JP2008106996A - Heat storage device - Google Patents

Abstract

An object of the present invention is to improve the rigidity of a heat storage device without inhibiting natural convection due to a temperature difference in the temperature distribution of the heat storage material.
A heat storage device comprising a plurality of tubular first heat medium branch pipes (5) into which a first heat medium (3) flows, and a heat storage material (1) provided on the outer periphery of the first heat medium branch pipe (5). The first header 6 communicates with the upper portion of the first heat medium branch pipe 5 and circulates the first heat medium 3, and communicates with the first header 6 to store the first heat medium 3. The first upper reservoir portion 7 and a first inlet portion 8 that communicates with the first upper reservoir portion 7 and allows the first heat medium 3 to flow therethrough, the first upper reservoir portion 7 being the first inlet portion. A heat storage device provided in a direction intersecting with eight streamline directions.
[Selection] Figure 1

Description

  The present invention relates to a heat storage device in which a first heat medium and a second heat medium circulate inside a heat storage material, and more particularly to a heat storage device capable of temporarily storing heat (or cold heat) of a medium such as a refrigerant. It is.

  Conventionally, when heat (or cold heat) is stored in a heat storage material in a heat storage device / cold storage device, the first heat medium and the second heat medium circulate through the flow path, and the flow path and the heat storage material are in contact with each other. Therefore, a heat accumulator that heats and cools the heat storage material is known, and an example thereof is described in Patent Document 1. In the invention described in Patent Document 1, a plurality of first flow paths and a plurality of second flow paths are provided, whereby the heat source fluid and the heat recovery fluid exchange heat directly. In addition, since a heat storage material is provided around the first flow path and the second flow path, the heat of the heat source fluid is temporarily stored in the heat storage material, and then transferred to the heat recovery medium for heat exchange. .

  Moreover, regarding the heat storage device in which heat exchange between the first heat medium and the second heat medium is performed inside the heat storage device, the first heat medium and the second heat medium are formed in a flow path formed by stacking heat transfer plates. Is known to be distributed, and an example thereof is described in Patent Document 2. In the invention described in Patent Document 2, heat exchange between the first heat medium and the second heat medium is performed via a heat transfer plate.

JP 2003-336974 A JP-A-10-232093

  In the invention described in Patent Document 1 described above, a path from the inlet to the tank is provided in a straight line, and a plurality of flow paths are provided in a direction crossing the tank. Therefore, when the flow rate of the first heat medium or the second heat medium flowing into the inlet fluctuates, the flow path is attached along with the fluctuation of the flow rate of the first heat medium or the second heat medium flowing in the flow path. There is a bias to the position. For this reason, a difference occurs in heat transfer between the first heat medium or the second heat medium and the heat storage material, and a difference in the temperature distribution of the heat storage material is likely to occur.

  In addition, when the flow rate of the first heat medium or the second heat medium flowing into the inlet fluctuates, bubbles are generated in the tank or the flow path, resulting in a gas-liquid mixed state. The amount of heat that can be directly exchanged between the two heat media is reduced.

  Furthermore, in the invention described in Patent Document 2, a heat transfer plate in which heat is exchanged between the first heat medium and the second heat medium and a heat storage tank that stores heat are separately provided. The heat storage device is enlarged.

  The present invention has been made in view of the above circumstances. Regarding a heat storage device that performs heat exchange between the first heat medium and the second heat medium and heat storage to the heat storage material by the same mechanism, the first heat medium or Even when the flow rate of the second heat medium fluctuates, the heat storage device is improved with respect to the bias with respect to the mounting positions of the plurality of flow paths, and the overall rigidity is improved by providing a tube for circulating the heat medium on the blade Is intended to provide.

  In order to achieve the above object, a first aspect of the present invention comprises a plurality of tubular first heat medium branch pipes into which a first heat medium flows, and a heat storage material provided on an outer periphery of the first heat medium branch pipe. In the heat storage device provided, a first header portion that communicates with an upper portion of the first heat medium branch pipe and distributes the first heat medium, and communicates with the first header portion to store the first heat medium. A first upper reservoir, and a first inlet that communicates with the first upper reservoir and allows the first heat medium to flow therethrough, the first upper reservoir in a streamline direction of the first inlet It is provided in the direction which cross | intersects.

  According to a second aspect of the present invention, in the first aspect of the invention, the first upper reservoir portion is formed so as to protrude downward from the upper portion, and an inclined surface is formed upward from the lower portion of the first upper reservoir portion. It is characterized by being.

  The invention of claim 3 is the invention of claim 1 or 2, wherein a plurality of second heat medium branch pipes for circulating the second heat medium, and a heat storage material provided on the outer periphery of the second heat medium branch pipe, A second header portion that communicates with an upper portion of the second heat medium branch pipe and circulates the second heat medium; and a second header portion that communicates with the second header portion. A second upper reservoir portion for storing the second outlet portion and the second outlet portion for communicating the second heat medium in communication with the second upper reservoir portion, wherein the second upper reservoir portion is a streamline of the second outlet portion; The first upper reservoir and the second upper reservoir are in contact with each other and are in contact with each other.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the first header portion and the second header portion are in contact with each other.

  According to a fifth aspect of the present invention, in any one of the first to fourth aspects, the first heat medium branch pipe is formed in a surface direction of the first plate-like tube.

  A sixth aspect of the invention is characterized in that, in any one of the first to fifth aspects of the invention, the second heat medium branch pipe is formed in the surface direction of the second plate-like tube.

  The invention of claim 7 is the invention of claim 5 or 6, wherein the first plate-like tube is provided so as to penetrate at least one of the second upper reservoir part or the second lower reservoir part, The first plate-like tube passing therethrough is provided with a hole.

  According to an eighth aspect of the present invention, in the invention according to any one of the fifth to seventh aspects, the second plate-like tube passes through at least one reservoir portion of the second upper reservoir portion or the second lower reservoir portion. A hole is provided in the second plate-like tube provided and penetrating.

  According to the first aspect of the present invention, when the first heat medium flows in from the first inlet portion, the first heat medium is accumulated in the first upper reservoir, and the first heat medium is discharged from the first upper reservoir. It flows into the first header part. Therefore, since the change in the flow rate of the first heat medium flowing into the first inlet portion is transmitted to the first header portion via the first upper reservoir portion, the change in the flow rate of the first heat medium in the first header portion is This is smaller than the change in the flow rate of the first heat medium at the first inlet. As a result, the flow rate of the first heat medium flowing through the first heat medium branch pipe becomes more stable, and variations in the temperature distribution of the heat storage material with respect to changes in the flow rate of the first heat medium are reduced.

  According to the second aspect of the present invention, the pressure loss when the first heat medium is caused to flow from the first inlet portion and the first heat medium is circulated through the inside of the heat storage device is reduced.

  According to the invention of claim 3, the second heat medium is stored in the second upper storage part via the second heat medium branch pipe and the second header part. Here, since the first upper reservoir and the second upper reservoir are in contact with each other, the first heat medium is stored in the first upper reservoir and the second heat medium is stored in the second upper reservoir. Then, even when heat energy is not accumulated in the heat storage material, direct heat exchange can be performed between the first heat medium and the second heat medium.

  According to invention of Claim 4, when the 1st heat medium is stored in the 1st header part and the 2nd heat medium is stored in the 2nd header part, in the case where heat energy does not accumulate in the heat storage material In addition, direct heat exchange can be performed between the first heat medium and the second heat medium.

  According to the fifth aspect of the present invention, the pressure-resistant structure can be formed by simple means in the direction parallel to the surface direction of the first plate-like tube, and the size, weight, and cost can be reduced.

  According to invention of Claim 6, it can be set as a pressure | voltage resistant structure with a simple means about the parallel direction with respect to the surface direction of a said 2nd plate-shaped tube, and reduction in size, weight, and cost reduction can be achieved.

  According to the seventh aspect of the present invention, since the cross-sectional area of the flow path in the reservoir portion penetrated by the first plate-like tube can be increased, the pressure loss of the first heat medium or the second heat medium can be reduced. it can.

  According to the eighth aspect of the present invention, the flow passage cross-sectional area in the reservoir portion penetrated by the second plate-like tube can be increased, so that the pressure loss of the first heat medium or the second heat medium can be reduced. it can.

  Next, the present invention will be described more specifically. The heat storage device according to the present invention can perform both positive heat storage for increasing energy and negative heat storage for reducing energy. However, in the following description, the latter so-called cold heat storage is performed. A specific example is shown below.

  In FIG. 1, the refrigerant as the second heat medium 2 carries in the cold to the heat storage material 1, and the brine as the first heat medium 3 carries out the cold heat of the heat storage material 1. It is an example. Therefore, this heat storage device 4 is configured as a regenerator that stores heat storage of negative heat that reduces energy.

  The heat storage device 4 includes a plurality of first heat medium branch pipes 5 into which the first heat medium 3 flows, and a heat storage material 1 provided on the outer periphery of the first heat medium branch pipes 5. . More specifically, the inside of the first heat medium branch pipe 5 is formed in a cavity, and the first heat medium branch pipe 5 is disposed inside the heat storage device 4 so that the first heat medium 3 flows. It is formed in the vertical direction. Further, the first heat medium branch pipes 5 are evenly arranged in the direction perpendicular to the lower surface of the first header portion 6 inside the heat storage device 4, whereby the first heat medium 3, which is cold, is arranged in each of the first heat medium 3. The heat medium branch pipe 5 is evenly distributed, and as a result, cold heat is stored evenly in the heat storage device 4. Since the heat storage material 1 is in contact with the outer periphery of the first heat medium branch pipe 5, the first heat medium 3 and the heat storage material 1 circulated through the first heat medium branch pipe 5. Heat is exchanged between them.

  In addition, the heat storage device 4 includes a first header portion 6 that communicates with the upper portion of the first heat medium branch pipe 5 and distributes the first heat medium 3. More specifically, the first header portion 6 is formed so as to be hollow inside, and is provided on the upper part of the heat storage device 4 so that the lower surface thereof is in the horizontal direction. Flows almost uniformly into the inside of the first header portion 6. Furthermore, the area of the upper surface and the lower surface inside the first header portion 6 is formed to be as large as possible. The first heat medium branch pipe 5 may or may not protrude upward in the first header section 6, but the first heat medium 3 is branched from the first header section 6 and the first heat medium branch. It needs to be formed so as to circulate through the pipe 5. The first heat medium branch pipe 5 and the first header section 6 are joined by welding or the like.

  Further, the heat storage device 4 includes a first upper reservoir portion 7 that communicates with the first header portion 6 and accumulates the first heat medium 3, and communicates with the first upper reservoir portion 7 to communicate the first heat reservoir 3. A tubular first inlet portion 8 through which the heat medium 3 flows is provided. The first upper reservoir 7 is provided in a direction intersecting the streamline direction of the first inlet 8. Here, the first upper reservoir portion 7 is configured such that the cross-sectional area of the first inlet portion 8 in the streamline direction is as large as possible. When the cross-sectional area is large, the first upper reservoir portion 7 flows from the first inlet portion 8. The amount of rise in the liquid level of the first heat medium 3 is reduced inside the first upper reservoir 7. This amount of rise is based on the ratio between the cross-sectional area of the first inlet 8 in the pipe direction and the cross-sectional area of the first upper reservoir 7 in the streamline direction of the first inlet 8, and the first inlet 8 When the cross-sectional area in the pipe direction is small, or when the cross-sectional area in the streamline direction of the first inlet portion 8 of the first upper reservoir portion 7 is large, the first upper reservoir portion 7 is circulated. 1 The amount of increase in the liquid level of the heat medium 3 is reduced. Thereby, even when the circulation amount of the first heat medium 3 is small, it is possible to exchange heat directly with the second heat medium 2 efficiently.

  The first upper reservoir 7 is configured so as to be hollow inside, whereby the first heat medium 3 is accumulated in the first upper reservoir 7. The first upper reservoir portion 7 communicates with the first header portion 6 at the upper end portion of the surface where the first inlet portion 8 is not attached. In other words, the surface where the first inlet portion 8 is attached. The first header portion 6 communicates with the upper end portion of the surface facing the first header portion 6. The first upper reservoir portion 7 is preferably provided so as to be perpendicular to the lower surface of the first header portion 6, but the first reservoir portion 7 and the lower surface of the first header portion 6 may not be provided perpendicularly. Any structure that is inclined and can store the first heat medium 3 in the first reservoir 7 may be used. The first header portion 6 is provided above the lower surface of the first upper reservoir portion 7.

  The first inlet portion 8 is formed in a tubular shape, and one end thereof communicates with the first upper reservoir portion 7. More specifically, the first inlet portion 8 communicates with the lower portion of the first upper reservoir portion 7, and the first inlet portion 8 is provided below the lower surface of the first header portion 6. The first upper reservoir portion 7 is preferably provided in a direction perpendicular to the streamline direction of the first inlet portion 8, but the first upper reservoir portion 7 and the first inlet portion 8 are not required to be perpendicular. As long as the direction of the streamline is inclined. In short, when the first heat medium 3 flows in from the first inlet portion 8, if there is an increase or decrease in the flow rate of the first heat medium 3, the pulsation of the first heat medium 3 becomes the first upper reservoir portion. 7, the first upper reservoir 7 needs to be provided so as to be inclined with respect to the streamline direction of the first inlet 8.

  Furthermore, the heat storage device 4 includes a first footer portion 9 that communicates with the lower portion of the first heat medium branch pipe 5. More specifically, the first footer unit 9 is configured to be hollow inside, and the first heat medium 3 is stored in the first footer unit 9 for that purpose. The first footer portion 9 communicating with the lower portion of the first heat medium branch pipe 5 is provided inside the heat storage device 4 so that the inner lower surface thereof is in the horizontal direction. Here, the area of the upper surface and the lower surface inside the first footer portion 9 is formed to be as large as possible.

  The upper surface of the first footer part 9 communicates with the first heat medium branch pipe 5, and the first heat medium branch pipe 5 is evenly arranged in the direction perpendicular to the upper surface of the first footer part 9 inside the heat storage device 4. Therefore, the first heat medium 3 flowing through the first heat medium branch pipe 5 can uniformly store the cold in the entire heat storage device 4. Further, the first heat medium branch pipe 5 may or may not protrude downward in the first footer portion 9. In short, the first heat medium 3 may be configured to flow through the first footer portion 9 and the first heat medium branch pipe 5. The first heat medium branch pipe 5 and the first footer 9 are joined by welding or the like.

  In addition, the heat storage device 4 includes a first lower reservoir portion 10 that communicates with the first footer portion 9, and a first outlet portion 11 that communicates with the first lower reservoir portion 10. ing. More specifically, the first lower reservoir portion 10 is configured to be hollow inside, and communicates with the first footer portion 9 at the lower end portion of the surface where the first outlet portion 11 is not attached. In other words, it communicates with the first footer 9 at the lower end of the surface facing the surface to which the first outlet 11 is attached. The first lower reservoir portion 10 is preferably provided so as to be perpendicular to the lower surface of the first footer portion 9, but is inclined even if not provided vertically, and the first lower reservoir portion has a first Any structure that can store the heat medium 3 may be used. The first footer 9 is provided below the upper surface of the first lower reservoir 10.

  The first outlet portion 11 is formed in a tubular shape, and one end thereof communicates with the first lower reservoir portion 10. In the heat storage device 4, the first lower reservoir portion 10 is provided in a direction intersecting the streamline direction of the first outlet portion 11, and the first lower reservoir portion 10 is the first outlet portion. 11 is preferably provided in a direction perpendicular to the streamline direction, but the first reservoir 10 and the streamline direction of the first outlet part 11 may be inclined even if not in the vertical direction.

  FIG. 2 shows an external perspective view of the heat exchanger of the present invention. In the heat storage device 4, the first upper reservoir portion 7 is formed so as to protrude below the upper portion, and an inclined surface 12 is formed from the lower portion to the upper portion of the first upper reservoir portion 7. The first inlet portion 8 is provided in the vicinity of the bottom of the first upper reservoir portion 7, and the inclined surface 12 is perpendicular to the flow direction of the first heat medium 3 flowing through the first header portion 6. It is provided as follows. In other words, the first upper reservoir 7 is configured such that the horizontal cross-sectional area with respect to the first header 6 is small on the lower side and the horizontal cross-sectional area is large on the upper side. Therefore, as the storage amount of the first heat medium 3 flowing from the first inlet portion 8 increases, the amount of the first heat medium 3 rising in the first upper reservoir portion 7 decreases. Therefore, a change in the flow rate of the first heat medium 3 flowing from the first inlet portion 8 is reduced in the first header portion 6. Moreover, the loss (pressure loss) at the time of the said 1st heat medium 3 which flowed in from the said 1st inlet part 8 by the said inclined surface 12 raises the said 1st upper reservoir part 7 can be reduced.

  Next, the passage through which the second heat medium 2 circulates will be described. The heat storage device 4 includes a plurality of second heat medium branch pipes 13 for circulating the second heat medium 2, and the heat storage material 1 is provided on the outer periphery of the second heat medium branch pipe 13. More specifically, the second heat medium branch pipe 13 is formed so that the second heat medium 2 flows in the vertical direction of the heat storage device 4. Since the heat storage material 1 is in contact with the outer periphery of the second heat medium branch pipe 13, the heat storage material 1 and the second heat medium 2 circulated through the second heat medium branch pipe 13. Heat is exchanged between them.

  Further, the heat storage device 4 is provided with a second header portion 14 that communicates with an upper portion of the second heat medium branch pipe 13 and distributes the second heat medium. More specifically, since the second header portion 14 is formed so as to be hollow, the second heat medium 2 accumulates inside the second header portion 14. And the 2nd header part 14 connected with the upper part of the branch pipe 13 for 2nd heat media is provided in the upper part of the thermal storage apparatus 4 so that a lower surface may be leveled. For this reason, the second heat medium 2 flows into the second header portion 14 almost uniformly.

  Although the second heat medium branch pipe 13 communicates with the second header portion 14, the second heat medium branch pipe 13 does not protrude even if it protrudes upward in the second header section 14. May be. In short, it is sufficient that the second heat medium 2 is formed so as to flow through the second header portion 14 and the second heat medium branch pipe 13, and the second header section 14 and the second heat medium branch pipe 13 are formed. Are joined by welding or the like. When the second header portion 14 is disposed below the first header portion 6, the first heat medium branch pipe 5 passes through the second header portion 14 and communicates with the first header portion 5. The

  Here, the first header portion 6 and the second header portion 14 are in contact with each other at an upper portion of the heat storage device 4. More specifically, the second header portion 14 is disposed below the first header portion 6, and the lower surface of the first header portion 6 and the lower surface of the second header portion 14 are in contact with each other. Yes. Thus, heat exchange is performed between the first heat medium 3 stored in the first header portion 6 and the second heat medium 2 stored in the second header portion 14.

  Further, the heat storage device 4 includes a second upper reservoir portion 15 that communicates with the second header portion 14 and accumulates the second heat medium, and communicates with the second upper reservoir portion 15 so as to communicate the second heat. A second outlet portion 16 for circulating the medium is provided. The second upper reservoir portion 15 is provided in a direction intersecting with the streamline direction of the second outlet portion 16. More specifically, since the second upper reservoir portion 15 is configured to be hollow, the second heat medium 2 accumulates in the second upper reservoir portion 15.

  The second upper reservoir portion 15 is an end portion to which the second outlet portion 16 is not attached. In other words, the second upper reservoir portion 15 communicates with the second header portion 6 on a surface facing the surface to which the second outlet portion 16 is attached. . The second upper reservoir portion 15 is preferably provided so as to be perpendicular to the lower surface of the second header portion 14, but the second upper reservoir portion 15 and the lower surface of the second header portion 14 are not provided vertically. Should be inclined. The second header portion 14 is provided above the lower surface of the second upper reservoir portion 15.

  Furthermore, the heat storage device 4 is configured such that the first upper reservoir portion 7 and the second upper reservoir portion 15 are in contact with each other. More specifically, the second upper reservoir portion 15 is provided inside the first upper reservoir portion 7 and is in contact with each other. Therefore, the side surface of the first header portion 6 in the first upper reservoir portion 7 and the side surface of the second upper reservoir portion 15 facing the second header portion 14 are in contact with each other. As a result, heat exchange can be performed between the first heat medium 3 stored in the first upper reservoir 7 and the second heat medium 2 stored in the second upper reservoir 15.

  The second outlet portion 16 is formed in a tubular shape, and one end of the second outlet portion 16 communicates with the second upper reservoir portion 15 and is provided below the second upper reservoir portion 15. The second upper reservoir portion 15 is preferably provided in a direction perpendicular to the streamline direction of the second outlet portion 16, but the second upper reservoir portion 15 and the second outlet portion 16 may not be perpendicular. As long as the direction of the streamline is inclined.

  Furthermore, the heat storage device 4 is provided with a second footer portion 17 communicating with the lower portion of the second heat medium branch pipe 13. More specifically, the second footer part 17 is provided inside the heat storage device 4 so that the second footer part 17 communicating with the lower part of the second heat medium branch pipe 13 has a lower surface in the horizontal direction. The inside of the second footer portion 17 is formed to be a cavity. Therefore, the second heat medium 2 flows into the second footer portion 17.

  The second footer portion 17 is configured to have a large upper surface area, and the second heat medium branch pipes 13 are equally arranged in the lower surface of the heat storage device 4 in the upper surface direction of the second footer portion 17. Therefore, the heat storage of the refrigerant is evenly performed inside the heat storage device 4. Therefore, the second heat medium 2 that flows in flows into the second footer portion 17 almost uniformly. Further, the second heat medium branch pipe 13 may or may not protrude downward within the second footer portion 17. In short, the second heat medium 2 is connected to the second footer portion 17 and the second heat exchanger portion 17. What is necessary is just to be comprised so that the branch pipe 13 for media may be distribute | circulated. Further, the second footer portion 17 and the second heat medium branch pipe 13 are joined by welding or the like. When the second footer portion 17 is disposed above the first footer portion 9, the first heat medium branch pipe 5 passes through the second footer portion 17 and communicates with the first footer portion 9. .

  In addition, the heat storage device 4 includes a second lower reservoir 18 that communicates with the second footer 17, and a second inlet 19 that communicates with the second lower reservoir 18. ing. Here, the second lower reservoir portion 18 is formed so as to be hollow inside, and the second inlet portion 19 is provided to communicate with the upper portion of the second lower reservoir portion 18. Reference numeral 18 denotes an end portion to which the second inlet portion 19 is not attached. In other words, the end portion 18 communicates with the second footer portion 17 on a surface facing the surface to which the second inlet portion 19 is attached. The second lower reservoir 18 is preferably provided so as to be perpendicular to the lower surface of the second footer 17, but may be inclined even if not provided vertically.

  The second inlet 19 is formed in a tubular shape, and one end thereof communicates with the second lower reservoir 18. In the heat storage device 4, the second lower reservoir 18 is provided in a direction that intersects the streamline direction of the second inlet 19. More specifically, the second lower reservoir portion 18 may be provided so as to be substantially perpendicular to the lower surface of the second footer portion 17 or to be inclined.

  Inside the heat storage device 4, the first heat medium branch pipe 5 and the second heat medium branch pipe 13 face each other, and the first heat medium branch pipe 5 and the second heat medium branch pipe 13 are connected to each other. A heat storage material 1 is provided therebetween. Therefore, cold heat is transmitted from the first heat medium 3 flowing through the first heat medium branch pipe 5 to the heat storage material 1, and thus the heat storage material 1 stores the cold heat. At this time, the first heat medium 3 is deprived of heat by the heat storage material 1, and the state of the first heat medium 3 changes from liquid to gas. Further, the cold heat stored in the heat storage material 1 is transmitted to the second heat medium 2 flowing through the second heat medium branch pipe 13, and thus the cold heat is transmitted to the second heat medium 2.

  The first heat medium branch pipe 5 and the second heat medium branch pipe 13 may be in contact with each other inside the heat storage device 4. At this time, the first heat medium 3 and the second heat medium flowing through the first heat medium branch pipe 5 at the contact portion between the first heat medium branch pipe 5 and the second heat medium branch pipe 13. Heat exchange is performed directly with the second heat medium 2 flowing through the branch pipe 13.

  FIG. 3 shows a schematic diagram of a circulation cycle for circulating the first heat medium 3 corresponding to the brine. The circulation passage through which the first heat medium 3 is circulated inside the heat storage device 4 is configured so as to form a circulation path with the heat exchanger 24 such as the passenger compartment side heat exchanger. A pump 25 is interposed on the way. Specifically, the flow path includes the first inlet 8, the first upper reservoir 7, the first header 6, the first heat medium branch pipe 5, the first footer 9, and the first lower reservoir 10. It refers to a passage that communicates with the first outlet 11.

  FIG. 4 shows a schematic diagram of a circulation cycle in which the second heat medium 2 corresponding to the refrigerant is circulated. The circulation cycle will be briefly described. The circulation cycle includes a compressor 20 driven by a power source (not shown) such as a vehicle engine, and a condenser 21, a receiver tank 22 and an expansion valve 23 are disposed on the discharge side. Are connected in order. The second inlet 19 is connected to the discharge side of the expansion valve 23, and the second outlet 16 not connected to the discharge side of the expansion valve 23 is connected to the suction side of the compressor 20.

  As in FIG. 1, the brine as the first heat medium 3 carries out the cold heat and the refrigerant as the second heat medium 2 carries out the cold heat of the heat storage material 1, as in FIG. 1. The structure which provided the branch pipe for heat media in the surface direction of the plate-shaped tube is shown. About the same structure as the heat storage apparatus 4 shown by FIG. 1, the same code | symbol is attached | subjected and the description is abbreviate | omitted.

  In the heat storage device 4, the first heat medium branch pipe 5 is configured to be formed in the surface direction of the first plate-shaped tube 26, and the second heat medium branch pipe 13 is formed on the surface of the second plate-shaped tube 27. It is configured to be formed in a direction. As shown in FIG. 6, the first plate-like tube 26 and the second plate-like tube 27 are configured by joining two heat transfer plates 28 and 29 corresponding to the plate material to face each other. On each heat transfer plate 28, 29, protrusions 28A, 29A formed by bending so that the inside becomes a hollow portion are formed substantially in parallel with a predetermined interval. And the part between these protrusion part 28A, 29A is flat part 28B, 29B. The shape of the protrusions 28A and 29A may be any shape such as a triangular cross section, a quadrangular cross section, a semicircular cross section, and the cross-sectional shape in FIG. An example of forming a triangle is described. Each of the protrusions 28A and 29A is configured such that an internal cavity opens to the joint surface side between the heat transfer plates 28 and 29, and thus each cavity has a groove shape. And each heat-transfer plate 28,29 is joined so that flat part 29B, 28B in the other heat-transfer plate 29,28 may oppose the protrusion part 28A, 29A in one heat-transfer plate 28,29. . Therefore, the opening of the hollow portion formed inside each protrusion 28A, 29A is closed by the flat portions 28B, 29B of the mating heat transfer plates 28, 29. Thus, the first heat medium branch pipe 5 or the second heat medium branch pipe 13 is formed inside each of the protrusions 28A and 29A.

  The first plate-like tube 26 penetrates the lower surface of the first header portion 6 and the upper surface of the first footer portion 9, and the direction in which the first heat medium 3 flows is substantially the same as the surface direction of the first plate-like tube 26. It is provided to be vertical. For this reason, the heat storage device 4 in which the first plate-like tube 26 is provided can have a pressure-resistant structure in the vertical direction and the flow path direction of the first heat medium 3 flowing through the first header portion 6.

  The first plate-like tube 26 is provided so as to penetrate at least one of the first upper reservoir portion 7 and the first lower reservoir portion 10. More specifically, since the first plate-like tube 26 is provided so that the flow direction of the first heat medium 3 is substantially perpendicular to the surface direction of the first plate-like tube 26, the first plate-like tube 26 penetrates in a direction substantially perpendicular to at least one of the first upper reservoir 7 or the first lower reservoir 10. The reservoir and the first plate tube 26 are joined by welding or the like.

  When the second header portion 14 is provided on the lower side of the first header portion 6, the first plate tube 26 penetrates the second header portion 14 in addition to the lower surface of the first header portion 6. It becomes the structure to do. Further, when the second footer portion 17 is provided on the upper side of the first footer portion 9, the first plate-like tube 26 has the first footer portion 17 in addition to the upper surface of the second footer portion 9. It becomes a structure that penetrates.

  Here, a hole 30 is provided in the first plate-like tube 26 penetrating at least one reservoir. More specifically, as shown in FIG. 7, a plurality of holes 30 are provided in the first plate-like tube 26 penetrating one reservoir. The shape of the hole 30 is not limited to a circle, a triangle, a rectangle, or the like, and may be provided so that the second heat medium stored in the reservoir is circulated. And since the said 1st plate-shaped tube 26 has penetrated the said storage part, the thermal storage apparatus 4 shall be taken as a pressure | voltage resistant structure about the up-down direction and the flow path direction of the 1st heat medium 3 which flows through the 1st header part 6. FIG. it can.

  The second plate tube 27 passes through the lower surface of the second header portion 14 and the upper surface of the second footer portion 17, and the direction in which the second heat medium 2 flows is the surface direction of the second plate tube 27. It is provided to be almost vertical. For this reason, the heat storage device 4 in which the second plate-like tube 27 is provided can have a pressure-resistant structure in the vertical direction and the flow path direction of the second heat medium 2 flowing through the second header portion 14.

  The second plate-like tube 27 is provided so as to penetrate at least one reservoir portion of the second upper reservoir portion 15 or the second lower reservoir portion 18. More specifically, since the second plate-shaped tube 27 is provided so that the direction in which the second heat medium 2 flows is perpendicular to the surface direction of the second plate-shaped tube 27, the second plate-shaped tube 27. Penetrates in a direction perpendicular to at least one of the second upper reservoir portion 15 or the second lower reservoir portion 18. Thereby, it can be set as a pressure | voltage resistant structure about a perpendicular | vertical direction with respect to the surface of the at least 1 reservoir part of the said 2nd upper reservoir part 15 or the said 2nd lower reservoir part 18. FIG. The reservoir and the second plate-like tube 27 are joined by welding or the like.

  Here, a plurality of holes 30 are provided in the second plate-like tube 27 penetrating at least one reservoir. The shape of the hole 30 is not limited to a circular shape, a triangular shape, a rectangular shape, or the like, and may be provided so that the second heat medium 2 stored in the storage portion is circulated. And since the said 2nd plate-shaped tube 27 has penetrated the said storage part, the thermal storage apparatus 4 shall be taken as a pressure | voltage resistant structure about the flow path direction of the 1st heat carrier 3 which flows through the up-down direction and the 1st header part 6. FIG. it can.

It is a figure of the heat exchanger which shows an example of this invention typically. It is an external appearance perspective view of the heat exchanger of this invention. It is a figure which shows typically the circulation path of the 2nd heat carrier of this invention. It is a figure which shows typically the circulation path of the 1st heat carrier of this invention. It is a figure of the heat exchanger which shows an example which provided the plate-shaped tube of this invention typically. It is the fragmentary cross-sectional view which expanded and showed the principal part of the plate-shaped tube used for the heat exchange apparatus. It is a figure of the heat exchanger which shows typically an example which provided the hole in the plate-shaped tube of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Thermal storage material, 2 ... 2nd thermal medium, 3 ... 1st thermal medium, 4 ... Thermal storage apparatus, 5 ... Branch pipe for 1st thermal media, 6 ... 1st header part, 7 ... 1st upper reservoir part, 8 DESCRIPTION OF SYMBOLS 1st inlet part, 9 ... 1st footer part, 10 ... 1st lower storage part, 11 ... 1st outlet part, 12 ... Inclined surface, 13 ... Branch pipe for 2nd heat carrier, 14 ... 2nd header part, DESCRIPTION OF SYMBOLS 15 ... 2nd upper reservoir part, 16 ... 2nd outlet part, 17 ... 2nd footer part, 18 ... 2nd lower reservoir part, 19 ... 2nd inlet part, 20 ... Compressor, 21 ... Condenser, 22 ... Receiver tank, DESCRIPTION OF SYMBOLS 23 ... Expansion valve 24 ... Heat exchanger 25 ... Pump 26 ... 1st plate-shaped tube 27 ... 2nd plate-shaped tube 28, 29 ... Heat-transfer plate, 28A, 29A ... Projection part, 28B, 29B ... Flat part, 30 ... hole.

Claims (8)

In a heat storage device comprising a plurality of tubular first heat medium branch pipes into which the first heat medium flows and a heat storage material provided on the outer periphery of the first heat medium branch pipes,
A first header portion that communicates with an upper portion of the first heat medium branch pipe and circulates the first heat medium; and a first upper reservoir portion that communicates with the first header portion and accumulates the first heat medium. A first inlet for communicating the first heat medium in communication with the first upper reservoir,
The heat storage device according to claim 1, wherein the first upper reservoir portion is provided in a direction intersecting a streamline direction of the first inlet portion.   2. The heat storage device according to claim 1, wherein the first upper reservoir portion is formed so as to protrude downward from an upper portion, and an inclined surface is formed upward from a lower portion of the first upper reservoir portion. . In a heat storage device comprising a plurality of second heat medium branch pipes for circulating the second heat medium and a heat storage material provided on the outer periphery of the second heat medium branch pipes,
A second header portion that communicates with an upper portion of the second heat medium branch pipe and distributes the second heat medium; and a second upper reservoir portion that communicates with the second header portion and accumulates the second heat medium. The second outlet for communicating the second heat medium in communication with the second upper reservoir,
The second upper reservoir portion is provided in a direction intersecting the streamline direction of the second outlet portion, and the first upper reservoir portion and the second upper reservoir portion are in contact with each other. The heat storage device according to claim 1 or 2.   The heat storage device according to any one of claims 1 to 3, wherein the first header portion and the second header portion are in contact with each other.   The heat storage device according to any one of claims 1 to 4, wherein the first heat medium branch pipe is formed in a surface direction of the first plate-like tube.   The heat storage device according to any one of claims 1 to 5, wherein the second heat medium branch pipe is formed in a surface direction of the second plate-like tube.   The first plate-like tube is provided so as to penetrate at least one of the second upper reservoir portion or the second lower reservoir portion, and a hole is provided in the penetrating first plate-like tube. The heat storage device according to claim 5 or 6, characterized in that.   The second plate-like tube is provided so as to penetrate at least one reservoir portion of the second upper reservoir portion or the second lower reservoir portion, and a hole is provided in the penetrating second plate-like tube. The heat storage device according to any one of claims 5 to 7, characterized in that.

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