connection part and the second connection part, and the first connection part or the second connection part. The filling amount of the working fluid is adjusted so as to be on the lower side of the other side of the portion.
According to this, when the equipment temperature control part is tilted, the working fluid evaporated in the equipment heat exchanger is transferred from the first connection part or the second connection part located above the liquid level to the first gas phase passage or the first gas phase passage. It flows into the second vapor phase passage. Therefore, the device temperature control device can improve the cooling performance of the target device by improving the circulation of the working fluid of the thermosiphon circuit.

According to the fifth aspect, the gas phase passage includes a merging portion and a merging passage. The merging portion merges the working fluid flowing through the first gas phase passage and the working fluid flowing through the second gas phase passage. The confluence passage allows the working fluid of the gas phase to flow between the confluence and the condenser. The merging portion is provided above the first connecting portion and the second connecting portion in the direction of gravity.
According to this, the equipment temperature control device is configured to connect the confluence part and the condenser by a confluence passage, so that the equipment temperature control part and the condenser are all connected by a plurality of gas phase passages. The number of pipes can be reduced as compared with the configuration.
Further, by providing the merging portion on the upper side in the gravity direction with respect to the first connecting portion and the second connecting portion, it is possible to prevent the merging portion from being submerged when the device temperature adjusting portion is tilted. If the confluence is submerged and the equipment temperature control is tilted, it may be difficult for the working fluid of the gas phase flowing through the first gas phase passage or the second gas phase passage to pass through the confluence. is there. On the other hand, if the confluence is not submerged when the equipment temperature control section is tilted, the working fluid of the gas phase flowing through the first gas phase passage or the second gas phase passage easily passes through the confluence. , Flows into the condenser. Therefore, the device temperature control device can improve the cooling performance of the target device by improving the circulation of the working fluid of the thermosiphon circuit.

According to the sixth aspect, when the equipment temperature adjusting portion is tilted at a predetermined angle, the filling amount of the working fluid is adjusted so that the liquid level of the working fluid is below the merging portion.
According to this, it is possible to prevent the merging portion from submerging when the equipment temperature adjusting portion is tilted.

According to the seventh aspect, the first connection portion and the second connection portion are provided at positions apart from each other in the horizontal direction in one heat exchanger for equipment.
According to this, when the equipment heat exchanger is tilted, the working fluid evaporated in the equipment heat exchanger is transferred from the first connection portion or the second connection portion located on the upper side in the direction of gravity to the first gas phase passage or the first gas phase passage. It flows through the second vapor phase passage and flows into the condenser. Therefore, the device temperature control device can cool the target device even when the device temperature control unit is tilted.

According to the eighth aspect, the heat exchanger for equipment has a shape having a longitudinal direction and a lateral direction when viewed from the direction of gravity, and is in direct contact with the target device or indirectly through a heat conductive member. It has a heat exchange unit. The first connection portion and the second connection portion are provided at positions outside the heat exchange portion in the longitudinal direction of the heat exchanger for equipment.
According to this, in one heat exchanger for equipment, the first connection portion and the second connection portion are provided at positions that are largely separated in the horizontal direction. Therefore, even when the equipment heat exchanger is greatly tilted, the working fluid of the gas phase evaporated in the equipment heat exchanger can be transferred from the first connection portion or the second connection portion to the first gas phase passage or the second vapor phase passage. It is possible to discharge to.

According to the ninth aspect, the first connection portion is provided at a position on the front side of the vehicle with respect to the heat exchange portion in the heat exchanger for equipment. The second connection portion is provided at a position on the rear side of the vehicle from the heat exchange portion of the heat exchanger for equipment. The first gas phase passage has a portion extending upward or forward of the vehicle from the first connecting portion, and the second gas phase passage has a portion extending upward or rearward of the vehicle from the second connecting portion.
According to this, when the portion of the first gas phase passage extending upward from the first connection portion or extending to the front of the vehicle is inclined upward, the first gas phase passage is higher than the heat exchange portion of the heat exchanger for equipment. Does not decrease relatively. Therefore, at such an inclination, the vapor phase refrigerant evaporated in the heat exchange section of the equipment heat exchanger is likely to be guided to the first vapor phase passage.
Further, when the portion of the second gas phase passage extending upward from the second connection portion or extending to the front of the vehicle is inclined upward, the second gas phase passage is relative to the heat exchange portion of the heat exchanger for equipment. Does not go down to. Therefore, at such an inclination, the vapor phase refrigerant evaporated in the heat exchange section of the equipment heat exchanger is likely to be guided to the second vapor phase passage.

According to the tenth viewpoint, the device temperature adjusting unit is provided in any one of a plurality of device heat exchangers provided at positions separated in the vehicle front-rear direction and a plurality of device heat exchangers. It has a connecting passage that connects the 1st connecting portion and the 2nd connecting portion.
According to this, when a plurality of heat exchangers for equipment having the equipment temperature control unit are tilted, one of the first connection portion and the second connection portion is located on the upper side in the direction of gravity, and the first connection portion and the second connection portion are connected. The other side of the part is located on the lower side in the direction of gravity. Therefore, the working fluid evaporated in the heat exchangers for a plurality of devices passes through the first gas phase passage or the second gas phase passage from the first connection portion or the second connection portion located on the upper side in the gravity direction via the connecting passage. Flow and flow into the condenser. Therefore, the equipment temperature controller can cool the target equipment even when the heat exchangers for the plurality of equipment are tilted.

According to the eleventh viewpoint, the first connection portion is provided in a predetermined heat exchanger for equipment arranged on the front side of the vehicle among the heat exchangers for equipment. The second connection portion is provided in another heat exchanger for equipment arranged on the rear side of the vehicle among the heat exchangers for equipment. The first gas phase passage has a portion extending upward or forward of the vehicle from the first connection portion. The second gas phase passage has a portion extending upward or rearward from the second connecting portion.
According to this, the eleventh viewpoint can also exert the same effect as the action and effect described in the ninth viewpoint.

According to the twelfth aspect, at least a part of the first gas phase passage or the second gas phase passage and the connecting passage form a parallel portion extending in a state of being in contact with or adjacent to each other.
According to this, the area occupied by the first gas phase passage or the second gas phase passage and the connecting passage becomes smaller. It is also possible to assemble the first gas phase passage or the second gas phase passage and the connecting passage together with the vehicle or the like. Therefore, this device temperature control device can improve the mountability and assembling property to a vehicle or the like.

According to the thirteenth aspect, at least a part of the first gas phase passage and at least a part of the second gas phase passage form a parallel portion extending in contact with each other or adjacent to each other.
According to this, the area occupied by the first gas phase passage and the second vapor phase passage becomes smaller. It is also possible to assemble the first gas phase passage and the second gas phase passage together with the vehicle or the like. Therefore, this device temperature control device can improve the mountability and assembling property to a vehicle or the like.

According to the fourteenth viewpoint, at least a part of the first gas phase passage or the second gas phase passage and the connecting passage have a double piping structure in which the other pipe is provided inside one pipe. ..
According to this, the area occupied by the first gas phase passage or the second gas phase passage and the connecting passage becomes smaller. It is also possible to assemble the first gas phase passage or the second gas phase passage having a double piping structure and the connecting passage together with the vehicle or the like. Therefore, this device temperature control device can improve the mountability and assembling property to a vehicle or the like.

According to the fifteenth viewpoint, at least a part of the first gas phase passage and at least a part of the second gas phase passage have a double piping structure in which the other pipe is provided inside one pipe. ..
According to this, the area occupied by the first gas phase passage and the second vapor phase passage becomes smaller. It is also possible to assemble the first gas phase passage and the second gas phase passage having a double piping structure together with the vehicle or the like. Therefore, this device temperature control device can improve the mountability and assembling property to a vehicle or the like.

According to the sixteenth viewpoint, the equipment temperature control device is provided in the first gas phase passage or the second gas phase passage, and allows the flow of the working fluid of the liquid phase from the connecting portion side to the merging portion side of the gas phase passage. It is equipped with a flow path area adjustment valve to regulate.
According to this, when the equipment temperature control part is tilted, the flow of the working fluid of the liquid phase from the connection part side located on the lower side in the gravity direction of the first connection part and the second connection part to the confluence side is regulated. By doing so, it is possible to prevent the confluence from being submerged. Therefore, the flow of the working fluid of the gas phase from the connecting portion side located on the upper side in the gravity direction of the first connecting portion and the second connecting portion to the merging passage via the merging portion is secured. Therefore, the equipment temperature control device can improve the mountability on a vehicle or the like by lowering the position of the confluence portion.
Further, when the equipment temperature adjusting portion is tilted, the working fluid of the liquid phase flowing from the connecting portion located on the lower side in the gravity direction of the first connecting portion and the second connecting portion to the gas phase passage is a flow path area adjusting valve. The flow is regulated. Therefore, when the equipment temperature adjusting portion is tilted, it is possible to reduce the amount of the working fluid of the liquid phase flowing from the equipment heat exchanger to the gas phase passage. Therefore, since the decrease in the working fluid in the liquid phase of the heat exchanger for equipment is suppressed, the equipment temperature control device can improve the cooling performance of the target equipment.

According to the seventeenth aspect, the equipment temperature control device further includes a tilt sensor for detecting the tilt of the equipment temperature adjusting unit. When the inclination of the equipment temperature adjusting unit is detected by the inclination sensor, the flow path area adjusting valve regulates the flow of the working fluid of the liquid phase from the connecting portion side of the gas phase passage to the condenser side.
According to this, since the flow path area adjusting valve operates in response to the inclination of the equipment temperature adjusting portion, the flow path area adjusting valve is the working fluid of the liquid phase from the connecting portion side to the merging portion side of the gas phase passage. The flow of can be reliably regulated.

According to the eighteenth aspect, the flow path area adjusting valve has a valve seat and a valve body. The valve seat is provided on the inner wall of the gas phase passage. The valve body sits on the valve seat by its own weight when the connection part of the gas phase passage is above the valve seat in the direction of gravity, and when the connection part of the gas phase passage is below the valve seat in the direction of gravity, from the valve seat. Leave. According to this, the structure of the flow path area adjusting valve can be simplified.

According to the nineteenth aspect, the flow path area adjusting valve has a valve seat and a valve body. The valve seat is provided on the inner wall of the gas phase passage. The valve body is seated on the valve seat by buoyancy when the working fluid of the liquid phase flows in the gas phase passage, and is separated from the valve seat when the working fluid of the gas phase flows in the gas phase passage. According to this, the structure of the flow path area adjusting valve can be simplified.

According to the twentieth viewpoint, the device temperature control device that adjusts the temperature of the target device by the phase change between the liquid phase and the gas phase of the working fluid includes a device temperature control unit, a condenser, a liquid phase passage, and a plurality of gas phases. It has a passage and a connecting passage. The equipment temperature control unit has a plurality of heat exchangers for equipment and a connecting passage. The heat exchangers for a plurality of devices are configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled. The connecting passage connects a plurality of heat exchangers for equipment to each other. The condenser dissipates the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out. The liquid phase passage allows the working fluid of the liquid phase to flow between the heat exchangers for a plurality of devices and the condenser. The plurality of gas phase passages allow the working fluid of the gas phase to flow between the plurality of equipment heat exchangers and the condenser. Of the plurality of gas phase passages, the first connection portion in which the first gas phase passage connects to the equipment temperature adjusting portion and the second connecting portion in which the second gas phase passage connects to the equipment temperature adjusting portion are separated in the horizontal direction. They are located in different locations and are either installed in separate equipment heat exchangers or in the same equipment heat exchanger.

According to this, when the device temperature adjusting part is tilted, one of the first connection part and the second connection part is located on the upper side in the gravity direction, and the other of the first connection part and the second connection part is on the lower side in the gravity direction. To position. Therefore, the working fluid evaporated in the heat exchangers for a plurality of devices flows from the first connection portion or the second connection portion located on the upper side in the direction of gravity through at least one of the first gas phase passage or the second vapor phase passage. It flows into the condenser. The working fluid condensed by the condenser flows through the liquid phase passage and flows into a plurality of equipment heat exchangers. By such circulation of the working fluid, the equipment temperature control device can cool the target equipment even when the equipment temperature adjusting unit is tilted.

1 Equipment temperature control device 10 Equipment temperature control unit 11 Equipment heat exchanger 50 Condenser 60 Liquid phase passage 21 1st gas phase passage 22 2nd gas phase passage 211 1st connection part 221 2nd connection part

Claims (17)

It is an equipment temperature control device that adjusts the temperature of the target equipment (2) by the phase change between the liquid phase and the gas phase of the working fluid.
Equipment temperature adjustment unit during cooling to the working fluid having the target device and the working fluid and the heat exchangeably configured heat exchanger for multiple devices (11 to 14) so as to evaporate the target device (10) When,
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit, and
A plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) for flowing the working fluid of the gas phase are provided between the device temperature adjusting unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the second connecting portion (221) .
The equipment temperature adjusting unit includes a plurality of heat exchangers for the equipment provided at positions separated in the front-rear direction of the vehicle, and the first connection unit provided in any one of the plurality of heat exchangers for the equipment. An equipment temperature control device having connecting passages (61, 62) connecting the second connecting portion . The first connection portion is provided in a predetermined heat exchanger for equipment arranged on the front side of the vehicle among a plurality of heat exchangers for equipment.
The second connection portion is provided in another heat exchanger for the equipment arranged on the rear side of the vehicle among the plurality of heat exchangers for the equipment.
The first gas phase passage has a portion (21a) extending upward or forward of the vehicle from the first connection portion.
The device temperature control device according to claim 1, wherein the second gas phase passage has a portion (22a) extending upward or rearward from the second connection portion. Wherein the at least a portion and the connecting passage of the first gas phase passage or the second gas phase passage constitute parallel portion (251) extending in a state of contact with or adjacent to each other, to claim 1 or 2 The equipment temperature control device described. The first to third aspects of claim 1 to 3 , wherein at least a part of the first gas phase passage and at least a part of the second vapor phase passage form a parallel portion (25) extending in contact with or adjacent to each other. The device temperature control device according to any one. Claimed that at least a part of the first gas phase passage or the second gas phase passage and the connecting passage have a double piping structure (26) in which the other pipe is provided inside one pipe. Item 2. The equipment temperature control device according to item 1 or 2 . Claimed that at least a part of the first gas phase passage and at least a part of the second gas phase passage have a double pipe structure (26) in which the other pipe is provided inside one pipe. Item 4. The device temperature control device according to any one of Items 1 to 5 . It is an equipment temperature control device that adjusts the temperature of the target equipment (2) by the phase change between the liquid phase and the gas phase of the working fluid.
A device temperature control unit (10) having a plurality of device heat exchangers (11 to 14) configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled. ,
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit, and
A plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) for flowing the working fluid of the gas phase are provided between the device temperature adjusting unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the second connecting portion (221).
The flow of the working fluid of the liquid phase provided in the first gas phase passage or the second gas phase passage from the first connection portion side or the second connection portion side of the gas phase passage to the condenser side. Controlled flow path area adjustment valves (80, 83, 86) and
A tilt sensor (82) for detecting the tilt of the device temperature adjusting unit is further provided.
When the inclination of the equipment temperature adjusting unit is detected by the inclination sensor, the flow path area adjusting valve moves from the first connection portion side or the second connection portion side of the gas phase passage to the condenser side. Equipment temperature control device that regulates the flow of working fluid in the liquid phase. It is an equipment temperature control device that adjusts the temperature of the target equipment (2) by the phase change between the liquid phase and the gas phase of the working fluid.
A device temperature control unit (10) having a plurality of device heat exchangers (11 to 14) configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled. ,
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit, and
A plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) for flowing the working fluid of the gas phase are provided between the device temperature adjusting unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the second connecting portion (221).
The flow of the working fluid of the liquid phase provided in the first gas phase passage or the second gas phase passage from the first connection portion side or the second connection portion side of the gas phase passage to the condenser side. Further equipped with a regulated flow path area adjusting valve (80, 83, 86),
The flow path area adjusting valve (83) is
A valve seat (84) provided on the inner wall of the gas phase passage and
When the first connection portion or the second connection portion of the gas phase passage is above the valve seat in the direction of gravity, the valve seat is seated by its own weight, and the first connection portion or the first connection portion of the gas phase passage. 2 An equipment temperature control device having a valve body (85) that separates from the valve seat when the connection portion is below the valve seat in the direction of gravity. It is an equipment temperature control device that adjusts the temperature of the target equipment (2) by the phase change between the liquid phase and the gas phase of the working fluid.
A device temperature control unit (10) having a plurality of device heat exchangers (11 to 14) configured so that the target device and the working fluid can exchange heat so that the working fluid evaporates when the target device is cooled. ,
A condenser (50) that dissipates heat from the working fluid of the gas phase and causes the working fluid of the condensed liquid phase to flow out.
A liquid phase passage (55) for flowing a liquid phase working fluid between the condenser and the equipment temperature control unit, and
A plurality of gas phase passages (21 to 24, 30 to 32, 40 to 42) for flowing the working fluid of the gas phase are provided between the device temperature adjusting unit and the condenser.
Of the plurality of gas phase passages, the first gas phase passage (21) is connected to the equipment temperature adjusting unit (211), and the second gas phase passage (22) is connected to the equipment temperature adjusting unit. It is located at a location horizontally separated from the second connecting portion (221).
The flow of the working fluid of the liquid phase provided in the first gas phase passage or the second gas phase passage from the first connection portion side or the second connection portion side of the gas phase passage to the condenser side. Further equipped with a regulated flow path area adjusting valve (80, 83, 86),
The flow path area adjusting valve (86) is
A valve seat (87) provided on the inner wall of the gas phase passage and
It has a valve body (88) that is seated on the valve seat by buoyancy when the working fluid of the liquid phase flows through the gas phase passage and is separated from the valve seat when the working fluid of the gas phase flows through the gas phase passage. Equipment temperature controller. The equipment temperature control device is installed in the vehicle and
The device temperature control device according to any one of claims 1 to 9, wherein the first connection portion and the second connection portion are located at locations separated from each other in the vehicle front-rear direction. When the equipment temperature adjusting portion is in the horizontal state, the liquid level (FL) of the working fluid is located in the middle of the heat exchanger for the equipment in the height direction, and the first connection portion and the second connection portion are The device temperature control device according to any one of claims 1 to 10, wherein the encapsulation amount of the working fluid is adjusted so as to be located above the liquid level of the working fluid in the device temperature adjusting section. When the equipment temperature adjusting portion is tilted at a predetermined angle, the liquid level of the working fluid is above one of the first connecting portion or the second connecting portion, and the other of the first connecting portion or the second connecting portion. The device temperature control device according to any one of claims 1 to 11, wherein the filling amount of the working fluid is adjusted so as to be on the lower side. The gas phase passage is between a confluence portion (30 to 32) that merges the working fluid flowing through the first gas phase passage and the working fluid flowing through the second gas phase passage, and between the confluence portion and the condenser. Consists of a confluence passage (40-42) through which the working fluid of the gas phase flows.
The device temperature control device according to any one of claims 1 to 12, wherein the merging portion is provided above the first connection portion and the second connection portion in the direction of gravity. The equipment temperature control according to claim 13, wherein when the equipment temperature adjusting portion is tilted at a predetermined angle, the encapsulation amount of the working fluid is adjusted so that the liquid level of the working fluid is below the confluence portion. apparatus. The first connection portion and the second connection portion according to any one of claims 7, 8 and 9 , wherein the first connection portion and the second connection portion are provided at positions separated in the horizontal direction from one heat exchanger for the device. Equipment temperature controller. The device heat exchanger has a shape having a longitudinal direction and a lateral direction when viewed from the direction of gravity, and is in direct contact with the target device or indirectly through a heat conductive member (113). Have and
The first connection portion and the second connection portion according to any one of claims 1 to 15, wherein the first connection portion and the second connection portion are provided at positions outside the heat exchange portion in the longitudinal direction of the heat exchanger for equipment. Equipment temperature controller. The first connection portion is provided at a position on the front side of the vehicle from the heat exchange portion of the heat exchanger for equipment.
The second connection portion is provided at a position on the rear side of the vehicle from the heat exchange portion of the heat exchanger for equipment.
The first gas phase passage has a portion (21a) extending upward or forward of the vehicle from the first connection portion.
The device temperature control device according to claim 16, wherein the second gas phase passage has a portion (22a) extending upward or rearward from the second connection portion.

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