JP2001343193A - Heat storage tank - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heat storage tank which enables deceleration of the inflow velocity from the tank or the outflow velocity toward the tank and improve a heat storage efficiency. SOLUTION: Header pipes 5, 6 are disposed at the upper part and the lower part of heat storage tanks 10, 20, respectively. The header pipe 5 is provided with a plurality of branch pipes 11-1. The diameter of each branch pipe 11-1 is set at 1/3 to 1/6 of the diameter of the header pipe 5. A distributor 12-1 having a plurality of holes 14-1 is connected to the branch pipe 11-1. The plurality of holes 14-1 are arranged in rows at both sides of a line that goes along the axial direction, at the opposite side of the portion connected to the branch pipe 11-1 except a cylindrical wall portion that faces the portion connected to the branch pipe 11-1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a distributor which can be suitably used for a heat storage tank and the like, and a heat storage tank using the distributor.

[0002]

2. Description of the Related Art In recent years, a temperature stratified heat storage tank for storing cold or hot water supplied to an air conditioner or the like for power load leveling has been used. Temperature-stratified thermal storage tanks use the difference in density due to the difference in the temperature of the water in the tank, with high-temperature, low-density water at the top of the tank and low-temperature, high-density water at the bottom of the tank. It is something to store. FIG. 11 is a schematic diagram of an air conditioner using the thermal stratification type heat storage layer. The air conditioner shown in FIG. 11 includes a heat storage tank 50, a cooling / heating device 54 such as a heat pump, an air conditioner 55, and the like. The heat storage tank 50 is provided with water supply / water intake units 51 and 52 at the upper and lower parts.

[0003] The cold water stored in the heat storage tank 50 is supplied to an air conditioner 55.
In the case of using the switch, the on-off valves 58-a and 58-b are opened. Then, a water supply / water intake unit 52 is provided by a pump 59.
Air from the lower part of the heat storage tank 50 through the air conditioner 55
To supply. The high-temperature cold water that has undergone heat exchange in the air conditioner 55 is returned to the upper part of the heat storage tank 50 from the water supply / water intake unit 51. In this way, cooling is performed by the air conditioner 55.
On the other hand, during a time period when power demand is low, such as at night,
Open 6-a and 56-b. Then, high-temperature cold water is supplied to the cooling / heating device 54 from the upper part of the heat storage tank 50 via the water supply / water intake unit 51 by the pump 57. The low-temperature cold water cooled by the cooling / heating device 54 is returned from the water supply / water intake unit 52 to the lower part of the heat storage tank 50. Thermal storage tank 50
Inside, the low-temperature cold water is divided into the lower part and the high-temperature cold water is divided into the upper part due to the density difference, so that a temperature stratification is formed. When using the hot water stored in the heat storage tank in the air conditioner 55, the on-off valves 58-a and 58-b are opened. Then, the heat storage tank 5 is supplied by the pump 59 through the water supply / water intake unit 51.
High-temperature hot water is supplied to the air conditioner 55 from the upper part of the air conditioner 55. The hot water that has been cooled by the heat exchange in the air conditioner 55 is returned to the lower part of the heat storage tank 50 from the water supply / water intake unit 52. In this way, heating is performed by the air conditioner 55. On the other hand, during time periods when power demand is low, such as at night, on-off valves 56-a and 56-
Open b. Then, low-temperature hot water is supplied to the cooling / heating device 54 from the lower part of the heat storage tank 50 through the water supply / water intake unit 52 by the pump 57. The high-temperature hot water heated by the cooling / heating device 54 is returned from the water supply / water intake unit 51 to the upper part of the heat storage tank 50. In the heat storage tank 50, the high-temperature hot water is divided into the upper part and the low-temperature hot water is divided into the lower part due to the density difference, so that a temperature stratification is formed. Water supply / water intake unit 51,
Each of the distributors 52 is formed of a cylindrical inflow / outflow pipe provided with a plurality of holes on the outer periphery. It should be noted that different pumps may be used when using hot water and when using cold water. In some cases, only cold water or only hot water is stored.

[0004]

The above-mentioned distributor provided in the conventional water supply / water intake section has a structure in which cold water or hot water flows radially in or out from a plurality of holes provided on the outer periphery. Alternatively, the outflow speed tends to be uneven. For this reason, mixing of high-temperature and low-temperature cold water or hot water tends to occur in a portion where the inflow speed or the outflow speed is high, so that a temperature stratification cannot be favorably formed and the heat storage performance deteriorates. Also, when the depth of the heat storage tank is shallow, the heat storage performance is further reduced. Therefore, the present invention
An object of the present invention is to provide a heat storage tank and a distributor in which the inflow speed or the outflow speed of a fluid is reduced, a uniform temperature stratification can be formed even in a heat storage tank having a shallow water depth, and the heat storage performance is improved.

[0005]

According to a first aspect of the present invention, there is provided a heat storage tank according to the present invention. By using the heat storage tank described in claim 1, the supply speed of the fluid from each supply unit provided on the header pipe and the discharge speed of the fluid from each discharge unit can be reduced. Therefore, mixing of high-temperature and low-temperature fluids does not easily occur, and the heat storage performance is improved. Further, a second invention of the present invention is a heat storage tank as described in claim 2. By using the heat storage tank according to claim 2, the supply speed of the fluid from each supply unit provided in the header pipe and the discharge speed of the fluid from each discharge unit can be reduced, and the flow rate from each supply unit can be reduced. The supply amount of the fluid and the discharge amount of the fluid from each discharge unit can be made uniform. Therefore, mixing of high-temperature and low-temperature fluids does not easily occur, and the heat storage performance is improved. A third invention of the present invention is a heat storage tank as described in claim 3. By using the heat storage tank according to the third aspect, the supply amount of fluid from each supply unit provided in each header pipe and the discharge amount of fluid from each discharge unit can be made more uniform. Further, the fourth invention of the present invention
A heat storage tank as described in claim 4. Claim 4
When the heat storage tank described in (1) is used, the fluid can be efficiently supplied or discharged from each hole. Further, the fifth aspect of the present invention.
The invention is a heat storage tank as described in claim 5.
If the heat storage tank according to claim 5 is used, the fluid squeezed by the branch pipe collides with a portion facing the connection portion with the branch pipe and is weakened, and is further decelerated by the plurality of holes. Can be further reduced. Further, the discharge speed of the fluid can be further reduced. A sixth invention according to the present invention is a heat storage tank as described in claim 6. If the heat storage tank according to claim 6 is used,
The supply amount or discharge amount of the fluid from each distributor provided on the header pipe can be made more uniform. A seventh invention of the present invention is a heat storage tank as described in claim 7. If the heat storage tank according to claim 7 is used,
A multi-storage tank can be easily configured. An eighth invention of the present invention is a heat storage tank as described in claim 8. When the heat storage tank according to claim 8 is used, the header pipe can be arranged using the communication port for making the temperature distribution of each tank uniform, so that the multi-storage heat storage tank is configured more easily. be able to. A ninth aspect of the present invention is a distributor according to the ninth aspect. By using the distributor according to the ninth aspect, the supply speed of the fluid or the discharge speed of the fluid can be reduced. A tenth aspect of the present invention is a distributor according to the tenth aspect. With the distributor according to the tenth aspect, the fluid flowing from the supply / discharge port collides with a location opposite to the supply / discharge port and is weakened, and is further decelerated by the plurality of holes. The feed rate can be reduced.
Further, the discharge speed of the fluid can be reduced.

[0006]

Embodiments of the present invention will be described below with reference to the drawings. 1 and 2 show schematic configuration diagrams of an embodiment of the heat storage tank of the present invention. It should be noted that FIG.
FIG. 2 is a view taken along line II-II of FIG. In this embodiment, a multi-tank temperature stratified type heat storage tank in which two heat storage tanks 10 and 20 are arranged in parallel using a double slab space provided in the basement of a building having an earthquake-resistant structure. . Underground beams 1 and 2 to form a double slab space under the base of the building with seismic structure
3 are provided. By using the underground beams 1 to 3 and the foundation concrete 4, a heat storage tank 10 is formed between the underground beams 1 and 2, and a heat storage tank 20 is formed between the underground beams 2 and 3. The underground beam 2 is provided with communication ports 7 and 8 for making the temperature distribution of water in the heat storage tank 10 and the heat storage tank 20 uniform. Through the communication port 7 of the underground beam 2, the heat storage tank 10
The header pipe 5 is disposed on the upper part of the header pipe 20.
Moreover, through the communication port 8 of the underground beam 2, the heat storage tanks 10 and 2
0, a header pipe 6 is provided. On the upper side of the header pipe 5 (upper side of the heat storage tanks 10 and 20), branch pipes 11-1 to 11-6 are provided in the heat storage tank 10, and branch pipes 21-1 to 21- in the heat storage tank 20. 6
Is provided. On the lower side of the header pipe 6 (the lower side of the heat storage tanks 10 and 20), branch pipes 15-1 to 15-6 are provided in the heat storage tank 10, and the heat storage tank 20 is provided.
Inside are provided branch pipes 25-1 to 25-6.
The branch pipes 11-1 to 11-6 and 21-1 to 21-6 are provided on the opposite side to the connection with the header pipe 5 (the heat storage tank 1).
Distributor (Diffuser) 12-1 on the upper side of 0 and 20)
To 12-6, 22-1 to 22-6 are connected. Also, branch pipes 15-1 to 15-6, 25-1 to 25-
6 has distributors 16-1 to 16-6, 2-6 on the side opposite to the connection with the header pipe 6 (the lower side of the heat storage layers 10 and 20).
6-1 to 26-6 are connected.

[0007] Header pipes 5 and 6, branch pipe 11-
1 to 11-6, 15-1 to 15-6, 21-1 to 21-
6, 25-1 to 25-6, distributors 12-1 to 12-6,
16-1 to 16-6, 22-1 to 22-6, 26-1 to
26-6 is formed in a hollow cylindrical body by, for example, PVC or the like. The heat storage tanks 10 and 20 include a distributor 12-
Water is supplied to a position higher than the arrangement positions of 1 to 12-6 and 22-1 to 22-6. In addition, a water level sensor for detecting the water level of the water surfaces of the heat storage tanks 10 and 20, a water supply pipe, and an overflow pipe are provided. When it is over, the heat storage tank 1 is drained from the overflow pipe.
The water level of the water surface of the heat storage tank 20 may be maintained at a predetermined level.

FIG. 3 is an enlarged view of a portion H in FIG. Also,
FIG. 4 is a view taken along the line IV-IV in FIG. Note that FIG. 3 shows only the branch pipe 11-1 and the distributor 12-1, but the other branch pipes and distributors have the same configuration. The distributor 12-1 is formed of, for example, a hollow cylindrical body, and caps 13-1 are attached to both ends.
As shown in FIG. 4, the distributor 12-1 includes a branch pipe 1
1-1 is connected so as to communicate with a substantially central cylindrical wall. Also, the branch pipe 11-1 of the distributor 12-1.
A branch pipe 11-
A plurality of holes 14 are provided at portions except for the portion facing the connection portion with
-1 is formed. The plurality of holes 14-1 are formed in an axial line (FIG. 3) on the side facing the connection with the branch pipe 11-1.
In this example, the upper portion of the distributor 12-1 is formed in a row along the axial direction at approximately 45 degrees on both sides of the upper axial line. The interval between the holes 14-1 in the length direction of the distributor 12-1 is:
It is preferable to increase the width in the vicinity of the portion facing the connection with the branch pipe 11-1 in order to make the flow velocity in each hole 14-1 uniform. The diameter of the inner circumference of the distributor 12-1 is
It is equal to or larger than the inner diameter of the header pipe 5.

The header pipe 5 has one end closed and the other end connected to a water supply side or a water intake side of the air conditioner. The header pipe 6 has one end closed and the other end connected to an intake side or a water supply side of the air conditioner. For example, as shown in FIG. 11, when cold water is used, the other end of the header pipe 6 provided at the bottom is connected to the intake side (inflow side) of the air conditioner, and the other end of the header pipe 5 provided at the top is used. The water supply side (outflow side) of the air conditioner is connected to the end. When the power load is small at night or the like, the intake side of the cooler is connected to the other end of the header pipe 5 provided at the upper part, and the water supply side of the cooler is connected to the other end of the header pipe 6 provided at the lower part. You. When using hot water, the other end of the header pipe 5 provided on the upper side is connected to the intake side of the air conditioner, and the other end of the header pipe 6 provided on the lower side is connected to the water supply side of the air conditioner. When the power load is low at night or the like, the intake side of the heater is connected to the other end of the header pipe 6 provided at the lower part, and the water supply side of the heater is connected to the other end of the header pipe 5 provided at the upper part. You. The conventional thermal storage tank of the temperature stratification type needs a certain depth of water in order to surely form the temperature stratification. However, for example, in a thermal stratification-type heat storage tank or the like using a double slab space under the building, the water depth cannot be increased. For this reason, in order to improve the heat storage efficiency of such a heat storage tank, the inflow speed and the outflow speed of the water are reduced, and the water can be distributed throughout the heat storage tank to form a uniform temperature stratification. Vessel is required. According to the present invention, a temperature stratification can be reliably formed even when the water depth is shallow.

When a plurality of branch pipes are provided in the header pipe, one end of the header pipe is closed, and water supply / water intake means is connected to the other end, the amount of water flowing in or out of each branch pipe is equalized. The heat storage efficiency of the heat storage tank can be improved. In particular, when a multi-tank temperature stratified type heat storage tank is configured as in this embodiment,
It is preferable to make the inflow or outflow of water in each branch pipe uniform. By making the diameter of the inner circumference of the branch pipe smaller than the diameter of the inner circumference of the header pipe, the inflow or outflow of water in each branch pipe provided in the header pipe can be made uniform. FIGS. 5 to 10 show the results of measuring the inflow and outflow of water in each branch pipe when the ratio of the inner diameter of the branch pipe to the inner diameter of the header pipe is different. The measurements shown in FIGS. 5 to 10 were performed on a header pipe provided with ten branch pipes. In FIGS. 5 to 10, (a) shows the case where the diameter of the header pipe is set to 75 mm and the diameter of the branch pipe is set to 75 mm, and (b) shows the case where the diameter of the header pipe is 75 mm and the diameter of the branch pipe is 50 m.
m, the diameter of the header pipe is 75
mm, the diameter of the branch pipe is set to 40 mm,
(d) When the diameter of the header pipe is set to 75 mm and the diameter of the branch pipe is set to 25 mm, (e) when the diameter of the header pipe is set to 75 mm and the diameter of the branch pipe is set to 13 mm, and (f) is the case where the diameter of the branch pipe is set to 13 mm. Is set to 50 mm, the diameter of the branch pipe is set to 15 mm, and a distributor having a plurality of holes is provided in the branch pipe. Figure 5
The horizontal axis in FIG. 10 indicates the number of the branch pipe. The branch pipes are numbered with number 1 for the branch pipe provided closest to the connection of the header pipe connected to the water supply / water intake section, and numbered 10 for the branch pipe provided at the furthest position. are doing. The vertical axis in FIGS. 5 to 10 indicates a value obtained by dimensioning the inflow velocity or outflow velocity of water in each branch pipe by an average velocity. The outflow velocity (inflow velocity) refers to the velocity of water flowing out (inflow) at each branch pipe location. The average flow velocity refers to a value obtained by summing outflow (inflow) flow rates in each branch pipe, dividing the total flow rate by the number of branch pipes, and obtaining an average flow velocity per one branch pipe. The vertical axis indicates the ratio of the outflow (inflow) flow velocity and the average flow velocity in each pipe [outflow (inflow) flow velocity / average flow velocity]. Each numerical value in the graph indicates a deviation from the average flow velocity. Note that the flow velocity in the outflow direction is [+]
The case of the flow velocity in the inflow direction is indicated by [-].
FIGS. 5, 7, and 9 show the case where water from the header pipe flows out (water supply) into the heat storage tank via each branch pipe. FIGS. 6, 8, and 10 show the case where the water in the heat storage tank is branched. It shows a case in which the water flows (takes water) into the header pipe via the pipe. 5 and 6 show that the flow rate of the header pipe is 625.
7 and 8 show the case where the flow rate of the header pipe is 1250 cc / s, and FIGS. 9 and 10 show the case where the flow rate of the header pipe is 2500 cc / s.

As shown in FIGS. 5 to 10, when flowing into the heat storage tank via each of the branch pipes 1 to 10, the diameter of the branch pipe is set to be 25 mm or more with respect to the diameter of the header pipe of 75 mm. When the diameter is small (the diameter of the branch pipe is set to 1/3 or less of the diameter of the header pipe), water can be uniformly discharged from each of the branch pipes 1 to 10.
In addition, the larger the flow rate of the header pipe, that is, the higher the flow velocity in the header pipe, the more uniform the outflow amount, but there is no significant difference. When water is allowed to flow into the header pipe from inside the heat storage tank through each of the branch pipes 1 to 10, when the diameter of the branch pipe is large, the header pipe connected to the water supply means is located at a position close to the connection with the water supply means. The amount of inflow from the provided branch pipes 1 and 2 is large. However, when the diameter of the branch pipe is smaller than 25 mm (the diameter of the branch pipe is set to 1/3 or less of the diameter of the header pipe), water flows from the branch pipes 1 to 10 uniformly into the header pipe from the heat storage tank. be able to.
On the other hand, if the diameter of the branch pipe is too small, the amount of flow (or the amount of flow) flowing out (or flowing into each branch pipe) from each branch pipe is uniform, but the flow velocity is high, and a temperature stratification is favorably formed. Can not do. This tendency appears when the diameter of the branch pipe is 1/6 or less of the diameter of the header pipe. If the diameter of the branch pipe is too small, it is difficult to manufacture the branch pipe. From the above,
The diameter of the branch pipe should be 1/3 to 1 of the diameter of the header pipe.
By setting / 6, the inflow or outflow in each branch pipe can be made uniform. Thereby, as in the present embodiment, when a plurality of heat storage tanks are installed in parallel to form a multi-tank temperature stratified type heat storage tank, the branch pipes provided in each heat storage tank are connected to each other. Water can be made to flow uniformly into each heat storage tank, or water in each heat storage tank can be made to flow uniformly from each branch pipe provided in each heat storage tank. Therefore, the heat storage efficiency is improved.

On the other hand, when the diameter of the branch pipe is made smaller than the diameter of the header pipe in order to equalize the inflow or outflow in the branch pipe, the flow velocity of water in the branch pipe increases. For this reason, if water flows directly into the heat storage tank from each branch pipe, mixing of cold water or hot water on the high temperature side and the low temperature side occurs, and the heat storage efficiency is reduced. Thus, in the present embodiment, each of the branch pipes 11-1 to 11-6, 15
-1 to 15-6, 21-1 to 21-6, 25-1 to 25
(Multi-port diffuser) 12-1 to 12-6, 16-1 to 1 in which a plurality of holes 14-1 are formed in -6
6-6, 22-1 to 22-6, and 26-1 to 26-6. As shown in FIGS. 5 to 8F, when the distributor is attached, the inflow and outflow are made more uniform. See Figure 3 for details of the distributor.
And in FIG. In the present embodiment, the plurality of holes 14-1 are provided on the side of the distributor 12-1 opposite to the connection with the branch pipe 11-1, and the cylindrical wall portion facing the connection with the branch pipe 11-1. It is formed in the part except for. Further, the plurality of holes 14-1 are formed in a row along the axial direction at a position of approximately 45 degrees on both sides of the axial line on the side facing the connection portion with the branch pipe 11-1. . Multiple holes 14-1
Is formed on the side opposite to the connection with the branch pipe 11-1, so that the water supplied from the branch pipe 11-1 flows out of the hole 14-1 efficiently. Also, a plurality of holes 14
-1 is formed in a portion excluding a cylindrical wall portion facing a connection portion with the branch pipe 11-1, so that the branch pipe 11
The water supplied from -1 collides with the inner surface of the cylindrical wall at the portion facing the branch pipe connection, and the flow velocity of the water decreases. Also, by forming the plurality of holes 14-1 in a row along the axial direction at approximately 45 degrees on both sides of the axial line on the side facing the connection with the branch pipe 11-1, The flow rate of water can be further reduced. That is, the branch pipe 11
The water whose flow velocity has been reduced by colliding with the cylindrical wall surface of the portion opposite to the connection portion with -1 is efficiently placed along a plurality of holes 14 along the cylindrical wall surface.
-1 and flows out of the hole 14-1. This allows
The water flow rate is further reduced.

As described above, in this embodiment, the inflow or outflow at each branch pipe is reduced by making the diameter of the inner surface of the plurality of branch pipes provided in the header pipe smaller than the diameter of the inner surface of the header pipe. It can be made uniform. A distributor having a plurality of holes is connected to each branch pipe. Here, the plurality of holes are formed in a row on both sides of a line along the axial direction in a portion excluding a cylindrical wall portion opposite to a connection portion with the branch pipe (opposing the connection portion with the branch pipe). Has formed. Thereby, the flow velocity in each hole can be reduced, and mixing of high and low temperature hot or cold water in the heat storage tank can be prevented. Therefore, the heat storage efficiency of the heat storage tank is improved. And since the flow rate in each branch pipe provided in the header pipe can be made uniform, it is possible to improve the heat storage efficiency of a multi-tank temperature stratified heat storage tank in which a plurality of shallow heat storage tanks are installed in parallel. it can. In addition, the header pipes arranged above and below each heat storage tank are shared by each heat storage tank. Thereby, since it is not necessary to provide a header pipe for each heat storage tank, the structure of a multi-tank temperature stratified heat storage tank is simplified.
Further, a header pipe is provided through a communication port for making the temperature distribution of water in a plurality of heat storage tanks installed in parallel uniform. Thus, since it is not necessary to make a hole for inserting a header pipe provided in each heat storage tank, the structure of the multi-tank temperature stratified type heat storage tank is simplified.

In the above embodiment, a two-tank multi-tank temperature stratified type heat storage tank has been described, but the present invention can also be configured as a multi-tank multi-layer temperature stratified heat storage tank. Further, it can be configured as one heat storage tank. Also, the heat storage tank that stores hot water or cold water using the water supply / water intake unit has been described, but it may be configured as a heat storage tank that stores only hot water or only cold water using the water supply unit or the water intake unit. Further, the formation position, the number, the shape, and the like of the plurality of holes formed in the distributor are not limited to the embodiments and can be variously changed. Further, the present invention has a characteristic as a distributor alone, and can be applied as a distributor of various temperature stratified heat storage tanks. In this case, the inflow velocity or the outflow velocity in the plurality of holes can be reduced. Although water was supplied to the heat storage tank, the fluid supplied to the heat storage tank is not limited to water.

[0015]

As described above, by using the heat storage tank described in claim 1, a heat storage tank with improved heat storage performance can be obtained. Further, the use of the heat storage tank described in claim 2 makes it possible to equalize the amount of fluid supplied from each supply unit provided in the header pipe and the amount of fluid discharged from each discharge unit. Further, the use of the heat storage tank according to the third aspect makes it possible to further uniform the supply and discharge of the fluid. In addition, by using the heat storage tank described in claim 4, the fluid can be efficiently supplied or discharged from each hole. Further, if the heat storage tank described in claim 5 is used, the supply speed of the fluid or the discharge speed of the fluid can be further reduced. In addition, the use of the heat storage tank according to claim 6 makes it possible to more uniformly supply or discharge the fluid from each distributor provided in the header pipe.
In addition, when the heat storage tank described in claim 7 is used, a multi-storage tank can be easily configured. In addition, when the heat storage tank described in claim 8 is used, a multi-tank heat storage tank can be configured more easily. Further, by using the distributor according to the ninth aspect, the supply speed of the fluid or the discharge speed of the fluid can be reduced. Further, the use of the distributor according to claim 10 makes it possible to further reduce the supply speed of the fluid or the discharge speed of the fluid.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of an embodiment of the present invention.

FIG. 2 is a view taken along line II-II of FIG.

FIG. 3 is an enlarged view of a portion H in FIG. 1;

FIG. 4 is a view taken along a line IV-IV in FIG. 3;

FIG. 5 is a diagram showing a relationship between a diameter ratio between a branch pipe and a header pipe and an outflow velocity.

FIG. 6 is a diagram showing a relationship between a diameter ratio between a branch pipe and a header pipe and an inflow velocity.

FIG. 7 is a diagram showing a relationship between a diameter ratio between a branch pipe and a header pipe and an outflow velocity.

FIG. 8 is a diagram showing a relationship between a diameter ratio between a branch pipe and a header pipe and an inflow velocity.

FIG. 9 is a diagram showing a relationship between a diameter ratio between a branch pipe and a header pipe and an outflow velocity.

FIG. 10 is a diagram illustrating a relationship between a diameter ratio of a branch pipe and a header pipe and an inflow velocity.

FIG. 11 is a schematic diagram of an air conditioner using a heat storage tank.

[Explanation of symbols]

 1, 2, 3 Underground beam 5, 6 Header pipe 7, 8 Communication port 10, 20 Heat storage tank 11, 15, 21, 25 Branch pipe 12, 16, 22, 26 Distributor 14-1 hole

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Minari Iwata 1 Higashi-Shinmachi, Higashi-ku, Nagoya City, Aichi Prefecture Inside Chubu Electric Power Co., Inc.

Claims (10)

[Claims] 1. A heat storage tank comprising a header pipe provided at an upper part and a lower part in a tank, a supply part provided at one of the header pipes provided at the upper part and a lower part, and a discharge part provided at the other. Wherein the supply unit and the discharge unit each include a branch pipe provided in the header pipe, and a distributor connected to the branch pipe and having a plurality of holes formed therein. 2. The heat storage tank according to claim 1, wherein the diameter of the branch pipe is smaller than the diameter of the header pipe. 3. The heat storage tank according to claim 2, wherein the diameter of the branch pipe is 1/3 to 1/6 of the diameter of the header pipe.
Thermal storage tank set to. 4. The heat storage tank according to claim 1, wherein the plurality of holes are formed on a side facing a connecting portion with the branch pipe. 5. The heat storage tank according to claim 1, wherein the plurality of holes are formed at locations other than a portion facing a connecting portion with the branch pipe. 6. The heat storage tank according to claim 5, wherein the plurality of holes are formed on both sides with respect to an axial line on a side facing the connection with the branch pipe. 7. The heat storage tank according to claim 1, wherein a plurality of heat storage tanks are provided, and a header pipe is provided over each tank. 8. The heat storage tank according to claim 7, wherein the header pipe is inserted into a communication port connecting the tanks. 9. A distributor having a supply / discharge port and a plurality of holes formed on a side facing the supply / discharge port and excluding a portion facing the supply / discharge port. 10. The distributor according to claim 9, wherein the plurality of holes are formed on both sides with respect to an axial line facing the supply / discharge port.