KR200166820Y1 - Storage device for ice storage system - Google Patents

Abstract

The present invention relates to a heat storage device for an ice heat storage system, wherein the water contained in the ice heat storage tank is provided with a plurality of heat exchange pipes that individually form lines to move the refrigerant in a horizontal direction with respect to the total depth, and one end of the heat exchange pipe is a refrigerant. It is connected to a distribution pipe connected to the supply pipe, and another end of the heat exchange pipe corresponding to the distribution pipe is connected to a recovery pipe connected to the recovery pipe to collectively recover the refrigerant moving horizontally along each line. As a structure, it is possible to form ice as a whole within a short time and to shorten the ice storage time and significantly reduce power consumption.

Description

Storage device for ice storage system {storage device for ice storage system}

The present invention relates to a heat storage device for an ice heat storage system, and more particularly, a plurality of heat exchange pipes that form each line individually so that the refrigerant moves horizontally is installed horizontally from the depth, and the refrigerant is uniform in each heat exchange pipe. By installing a distributor so that the water is supplied, the water stored in the heat storage tank can be rapidly and totally iced to improve the efficiency of the ice heat storage.

Generally, the ice storage system first accommodates circulating water in the ice storage tank to a certain level, and then cools it with ice at night using low-cost late night electricity in summer, and then supplies cold water that thawed ice during the day to the indoor unit. By using it for cooling, it is a cooling method that can reduce the power load during the day as well as economical cooling by significantly reducing the cost of using the power of the indoor unit during the cooling operation during the day.

1 is a view illustrating a conventional heat storage device for an ice storage system, and first, a water supply pipe having a water supply valve 12 to supply water 16 to an upper side of the ice storage tank 10. 14 is connected and installed, and the water 16 accommodated in the ice storage tank 10 is attached to a heat exchange pipe 18 having a '⊂' shape while forming each line individually, as shown in FIG. 2. It is vertically spaced apart.

In addition, the upper end of the heat exchange pipe 18, which is individually formed, is all connected to one distribution pipe 22 to which the refrigerant supply pipe 20 is connected, and the other end of the heat exchange pipe 18 integrates the refrigerant. All of them are connected to one recovery pipe 24 for recovery, and a recovery pipe 26 is connected to the center of the recovery pipe 24 and drawn out to the outside.

Meanwhile, a circulation pump 28 is installed at one bottom surface of the ice storage tank 10, and the circulation pump 28 is connected to the upper portion of the ice storage tank 10 by a connection pipe 30. On the lower side of the other side corresponding thereto, a recovery pipe 34 having a control valve 32 is installed to be connected to the inside of the ice storage tank 10.

In addition, the discharge portion of the circulation pump 28 is connected to the indoor unit through the supply pipe 36 for supplying the circulating water, which is recovered to recover the circulated water for cooling the ice storage tank 10. It is interconnected with the recovery pipe 34 via a pipe 38.

In the conventional heat storage device for an ice storage system configured as described above, one distribution pipe is provided along a refrigerant supply pipe 20 as shown in FIGS. 1 and 2 to which an refrigerant cooled by an outdoor unit (not shown) is attached. At this time, the upper and lower ends of the plurality of heat exchange pipes 18 forming each line are connected to the distribution pipe 22 so that the refrigerant collected in the distribution pipe 22 is heat exchanged in each line. Simultaneously supplied to the pipe 18, the refrigerant moving along the heat exchange pipe 18 of each line is integrated and recovered into one recovery pipe 24 to which another lower end of the heat exchange pipe 18 is connected. 26) is returned to the outdoor unit.

On the other hand, when the refrigerant moves along a plurality of heat exchange pipes 18 forming each line, the heat exchange pipe 18 is immersed in the water 16 contained in the ice storage tank 10 to move the refrigerant and water 16 Ice is formed on the surface of the heat exchange pipe 18 by heat exchange. At this time, heat is first exchanged from the upper portion of the heat exchange pipe 18 installed vertically, and the cooling temperature of the refrigerant is gradually increased while moving downward. Gradually ice is made from the top of the ice heat storage tank (10).

In addition, when the circulation pump 28 installed in the ice storage tank 10 is operated in order to cool during the day in the above state, the circulation pump 28 connects the upper portion of the ice storage tank 10 to the connection pipe 18. Connected to each other to suck the cold water 16 present in the ice storage tank 10, the sucked water 16 is supplied to the indoor unit along the supply pipe 36 connected to the circulation pump 28 After the heat exchange is performed, it is recovered into the ice storage tank 10 by the recovery pipe 38 connected to the indoor unit.

At this time, the recovered water 16 is recovered and introduced into the ice storage tank 10 at a temperature that is higher than the temperature before heat exchange with the indoor unit, thereby being present in the ice storage tank 10 by the temperature of the water 16 recovered. It is quickly melting some of the ice that is done.

On the other hand, the water 16 contained in the ice storage tank 10 sets its temperature to 0 ° C. to maintain both the solid ice and the liquid water 16 at a similar ratio, which is below zero. In the case of setting, the water 16 contained in the ice storage tank 10 is frozen in solid ice to prevent the supply of circulating water due to cooling of the ice storage heat in the future, and the connection pipe of the ice storage tank 10. The reason why the horizontal position of the 18 and the recovery pipe 24 is spaced apart is that the elevated water 16 flowing from the recovery pipe 24 does not serve as sea ice and is located on the same line as the connection pipe 18. In order to prevent as much as possible by being directly introduced into the furnace, the efficiency of cooling is reduced.

However, in the conventional heat storage device for an ice storage system as described above, first, the temperature of the air that exists in the upper portion from the water surface of the water 16 is the water 16 of the upper portion to be present inside the ice storage tank 10 By the temperature of the lower portion of the water (16) to rise above, at this time, all of the heat exchange pipes 18 forming each line is installed vertically so that the first heat supply to the heat exchange from the upper portion of the water (16) is started In this case, the heat exchange is large in the upper line of all the heat exchange pipes 18 into which the refrigerant is first introduced, and thus the refrigerant introduced into the refrigerant is rapidly increased in temperature, and thus water 16 is present in the upper portion. Ice making time will be longer. In addition, the water 16 of the lower portion has already had a problem that the heat exchange capacity of the refrigerant is rapidly reduced, so that the overall ice heat storage time is long.

The present invention was devised to solve the above problems, by installing a plurality of heat exchange pipes forming a separate line in the horizontal direction from the depth to allow the refrigerant to move horizontally to exchange heat, and to each line of the heat exchange pipe It is an object of the present invention to provide a heat storage device for an ice heat storage system that can shorten the overall ice making time and significantly reduce power consumption by providing a distributor so that the refrigerant is uniformly supplied.

The present invention for achieving the above object is provided with a plurality of heat exchange pipes to form a line in the water contained in the ice storage tank to move the refrigerant in a horizontal direction with respect to the total depth, one end of the heat exchange pipe is supplied with a refrigerant It is connected to one distribution pipe connected to the pipe, and another end of the heat exchange pipe corresponding to the distribution pipe is connected to a recovery pipe connected to the recovery pipe to collectively recover the refrigerant moving horizontally along each line. As a whole, ice-making of water contained in the ice storage tank is formed as a whole within a short time, so that the ice storage time can be shortened and power consumption can be significantly reduced.

1 is a front view showing the interior of a conventional heat storage device for ice heat storage system;

2 is a perspective view showing a heat exchange pipe installation state of FIG.

Figure 3 is a front view showing the interior of the heat storage device for ice storage system of the present invention

4 is a perspective view showing a heat exchange pipe installation state of FIG.

<Description of the code | symbol about the principal part of drawing>

10: ice storage tank 12: water supply valve

14: water supply pipe 16: water

18,40: heat exchange pipe 20: refrigerant supply pipe

22,42: Distribution pipe 24,34,44: Recovery pipe

26,38: recovery pipe 28: circulation pump

30: connection pipe 32: control valve

36: supply pipe

3 and 4 is a view showing a heat storage device for an ice heat storage system of the present invention, the same reference numerals as in the accompanying example drawings 1 and 2 denote the same parts, so a description thereof will be omitted. Only differences from FIG. 1 will be described.

3 and 4, first, in the ice storage tank 10, a plurality of heat exchange pipes 40 forming a '⊂' shape along the depth of water 16 are spaced apart from each other. Is installed horizontally so as to move horizontally along an individual line, and one end of the heat exchange pipe 40 constituting each line is connected to one distribution pipe 42 vertically installed, and this distribution pipe 42 At the center of the) is a refrigerant supply pipe 20 for supplying a refrigerant.

In addition, the other end of the distribution pipe 42 and the corresponding heat exchange pipe 40 are all connected to the vertically installed recovery pipe 44 to collectively recover the refrigerant moving along each line. A recovery pipe 26 for finally recovering the refrigerant is connected to the recovery pipe 44 so as to be drawn out of the ice storage tank 10.

The present invention configured as described above is shown in the accompanying drawings, Figure 3 and 4, first, the refrigerant cooled by the operation of the outdoor unit not shown is moved along the refrigerant supply pipe 20 ice storage tank 10 In the distribution pipe 42 is installed in the interior of the distribution pipe 42 is connected to a plurality of heat exchange pipes 40 to form each line horizontally, the first to be present in the distribution pipe 42 The refrigerant is temporarily supplied to the heat exchange pipes 40 of the horizontal lines.

However, the water 16 of the upper portion that is present inside the ice storage tank 10 is somewhat higher than the temperature of the lower portion 16 by the temperature of the air that is present in the upper portion from the water surface of the water 16. In this case, the heat exchange pipes 18 forming each line are installed so that heat exchange is performed horizontally from a depth existing in the ice storage tank 10, and thus the heat exchange pipe 18 is positioned at the top end. In the line of heat exchange, as in the prior art, the ice making time of the water 16 existing in the upper portion becomes long, but the heat exchange pipe 18 of each line located at the lower portion has a cooling loss of the refrigerant to be heat exchanged for the first time. By being reduced in comparison with the conventional, water 16 which is present in the central portion and the lower portion of the heat storage tank 10 is frozen at a uniform and rapid rate, and thus frozen. Is as ice as a whole proceeds rapidly reduce the speed and its power consumption is thereby in accordance with the temperature rapidly decreases in the cold-heat accumulating time of the entire hot and cold water 16 which is present in the top.

As described above, the present invention is provided with a plurality of heat exchange pipes horizontally so that the refrigerant moves horizontally from the water depth of the heat storage tank, and by installing a distributor so that the refrigerant is uniformly supplied to each heat exchange pipe, the overall uniformity within a quick time While performing ice heat storage, power consumption can be significantly reduced.

Claims (1)

In the heat storage device for an ice storage system for circulating the cooled refrigerant to ice the water (16) contained in the ice storage tank 10, The water 16 accommodated in the ice storage tank 10 is provided with a plurality of heat exchange pipes 40 which individually form lines so that the refrigerant moves in a horizontal direction with respect to the total depth, and one end of the heat exchange pipe 40. Is connected to one distribution pipe 42 connected to the refrigerant supply pipe 20, and another end of the heat exchange pipe 40 corresponding to the distribution pipe 42 is a refrigerant moving horizontally along each line. Heat storage device for an ice storage system, characterized in that connected to the recovery pipe 44 connected to the recovery pipe 26 to recover integrally.