JP2019199992A - Equipment temperature control device - Google Patents

Abstract

To provide an equipment temperature control device in which a plurality of heat exchange core parts are connected in parallel, and that reduces variations in cooling capacity of the respective heat exchange core parts.SOLUTION: In an equipment temperature control device 1, one working fluid circuit in which each of a plurality of heat exchange core parts 113a, 113b, and 113c and each of a plurality of capacitors 20A and 20B communicate with one another via gas phase flow passages 30, 111a, 111b, and 111c and liquid phase flow passages 40, 112a, 112b, and 112c is formed. The working fluid circuit is constituted so that when working fluid flows through each of the plurality of heat exchange core parts 113a, 113b, and 113c and each of the plurality of capacitors 20A and 20B, the whole of the working fluid flowing out of the plurality of heat exchange core parts 113a, 113b, and 113c does not merge.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a device temperature control device that adjusts the temperature of a target device by a phase change between a liquid phase and a gas phase of a working fluid.

  Patent Document 1 discloses a device temperature control device that adjusts the temperature of a target device by a phase change between a liquid phase and a gas phase of a working fluid. This equipment temperature control device includes a plurality of heat exchangers. The plurality of heat exchangers cool the target device by latent heat of vaporization when the liquid-phase working fluid evaporates.

  In patent document 1, each heat exchanger is not connected. Each heat exchanger and a condenser corresponding to each heat exchanger are connected. A plurality of independent working fluid circuits are formed.

JP 2017-11229 A

  By the way, the present inventors have studied an apparatus temperature control apparatus in which one condenser and a plurality of heat exchangers are connected to form one working fluid circuit. Below, this apparatus temperature control apparatus is called the apparatus temperature control apparatus of the examination example.

  In the apparatus temperature control apparatus of the examination example, the plurality of heat exchangers are sequentially arranged from the side closer to the condenser toward the side farther from the condenser. Each heat exchanger is connected in parallel so that the flow path length between each heat exchanger and the condenser is as short as possible. When each heat exchanger is connected in parallel, the liquid phase working fluid flowing out from the condenser flows into each heat exchanger, and the gas phase working fluid flowing out from each heat exchanger flows into the condenser. Means connected. In this apparatus temperature control apparatus, the working fluid that has flowed out of the condenser branches and flows toward each of the plurality of heat exchangers in the order closer to the condenser. The working fluid that has flowed out from each of the plurality of heat exchangers joins the condenser after being merged in order from the condenser.

  In the apparatus temperature control apparatus of the examination example, the circulation path of the working fluid when the working fluid circulates between the heat exchange core portion and the condenser of each heat exchanger is the heat exchange core portion of each heat exchanger. It depends on. For this reason, a difference in pressure loss occurs in the working fluid flowing through the circulation path in the heat exchange core portion of each heat exchanger. Due to this difference in pressure loss, variations occur in the height of the equivalent liquid level in each heat exchange core. The height of the equivalent liquid level is a theoretical liquid level height defined by the pressure balance. The higher the equivalent liquid level, the higher the cooling capacity of the heat exchange core. For this reason, the present inventor found a problem that variation in cooling capacity of each heat exchange core portion occurs due to variation in equivalent liquid level.

  In view of the above points, an object of the present invention is to suppress variation in cooling capacity of each heat exchange core part in an apparatus temperature control apparatus in which a plurality of heat exchange core parts are connected in parallel.

In order to achieve the above object, in the invention described in claim 1,
A 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.
A plurality of heat exchange core parts (113a, 113b, 113c) configured to be able to exchange heat with the target device so that the liquid-phase working fluid evaporates when the target device is cooled;
A plurality of condensers (20A, 20B) that dissipate heat and condense the vapor phase working fluid evaporated in the plurality of heat exchange core parts;
A gas phase flow path (30, 111a, 111b, 111c) for guiding a gas phase working fluid to a plurality of condensers;
A liquid phase flow path (40, 112a, 112b, 112c) for guiding the liquid phase working fluid to a plurality of heat exchange core parts,
The plurality of heat exchange core parts, the plurality of condensers, the gas phase flow path, and the liquid phase flow path are configured such that each of the plurality of heat exchange core parts and each of the plurality of condensers are gas phase flow paths and liquid phase flow paths. Forming a circuit of one working fluid communicating with each other via
When the working fluid flows through each of the plurality of heat exchange core portions and each of the plurality of condensers, the circuit is configured so that all of the working fluids flowing out from the plurality of heat exchange core portions do not merge.

  Here, in the apparatus temperature control apparatus of the examination example mentioned above, the working fluid which flowed out from the other heat exchange core part except the heat exchange core part closest to a condenser joins among several heat exchange core parts. The merged working fluid merges with the working fluid flowing out from the heat exchange core portion closest to the condenser, and then flows toward the condenser. Moreover, the working fluid that has flowed out of the condenser is divided into a flow toward the heat exchange core portion closest to the condenser and a flow toward the other heat exchange core portion. Thus, in the apparatus temperature control apparatus of the examination example, the circuit of the working fluid is configured so that all of the working fluids flowing out from the plurality of heat exchange core portions merge.

  For this reason, in the apparatus temperature control apparatus of the examination example, other heat exchanges among the gas phase flow paths are provided in the circulation path of the working fluid in which the working fluid circulates between each of the other heat exchange core units and the condenser. The part where the working fluid flowing out from the core part flows together and the part where the working fluid toward the other heat exchange core part flows together in the liquid phase flow path are included. On the other hand, these two portions are not included in the circulation path of the working fluid in which the working fluid circulates between the heat exchange core portion closest to the condenser and the condenser. In these two parts, the flow rate of the working fluid is high. The greater the flow rate of the working fluid, the greater the pressure loss of the working fluid. For this reason, the difference between the pressure loss of the working fluid flowing through the circulation path of the heat exchange core part closest to the condenser and the pressure loss of the working fluid flowing through the circulation path of the other heat exchange core part becomes large. This is one of the reasons why the difference in pressure loss of the working fluid flowing through each heat exchange core is large.

  The device temperature control device of the present invention is compared with the device temperature control device of the study example with the same number of heat exchange core parts. According to the apparatus temperature control apparatus of the present invention, the same working fluid circuit as that of the apparatus temperature control apparatus of the examination example is not configured. For this reason, in each circulation path in which the working fluid circulates between each heat exchange core unit and the plurality of condensers, the flow rate of the working fluid at the portion where the flow rate of the working fluid is maximum is adjusted to the device temperature control in the study example. The flow rate of the working fluid in the above two parts of the apparatus can be reduced. Alternatively, when the portion where the flow rate of the working fluid is maximum is the same as the flow rate of the working fluid in the above two portions in the device temperature control device of the study example, the length of the portion where the flow rate of the working fluid is maximum is shortened. can do. Thereby, the difference of the pressure loss which arises in the working fluid which flows through the circulation path of each heat exchange core part can be controlled. Therefore, variation in the cooling capacity of each heat exchange core can be suppressed.

  Reference numerals in parentheses attached to each component and the like indicate an example of a correspondence relationship between the component and the like and specific components described in the embodiments described later.

It is a perspective view which shows the whole structure of the apparatus temperature control apparatus of 1st Embodiment. It is a perspective view of the heat exchanger and battery module in FIG. It is sectional drawing of the heat exchanger and battery module in FIG. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of the comparative example 1. It is a figure which shows the heat exchange core part of each heat exchanger of the apparatus temperature control apparatus of the comparative example 1. FIG. It is a figure for demonstrating the relationship between the liquid level height of the working fluid in the inside of a heat exchange core part, and cooling capacity. It is a graph which shows the relationship between the liquid level height of a working fluid in the inside of a heat exchange core part, and thermal resistance. It is a figure which shows the liquid level height of each heat exchange core part in the apparatus temperature control apparatus of the comparative example 1. It is a figure which shows the temperature of the battery cell in each battery module of the apparatus temperature control apparatus of the comparative example 1. It is a mimetic diagram showing the whole device temperature control device composition of a 1st embodiment. It is a figure which shows the liquid level height of each heat exchange core part in the apparatus temperature control apparatus of 1st Embodiment. It is a figure which shows the temperature of the battery cell in each battery module of the apparatus temperature control apparatus of 1st Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 2nd Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 3rd Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 4th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 5th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of the comparative example 2. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 6th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 7th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of the comparative example 3. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 8th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 9th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 10th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 11th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of the comparative example 4. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 12th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 13th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 14th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 15th Embodiment. It is a schematic diagram which shows the whole structure of the apparatus temperature control apparatus of 16th Embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following embodiments, parts that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
The apparatus temperature control apparatus 1 of 1st Embodiment is demonstrated with reference to FIGS. The device temperature control device 1 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 cools or warms up a secondary battery (hereinafter referred to as “battery”) mounted on a vehicle and adjusts the temperature of the battery.

  First, the battery 2 as a target device for which the device temperature control device 1 performs temperature adjustment will be described. The large battery 2 installed in the vehicle is a battery pack (that is, a power storage device) in which a plurality of battery modules 2a, 2b, and 2c in which a plurality of battery cells 3 are combined is stored, such as under a vehicle seat or under a trunk room. Mounted on. The electric power stored in the battery 2 is supplied to the vehicle driving motor via an inverter or the like. The battery 2 self-heats when power is supplied while the vehicle is running. When the battery 2 reaches a high temperature, not only cannot a sufficient function be exhibited, but also deterioration is promoted. Therefore, it is necessary to limit output and input so that self-heating is reduced. Therefore, in order to ensure the output and input of the battery 2, a cooling device for maintaining the battery 2 at a predetermined temperature or less is required.

  In addition, in the season when the outside air temperature is high such as summer, the temperature of the battery 2 rises not only when the vehicle is running but also when the vehicle is parked. Further, the battery 2 is often arranged under the floor of a vehicle or under a trunk room, and although the amount of heat given to the battery 2 per unit time is small, the temperature of the battery 2 gradually rises due to being 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 maintain the temperature of the battery 2 below a predetermined temperature even during parking of the vehicle.

  Furthermore, the battery 2 is composed of a plurality of battery cells 3. In the battery 2, if the temperature of each battery cell 3 varies, the battery cell 3 is unevenly deteriorated and the power storage performance is lowered. This is because the battery 2 has a configuration in which a plurality of battery cells 3 are electrically connected in a series or parallel combination, and the input / output characteristics of the battery 2 are determined in accordance with the characteristics of the battery cell 3 that is most deteriorated. is there. Therefore, in order for the battery 2 to exhibit desired performance over a long period of time, it is important to equalize the temperature so as to reduce the temperature variation among the plurality of battery cells 3.

  In general, as other cooling devices for cooling the battery 2, an air-cooling cooling means using a blower and a cooling means utilizing the cold heat of a vapor compression refrigeration cycle are generally used. However, since the air-cooled cooling means using the blower only blows air in the passenger compartment, the cooling capacity is low. Moreover, since the air blown by the blower cools the battery 2 with the sensible heat of the air, the temperature difference between the upstream and downstream of the air flow becomes large, and the temperature variation among the plurality of battery cells 3 cannot be sufficiently suppressed. Moreover, 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 power while the vehicle is parked. This is undesirable because it leads to an increase in power consumption and an increase in noise.

  Therefore, the apparatus temperature control device 1 of the present embodiment employs a thermosiphon system that adjusts the temperature of the battery 2 by natural circulation of the working fluid without forcibly circulating the working fluid by a compressor.

  Next, the structure of the apparatus temperature control apparatus 1 is demonstrated. As shown in FIG. 1, the device temperature control device 1 includes a plurality of heat exchangers 11A, 11B, and 11C, a plurality of condensers 20A and 20B, a gas pipe 30, and a liquid pipe 40. The plurality of heat exchangers 11A, 11B, 11C, the plurality of condensers 20A, 20B, the gas pipe 30 and the liquid pipe 40 are separated into a flow path through which a gas-phase working fluid flows and a flow path through which a liquid-phase working fluid flows. A looped thermosiphon circuit is formed. A predetermined amount of working fluid is sealed in the thermosiphon circuit. As the working fluid, for example, a fluorocarbon refrigerant such as HFO-1234yf or HFC-134a is used. In addition, the upper side and the lower side indicated by the double arrows in the drawing indicate the upper side and the lower side in the direction of gravity in a state where the device temperature control device 1 is mounted on a vehicle or the like.

  In the present embodiment, as the plurality of heat exchangers 11A, 11B, and 11C, three heat exchangers 11A, 11B, and 11C of the first heat exchanger 11A, the second heat exchanger 11B, and the third heat exchanger 11C are used. It has been. The configuration of the plurality of heat exchangers 11A, 11B, and 11C is the same. The plurality of heat exchangers 11A, 11B, 11C are arranged in one direction in the order of the first heat exchanger 11A, the second heat exchanger 11B, and the third heat exchanger 11C.

  As shown in FIGS. 2 and 3, each of the heat exchangers 11A, 11B, 11C includes a cylindrical upper header tank 111a, 111b, 111c, a cylindrical lower header tank 112a, 112b, 112c, and a heat exchange core section. 113a, 113b, 113c. Each upper header tank 111a, 111b, 111c is provided in the position which becomes the gravity direction upper side among each heat exchanger 11A, 11B, 11C. Each upper header tank 111a, 111b, 111c forms the flow path through which the working fluid which flowed out from each heat exchange core part 113a, 113b, 113c flows. Each lower header tank 112a, 112b, 112c is provided in the position which becomes the gravity direction lower side among each heat exchanger 11A, 11B, 11C. Each of the lower header tanks 112a, 112b, and 112c forms therein a flow path through which a working fluid flowing into each of the heat exchange core portions 113a, 113b, and 113c flows. Each heat exchange core part 113a, 113b, 113c is configured to be able to exchange heat with the target device so that the liquid-phase working fluid evaporates when the target device is cooled. Each heat exchange core part 113a, 113b, 113c has a plurality of tubes that communicate the flow path in each upper header tank 111a, 111b, 111c with the flow path in each lower header tank 112a, 112b, 112c. Yes. Each heat exchange core part 113a, 113b, 113c may have a plurality of flow paths formed inside a plate-like member.

  The heat exchange core parts of the first heat exchanger 11A, the second heat exchanger 11B, and the third heat exchanger 11C are respectively replaced with a first heat exchange core part 113a, a second heat exchange core part 113b, and a third heat exchange. Called the core part 113c. The upper header tanks of the first heat exchanger 11A, the second heat exchanger 11B, and the third heat exchanger 11C are respectively referred to as a first upper header tank 111a, a second upper header tank 111b, and a third upper header tank 111c. Call. The lower header tanks of the first heat exchanger 11A, the second heat exchanger 11B, and the third heat exchanger 11C are respectively referred to as a first lower header tank 112a, a second lower header tank 112b, and a third lower header tank 112c. Call.

  Each component of each heat exchanger 11A, 11B, 11C is comprised with the metal with high heat conductivity, such as aluminum and copper, for example. In addition, each structural member of each heat exchanger 11A, 11B, 11C can also be comprised with materials with high heat conductivity other than a metal.

  Battery modules 2a, 2b, and 2c are installed outside the respective heat exchange core portions 113a, 113b, and 113c via electrically insulating heat conductive sheets 114a, 114b, and 114c. The heat conduction sheets 114a, 114b, and 114c ensure insulation between the heat exchange core portions 113a, 113b, and 113c and the battery modules 2a, 2b, and 2c. Furthermore, the thermal resistance between each heat exchange core part 113a, 113b, 113c and each battery module 2a, 2b, 2c becomes small.

  In the present embodiment, the plurality of battery cells 3 constituting each of the battery modules 2a, 2b, and 2c are arranged in a direction that intersects the direction of gravity. As shown in FIG. 3, each of the battery modules 2a, 2b, and 2c has a surface 6 opposite to the surface 5 on which the terminals 4 are provided, and the heat exchange sheets 114a, 114b, and 114c are used for heat exchange. It is installed in the core portions 113a, 113b, 113c. In addition, it is also possible to omit each heat conductive sheet 114a, 114b, 114c, and to directly connect each battery module 2a, 2b, 2c and each heat exchange core part 113a, 113b, 113c.

  Each of the battery modules 2a, 2b, and 2c can exchange heat with the working fluid inside each of the heat exchange core portions 113a, 113b, and 113c. When the plurality of battery cells 3 generate heat, the liquid-phase working fluid inside each heat exchange core portion 113a, 113b, 113c evaporates. Thereby, the several battery cell 3 is cooled equally by the evaporation latent heat of a working fluid.

  As shown in FIG. 2, outlets 115a, 115b, and 115c through which the working fluid flows out are provided at the longitudinal ends of the upper header tanks 111a, 111b, and 111c. The lower header tanks 112a, 112b, and 112c are respectively provided with inlets 116a, 116b, and 116c into which working fluid flows at the longitudinal ends thereof.

  As shown in FIG. 1, in the present embodiment, two condensers 20A and 20B, that is, a first condenser 20A and a second condenser 20B are used as the plurality of condensers 20A and 20B. The plurality of condensers 20A and 20B dissipate and condense the vapor-phase working fluid evaporated in the plurality of heat exchangers 11A, 11B, and 11C. The plurality of condensers 20 </ b> A and 20 </ b> B are heat exchangers that exchange heat between a gas-phase working fluid and a predetermined heat receiving medium. Examples of the predetermined heat receiving medium include air, cooling water circulating in the cooling water circuit, refrigerant circulating in the refrigeration cycle, and the like.

  The plurality of condensers 20A and 20B have inlets 22A and 22B into which a gas-phase working fluid flows and outlets 24A and 24B from which a liquid-phase working fluid flows out. The inflow ports 22A and 22B are provided above the outflow ports 24A and 24B in the gravity direction.

  The plurality of condensers 20A and 20B are arranged above the plurality of heat exchangers 11A, 11B, and 11C in the gravity direction. The plurality of condensers 20A and 20B are installed in an engine room in front of the vehicle (not shown).

  The gas pipe 30 forms therein a flow path for guiding the vapor-phase working fluid evaporated inside the plurality of heat exchangers 11A, 11B, and 11C to the plurality of condensers 20A and 20B. The liquid pipe 40 forms therein a flow path for guiding the liquid-phase working fluid condensed inside the plurality of condensers 20A, 20B to the plurality of heat exchangers 11A, 11B, 11C. The gas pipe 30 and the liquid pipe 40 connect a plurality of heat exchangers 11A, 11B, and 11C in parallel.

  The gas pipe 30 is connected to the outlet side of each heat exchanger 11A, 11B, 11C. The gas pipe 30 allows the outlet sides of the heat exchangers 11A, 11B, and 11C to communicate with each other. The gas pipe 30 is connected to the inlet side of the plurality of condensers 20A and 20B. The gas pipe 30 communicates the inlet sides of the plurality of condensers 20A and 20B.

  Specifically, the gas pipe 30 includes a first outlet pipe 302, a second outlet pipe 304, a third outlet pipe 306, a first outlet connection portion 308, a second outlet connection portion 310, and a third outlet. The connecting portion 312, the first outlet connecting pipe 314, the second outlet connecting pipe 316, the first inflow side pipe 318, and the second inflow side pipe 320 are included.

  One end of the first outlet pipe 302 is connected to the outlet 115a of the first heat exchanger 11A. One end of the second outlet pipe 304 is connected to the outlet 115b of the second heat exchanger 11B. One end of the third outlet pipe 306 is connected to the outlet 115c of the third heat exchanger 11C.

  At the first outlet connecting portion 308, the other end portion of the first outlet pipe 302 and the one end portion of the first outlet connecting pipe 314 are connected. At the second outlet connecting portion 310, the other end of the second outlet pipe 304, the other end of the first outlet connecting pipe 314, and the one end of the second outlet connecting pipe 316 are connected. Has been. At the third outlet connecting portion 312, the other end of the third outlet pipe 306 and the other end of the second outlet connecting pipe 316 are connected.

  The first outlet connecting pipe 314 connects the first outlet connecting portion 308 and the second outlet connecting portion 310. The second outlet connection pipe 316 connects the second outlet connection part 310 and the third outlet connection part 312.

  One end of the first inflow side pipe 318 is connected to the inlet 22A of the first condenser 20A. The other end portion of the first inflow side pipe 318 is connected to the first outlet connection portion 308. One end of the second inflow pipe 320 is connected to the inlet 22B of the second condenser 20B. The other end of the second inflow side pipe 320 is connected to a fourth outlet connection part 322 provided in the middle of the second outlet connection pipe 316.

  The liquid pipe 40 is connected to the inlet side of each heat exchanger 11A, 11B, 11C. The liquid pipe 40 allows the inlet sides of the heat exchangers 11A, 11B, and 11C to communicate with each other. The liquid pipe 40 is connected to the outlet sides of the plurality of condensers 20A and 20B. The liquid piping 40 allows the inlet sides of the plurality of condensers 20A and 20B to communicate with each other.

  Specifically, the liquid pipe 40 includes a first inlet pipe 402, a second inlet pipe 404, a third inlet pipe 406, a first inlet connection portion 408, a second inlet connection portion 410, and a third inlet. It includes a connection portion 412, a first inlet connection pipe 414, a second inlet connection pipe 416, a first outflow side pipe 418, and a second outflow side pipe 420.

  One end of the first inlet pipe 402 is connected to the inlet 116a of the first heat exchanger 11A. One end of the second inlet pipe 404 is connected to the inlet 116b of the second heat exchanger 11B. One end of the third inlet pipe 406 is connected to the inlet 116c of the third heat exchanger 11C.

  At the first inlet connection portion 408, the other end portion of the first inlet pipe 402 and the one end portion of the first inlet connection pipe 414 are connected. At the second inlet connection portion 410, the other end of the second inlet pipe 404, the other end of the first inlet connection pipe 414, and the one end of the second inlet connection pipe 416 are connected. Has been. At the third inlet connecting portion 412, the other end of the third inlet pipe 406 and the other end of the second inlet connecting pipe 416 are connected.

  The first inlet connection pipe 414 connects the first inlet connection portion 408 and the second inlet connection portion 410. The second inlet connection pipe 416 connects the second inlet connection part 410 and the third inlet connection part 412.

  One end of the first outlet pipe 418 is connected to the outlet 24A of the first condenser 20A. The other end of the first outflow pipe 418 is connected to the first inlet connection 408. One end of the second outflow side pipe 420 is connected to the outlet 24B of the second condenser 20B. The other end portion of the second outflow side pipe 420 is connected to a fourth inlet connection part 422 provided in the middle of the second inlet connection pipe 416.

  In addition, the shape of the gas piping 30 and the liquid piping 40 can be changed as appropriate in consideration of the mounting property on the vehicle.

  Next, the action | operation of the apparatus temperature control apparatus 1 is demonstrated using FIG.

  When the battery 2 is cooled, in each of the heat exchange core portions 113a, 113b, and 113c, the liquid-phase working fluid evaporates by exchanging heat with the battery modules 2a, 2b, and 2c. In this process, each battery module 2a, 2b, 2c is cooled by the latent heat of vaporization of the working fluid. Thereafter, the working fluid that has become a gas phase flows out from each of the heat exchange core portions 113a, 113b, and 113c.

  The working fluid that has flowed out of the first heat exchange core portion 113a sequentially flows through the first upper header tank 111a, the first outlet pipe 302, the first outlet connection portion 308, and the first inflow side pipe 318, and then the first condenser. Flows into 20A. The working fluid that has flowed out of the third heat exchange core portion 113c flows in order through the third upper header tank 111c, the third outlet pipe 306, the third outlet connection portion 312, the fourth outlet connection portion 322, and the second inflow side piping 320. After that, it flows into the second condenser 20B.

  The working fluid that has flowed out of the second heat exchange core part 113 b flows through the second upper header tank 111 b and the second outlet pipe 304 and then branches at the second outlet connection part 310. One working fluid branched off at the second outlet connecting portion 310 flows through the first outlet connecting pipe 314, the first outlet connecting portion 308, and the first inflow side piping 318 in this order, and then flows into the first condenser 20A. The other working fluid branched off at the second outlet connection part 310 flows through the fourth outlet connection part 322 and the second inflow side piping 320 in this order, and then flows into the second condenser 20B.

  In the plurality of condensers 20A and 20B, heat exchange between the gas-phase working fluid and a predetermined heat receiving medium is performed. Thereby, the working fluid condensed into a liquid phase by the plurality of condensers 20A and 20B flows out from the plurality of condensers 20A and 20B.

  The working fluid flowing out from the first condenser 20A flows down through the first outflow side pipe 418 by its own weight. The working fluid that has flowed down the first outflow side pipe 418 is branched at the first inlet connection portion 408. One working fluid branched at the first inlet connection portion 408 flows in order through the first inlet pipe 402 and the first lower header tank 112a, and then flows into the first heat exchange core portion 113a. The other working fluid branched at the first inlet connection portion 408 flows through the first inlet connection pipe 414, the second inlet connection section 410, the second inlet pipe 404, and the second lower header tank 112b in this order, and then the second heat It flows into the exchange core part 113b.

  The working fluid that has flowed out of the second condenser 20B flows down through the second outflow side pipe 420 by its own weight. The working fluid flowing down the second outflow side pipe 420 branches at the fourth inlet connection portion 422. One working fluid branched at the fourth inlet connection portion 422 flows through the third inlet connection portion 412, the third inlet pipe 406, and the third lower header tank 112c in this order, and then flows into the third heat exchange core portion 113c. . The other working fluid branched at the fourth inlet connection portion 422 flows through the second inlet connection portion 410, the second inlet pipe 404, and the second lower header tank 112b in this order, and then flows into the second heat exchange core portion 113b. . Thus, the apparatus temperature control apparatus 1 adjusts the temperature of the battery 2 by the phase change between the liquid phase and the gas phase of the working fluid.

  In the present embodiment, the gas pipe 30 and the upper header tanks 111a, 111b, 111c constitute a gas phase flow path for guiding the gas phase working fluid to the plurality of condensers 20A, 20B. The liquid pipe 40 and the lower header tanks 112a, 112b, 112c constitute a liquid phase flow path for guiding the liquid phase working fluid to the plurality of heat exchange core portions 113a, 113b, 113c. The plurality of heat exchange core parts 113a, 113b, 113c, the plurality of condensers 20A, 20B, the gas phase flow path and the liquid phase flow path are respectively connected to the plurality of heat exchange core parts 113a, 113b, 113c. Each of the vessels 20A and 20B forms a circuit of one working fluid that communicates with each other via a gas phase channel and a liquid phase channel.

  The first heat exchange core portion 113a is a heat exchange core portion having the shortest distance along the gas phase flow path from the first condenser 20A among the plurality of heat exchange core portions 113a, 113b, and 113c. The third heat exchange core portion 113c is a heat exchange core portion having the longest distance along the gas phase flow path from the first condenser 20A among the plurality of heat exchange core portions 113a, 113b, and 113c. In addition, the third heat exchange core portion 113c is a heat exchange core portion that is disposed at a position farthest from the first heat exchange core portion 113a among the plurality of heat exchange core portions 113a, 113b, and 113c.

  In the present embodiment, the first upper header tank 111a, the first outlet pipe 302, the first outlet connection part 308, the first outlet connection pipe 314, the second outlet connection part 310, the second outlet pipe 304, and the second upper part. The header tank 111b constitutes a first connection channel that connects the first heat exchange core part 113a and the second heat exchange core part 113b. The second outlet connecting pipe 316, the third outlet connecting part 312, the third outlet pipe 306, and the third upper header tank 111c connect the first connecting passage and the third heat exchange core part 113c. Is configured.

  The first condenser 20A is connected to the first outlet connection portion 308. For this reason, the first condenser 20A is connected to the first connection channel of the gas phase channel. The second condenser 20B is connected to the second outlet connection pipe 316. For this reason, the second condenser 20B is connected to the second connection channel of the gas phase channel.

  The first lower header tank 112a, the first inlet pipe 402, the first inlet connection part 408, the first inlet connection pipe 414, the second inlet connection part 410, the second inlet pipe 404 and the second lower header tank 112b are the first. A third connection channel that connects the heat exchange core portion 113a and the second heat exchange core portion 113b is configured. The second inlet connection pipe 416, the third inlet connection part 412, the third inlet pipe 406, and the third lower header tank 112c connect the third connection path and the third heat exchange core part 113c to the fourth connection path. Is configured.

  The first condenser 20A is connected to the first inlet connection 408. For this reason, the first condenser 20A is connected to the third connection channel of the liquid phase channel. The second condenser 20B is connected to the second inlet connection pipe 416. For this reason, the 2nd condenser 20B is connected to the 4th connection channel of a liquid phase channel.

  In other words, in the present embodiment, the gas phase flow path includes a first flow path that connects the first heat exchange core portion 113a and the first condenser 20A. The first heat exchange core portion 113a corresponds to one heat exchange core portion among the plurality of heat exchange core portions. The first condenser 20A corresponds to one condenser among the plurality of condensers. The first upper header tank 111a, the first outlet pipe 302, and the first inflow side pipe 318 correspond to the first flow path.

  Further, the gas phase flow path includes a second flow path that connects the first outlet connection portion 308 provided in the first flow path and the third heat exchange core portion 113c. The first outlet connection portion 308 corresponds to the gas phase side connection portion. The third heat exchange core part 113c corresponds to another one heat exchange core part among the plurality of heat exchange core parts. The third upper header tank 111c, the third outlet pipe 306, the second outlet connecting pipe 316, and the first outlet connecting pipe 314 correspond to the second flow path.

  Further, the gas phase flow path includes a third flow path for guiding the working fluid flowing out from the third heat exchange core portion 113c to the second condenser 20B without passing through the first outlet connection portion 308. The second condenser 20B corresponds to another one of the plurality of condensers. The second inflow side pipe 320 corresponds to the third flow path.

  And as shown in FIG. 1, the shortest length L1 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among gas phase flow paths is the 3rd heat exchange core part among gas phase flow paths. It is shorter than the shortest length L2 of the part from 113c to the 1st condenser 20A. The shortest length L1 is the length from the end on the outlet 115c side of the third upper header tank 111c to the inlet 22B of the second condenser 20B in the third heat exchange core portion 113c. The shortest length L2 is the length from the end on the outlet 115c side of the third upper header tank 111c to the inlet 22A of the first condenser 20A in the third heat exchange core 113c.

  Further, the liquid phase flow path includes a fourth flow path that connects the first heat exchange core portion 113a and the first condenser 20A. The first lower header tank 112a, the first inlet pipe 402, and the first outlet side pipe 418 correspond to the fourth flow path.

  Furthermore, the liquid phase flow path includes a fifth flow path that connects the first inlet connection portion 408 provided in the fourth flow path and the third heat exchange core portion 113c. The first inlet connection portion 408 corresponds to the liquid phase side connection portion. The third lower header tank 112c, the third inlet pipe 406, the second inlet connecting pipe 416, and the first inlet connecting pipe 414 correspond to the fifth flow path.

  Further, the liquid phase flow path includes a sixth flow path for guiding the working fluid flowing out from the second condenser 20B to the third heat exchange core section 113c without passing through the first inlet connection portion 408. The second outflow side pipe 420 corresponds to the sixth flow path.

  And as shown in FIG. 1, the shortest length L3 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among liquid phase flow paths is the 3rd heat exchange core part among liquid phase flow paths. It is shorter than the shortest length L4 of the part from 113c to the 1st condenser 20A. The shortest length L3 is a length from the end on the inlet 116c side of the third lower header tank 112c to the outlet 24B of the second condenser 20B in the third heat exchange core portion 113c. The shortest length L4 is the length from the end of the third lower header tank 112c on the inlet 116c side of the third heat exchange core 113c to the outlet 24A of the first condenser 20A.

  Next, the effect which the apparatus temperature control apparatus 1 of this embodiment show | plays is demonstrated compared with the apparatus temperature control apparatus J1 of the comparative example 1 shown in FIG. The device temperature control device J1 of Comparative Example 1 is the device temperature control device of the above-described study example. The apparatus temperature control apparatus J1 of the comparative example 1 is different from the apparatus temperature control apparatus 1 of the present embodiment in that it does not include the second condenser 20B, the second inflow side pipe 320, and the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus J1 of the comparative example 1 is the same as the apparatus temperature control apparatus 1 of this embodiment.

  As shown in FIG. 4, in the apparatus temperature control device J1 of the comparative example 1, the working fluid that has flowed out of the third heat exchange core portion 113c flows through the second outlet connection pipe 316 and then flows through the second outlet connection portion 310. The working fluid that has flowed out of the second heat exchange core portion 113b joins. The working fluid that has joined at the second outlet connecting portion 310 flows through the first outlet connecting pipe 314, and then joins with the working fluid that has flowed out of the first heat exchange core portion 113a at the first outlet connecting portion 308. The working fluid merged at the first outlet connection portion 308 flows through the first inflow side piping 318 and then flows into the first condenser 20A.

  The working fluid that has flowed out of the first condenser 20A flows through the first outflow side pipe 418, and then branches at the first inlet connection portion 408. One working fluid branched at the first inlet connection portion 408 flows into the first heat exchange core portion 113a. The other working fluid branched at the first inlet connection 408 flows through the first inlet connection pipe 414 and then branches at the second inlet connection 410. One working fluid branched at the second inlet connection portion 410 flows into the second heat exchange core portion 113b. The other working fluid branched at the second inlet connection portion 410 flows through the second inlet connection pipe 416 and the third inlet connection portion 412 in this order, and then flows into the third heat exchange core portion 113c.

  Thus, in the apparatus temperature control apparatus J1 of the comparative example 1, all the working fluids flowing out from the plurality of heat exchange core parts 113a, 113b, and 113c merge at the first outlet connection part 308. The combined working fluid flows out of the first condenser 20A and then branches at the first inlet connection 408.

  Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, and 113c. The total flow rate of the working fluid flowing out from each heat exchange core part 113a, 113b, 113c is defined as Gr.

  In this case, the flow rate of the working fluid flowing through the second outlet connection pipe 316 is (1/3) Gr. The flow rate of the working fluid flowing through the first outlet connecting pipe 314 is (2/3) Gr. The flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 is Gr. The flow rate of the working fluid flowing through the first inlet connection pipe 414 is (2/3) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 is (1/3) Gr.

  Moreover, in the apparatus temperature control apparatus J1 of the comparative example 1, the circulation path of each heat exchange core part 113a, 113b, 113c is compared. The circulation path of each heat exchange core part 113a, 113b, 113c is a path of the working fluid when the working fluid circulates between each heat exchange core part 113a, 113b, 113c and the first condenser 20A. is there.

  The circulation path of the third heat exchange core part 113c and the circulation path of the second heat exchange core part 113b include a first outlet connection pipe 314 and a first inlet connection pipe 414. That is, the circulation path of the third heat exchange core portion 113c and the circulation path of the second heat exchange core portion 113b include a portion where the flow rate of the working fluid is (2/3) Gr. On the other hand, the first outlet connection pipe 314 and the first inlet connection pipe 414 are not included in the circulation path of the first heat exchange core portion 113a. That is, the circulation path of the first heat exchange core portion 113a does not include a portion where the flow rate of the working fluid is (2/3) Gr.

  When the flow path cross-sectional area is constant, the flow rate of the working fluid increases as the flow rate of the working fluid flowing through the flow path increases. In general, the pressure loss of fluid is proportional to 1 to the square of the flow rate. For this reason, the pressure loss of the working fluid in the circulation path of the third heat exchange core part 113c and the circulation path of the second heat exchange core part 113b occurs at least in a part where the flow rate of the working fluid is (2/3) Gr. The pressure loss is larger than the pressure loss of the working fluid in the circulation path of the first heat exchange core portion 113a.

  Note that the pressure loss of the working fluid in the circulation path of the third heat exchange core portion 113c is added to the pressure loss generated at the portion where the flow rate of the working fluid is (1/3) Gr. For this reason, the pressure loss of the working fluid in the circulation path of the 3rd heat exchange core part 113c is the largest.

  Thus, each heat exchange includes that the circulation path of the third heat exchange core part 113c and the circulation path of the second heat exchange core part 113b include a portion where the flow rate of the working fluid is (2/3) Gr. This is one of the reasons why the difference in the pressure loss of the working fluid increases in the circulation path of the core portions 113a, 113b, and 113c. Note that the flow rate of the working fluid flowing through the first inflow side pipe 318 and the first outflow side pipe 418 is the largest. However, the 1st inflow side piping 318 and the 1st outflow side piping 418 are flow paths common to the circulation path of each heat exchange core part 113a, 113b, 113c. For this reason, the flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 does not affect the difference in pressure loss of the working fluid in the circulation path of each heat exchange core portion 113a, 113b, 113c.

  As shown in FIG. 5, due to the difference in pressure loss of the working fluid in the circulation path of each heat exchange core part 113a, 113b, 113c, the height h1 of the liquid level inside each heat exchange core part 113a, 113b, 113c, Variations occur in h2 and h3. In addition, in each heat exchange core part 113a, 113b, 113c, the liquid is gasified and it blows up and a liquid level cannot be observed. For this reason, the liquid level as used in this specification is the theoretical equivalent liquid level prescribed | regulated from a pressure balance. Moreover, in FIG. 5, the path | route of the working fluid which passes along the 1st heat exchange core part 113a, and the path | route of the working fluid which passes along the 3rd heat exchange core part 113c are shown by the arrow.

  Here, it is set as the magnitude | size (DELTA) P1 of the pressure loss which arises in the working fluid which flows through the 1st heat exchange core part 113a. The magnitude of the pressure loss generated in the working fluid flowing through the third heat exchange core portion 113c is assumed to be ΔP3. Let ρ be the density of the liquid-phase working fluid. Let g be the acceleration of gravity. At this time, the following equation (1) is established from the law of conservation of fluid energy. Equation (2) is derived from Equation (1).

ΔP3 + ρ × g × h3 = ΔP1 × ρ × g × h1 (1)
ΔP1-ΔP3 = ρ × g × (h1-h3) (2)
As shown in Expression (2), the difference in pressure loss appears as a difference in liquid level.

  As shown in FIG. 6, the cooling capacity of the heat exchange core part greatly depends on the height of the liquid level. When the liquid level is high, the cooling capacity is high because there is liquid in the entire vertical direction of the heat exchange core. When the liquid level is low, the upper part of the heat exchange core part does not cool, so the cooling capacity is low. When the liquid level is “medium” as shown in FIG. 6, the liquid is blown up by the bubbles, and the upper inner surface of the heat exchange core is wetted. For this reason, the cooling capacity is high.

  Therefore, as shown in FIG. 7, the higher the liquid level, the higher the cooling capacity of the heat exchange core part. The horizontal axis of the graph in FIG. 7 indicates the height of the liquid level when the position of the lower surface of the tube of the heat exchange core is 0 and the position of the upper surface of the tube is 10. The vertical axis in FIG. 7 indicates thermal resistance, that is, cooling capacity. Thermal resistance is the temperature difference between the object to be cooled and the working fluid. The smaller the thermal resistance, the higher the cooling capacity. However, when the liquid level is higher than a certain level, that is, when the liquid level is higher than the “medium” level shown in FIG. 6, the cooling capacity is saturating.

  For this reason, variation in the cooling capacity of each heat exchange core part 113a, 113b, 113c occurs due to variation in the liquid level. In this case, as shown in FIG. 8, in the 3rd heat exchange core part 113c with a large pressure loss, the height of a liquid level becomes lower than the liquid level height of the standard for ensuring desired cooling capacity. For this reason, the present inventors have found that the third heat exchange core portion 113c cannot obtain a desired cooling capacity.

  In particular, when the device temperature control device 1 is mounted on an electric vehicle as in the present embodiment, the above-described problem appears remarkably. As in the present embodiment, when the plurality of heat exchangers 11A, 11B, and 11C cool the battery 2 that supplies power for vehicle travel, the battery 2 is combined with the plurality of battery cells 3 as described above. The battery modules 2a, 2b and 2c are connected to each other. For this reason, the distance between the heat exchangers installed in each battery module 2a, 2b, 2c becomes long. A difference arises in the path | route of the working fluid which flows through each heat exchanger 11A, 11B, 11C, and the pressure loss difference of the working fluid which flows through each heat exchanger 11A, 11B, 11C becomes large. Then, as described above, the variation in cooling capacity occurs, and as a result, as shown in FIG. 9, the temperature variation of the battery cell 3 occurs between the battery modules 2a, 2b, and 2c. As a result, the overall performance of the battery 2 is degraded.

  In the present embodiment, as described above, the working fluid can flow as indicated by the arrows in FIG. That is, in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, 113c. The working fluid circuit is configured so that all of the working fluid flowing out of the fluid does not join.

  Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, and 113c. It is assumed that the working fluid that has flowed out of the second heat exchange core part 113b branches equally at the second outlet connection part 310. That is, it is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through each heat exchange core portion 113a, 113b, 113c is Gr.

  In this case, as shown in FIG. 10, the flow rate of the working fluid flowing through the first outlet connecting pipe 314 from the second outlet connecting portion 310 toward the first outlet connecting portion 308 is (1/6) Gr. The flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 is (1/2) Gr. The flow rate of the working fluid flowing through the first inlet connection pipe 414 is (1/6) Gr.

  The flow rate of the working fluid flowing through the second outlet connection pipe 316 from the second outlet connection part 310 toward the fourth outlet connection part 322 is (1/6) Gr. The flow rate of the working fluid flowing through the second outlet connecting pipe 316 from the third outlet connecting portion 312 toward the fourth outlet connecting portion 322 is (1/3) Gr. The flow rate of the working fluid flowing through the second inflow side piping 320 and the second outflow side piping 420 is (1/2) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 from the fourth inlet connection part 422 toward the second inlet connection part 410 is (1/6) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 from the fourth inlet connection part 422 toward the third inlet connection part 412 is (1/3) Gr.

  In the present embodiment, in the circulation path of each heat exchange core portion 113a, 113b, 113c, the flow rate at the portion where the flow rate of the working fluid is maximum is (1/2) Gr. The circulation path of each heat exchange core part 113a, 113b, 113c is the operation when the working fluid circulates between each heat exchange core part 113a, 113b, 113c and one of the condensers 20A, 20B. The fluid path. The circulation path of the first heat exchange core part 113a is a path through which the working fluid circulates between the first heat exchange core part 113a and the first condenser 20A. The circulation path of the third heat exchange core part 113c is a path through which the working fluid circulates between the third heat exchange core part 113c and the second condenser 20B. The circulation path of the second heat exchange core part 113b includes a path through which the working fluid circulates between the second heat exchange core part 113b and the first condenser 20A, and a second heat exchange core part 113b and the second condenser. Two circulation paths including a path through which the working fluid circulates between 20B and 20B are included.

  The flow rate at the portion where the flow rate of the working fluid is maximum is less than (2/3) Gr which is the flow rate in the first outlet connection pipe 314 and the first inlet connection pipe 414 in the first comparative example. This (2/3) Gr corresponds to Gr × (N−1) / N where N is the number of heat exchange core portions. In the present embodiment, N is 3.

  Thereby, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J1 of the comparative example 1, the pressure loss of the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b, 113c The difference of can be suppressed.

  For this reason, as shown in FIG. 11, the dispersion | variation in the liquid level height of each heat exchange core part 113a, 113b, 113c can be suppressed. Therefore, variation in the cooling capacity of each heat exchange core part 113a, 113b, 113c can be suppressed. In other words, as shown in FIG. 11, the liquid level height of each heat exchange core part 113a, 113b, 113c can be made higher than the desired liquid level. Therefore, the cooling capacity of each heat exchange core part 113a, 113b, 113c can be made more than desired performance. As a result, as shown in FIG. 12, the temperature variation of the battery cell 3 generated between the battery modules 2a, 2b, and 2c can be suppressed.

  Moreover, in this embodiment, each heat exchange core part 113a, 113b, 113c is connected to each of the 1st condenser 20A and the 2nd condenser 20B via the gaseous-phase flow path. For this reason, even when the working fluid does not flow to one of the first condenser 20A and the second condenser 20B, the working fluid is condensed on the other of the first condenser 20A and the second condenser 20B. be able to.

(Second Embodiment)
As shown in FIG. 13, in the present embodiment, the second condenser 20 </ b> B is connected to the third outlet connection portion 312 via the second inflow side pipe 320. The second condenser 20 </ b> B is connected to the third inlet connection portion 412 via the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus 1 is the same as 1st Embodiment.

  As described in the first embodiment, the third outlet connection portion 312 is a part of the second connection channel of the gas phase channel. The 3rd inlet connection part 412 is a part of 4th connection flow path of a liquid phase flow path. Therefore, also in the present embodiment, the second condenser 20B is connected to the second connection channel of the gas phase channel. The second condenser 20B is connected to the fourth connection channel of the liquid phase channel.

  Also in the present embodiment, as in the first embodiment, the gas phase flow path includes a first flow path, a second flow path, and a third flow path. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. And the shortest length L1 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B in a gaseous-phase flow path is the 1st condenser 20A from the 3rd heat exchange core part 113c in a gaseous-phase flow path. It is shorter than the shortest length L2 of the part up to.

  Further, similarly to the first embodiment, the liquid phase flow path includes a fourth flow path, a fifth flow path, and a sixth flow path. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. And the shortest length L3 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among liquid phase flow paths is the 1st condenser 20A from the 3rd heat exchange core part 113c among liquid phase flow paths. Is shorter than the shortest length L4.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, 113c The working fluid circuit is configured so that all of the outflowing working fluid does not join.

  Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, and 113c. It is assumed that the working fluid that has flowed out of the second heat exchange core part 113b branches equally at the second outlet connection part 310. That is, it is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through each heat exchange core portion 113a, 113b, 113c is Gr. In this case, the flow rate of the working fluid is as shown in FIG.

  In the present embodiment, in the circulation path of each heat exchange core portion 113a, 113b, 113c, the flow rate at the portion where the flow rate of the working fluid is maximum is (1/2) Gr. This flow rate is less than (2/3) Gr, which is the flow rate in the first outlet connecting pipe 314 and the first inlet connecting pipe 414 in Comparative Example 1. For this reason, the effect similar to 1st Embodiment is acquired.

(Third embodiment)
As shown in FIG. 14, in the present embodiment, the first condenser 20 </ b> A is connected to a fifth outlet connecting portion 324 provided in the first outlet connecting pipe 314 via the first inflow side pipe 318. . The first condenser 20A is connected to a fifth inlet connection portion 424 provided in the first inlet connection pipe 414 via the first outlet side pipe 418. The other structure of the apparatus temperature control apparatus 1 is the same as 1st Embodiment.

  As described in the first embodiment, the first outlet connecting pipe 314 is a part of the first connecting channel of the gas phase channel. The first outflow side pipe 418 is a part of the third connection channel of the liquid phase channel. Therefore, also in this embodiment, the first condenser 20A is connected to the first connection channel of the gas phase channel. The first condenser 20A is connected to the third connection channel of the liquid phase channel.

  In the present embodiment, the gas phase flow path includes a first flow path that connects the first heat exchange core portion 113a and the first condenser 20A. The first heat exchange core portion 113a corresponds to one heat exchange core portion among the plurality of heat exchange core portions. The first condenser 20A corresponds to one condenser among the plurality of condensers. A portion from the first outlet connecting portion 308 to the fifth outlet connecting portion 324 in the first upper header tank 111a, the first outlet pipe 302, and the first outlet connecting pipe 314 shown in FIG. The side pipe 318 corresponds to the first flow path.

  Further, the gas phase flow path includes a second flow path that connects the fifth outlet connection portion 324 provided in the first flow path and the third heat exchange core portion 113c. The fifth outlet connection portion 324 corresponds to the gas phase side connection portion. The third heat exchange core part 113c corresponds to another one heat exchange core part among the plurality of heat exchange core parts. Of the third upper header tank 111c, the third outlet pipe 306, the second outlet connecting pipe 316 and the first outlet connecting pipe 314 shown in FIG. 14, the second outlet connecting section 310 to the fifth outlet connecting section 324 are not shown in FIG. The portion up to this corresponds to the second flow path.

  Furthermore, the gas phase flow path includes a third flow path for guiding the working fluid flowing out from the third heat exchange core portion 113c to the second condenser 20B without passing through the fifth outlet connection portion 324. The second condenser 20B corresponds to another one of the plurality of condensers. The first inflow side piping 318 corresponds to the third flow path. And the shortest length L1 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B in a gaseous-phase flow path is the 1st condenser 20A from the 3rd heat exchange core part 113c in a gaseous-phase flow path. It is shorter than the shortest length L2 of the part up to.

  Further, the liquid phase flow path includes a fourth flow path that connects the first heat exchange core portion 113a and the first condenser 20A. The first lower header tank 112a, the first inlet pipe 402, the first inlet connection pipe 414 shown in FIG. 14 and the first outlet connection section 408 to the fifth inlet connection section 424 and the first outflow are not shown in FIG. The side pipe 418 corresponds to the fourth flow path.

  Further, the liquid phase flow path includes a fifth flow path that connects the fifth inlet connection portion 424 provided in the fourth flow path and the third heat exchange core portion 113c. The fifth inlet connection portion 424 corresponds to the liquid phase side connection portion. Of the third lower header tank 112c, the third inlet pipe 406, the second inlet connecting pipe 416, and the first inlet connecting pipe 414 shown in FIG. 14, the second inlet connecting section 410 to the fifth inlet connecting section 424 are not shown in FIG. The portion up to this corresponds to the fifth flow path.

  Further, the liquid phase flow path includes a sixth flow path for guiding the working fluid flowing out from the second condenser 20B to the third heat exchange core section 113c without passing through the fifth inlet connection portion 424. The second outflow side pipe 420 corresponds to the sixth flow path. And the shortest length L3 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among liquid phase flow paths is the 1st condenser 20A from the 3rd heat exchange core part 113c among liquid phase flow paths. Is shorter than the shortest length L4.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, 113c The working fluid circuit is configured so that all of the outflowing working fluid does not join.

  Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, and 113c. It is assumed that the working fluid that has flowed out of the second heat exchange core part 113b branches equally at the second outlet connection part 310. That is, it is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through each heat exchange core portion 113a, 113b, 113c is Gr. In this case, the flow rate of the working fluid is as shown in FIG.

  In the present embodiment, in the circulation path of each heat exchange core portion 113a, 113b, 113c, the flow rate at the portion where the flow rate of the working fluid is maximum is (1/2) Gr. This flow rate is less than (2/3) Gr, which is the flow rate in the first outlet connecting pipe 314 and the first inlet connecting pipe 414 in Comparative Example 1. For this reason, the effect similar to 1st Embodiment is acquired.

(Fourth embodiment)
As shown in FIG. 15, in the present embodiment, the second condenser 20 </ b> B is connected to a fifth outlet connecting portion 324 provided in the first outlet connecting pipe 314 via the second inflow side pipe 320. . The second condenser 20 </ b> B is connected to a fifth inlet connection portion 424 provided in the first inlet connection pipe 414 through the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus 1 is the same as 1st Embodiment.

  As described in the first embodiment, the first outlet connecting pipe 314 is a part of the first connecting channel of the gas phase channel. The first outflow side pipe 418 is a part of the third connection channel of the liquid phase channel. Therefore, in the present embodiment, both the first condenser 20A and the second condenser 20B are connected to the first connection channel of the gas phase channel. Both the first condenser 20A and the second condenser 20B are connected to the third connection channel of the liquid phase channel.

  Also in the present embodiment, as in the first embodiment, the gas phase flow path includes a first flow path, a second flow path, and a third flow path. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. And the shortest length L1 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B in a gaseous-phase flow path is the 1st condenser 20A from the 3rd heat exchange core part 113c in a gaseous-phase flow path. It is shorter than the shortest length L2 of the part up to.

  The liquid phase flow path includes a fourth flow path, a fifth flow path, and a sixth flow path, as in the first embodiment. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. And the shortest length L3 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among liquid phase flow paths is the 1st condenser 20A from the 3rd heat exchange core part 113c among liquid phase flow paths. Is shorter than the shortest length L4.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, 113c The working fluid circuit is configured so that all of the outflowing working fluid does not join.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, and 113c. It is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through each heat exchange core portion 113a, 113b, 113c is Gr. In this case, the flow rate of the working fluid is as shown in FIG.

  In the present embodiment, in the circulation path of each heat exchange core part 113a, 113b, 113c, the part where the flow rate of the working fluid is maximum is the second outlet connection part 310 and the fifth outlet connection in the first outlet connection pipe 314. And a portion between the fifth inlet connecting portion 424 and the second inlet connecting portion 410 in the first inlet connecting pipe 414. The flow rates in these portions are the same as (2/3) Gr, which is the flow rate in the first outlet connecting pipe 314 and the first inlet connecting pipe 414 in Comparative Example 1. However, according to the present embodiment, the length of the portion where the flow rate of the working fluid is maximum can be shortened as compared with Comparative Example 1. Thereby, the difference of the pressure loss which arises in the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b, 113c can be suppressed. Therefore, variation in the cooling capacity of each heat exchange core part 113a, 113b, 113c can be suppressed.

(Fifth embodiment)
As shown in FIG. 16, in this embodiment, two heat exchangers 11A and 11B of a first heat exchanger 11A and a second heat exchanger 11B are used as a plurality of heat exchangers. The first heat exchanger 11A, the second heat exchanger 11B, and the first condenser 20A are connected in the same manner as in the first embodiment. The second condenser 20B is connected to the second outlet connection portion 310 via the second inflow side pipe 320. The second condenser 20B is connected to the second inlet connection portion 410 via the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus 1 is the same as 1st Embodiment.

  In the present embodiment, the gas phase flow path includes a first flow path that connects the first heat exchange core portion 113a and the first condenser 20A. The first heat exchange core portion 113a corresponds to one heat exchange core portion among the plurality of heat exchange core portions. The first condenser 20A corresponds to one condenser among the plurality of condensers. The first upper header tank 111a, the first outlet pipe 302, and the first inflow side pipe 318 shown in FIG. 16 correspond to the first flow path, which are not shown in FIG.

  Furthermore, the gas phase flow path includes a second flow path that connects the first outlet connection portion 308 and the second heat exchange core portion 113b provided in the first flow path. The first outlet connection portion 308 corresponds to the gas phase side connection portion. The second heat exchange core portion 113b corresponds to another one heat exchange core portion among the plurality of heat exchange core portions. The second upper header tank 111b, the second outlet pipe 304, and the first outlet connecting pipe 314 shown in FIG. 16 correspond to the second flow path, which are not shown in FIG.

  Further, the gas phase flow path includes a third flow path for guiding the working fluid flowing out from the second heat exchange core portion 113b to the second condenser 20B without passing through the first outlet connection portion 308. The second condenser 20B corresponds to another one of the plurality of condensers. The second inflow side pipe 320 corresponds to the third flow path. As in the first embodiment, the shortest length L1 of the portion from the second heat exchange core portion 113b to the second condenser 20B in the gas phase flow path is the second heat exchange core in the gas phase flow path. It is shorter than the shortest length L2 of the part from the part 113b to the first condenser 20A.

  Further, the liquid phase flow path includes a fourth flow path that connects the first heat exchange core portion 113a and the first condenser 20A. The first lower header tank 112a, the first inlet pipe 402, and the first outlet pipe 418 shown in FIG. 16 correspond to the fourth flow path, which are not shown in FIG.

  Furthermore, the liquid phase flow path includes a fifth flow path that connects the first inlet connection portion 408 and the second heat exchange core portion 113b provided in the fourth flow path. The first inlet connection portion 408 corresponds to the liquid phase side connection portion. The second lower header tank 112b, the second inlet pipe 404, and the first inlet connecting pipe 414 shown in FIG. 16, which are not shown in FIG. 16, correspond to the fifth flow path.

  Furthermore, the liquid phase flow path includes a sixth flow path for guiding the working fluid flowing out from the second condenser 20B to the second heat exchange core section 113b without passing through the first inlet connection portion 408. The second outflow side pipe 420 corresponds to the sixth flow path. As in the first embodiment, the shortest length L3 of the portion from the second heat exchange core portion 113b to the second condenser 20B in the liquid phase flow path is the second heat exchange core in the liquid phase flow path. It is shorter than the shortest length L4 of the part from the part 113b to the 1st condenser 20A.

  Next, the effect which the apparatus temperature control apparatus 1 of this embodiment show | plays is demonstrated compared with the apparatus temperature control apparatus J2 of the comparative example 2 shown in FIG. The apparatus temperature control device J2 of Comparative Example 2 is different from the device temperature control device 1 of the present embodiment in that it does not include the second condenser 20B, the second inflow side piping 320, and the second outflow side piping 420. The other structure of the apparatus temperature control apparatus J2 of the comparative example 2 is the same as the apparatus temperature control apparatus 1 of this embodiment.

  In the device temperature control device J2 of the comparative example 2, the working fluid flows as indicated by an arrow in FIG. Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, and 113c. The total flow rate of the working fluid flowing out from each heat exchange core part 113a, 113b, 113c is defined as Gr. In this case, the flow rate of the working fluid flowing through the first outlet connecting pipe 314 and the first inlet connecting pipe 414 is (1/2) Gr. The flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 is Gr.

  In the device temperature control device J2 of Comparative Example 2, the circulation paths of the heat exchange core portions 113a and 113b are compared. The circulation path of the second heat exchange core portion 113b includes a first outlet connection pipe 314 and a first inlet connection pipe 414. In other words, the circulation path of the second heat exchange core portion 113b includes a portion where the flow rate of the working fluid is (1/2) Gr. On the other hand, the first outlet connection pipe 314 and the first inlet connection pipe 414 are not included in the circulation path of the first heat exchange core portion 113a. In other words, the circulation path of the first heat exchange core portion 113a does not include a portion where the flow rate of the working fluid is (1/2) Gr.

  For this reason, the pressure loss of the working fluid in the circulation path of the second heat exchange core portion 113b is at least the amount of the pressure loss that occurs in the portion where the flow rate of the working fluid is (1/2) Gr. It is larger than the pressure loss of the working fluid in the circulation path 113a. Thus, the fact that the flow path of the second heat exchange core portion 113b includes a portion where the flow rate of the working fluid is (1/2) Gr means that the working fluid flows in the circulation paths of the heat exchange core portions 113a and 113b. This is one of the reasons why the difference in pressure loss increases. Note that the flow rate of the working fluid flowing through the first inflow side pipe 318 and the first outflow side pipe 418 is the largest. However, the 1st inflow side piping 318 and the 1st outflow side piping 418 are flow paths common to the circulation path of each heat exchange core part 113a and 113b. For this reason, the flow rate of the working fluid flowing through the first inflow side pipe 318 and the first outflow side pipe 418 does not affect the difference in pressure loss of the working fluid in the circulation path of the heat exchange core portions 113a and 113b.

  On the other hand, in the present embodiment, the working fluid can flow as indicated by arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a and 113b and each of the plurality of condensers 20A and 20B, the working fluid that has flowed out of the plurality of heat exchange core portions 113a and 113b. The working fluid circuit is configured so that all of the fluids do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a and 113b. It is assumed that all of the working fluid flowing out from the first heat exchange core portion 113a flows into the first condenser 20A. It is assumed that all of the working fluid flowing out from the second heat exchange core part 113b flows into the second condenser 20B. That is, it is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through the heat exchange core portions 113a and 113b is defined as Gr.

  In this case, the flow rate of the working fluid is as shown in FIG. The flow rate of the working fluid flowing through the first outlet connecting pipe 314 and the first inlet connecting pipe 414 is zero. Therefore, the flow rate of the working fluid flowing through the first outlet connection pipe 314 and the first inlet connection pipe 414 is less than (1/2) Gr, which is the flow rate of the working fluid in the same portion of the comparative example 2. This (1/2) Gr corresponds to Gr × (N−1) / N where N is the number of heat exchange core portions. In this embodiment, N is 2.

  Thereby, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J2 of the comparative example 2, the difference of the pressure loss of the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b Can be suppressed. For this reason, the effect similar to 1st Embodiment is acquired.

  In other words, the first inflow side pipe 318 which is a part of the circulation path of the first heat exchange core part 113a corresponds to the second inflow side pipe 320 which is a part of the circulation path of the second heat exchange core part 113b. . The first outflow side pipe 418 which is a part of the circulation path of the first heat exchange core part 113a corresponds to the second outflow side pipe 420 which is a part of the circulation path of the second heat exchange core part 113b. The flow rates of the working fluid flowing through the first inflow side piping 318, the first outflow side piping 418, the second inflow side piping 320, and the second outflow side piping 420 are the same. For this reason, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J2 of the comparative example 2, the difference of the pressure loss of the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b Can be suppressed.

(Sixth embodiment)
As shown in FIG. 18, in this embodiment, two heat exchangers 11A and 11B are used as a plurality of heat exchangers, as in the fifth embodiment. The second condenser 20B is connected to a fifth outlet connecting portion 324 provided in the first outlet connecting pipe 314 via the second inflow side pipe 320. The second condenser 20 </ b> B is connected to a fifth inlet connection portion 424 provided in the first inlet connection pipe 414 through the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus 1 is the same as 5th Embodiment.

  Also in the present embodiment, as in the fifth embodiment, the gas phase flow path includes a first flow path, a second flow path, and a third flow path. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. And the shortest length L1 of the part from the 2nd heat exchange core part 113b to the 2nd condenser 20B among gas phase flow paths is 20A of the 1st condenser 20A from the 2nd heat exchange core part 113b among gas phase flow paths. It is shorter than the shortest length L2 of the part up to.

  The liquid phase flow path includes a fourth flow path, a fifth flow path, and a sixth flow path. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. And the shortest length L3 of the part from the 2nd heat exchange core part 113b to the 2nd condenser 20B among liquid phase flow paths is the 1st condenser 20A from the 2nd heat exchange core part 113b among liquid phase flow paths. Is shorter than the shortest length L4.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a and 113b and each of the plurality of condensers 20A and 20B, the working fluid that has flowed out of the plurality of heat exchange core portions 113a and 113b. The working fluid circuit is configured so that all of the fluids do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a and 113b. It is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through the heat exchange core portions 113a and 113b is defined as Gr. In this case, the flow rate of the working fluid is as shown in FIG.

  Of the first outlet connecting pipe 314, a portion between the fifth outlet connecting part 324 and the first outlet connecting part 308 and between the first inlet connecting part 408 and the fifth inlet connecting part 424 of the first inlet connecting pipe 414. The flow rate of the working fluid flowing through the intermediate portion is zero. Therefore, the flow rate of the working fluid flowing through these two portions is less than (1/2) Gr, which is the flow rate of the working fluid in the first outlet connection pipe 314 and the first inlet connection pipe 414 of Comparative Example 2. This (1/2) Gr corresponds to Gr × (N−1) / N where N is the number of heat exchange core portions. In this embodiment, N is 2.

  Thereby, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J2 of the comparative example 2, the difference of the pressure loss of the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b Can be suppressed. For this reason, the effect similar to 1st Embodiment is acquired.

  In other words, the portion between the second outlet connection portion 310 and the fifth outlet connection portion 324 and the second inflow side of the first outlet connection pipe 314, which is a part of the circulation path of the second heat exchange core portion 113b. The piping 320 corresponds to the first inflow side piping 318 that is a part of the circulation path of the first heat exchange core portion 113a. The flow rate of the working fluid flowing through them is the same. Further, a portion between the second inlet connecting portion 410 and the fifth inlet connecting portion 424 and the second outlet side piping in the first inlet connecting pipe 414, which is a part of the circulation path of the second heat exchange core portion 113b. 420 corresponds to the first outflow side pipe 418 which is a part of the circulation path of the first heat exchange core 113a. The flow rate of the working fluid flowing through them is the same. For this reason, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J2 of the comparative example 2, the difference of the pressure loss of the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b Can be suppressed.

(Seventh embodiment)
As shown in FIG. 19, in this embodiment, four heats of a first heat exchanger 11A, a second heat exchanger 11B, a third heat exchanger 11C, and a fourth heat exchanger 11D are used as a plurality of heat exchangers. An exchanger is used. In this embodiment, 4th heat exchanger 11D is added between the 2nd heat exchanger 11B and the 3rd heat exchanger 11C with respect to the apparatus temperature control apparatus 1 of 1st Embodiment. Therefore, the plurality of heat exchangers 11A, 11B, 11C, and 11D are arranged in one direction in the order of the first heat exchanger 11A, the second heat exchanger 11B, the fourth heat exchanger 11D, and the third heat exchanger 11C. Has been. Therefore, also in this embodiment, the 3rd heat exchange core part 113c is the heat exchange arrange | positioned in the position most distant from the 1st heat exchange core part 113a among the several heat exchange core parts 113a, 113b, 113c, 113d. It is a core part.

  The configuration of the fourth heat exchanger 11D is the same as that of the first heat exchanger 11A. The fourth heat exchanger 11D includes a fourth upper header tank (not shown), a fourth lower header tank (not shown), and a fourth heat exchange core portion 113d.

  The gas pipe 30 includes a fourth outlet pipe (not shown), a fourth outlet connecting portion 313, and a third outlet connecting pipe 317. The 4th outlet connection part 313 is connected to the 4th upper header tank via the 4th exit piping. The second outlet connecting pipe 316 connects the third outlet connecting portion 312 and the fourth outlet connecting portion 313. The third outlet connecting pipe 317 connects the second outlet connecting part 310 and the fourth outlet connecting part 313.

  The liquid pipe 40 includes a fourth inlet pipe (not shown), a fourth inlet connecting portion 413, and a third inlet connecting pipe 417. The 4th inlet connection part 413 is connected to the 4th lower header tank via the 4th inlet piping. The second inlet connecting pipe 416 connects the third inlet connecting portion 412 and the fourth inlet connecting portion 413. The third inlet connection pipe 417 connects the second inlet connection part 410 and the fourth inlet connection part 413.

  The other structure of the apparatus temperature control apparatus 1 is the same as 1st Embodiment.

  In the present embodiment, the third outlet connecting pipe 317, the second outlet connecting pipe 316, the third outlet connecting portion 312, the third outlet pipe 306 and the third upper header tank 111c not shown in FIG. The 2nd connection channel which connects 1 connection channel and the 3rd heat exchange core part 113c is constituted. The second condenser 20B is connected to the second outlet connection pipe 316. For this reason, the second condenser 20B is connected to the second connection channel of the gas phase channel.

  Further, the third inlet connecting pipe 417, the second inlet connecting pipe 416, the third inlet connecting portion 412, the third inlet pipe 406 and the third lower header tank 112c not shown in FIG. The 4th connection flow path which connects a path | route and the 3rd heat exchange core part 113c is comprised. The second condenser 20B is connected to the second inlet connection pipe 416. For this reason, the 2nd condenser 20B is connected to the 4th connection channel of a liquid phase channel.

  In other words, the present embodiment includes the first flow path, the second flow path, and the third flow path, as in the first embodiment. However, in the present embodiment, the third upper header tank 111c, the third outlet pipe 306, the second outlet connecting pipe 316, the third outlet connecting pipe 317 and the first outlet connecting pipe 314 which are not shown in FIG. 19 are shown. Corresponds to the second flow path. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. Similarly to the first embodiment, the shortest length L1 of the portion from the third heat exchange core portion 113c to the second condenser 20B in the gas phase channel is the third heat exchange core in the gas phase channel. It is shorter than the shortest length L2 of the part from the part 113c to the first condenser 20A.

  Further, similarly to the first embodiment, the liquid phase flow path includes a fourth flow path, a fifth flow path, and a sixth flow path. However, in the present embodiment, the third lower header tank 112c, the third inlet pipe 406, the second inlet connecting pipe 416, the third inlet connecting pipe 417, and the first inlet connecting pipe 414 which are not shown in FIG. 19 are shown. Corresponds to the fifth flow path. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. As in the first embodiment, the shortest length L3 of the portion from the third heat exchange core portion 113c to the second condenser 20B in the liquid phase flow path is the third heat exchange core in the liquid phase flow path. It is shorter than the shortest length L4 of the part from the part 113c to the first condenser 20A.

  Next, the effect which the apparatus temperature control apparatus 1 of this embodiment show | plays is demonstrated compared with the apparatus temperature control apparatus J3 of the comparative example 3 shown in FIG. The apparatus temperature adjustment device J3 of Comparative Example 3 is different from the apparatus temperature adjustment device 1 of the present embodiment in that it does not include the second condenser 20B, the second inflow side pipe 320, and the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus J3 of the comparative example 3 is the same as the apparatus temperature control apparatus 1 of this embodiment.

  In the apparatus temperature control device J3 of the comparative example 3, the working fluid flows as indicated by an arrow in FIG. Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, and 113d. The total flow rate of the working fluid flowing out from each heat exchange core part 113a, 113b, 113c, 113d is defined as Gr. In this case, the flow rate of the working fluid flowing through the first outlet connecting pipe 314 is (3/4) Gr. The flow rate of the working fluid flowing through the first inlet connection pipe 414 is (3/4) Gr.

  In the device temperature control device J3 of Comparative Example 3, the circulation paths of the heat exchange core portions 113a, 113b, 113c, and 113d are compared. The circulation path of the other heat exchange core parts 113b, 113c, 113d excluding the first heat exchange core part 113a includes a first outlet connection pipe 314 and a first inlet connection pipe 414. In other words, the circulation path of the other heat exchange core portions 113b, 113c, 113d includes a portion where the flow rate of the working fluid is (3/4) Gr. On the other hand, the first outlet connection pipe 314 and the first inlet connection pipe 414 are not included in the circulation path of the first heat exchange core portion 113a. That is, the circulation path of the first heat exchange core portion 113a does not include a portion where the flow rate of the working fluid is (3/4) Gr.

  For this reason, the pressure loss of the working fluid in the circulation path of the other heat exchange core parts 113b, 113c, 113d is the first of the pressure loss that occurs at the portion where the flow rate of the working fluid is (3/4) Gr. It is larger than the pressure loss of the working fluid in the circulation path of the heat exchange core part 113a. As described above, the heat exchange core portions 113a, 113b, and 113c each include a portion in which the flow rate of the working fluid is (3/4) Gr in the circulation path of the other heat exchange core portions 113b, 113c, and 113d. This is one of the reasons why the difference in pressure loss of the working fluid becomes large in the circulation path 113d.

  On the other hand, in the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in the present embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, The working fluid circuit is configured so that all the working fluids flowing out from 113c and 113d do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, and 113d. It is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20B. The total flow rate of the working fluid flowing through the heat exchange core portions 113a, 113b, 113c, and 113d is defined as Gr.

  In this case, the flow rate of the working fluid is as shown in FIG. The flow rate of the working fluid flowing through the first outlet connecting pipe 314 from the second outlet connecting portion 310 toward the first outlet connecting portion 308 is (1/4) Gr. The flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 is (1/2) Gr. The flow rate of the working fluid flowing through the first inlet connecting pipe 414 from the first inlet connecting portion 408 toward the second inlet connecting portion 410 is (1/4) Gr.

  The flow rate of the working fluid flowing through the second outlet connecting pipe 316 from the fourth outlet connecting portion 313 toward the fourth outlet connecting portion 322 is (1/4) Gr. The flow rate of the working fluid flowing through the second outlet connecting pipe 316 from the third outlet connecting portion 312 toward the fourth outlet connecting portion 322 is (1/4) Gr. The flow rate of the working fluid flowing through the second inflow side piping 320 and the second outflow side piping 420 is (1/2) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 from the fourth inlet connection part 422 toward the fourth inlet connection part 413 is (1/4) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 from the fourth inlet connection part 422 toward the third inlet connection part 412 is (1/4) Gr.

  In this embodiment, in the circulation path of each heat exchange core part 113a, 113b, 113c, 113d, the flow rate at the portion where the flow rate of the working fluid is maximum is (1/2) Gr. This flow rate is less than (3/4) Gr, which is the flow rate in the first outlet connecting pipe 314 and the first inlet connecting pipe 414 in Comparative Example 3. This (3/4) Gr corresponds to Gr × (N−1) / N, where N is the number of heat exchange core portions. In this embodiment, N is 4.

  Thereby, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J3 of the comparative example 3, the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b, 113c, 113d The difference in pressure loss can be suppressed. For this reason, the effect similar to 1st Embodiment is acquired.

(Eighth embodiment)
As shown in FIG. 21, in the present embodiment, four heat exchangers are used as a plurality of heat exchangers as in the seventh embodiment. The second condenser 20 </ b> B is connected to the third outlet connection portion 312 via the second inflow side pipe 320. The second condenser 20 </ b> B is connected to the third inlet connection portion 412 via the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus 1 is the same as 7th Embodiment.

  In the present embodiment, the gas phase flow path includes the first connection flow path described in the first embodiment and the second connection flow path described in the seventh embodiment. The second condenser 20B is connected to the third outlet connection portion 312. For this reason, the 2nd condenser 20B is connected to the 2nd connection channel.

  The liquid phase flow path includes the third connection flow path described in the first embodiment and the fourth connection flow path described in the seventh embodiment. The second condenser 20B is connected to the third inlet connection portion 412. For this reason, the 2nd condenser 20B is connected to the 4th connection channel.

  In other words, in the present embodiment, the gas phase flow path includes the first flow path, the second flow path, and the third flow path described in the seventh embodiment. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. And the shortest length L1 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B in a gaseous-phase flow path is the 1st condenser 20A from the 3rd heat exchange core part 113c in a gaseous-phase flow path. It is shorter than the shortest length L2 of the part up to.

  The liquid phase flow path includes the fourth flow path, the fifth flow path, and the sixth flow path described in the seventh embodiment. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. And the shortest length L3 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among liquid phase flow paths is the 1st condenser 20A from the 3rd heat exchange core part 113c among liquid phase flow paths. Is shorter than the shortest length L4.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in the present embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, The working fluid circuit is configured so that all the working fluids flowing out from 113c and 113d do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, and 113d. It is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through the heat exchange core portions 113a, 113b, 113c, and 113d is defined as Gr.

  In this case, the flow rate of the working fluid is as shown in FIG. The flow rate of the working fluid flowing through the first outlet connecting pipe 314 from the second outlet connecting portion 310 toward the first outlet connecting portion 308 is (1/4) Gr. The flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 is (1/2) Gr. The flow rate of the working fluid flowing through the first inlet connecting pipe 414 from the first inlet connecting portion 408 toward the second inlet connecting portion 410 is (1/4) Gr.

  The flow rate of the working fluid flowing through the second outlet connecting pipe 316 from the fourth outlet connecting portion 313 toward the third outlet connecting portion 312 is (1/4) Gr. The flow rate of the working fluid flowing through the second inflow side piping 320 and the second outflow side piping 420 is (1/2) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 from the third inlet connection portion 412 toward the fourth inlet connection portion 413 is (1/4) Gr.

  In this embodiment, in the circulation path of each heat exchange core part 113a, 113b, 113c, 113d, the flow rate at the portion where the flow rate of the working fluid is maximum is (1/2) Gr. Thereby, according to the apparatus temperature control apparatus 1 of this embodiment, compared with the apparatus temperature control apparatus J3 of the comparative example 3, the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b, 113c, 113d The difference in pressure loss can be suppressed. For this reason, the effect similar to 1st Embodiment is acquired.

(Ninth embodiment)
As shown in FIG. 22, in this embodiment, four heat exchangers are used as a plurality of heat exchangers, as in the seventh embodiment. The second condenser 20B is connected to a fifth outlet connecting portion 324 provided in the first outlet connecting pipe 314 via the second inflow side pipe 320. The second condenser 20 </ b> B is connected to a fifth inlet connection portion 424 provided in the first inlet connection pipe 414 through the second outflow side pipe 420. The other structure of the apparatus temperature control apparatus 1 is the same as 7th Embodiment.

  In the present embodiment, the gas phase flow path includes the first connection flow path described in the first embodiment and the second connection flow path described in the seventh embodiment. The second condenser 20B is connected to the first outlet connection pipe 314. For this reason, the 2nd condenser 20B is connected to the 1st connection channel.

  The liquid phase flow path includes the third connection flow path described in the first embodiment and the fourth connection flow path described in the seventh embodiment. The second condenser 20B is connected to the first inlet connection pipe 414. For this reason, the 2nd condenser 20B is connected to the 3rd connection channel.

  In other words, in the present embodiment, the gas phase flow path includes the first flow path, the second flow path, and the third flow path described in the seventh embodiment. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. And the shortest length L1 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B in a gaseous-phase flow path is the 1st condenser 20A from the 3rd heat exchange core part 113c in a gaseous-phase flow path. It is shorter than the shortest length L2 of the part up to.

  The liquid phase flow path includes the fourth flow path, the fifth flow path, and the sixth flow path described in the seventh embodiment. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. And the shortest length L3 of the part from the 3rd heat exchange core part 113c to the 2nd condenser 20B among liquid phase flow paths is the 1st condenser 20A from the 3rd heat exchange core part 113c among liquid phase flow paths. Is shorter than the shortest length L4.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in the present embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, 113b, The working fluid circuit is configured so that all the working fluids flowing out from 113c and 113d do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, and 113d. It is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20. The total flow rate of the working fluid flowing through the heat exchange core portions 113a, 113b, 113c, and 113d is defined as Gr.

  In this case, the flow rate of the working fluid is as shown in FIG. In the present embodiment, in the circulation path of each heat exchange core part 113a, 113b, 113c, 113d, the part where the flow rate of the working fluid is maximum is the second outlet connection part 310 and the fifth part of the first outlet connection pipe 314. A portion between the outlet connection portion 324 and a portion between the fifth inlet connection portion 424 and the second inlet connection portion 410 in the first inlet connection pipe 414. The flow rates in these portions are the same as (3/4) Gr, which is the flow rate in the first outlet connection pipe 314 and the first inlet connection pipe 414 in Comparative Example 3. However, according to the present embodiment, the length of the portion where the flow rate of the working fluid is maximum can be shortened as compared with the comparative example 3. Thereby, the difference of the pressure loss which arises in the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b, 113c, 113d can be suppressed. Therefore, variation in the cooling capacity of each heat exchange core part 113a, 113b, 113c, 113d can be suppressed.

(10th Embodiment)
As shown in FIG. 23, the apparatus temperature control apparatus 1 of this embodiment differs from the apparatus temperature control apparatus 1 of 8th Embodiment of FIG. 21 by the point which does not have the 3rd exit connection piping 317. The other structure of the apparatus temperature control apparatus 1 is the same as 8th Embodiment. In the present embodiment, as shown in FIG. 23, the working fluid flows in the same manner as in the eighth embodiment. For this reason, according to this embodiment, the effect similar to 8th Embodiment is acquired.

  As described above, the gas pipe 30 may not communicate with some adjacent heat exchange core portions among the plurality of heat exchange core portions. In this case, the liquid piping 40 makes each heat exchange core part communicate. As a result, also in the present embodiment, each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d and each of the plurality of condensers 20A, 20B are mutually connected via the gas phase channel and the liquid phase channel. A circuit of one working fluid that communicates is formed.

  However, in the circulation path of each heat exchange core portion 113a, 113b, 113c, 113d, the flow rate at the portion where the flow rate of the working fluid is maximum is Gr × (N− where N is the number of heat exchange core portions. 1) It is necessary to form a circuit so as to be less than / N. When the number of heat exchange core parts is 4, as in this embodiment, the second and third heat exchange core parts 113b and 113d are counted from the first heat exchange core part 113a among the plurality of heat exchange core parts. May not be communicated by the gas pipe 30.

  Moreover, unlike this embodiment, the liquid piping 40 does not need to connect some adjacent heat exchange core parts among several heat exchange core parts. In this case, the gas piping 30 makes each heat exchange core part communicate. Also in this case, each of the plurality of heat exchange core portions 113a, 113b, 113c, and 113d and each of the plurality of condensers 20A and 20B communicate with each other through the gas phase channel and the liquid phase channel. A working fluid circuit is formed.

(Eleventh embodiment)
As shown in FIG. 24, in this embodiment, five heat exchangers are used as a plurality of heat exchangers. In the present embodiment, a fifth heat exchanger 11E is added between the second heat exchanger 11B and the fourth heat exchanger 11D with respect to the apparatus temperature control device 1 of the eighth embodiment shown in FIG. ing. Therefore, the plurality of heat exchangers 11A, 11B, 11C, 11D, and 11E include the first heat exchanger 11A, the second heat exchanger 11B, the fifth heat exchanger 11E, and the fourth heat exchanger 11D in one direction. The third heat exchanger 11C is arranged in this order. Therefore, also in this embodiment, the 3rd heat exchange core part 113c was arrange | positioned in the position most distant from the 1st heat exchange core part 113a among several heat exchange core parts 113a, 113b, 113c, 113d, and 113e. It is a heat exchange core part.

  The configuration of the fifth heat exchanger 11E is the same as that of the first heat exchanger 11A. The fifth heat exchanger 11E includes a fifth upper header tank (not shown), a fifth lower header tank (not shown), and a fifth heat exchange core portion 113e.

  The gas pipe 30 includes a fifth outlet pipe (not shown), a fifth outlet connection portion 315, and a fourth outlet connection pipe 319. The fifth outlet connection portion 315 is connected to the fifth upper header tank via the fifth outlet pipe. The third outlet connecting pipe 317 connects the fourth outlet connecting portion 313 and the fifth outlet connecting portion 315. The fourth outlet connection pipe 319 connects the second outlet connection part 310 and the fifth outlet connection part 315.

  The liquid pipe 40 includes a fifth inlet pipe (not shown), a fifth inlet connection portion 415, and a fourth inlet connection pipe 419. The fifth inlet connection portion 415 is connected to the fifth lower header tank via the fifth inlet pipe. The third inlet connecting pipe 417 connects the fourth inlet connecting portion 413 and the fifth inlet connecting portion 415. The fourth inlet connecting pipe 419 connects the second inlet connecting part 410 and the fifth inlet connecting part 415.

  Other configurations of the device temperature control apparatus 1 other than the above are the same as those in the eighth embodiment.

  In the present embodiment, the gas phase flow path includes the first connection flow path described in the first embodiment. Further, the gas phase flow path includes a second connection flow path that connects the first connection flow path and the third heat exchange core portion 113c. The fourth outlet connecting pipe 319, the third outlet connecting pipe 317, the second outlet connecting pipe 316, the third outlet connecting portion 312, the third outlet pipe 306 and the third upper header tank 111c which are not shown in FIG. The 2nd connection flow path is comprised. The second condenser 20B is connected to the third outlet connection portion 312. For this reason, the 2nd condenser 20B is connected to the 2nd connection channel.

  The liquid phase flow path includes the third connection flow path described in the first embodiment. Furthermore, the liquid phase flow path includes a fourth connection flow path that connects the third connection flow path and the third heat exchange core portion 113c. 24 includes a fourth inlet connection pipe 419, a third inlet connection pipe 417, a second inlet connection pipe 416, a third inlet connection portion 412, a third inlet pipe 406 and a third lower header tank 112c which are not shown in FIG. The 4th connection flow path is comprised. The second condenser 20B is connected to the third inlet connection portion 412. For this reason, the 2nd condenser 20B is connected to the 4th connection channel.

  In other words, also in the present embodiment, the gas phase flow path includes the first flow path, the second flow path, and the third flow path, as in the first embodiment. However, in this embodiment, the third upper header tank 111c, the third outlet pipe 306, the second outlet connecting pipe 316, the third outlet connecting pipe 317, and the fourth outlet connecting pipe 319 which are not shown in FIG. The first outlet connecting pipe 314 corresponds to the second flow path. Also in this embodiment, the 2nd inflow side piping 320 is equivalent to a 3rd flow path. Similarly to the first embodiment, the shortest length L1 of the portion from the third heat exchange core portion 113c to the second condenser 20B in the gas phase channel is the third heat exchange core in the gas phase channel. It is shorter than the shortest length L2 of the part from the part 113c to the first condenser 20A.

  In addition, the liquid phase flow path includes the fourth flow path, the fifth flow path, and the sixth flow path, as in the first embodiment. However, in this embodiment, the third lower header tank 112c, the third inlet pipe 406, the second inlet connecting pipe 416, the third inlet connecting pipe 417, and the fourth inlet connecting pipe 419 which are not shown in FIG. The first inlet connection pipe 414 corresponds to the fifth flow path. Also in this embodiment, the 2nd outflow side piping 420 is equivalent to a 6th flow path. As in the first embodiment, the shortest length L3 of the portion from the third heat exchange core portion 113c to the second condenser 20B in the liquid phase flow path is the third heat exchange core in the liquid phase flow path. It is shorter than the shortest length L4 of the part from the part 113c to the first condenser 20A.

  Next, the effect which the apparatus temperature control apparatus 1 of this embodiment show | plays is demonstrated compared with the apparatus temperature control apparatus J4 of the comparative example 4 shown in FIG. The apparatus temperature control device J4 of Comparative Example 4 is different from the device temperature control device 1 of the present embodiment in that it does not include the second condenser 20B, the second inflow side piping 320, and the second outflow side piping 420. The other structure of the apparatus temperature control apparatus J4 of the comparative example 4 is the same as the apparatus temperature control apparatus 1 of this embodiment.

  In the apparatus temperature control device J4 of the comparative example 4, the working fluid flows as indicated by an arrow in FIG. Here, it is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, 113d, and 113e. The total flow rate of the working fluid flowing out from each heat exchange core part 113a, 113b, 113c, 113d, 113e is defined as Gr. In this case, the flow rate of the working fluid flowing through the first outlet connection pipe 314 is (4/5) Gr. The flow rate of the working fluid flowing through the first inlet connection pipe 414 is (4/5) Gr.

  In the device temperature control device J4 of Comparative Example 4, the circulation paths of the heat exchange core portions 113a, 113b, 113c, 113d, and 113e are compared. The circulation path of the other heat exchange core parts 113b, 113c, 113d, and 113e excluding the first heat exchange core part 113a includes a first outlet connection pipe 314 and a first inlet connection pipe 414. That is, the circulation path of the other heat exchange core portions 113b, 113c, 113d, and 113e includes a portion where the flow rate of the working fluid is (4/5) Gr. On the other hand, the first outlet connection pipe 314 and the first inlet connection pipe 414 are not included in the circulation path of the first heat exchange core portion 113a. In other words, the circulation path of the first heat exchange core portion 113a does not include a portion where the flow rate of the working fluid is (4/5) Gr.

  For this reason, the pressure loss of the working fluid in the circulation path of the other heat exchange core portions 113b, 113c, 113d, and 113e is at least the amount of pressure loss that occurs in the portion where the flow rate of the working fluid is (4/5) Gr, It is larger than the pressure loss of the working fluid in the circulation path of the first heat exchange core portion 113a. As described above, the heat exchange core portions 113b, 113c, 113d, and 113e include portions where the flow rate of the working fluid is (4/5) Gr in the circulation path of each of the heat exchange core portions 113b, 113c, 113d, and 113e. , 113c, 113d, 113e is one of the reasons why the difference in pressure loss of the working fluid becomes large.

  On the other hand, in the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d, 113e and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, The working fluid circuit is configured so that all of the working fluids flowing out from 113b, 113c, 113d, and 113e do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, 113d, and 113e. It is assumed that the working fluid flows evenly through the plurality of condensers 20A and 20B. The total flow rate of the working fluid flowing through the heat exchange core portions 113a, 113b, 113c, 113d, and 113e is Gr.

  In this case, the flow rate of the working fluid is as shown in FIG. The flow rate of the working fluid flowing through the fourth outlet connecting pipe 319 from the fifth outlet connecting portion 315 toward the second outlet connecting portion 310 is (1/10) Gr. The flow rate of the working fluid flowing through the first outlet connecting pipe 314 from the second outlet connecting portion 310 toward the first outlet connecting portion 308 is (3/10) Gr. The flow rate of the working fluid flowing through the first inflow side piping 318 and the first outflow side piping 418 is (1/2) Gr. The flow rate of the working fluid flowing through the first inlet connection pipe 414 from the first inlet connection portion 408 toward the second inlet connection portion 410 is (3/10) Gr. The flow rate of the working fluid flowing through the fourth inlet connecting pipe 419 from the second inlet connecting portion 410 toward the fifth inlet connecting portion 415 is (1/10) Gr.

  The flow rate of the working fluid flowing through the third outlet connecting pipe 317 from the fifth outlet connecting portion 315 toward the fourth outlet connecting portion 313 is (1/10) Gr. The flow rate of the working fluid flowing through the second outlet connecting pipe 316 from the fourth outlet connecting portion 313 toward the third outlet connecting portion 312 is (3/10) Gr. The flow rate of the working fluid flowing through the second inflow side piping 320 and the second outflow side piping 420 is (1/2) Gr. The flow rate of the working fluid flowing through the second inlet connection pipe 416 from the third inlet connection part 412 toward the fourth inlet connection part 413 is (3/10) Gr. The flow rate of the working fluid flowing through the third inlet connecting pipe 417 from the fourth inlet connecting portion 413 toward the fifth inlet connecting portion 415 is (1/10) Gr.

  In the present embodiment, in the circulation path of each heat exchange core portion 113a, 113b, 113c, 113d, 113e, the flow rate at the portion where the flow rate of the working fluid is maximum is (1/2) Gr. This is less than (4/5) Gr which is the flow rate in the first outlet connecting pipe 314 and the first inlet connecting pipe 414 in the comparative example 4. Thereby, the difference of the pressure loss which arises in the working fluid which flows through the circulation path of each heat exchange core part 113a, 113b, 113c, 113d, 113e can be suppressed. Therefore, variation in the cooling capacity of each heat exchange core part 113a, 113b, 113c, 113d, 113e can be suppressed.

(Twelfth embodiment)
As shown in FIG. 26, the device temperature adjustment device 1 of the present embodiment is different from the device temperature adjustment device 1 of the eleventh embodiment of FIG. 24 in that the third outlet connection pipe 317 is not provided. The other structure of the apparatus temperature control apparatus 1 is the same as the apparatus temperature control apparatus 1 of 11th Embodiment. Also in the present embodiment, each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d, and 113e and each of the plurality of condensers 20A and 20B communicate with each other through a gas phase channel and a liquid phase channel. A working fluid circuit is formed.

  In the present embodiment, the working fluid can flow as indicated by the arrows in FIG. Also in this embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c, 113d, 113e and each of the plurality of condensers 20A, 20B, the plurality of heat exchange core portions 113a, The working fluid circuit is configured so that all of the working fluids flowing out from 113b, 113c, 113d, and 113e do not merge.

  It is assumed that the working fluid flows evenly through the heat exchange core portions 113a, 113b, 113c, 113d, and 113e. The total flow rate of the working fluid flowing through the heat exchange core portions 113a, 113b, 113c, 113d, and 113e is Gr. In this case, the flow rate of the working fluid is as shown in FIG.

  In the present embodiment, the flow rate at the portion where the flow rate of the working fluid is maximum in the circulation path of each heat exchange core portion 113a, 113b, 113c, 113d, 113e is (3/5) Gr. This is less than (4/5) Gr which is the flow rate in the first outlet connecting pipe 314 and the first inlet connecting pipe 414 in the comparative example 4. Therefore, the same effect as the first embodiment can be obtained.

  As described above, the gas pipe 30 may not communicate with some adjacent heat exchange core portions among the plurality of heat exchange core portions. However, in the circulation path of each heat exchange core part 113a, 113b, 113c, 113d, 113e, the flow rate at the portion where the flow rate of the working fluid is maximum is Gr × (N where the number of heat exchange core parts is N. It is necessary to form the circuit so that it is less than (N-1) / N.

  Moreover, unlike this embodiment, the liquid piping 40 does not need to connect some adjacent heat exchange core parts among several heat exchange core parts. In this case, the gas piping 30 makes each heat exchange core part communicate.

(13th Embodiment)
As shown in FIG. 27, in this embodiment, three condensers of a first condenser 20A, a second condenser 20B, and a third condenser 20C are used as a plurality of condensers. In this embodiment, the 3rd condenser 20C is added with respect to the apparatus temperature control apparatus 1 of 1st Embodiment of FIG. The inflow side of the third condenser 20C is connected to the first outlet connection pipe 314 via the third inflow side pipe 326. The outflow side of the third condenser 20C is connected to the first inlet connection pipe 414 via the third outflow side pipe 426. The other structure of the apparatus temperature control apparatus 1 is the same as the apparatus temperature control apparatus 1 of 1st Embodiment. According to the present embodiment, the same effects as those of the first embodiment can be obtained by the configuration common to the first embodiment.

  The inflow side of the third condenser 20C may be connected to the third outlet connection portion 312. The outflow side of the third condenser 20C may be connected to the third inlet connection portion 412.

  Moreover, a 4th condenser may be further added with respect to the apparatus temperature control apparatus 1 of this embodiment. In this case, the inflow side of the fourth condenser is connected to the third outlet connection portion 312. The outflow side of the fourth condenser is connected to the third inlet connection portion 412. As described above, the number of the plurality of condensers may be three or more.

(14th Embodiment)
As shown in FIG. 28, in this embodiment, three heat exchangers are added to the device temperature control device 1 of the second embodiment. The three heat exchangers are a fourth heat exchanger 11D, a fifth heat exchanger 11E, and a sixth heat exchanger 11F. The fourth heat exchanger 11D is opposed to the first heat exchanger 11A in the longitudinal direction of the first heat exchanger 11A. The fifth heat exchanger 11E is opposed to the second heat exchanger 11B in the longitudinal direction of the second heat exchanger 11B. The sixth heat exchanger 11F is opposed to the third heat exchanger 11C in the longitudinal direction of the third heat exchanger 11C. Each of the heat exchangers 11D, 11E, and 11F has the same configuration as that of the first heat exchanger 11A. The heat exchange core parts of the fourth heat exchanger 11D, the fifth heat exchanger 11E, and the sixth heat exchanger 11F are respectively replaced with a fourth heat exchange core part 113d, a fifth heat exchange core part 113e, and a sixth heat exchange. It is called a core part 113f.

  The gas pipe 30 includes a fourth outlet pipe 302a, a fifth outlet pipe 304a, and a sixth outlet pipe 306a. The fourth outlet pipe 302a is connected to the outlet side of the fourth heat exchanger 11D. The fourth outlet pipe 302a is connected to the first outlet connecting portion 308. The fifth outlet pipe 304a is connected to the outlet side of the fifth heat exchanger 11E. The fifth outlet pipe 304 a is connected to the second outlet connection part 310. The sixth outlet pipe 306a is connected to the outlet side of the sixth heat exchanger 11F. The sixth outlet pipe 306a is connected to the third outlet connecting portion 312.

  The liquid pipe 40 includes a fourth inlet pipe 402a, a fifth inlet pipe 404a, and a sixth inlet pipe 406a. The fourth inlet pipe 402a is connected to the inlet side of the fourth heat exchanger 11D. The fourth inlet pipe 402a is connected to the first inlet connection portion 408. The fifth inlet pipe 404a is connected to the inlet side of the fifth heat exchanger 11E. The fifth inlet pipe 404 a is connected to the second inlet connection portion 410. The sixth inlet pipe 406a is connected to the inlet side of the sixth heat exchanger 11F. The sixth inlet pipe 406 a is connected to the third inlet connection portion 412.

  The structure of the apparatus temperature control apparatus 1 other than the above is the same as the apparatus temperature control apparatus 1 of the second embodiment.

  According to this embodiment, for the same reason as in the second embodiment, each heat exchange core portion 113a, 113b, 113c, 113d is compared with the case where the device temperature control device 1 does not include the second condenser 20B. , 113e and 113f, the flow rate at the portion where the flow rate of the working fluid becomes maximum can be reduced. Therefore, the difference in the pressure loss of the working fluid flowing through the circulation path of each heat exchange core part 113a, 113b, 113c, 113d, 113e, 113f can be suppressed.

(Fifteenth embodiment)
As shown in FIG. 29, in this embodiment, the arrangement direction of the heat exchangers 11A and 11B is changed with respect to the fifth embodiment. Each heat exchanger 11A, 11B is arranged in the longitudinal direction of each heat exchanger 11A, 11B. That is, each heat exchange core part 113a, 113b is located in a line with the longitudinal direction of each heat exchange core part 113a, 113b.

  First outlets 115a and 115b through which working fluid flows out or flow in are provided at one end in the longitudinal direction of the upper header tanks 111a and 111b. Second outlets 117a and 117b through which the working fluid flows out or flow in are provided at the other longitudinal ends of the upper header tanks 111a and 111b.

  Third end inlets 116a and 116b through which the working fluid flows out or inflows are provided at one end in the longitudinal direction of the lower header tanks 112a and 112b. Fourth outflow ports 118a and 118b through which the working fluid flows out or flow in are provided at the other longitudinal ends of the lower header tanks 112a and 112b.

  The gas pipe 30 includes a first outlet connection pipe 330, a first inflow side pipe 318, and a second inflow side pipe 320. The first outlet connection pipe 330 connects the second outlet / inlet 117a of the first upper header tank 111a and the first outlet / inlet 115b of the second upper header tank 111b. The first inflow side piping 318 is connected to the first outflow port 115a of the first upper header tank 111a. The second inflow side pipe 320 is connected to the second outflow port 117b of the second upper header tank 111b.

  The liquid pipe 40 includes a first inlet connection pipe 430, a first outflow side pipe 418, and a second outflow side pipe 420. The first inlet connection pipe 430 connects the fourth outlet 118a of the first lower header tank 112a and the third outlet 116b of the second lower header tank 112b. The first outlet pipe 418 is connected to the third outlet 116a of the first lower header tank 112a. The second outflow side pipe 420 is connected to the fourth outflow inlet 118b of the second lower header tank 112b.

  Also in the present embodiment, the gas pipe 30 and the liquid pipe 40 connect a plurality of heat exchangers 11A and 11B in parallel. The structure of the apparatus temperature control apparatus 1 other than the above is the same as that of the apparatus temperature control apparatus 1 of the fifth embodiment. In the present embodiment, the working fluid can flow in the same manner as in the fifth embodiment. For this reason, according to this embodiment, the effect similar to 5th Embodiment is acquired.

  In the first to fourth embodiments and the seventh to thirteenth embodiments, three or more heat exchangers may be connected as in this embodiment.

(Sixteenth embodiment)
As shown in FIG. 30, in this embodiment, two heat exchangers are added to the device temperature control apparatus 1 of the fifteenth embodiment of FIG. The two added heat exchangers are a third heat exchanger 11C and a fourth heat exchanger 11D. The third heat exchanger 11C and the fourth heat exchanger 11D are arranged in a line in the longitudinal direction of the heat exchangers 11C and 11D. The third heat exchanger 11C and the fourth heat exchanger 11D are arranged in a direction crossing the arrangement direction of the first heat exchanger 11A and the second heat exchanger 11B. That is, in this embodiment, the plurality of heat exchangers are arranged in two rows.

  The gas pipe 30 includes a second outlet connection pipe 332, a third outlet connection pipe 334, and a fourth outlet connection pipe 336. The second outlet connecting pipe 332 connects the second outlet / inlet 117c of the third upper header tank 111c and the first outlet / inlet 115d of the fourth upper header tank 111d. The third outlet connecting pipe 334 connects the first outlet / inlet 115a of the first upper header tank 111a and the first outlet / inlet 115c of the third upper header tank 111c. The fourth outlet connecting pipe 336 connects the second outlet / inlet 117b of the second upper header tank 111b and the second outlet / inlet 117d of the fourth upper header tank 111d. The first inflow side pipe 318 is connected in the middle of the third outlet connection pipe 334. The second inflow side pipe 320 is connected in the middle of the fourth outlet connection pipe 336.

  The liquid pipe 40 includes a second inlet connecting pipe 432, a third inlet connecting pipe 434, and a fourth inlet connecting pipe 436. The second inlet connection pipe 432 connects the fourth outlet 118c of the third lower header tank 112c and the third outlet 116d of the fourth lower header tank 112d. The third inlet connection pipe 434 connects the third outlet / inlet 116a of the first lower header tank 112a and the third outlet / inlet 116c of the third lower header tank 112c. The fourth inlet connection pipe 436 connects the fourth outlet 118b of the second lower header tank 112b and the fourth outlet 118d of the fourth lower header tank 112d. The first outflow side pipe 418 is connected in the middle of the third inlet connection pipe 434. The second outflow side pipe 420 is connected in the middle of the fourth inlet connection pipe 436.

  The structure of the apparatus temperature control apparatus 1 other than the above is the same as that of the apparatus temperature control apparatus 1 of the fifteenth embodiment.

  In the present embodiment, when the working fluid flows through each of the plurality of heat exchange core portions 113a, 113b, 113c, and 113d and each of the plurality of condensers 20A and 20B, the working fluid flows as follows. The working fluid that has flowed out of the first heat exchange core part 113a and the third heat exchange core part 113c flows into the first condenser 20A. The working fluid flowing out from the first condenser 20A flows into the first heat exchange core portion 113a and the third heat exchange core portion 113c. The working fluid that has flowed out of the second heat exchange core part 113b and the fourth heat exchange core part 113d flows into the second condenser 20B. The working fluid flowing out from the second condenser 20B flows into the second heat exchange core portion 113b and the fourth heat exchange core portion 113d.

  Thus, also in this embodiment, the circuit of the working fluid is configured so that all of the working fluid flowing out from the plurality of heat exchange core portions 113a, 113b, 113c, and 113d does not merge. Therefore, the present embodiment can provide the same effects as those of the first embodiment.

(Other embodiments)
(1) In each said embodiment, each battery module 2a, 2b, 2c was installed as shown in FIGS. However, other methods can be adopted as a method of installing each battery module 2a, 2b, 2c. For example, although not shown, a plurality of battery cells 3 may be arranged so that the surface 5 on which the terminals 4 are provided faces upward in the gravity direction. Moreover, although not shown in figure, each heat exchanger 11A, 11B, 11C may be arrange | positioned under the some battery cell 3. FIG.

  (2) In each of the embodiments described above, the target device whose temperature is adjusted by the device temperature adjustment device 1 is the battery 2. However, the target device may be another device that needs to be cooled or warmed up, such as a motor, an inverter, or a charger.

  (3) 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 other embodiment, the apparatus temperature control apparatus 1 may be provided with the function to warm up an object apparatus.

  (4) In each of the above embodiments, a chlorofluorocarbon refrigerant is employed as the working fluid. However, other fluids such as propane and water may be employed as the working fluid.

  (5) In each said embodiment, several condenser 20A, 20B was arrange | positioned rather than several heat exchanger 11A, 11B, 11C above the gravitational direction. However, as long as the working fluid can be circulated, the plurality of condensers 20A, 20B may be arranged at the same position in the direction of gravity as the plurality of heat exchangers 11A, 11B, 11C.

  (6) In each of the embodiments described above, the flow path pipe has a perpendicular parallel line shape, but may be arranged so as to bypass other parts and members for the convenience of mounting. In each of the above embodiments, the plurality of heat exchangers are arranged at the same position in the vertical direction, but may be arranged at different positions in the vertical direction for convenience of mounting. Similarly, in each of the above embodiments, the plurality of condensers are arranged at the same position in the vertical direction, but may be arranged at different positions in the vertical direction for convenience of mounting.

  (7) The present invention is not limited to the above-described embodiment, and can be appropriately changed within the scope described in the claims, and includes various modified examples and modifications within the equivalent range. Further, the above embodiments are not irrelevant to each other, and can be combined as appropriate unless the combination is clearly impossible. In each of the above-described embodiments, it is needless to say that elements constituting the embodiment are not necessarily essential unless explicitly stated as essential and clearly considered essential in principle. Yes. Further, in each of the above embodiments, when numerical values such as the number, numerical value, quantity, range, etc. of the constituent elements of the embodiment are mentioned, it is clearly limited to a specific number when clearly indicated as essential and in principle. The number is not limited to the specific number except for the case. In each of the above embodiments, when referring to the material, shape, positional relationship, etc. of the constituent elements, etc., unless otherwise specified, or in principle limited to a specific material, shape, positional relationship, etc. The material, shape, positional relationship, etc. are not limited.

(Summary)
According to the first aspect shown in part or all of each of the above embodiments, the device temperature control device includes a plurality of heat exchange core units, a plurality of condensers, a gas phase flow path, and a liquid phase flow. Road. The plurality of heat exchange core parts, the plurality of condensers, the gas phase flow path, and the liquid phase flow path are respectively formed of a gas flow path and a liquid phase flow path. One working fluid circuit communicating with each other is formed. When the working fluid flows through each of the plurality of heat exchange core portions and each of the plurality of condensers, the circuit is configured so that all of the working fluids flowing out from the plurality of heat exchange core portions do not merge.

  Moreover, according to the 2nd viewpoint, an apparatus temperature control apparatus is provided with a some heat exchange core part, a some condenser, a gaseous phase flow path, and a liquid phase flow path. The plurality of heat exchange core parts, the plurality of condensers, the gas phase flow paths, and the liquid phase flow paths are configured such that each of the plurality of heat exchange core sections and each of the plurality of condensers has a gas phase flow path and a liquid phase flow path. A circuit of one working fluid that communicates with each other is formed. The gas phase flow path includes a first flow path, a second flow path, and a third flow path. The first flow path connects one heat exchange core part among the plurality of heat exchange core parts and one condenser among the plurality of condensers. The second flow path connects the gas phase side connection portion provided in the first flow path and the other heat exchange core portion among the plurality of heat exchange core portions. The third flow path is a flow path for guiding the working fluid flowing out from the other one heat exchange core portion to the other one of the plurality of condensers without passing through the gas phase side connection portion. .

  As a specific configuration of the first aspect, the configuration of the second aspect can be adopted.

  According to the third aspect, the liquid phase flow path includes a fourth flow path, a fifth flow path, and a sixth flow path. The fourth flow path connects one heat exchange core part and one condenser. The fifth flow path connects the liquid phase side connecting portion provided in the fourth flow path and the other one heat exchange core portion. The sixth flow path is a flow path for guiding the working fluid flowing out from the other one condenser to the other heat exchange core section without passing through the liquid phase side connection section.

  In the second aspect, the configuration of the third aspect can be further adopted.

  Moreover, according to the 4th viewpoint, an apparatus temperature control apparatus is provided with a some heat exchange core part, a some condenser, a gaseous-phase flow path, and a liquid phase flow path. The plurality of heat exchange core parts, the plurality of condensers, the gas phase flow paths, and the liquid phase flow paths are configured such that each of the plurality of heat exchange core sections and each of the plurality of condensers has a gas phase flow path and a liquid phase flow path. A circuit of one working fluid that communicates with each other is formed. The plurality of heat exchange core parts include a first heat exchange core part, a second heat exchange core part, and a third heat exchange core part. The plurality of condensers includes a first condenser and a second condenser. The gas phase flow path includes a first connection flow path that connects the first heat exchange core section and the second heat exchange core section, and a second connection flow that connects the first connection flow path and the third heat exchange core section. Including roads. The first condenser is connected to the first connection channel. The second condenser is connected to the second connection channel.

  As a specific configuration of the first aspect, the configuration of the fourth aspect can be employed. According to this, in each circulation path in which the working fluid circulates between each heat exchange core portion and the plurality of condensers, the flow rate of the working fluid at the portion where the flow rate of the working fluid is maximized The flow rate of the working fluid in the two parts of the temperature control device can be reduced.

  According to the fifth aspect, the liquid phase flow path includes a third connection flow path that connects the first heat exchange core part and the second heat exchange core part, a third connection flow path, and a third heat exchange. A fourth connection channel connecting the core part. The first condenser is connected to the third connection channel. The second condenser is connected to the fourth connection channel.

  In the fourth aspect, the configuration of the fifth aspect can be further adopted.

  Moreover, according to the 6th viewpoint, the apparatus temperature control apparatus is mounted in a vehicle. The target device is a battery that supplies power for traveling the vehicle. Thus, the apparatus temperature control apparatus of the 1st-5th viewpoint can be applied to the apparatus temperature control apparatus which adjusts the temperature of the battery which supplies the electric power for vehicle travel.

113a, 113b, 113c 1st, 2nd, 3rd heat exchange core part 111a, 111b, 111c 1st, 2nd, 3rd upper header tank 112a, 112b, 112c 1st, 2nd, 3rd lower header tank 30 Gas piping 40 Liquid piping 20A, 20B First and second condensers

Claims (6)

A device temperature control device for adjusting the temperature of a target device by a phase change between a liquid phase and a gas phase of a working fluid,
A plurality of heat exchange core parts (113a, 113b, 113c) configured to be capable of exchanging heat with the target device such that a liquid-phase working fluid evaporates when the target device is cooled;
A plurality of condensers (20A, 20B) that dissipate heat and condense the vapor-phase working fluid evaporated in the plurality of heat exchange core parts;
A gas phase flow path (30, 111a, 111b, 111c) for guiding a gas phase working fluid to the plurality of condensers;
A liquid phase flow path (40, 112a, 112b, 112c) for guiding a liquid phase working fluid to the plurality of heat exchange core parts,
The plurality of heat exchange core sections, the plurality of condensers, the gas phase flow path, and the liquid phase flow path are configured such that each of the plurality of heat exchange core sections and each of the plurality of condensers are in the gas phase flow. Forming a circuit of one working fluid communicating with each other via a channel and the liquid phase channel;
The circuit is configured such that when the working fluid flows through each of the plurality of heat exchange core portions and each of the plurality of condensers, all of the working fluids flowing out from the plurality of heat exchange core portions do not merge. An equipment temperature control device. A device temperature control device for adjusting the temperature of a target device by a phase change between a liquid phase and a gas phase of a working fluid,
A plurality of heat exchange core parts (113a, 113b, 113c) configured to be capable of exchanging heat with the target device such that a liquid-phase working fluid evaporates when the target device is cooled;
A plurality of condensers (20A, 20B) that dissipate heat and condense the vapor-phase working fluid evaporated in the plurality of heat exchange core parts;
A gas phase flow path (30) for guiding a gas phase working fluid to the plurality of condensers;
A liquid phase flow path (40) for guiding a liquid phase working fluid to the plurality of heat exchange core parts,
The plurality of heat exchange core sections, the plurality of condensers, the gas phase flow path, and the liquid phase flow path are configured such that each of the plurality of heat exchange core sections and each of the plurality of condensers are in the gas phase flow. Forming a circuit of one working fluid communicating with each other via a channel and the liquid phase channel;
The gas phase flow path is
A first flow path (111a, 302, 318) connecting one heat exchange core part (113a) of the plurality of heat exchange core parts and one condenser (20A) of the plurality of condensers;
The second flow path (111c, 306) that connects the gas phase side connection part (308) provided in the first flow path and the other heat exchange core part (113c) among the plurality of heat exchange core parts. 316, 314), and
A third flow path for guiding the working fluid that has flowed out of the other one heat exchange core without passing through the vapor phase side connection to the other condenser (20B) among the plurality of condensers. (320) The apparatus temperature control apparatus containing. The liquid phase flow path is
A fourth flow path (112a, 402, 418) connecting the one heat exchange core part and the one condenser;
A fifth flow path (112c, 406, 416, 414) for connecting the liquid phase side connection part (408) provided in the fourth flow path and the other one heat exchange core part,
A sixth flow path (420) for guiding the working fluid flowing out from the other one condenser to the other one heat exchange core without passing through the liquid phase side connection. 2. The apparatus temperature control apparatus according to 2. A device temperature control device for adjusting the temperature of a target device by a phase change between a liquid phase and a gas phase of a working fluid,
A plurality of heat exchange core parts (113a, 113b, 113c) configured to be capable of exchanging heat with the target device such that a liquid-phase working fluid evaporates when the target device is cooled;
A plurality of condensers (20A, 20B) that dissipate heat and condense the vapor-phase working fluid evaporated in the plurality of heat exchange core parts;
A gas phase flow path (30) for guiding a gas phase working fluid to the plurality of condensers;
A liquid phase flow path (40) for guiding a liquid phase working fluid to the plurality of heat exchange core parts,
The plurality of heat exchange core sections, the plurality of condensers, the gas phase flow path, and the liquid phase flow path are configured such that each of the plurality of heat exchange core sections and each of the plurality of condensers are in the gas phase flow. Forming a circuit of one working fluid communicating with each other via a channel and the liquid phase channel;
The plurality of heat exchange core parts include a first heat exchange core part (113a), a second heat exchange core part (113b), and a third heat exchange core part (113c),
The plurality of condensers include a first condenser (20A) and a second condenser (20B),
The gas phase flow path includes a first connection flow path (111a, 111b, 302, 304, 308, 310, 314) that connects the first heat exchange core part and the second heat exchange core part, A second connection channel (111c, 306, 312, 316) that connects the one connection channel and the third heat exchange core part,
The first condenser is connected to the first connection channel,
The second condenser is a device temperature control device connected to the second connection channel. The liquid phase flow path includes a third connection flow path (112a, 112b, 402, 404, 408, 410, 414) that connects the first heat exchange core part and the second heat exchange core part, and the first heat exchange core part. A fourth connection channel (112c, 406, 412, 416) that connects the three connection channels and the third heat exchange core part,
The first condenser is connected to the third connection channel,
The apparatus temperature control device according to claim 4, wherein the second condenser is connected to the fourth connection channel. The device temperature control device is mounted on a vehicle,
The device temperature control device according to any one of claims 1 to 5, wherein the target device is a battery (2) that supplies electric power for vehicle travel.

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