KR200242390Y1 - Jet device for ice container - Google Patents

Abstract

The present invention is to spray the hot water recovered from the indoor unit through the injection port in the ice storage tank to effectively and quickly thaw the ice present in the ice storage tank to facilitate the supply of cold water supplied to the indoor unit, and to minimize the ice remaining in the ice storage tank It relates to an ice storage tank injection port.

Conventional ice heat storage system dissolves ice while cooling water from the indoor unit is recovered to the ice heat storage tank. At this time, the ice heat storage tank has a large capacity, or during the initial cooling operation, the ice existing in the ice storage heat tank can be quickly recovered using only the circulating water recovered from the recovery pipe. It was difficult to thaw so that there was a problem that the cooling efficiency is rapidly lowered.

The present invention has been made in view of such a conventional problem, the hot water pipe for connecting the hot water inflow to connect from one side of the recovery valve, at least one other hot water pipe fastened by a socket to the hot water pipe, and the hot water pipe It consists of a nozzle that is attached to one end of the.

The present invention having such a configuration by spraying the hot water recovered from the indoor unit through the injection port in the ice storage tank, to quickly and effectively thaw the ice present in the ice storage tank to facilitate the circulation of the cold water supplied to the indoor unit, in the ice storage tank This is to minimize the remaining ice.

Description

Jet device for ice storage tank {Jet device for ice container}

The present invention relates to an injection port for an ice storage tank, and more specifically, to efficiently and quickly thaw the ice present in the ice storage tank with hot water recovered from the indoor unit to smoothly supply the cold water supplied to the indoor unit, and to remove the ice remaining in the ice storage tank. It relates to an ice storage tank nozzle to minimize.

In general, the ice storage tank provided in the ice storage system accommodates water up to a certain level, and then cools it with ice at night using low-cost late night power in the summer, and then cools it with an indoor unit by supplying cold water that has thawed ice during the day. By using it, it is a cooling method that can significantly reduce the cost of electric power use according to the daytime cooling operation to achieve economical cooling as well as reduce the power load.

1 is a view illustrating a conventional ice heat storage system. First, an upper side of an ice heat storage tank 10 is connected to a water supply pipe 16 having a water supply valve 14 to supply water 12 therein. The water 12 accommodated in the ice storage tank 10 is vertically spaced apart from each other, as shown in FIG. 2, in which a plurality of heat exchange pipes 18 constituting each line are attached.

In addition, the upper end of the heat exchange pipe (18) made separately is 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 refrigerant recovery tube 24 for recovery, and a refrigerant recovery pipe 26 is connected to the center of the refrigerant recovery tube 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 each other through an upper portion of the ice storage tank 10 and a connection pipe 30. In addition, the lower side of the other side corresponding to the recovery valve 34 having a control valve 32 is installed to be connected to the interior of the ice storage tank (10).

The discharge portion of the circulation pump 28 is interconnected with the indoor unit 37 via a supply pipe 36 for supplying the circulation water, and the indoor unit 37 stores the circulating water for cooling the ice storage tank. It is connected to the recovery pipe 38 to recover with 10, and the other end of the recovery pipe 38 is interconnected with the recovery valve 34.

In the conventional ice storage tank configured as described above, as shown in the accompanying drawings of FIGS. 1 and 2, first, a refrigerant cooled by an outdoor unit (not shown) is supplied to one distribution pipe 22 along the refrigerant supply pipe 20. In this case, all of the upper 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 the heat exchange pipe 18 of each line. Refrigerant which is supplied at a time and moves along the heat exchange pipe 18 of each line is recovered back to the outdoor unit through the heat exchange pipe 18.

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 12 accommodated in the ice storage tank 10 to move the refrigerant and water 12 The heat is exchanged with each other to form ice on the surface of the heat exchange pipe 18. At this time, the heat is exchanged for the first time 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. As a result, the ice making is gradually made from the top of the ice 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 and the connection pipe 30 of the ice storage tank 10 to each other. It is connected to each other via a medium to suck the cold water 12 that is present in the ice storage tank (10).

In addition, the water 12 sucked as described above is supplied to the indoor unit 37 along the supply pipe 36 connected to the circulation pump 28 to perform heat exchange, and then the recovery pipe 38 connected to the indoor unit 37. Recovered to the inside of the ice storage tank 10 through the), wherein the recovered water 12 is recovered and introduced into the ice storage tank 10 at a temperature higher than the temperature before heat exchange with the indoor unit 37, and eventually recovered The ice that is present in the ice storage tank 10 is melted by the temperature of the water 12.

On the other hand, the water 12 accommodated in the ice storage tank 10 sets its temperature to 0 ° C., so that both the solid ice and the liquid water 12 are present in a similar ratio, which is below zero. In order to prevent the supply of circulating water due to the cooling of the ice storage heat after cooling the water (12) accommodated in the ice storage tank (10) all solid ice in the case of setting, the connection of the ice storage tank (10) The reason why the horizontal position of the pipe 30 and the recovery valve 34 is different is that the water 12 at room temperature flowing from the recovery valve 34 does not play a role of sea ice, and the connection pipe 30 is located on the same line. In order to prevent the reduction of both the efficiency of thawing and cooling by flowing directly into the furnace.

However, the conventional ice heat storage system as described above melts ice while the water 12 having been cooled from the indoor unit 37 is recovered to the ice heat storage tank 10, in which the ice storage heat storage tank 10 is a large capacity or an initial stage. During the cooling operation, it is difficult to quickly thaw the ice present in the ice storage tank 10 only with the circulating water recovered from the recovery pipe 38, and thus, the supply and circulation of the cold and hot water supplied to the indoor unit 37 is naturally delayed. There was a problem that the cooling efficiency is rapidly reduced because it can not maximize the cooling in a short time.

The present invention has been made in view of the above problems, by spraying the hot water recovered from the indoor unit through the injection port in the ice storage tank to effectively and quickly thaw the ice existing in the ice storage tank to supply the cold water supplied to the indoor unit smoothly It is an object to provide a nozzle for the ice storage tank to minimize the ice remaining in the ice storage tank.

1 is a front view showing the interior of a typical ice storage tank

Figure 2 is a perspective view of the heat exchange pipe of Figure 1

Figure 3 is a front view showing the ice storage tank of the present invention

4 is an enlarged view of the hot water pipe and the nozzle of the present invention

Figure 5 is an enlarged view showing the bottom of the nozzle of the present invention

* Description of the symbols for the main parts of the drawings *

10: ice storage tank 12: water

14: water supply valve 16: water supply pipe

18: heat exchange pipe 20: refrigerant pipe

22: distribution pipe 24: refrigerant recovery pipe

26: refrigerant recovery pipe 28: circulation pump

30: connection pipe 32: control valve

34: recovery valve 36: supply pipe

37: indoor unit 38: recovery pipe

40,42: hot water pipe 41: socket

43: injection hole 44: the outer surface

45: injection hole 46: injection water

The present invention for achieving the above object is an ice storage tank for ice-making the water accommodated by the built-in heat exchange pipe, an indoor unit for receiving heat from the ice storage tank to heat exchange, and recovering the circulating water heat exchanged from the indoor unit An ice heat storage device interconnected with a recovery valve provided at one side, comprising: a hot water pipe connected to one side of the recovery valve to introduce hot water, at least one other hot water pipe connected to the hot water pipe by a socket, and the hot water It is characterized by a technical feature consisting of the injection hole attached to one end of the pipe.

In addition, the injection hole is formed with a spray hole for injecting the hot water introduced from the hot water pipe, characterized in that formed in a spiral in the vertical direction.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a view illustrating a state in which an injection port for an ice storage tank according to the present invention is mounted on an ice storage tank, and the same reference numerals as the accompanying drawings 1 and 2 denote the same parts, and thus description thereof will be omitted. Only different points from FIGS. 1 and 2 will be described.

The present invention is an ice storage tank 10 for ice-making water 12 accommodated by the built-in heat exchange pipe 18, an indoor unit 37 for receiving cold water from the ice storage tank 10 and heat exchange, and the indoor unit 37 In the ice heat storage device interconnected with the recovery valve 34 provided on one side of the ice storage tank 10 to recover the heat-exchanged circulating water from the water), the hot water connected to pass from one side of the recovery valve 34 to introduce hot water A pipe 40; One or more hot water pipes 42 fastened to the hot water pipes 40 by sockets 41; It consists of a spray port 43 is attached to one end of the hot water pipe 42.

At this time, preferably the hot water pipe 42 is bent 90 degrees so that the injection hole 43 can be directed downward in the water direction, more preferably two hot water pipes 42 are bent at both ends 90 degrees Is fastened to the hot water pipe 40 is connected to the 'T' type socket 41 through the recovery valve 34 can be fixed. Furthermore, if the number of injection holes 43 is to be increased to speed up the thawing speed of ice, the hot water pipe 42 provided with the injection holes 43 is connected to an appropriate number of sockets 41 and another hot water pipe 42. Furnace, the fastening and fastening to the hot water pipe 40 connected to the recovery valve 34. 3 and 4, three 'T' type sockets (2) are provided in the hot water pipe 40 having the injection hole 43 and two hot water pipes 42 bent at both ends thereof connected to the recovery valve 34. 41) and another hot water pipe 42 is fastened. It shows that it is fixed.

In addition, the injection port 43 is injected and discharged at high speed while the hot water introduced from the hot water pipes 40 and 42 passes through the narrow injection hole 45 due to the pushing force of the circulation pump 28, and at the same time spiral Flow along the outer surface 44 is made to receive a circumferential force is sprayed to a wide range.

Here, since the injection hole 43 is narrow in shape as it rotates in a spiral as it goes down in the vertical direction, a part of the hot water introduced from the hot water pipe 42 is injected as soon as it exits the injection hole 45, The other part may be discharged from the injection hole 45 and then flows along the outer surface of the injection hole 43 to have high-speed injection with circumferential force and may have an injection angle of up to 150 degrees.

The present invention configured as described above, as shown in the accompanying drawings of Figure 1, first, after the cooling operation during the cooling operation of the cold-heated water 12 is supplied to the indoor unit 37 to perform the cooling, ice storage tank 10 ) Is recovered through the recovery valve 34, and the circulated water recovered in this way is heated by the heat exchange action while passing through the indoor unit 37. The hot water circulating water thaws the ice present in the ice storage tank 10. At this time, when the ice storage tank 10 has a large capacity or during the initial cooling operation, the ice storage heat is generated only by the circulating water recovered from the recovery pipe 38. It is difficult to thaw the ice existing in the tank 10 in a short time, so the cooling efficiency is drastically lowered.

At this time, the hot water pipe 40 is connected to the recovery valve 34 as in the present invention of FIG. 3, and at least one hot water pipe 42 having the injection hole 43 attached to the hot water pipe 40. After fastening and configuring the socket 41, when the circulation pump 28 circulated and connected to the ice storage tank 10 is operated, the water 12 existing in the ice storage tank 10 is supplied to the indoor unit 37. After the cooling is performed, the hot water pipe 40 is introduced into the hot water pipe 40 through the recovery valve 34 of the ice storage tank 10, and is sprayed at a high speed through the injection hole 43 through another hot water pipe 42 connected thereto. .

Accordingly, during spraying, hot water is injected through the narrow spray hole 45, so that the spraying range is widened. Furthermore, the shape of the spray hole 43 is helical, and thus the hot water sprayed is ejected through the outer surface of the spiral. Has a spraying range.

When hot water is sprayed at a high speed in a wide range as described above, the water 12 existing in the ice storage tank 10 flows as a whole by the injection force of the hot water, and the ice partly iced according to the flow of the water 12 Cold water is rapidly supplied to the indoor unit 37 while thawing quickly.

As described above, the present invention injects the hot water recovered from the indoor unit through the injection port in the ice storage tank, thereby quickly and effectively thawing the ice present in the ice storage tank to smooth the circulation of the cold water supplied to the indoor storage tank, It is possible to minimize the remaining ice is a very useful design.

Claims (2)

Ice storage tank 10 for ice-making water 12 received by the built-in heat exchange pipe 18, An indoor unit (37) for receiving heat from the ice storage tank (10) and exchanging heat; In the ice storage device interconnected with the recovery valve 34 provided on one side of the ice storage tank 10 to recover the circulating water heat exchanged from the indoor unit 37, A hot water pipe 40 connected to one side of the recovery valve 34 to introduce hot water; One or more hot water pipes 42 fastened to the hot water pipes 40 by sockets 41; Ice storage tank injection port characterized in that consisting of the injection port 43 is attached to one end of the hot water pipe (42). The method of claim 1, The injection hole (43) is formed with a spray hole (45) for injecting the hot water introduced from the hot water pipes (40, 42), characterized in that formed in a spiral in the vertical direction.