KR970000500B1 - Heat storing system - Google Patents

Abstract

The heat accumulating system is capable of absorbing a frozen refrigerant from an ice manufacturing plate and rapidly cooling the ice manufacturing plate, while stopping the supply of refrigerant to the ice manufacturing plate of an ice manufacturing machine, thus to breaks the ice formed on the ice manufacturing plate into pieces. The heat accumulating system includes the ice manufacturing machine(2) and a heat accumulating vessel(3) into which ice is accumulated. The heat accumulating vessel(3) is adapted to be connected to the ice manufacturing machine(2), and while ventilating a normal temperature water accumulated in the heat accumulating vessel(3), the refrigerant is supplied to the ice manufacturing plate(4). Here, the water is cool up to water temperature of 2-5 deg. C and the cooling water is suppliedto the ice manufacturing machine(2), where the cooling water is changed to the ice. The ice is finally accumulated the heat accumulating vessel(3).

Description

Heat storage system

1 is a schematic view showing the configuration of a heat storage system of the present invention.

* Explanation of symbols for main parts of the drawings

1: heat storage device 2: ice maker

3: heat storage tank 4: ice making plate

5: Refrigerator 6: Refrigerant Circulation Pipe

6A: supply pipe 6B: return pipe

7: hot water tank 7A: hot water supply pipe

7B: Pump 7C: Hot Plate

8: high temperature gas discharge pipe 9: feed water pump

10 pump 11: partition

12: waterproof heat storage section 13: cold water section

14: outlet 15: inlet

16: water supply port 17: automatic water supply valve

18: expansion valve 19: electronic valve

20: bypass plate 21: electronic valve

The present invention relates to a heat storage system capable of improving heat storage efficiency and ice filling efficiency.

Conventionally, there is a type of heat storage system that accumulates a cold heat source using night power, and an ice maker is used. The co-heat storage device is an ice maker that manufactures ice and a heat storage tank that accumulates ice water as a heat source and a freezer that supplies refrigerant to ice makers. It is designed to store ice in the heat storage tank and to send cold water from the heat storage tank to the air conditioner during the day, and to control the air temperature by the cold water, but such a temperature measuring device supplies water to the ice making plate of the ice maker, An ice-making refrigerant was sent to cool the copper ice-making plate by the refrigerant to freeze water on its surface, and the ice formed on the ice-making plate was stored as cold heat in the heat storage tank.

In addition, the heat storage system supplies the refrigerant from the freezer to the ice making plate to cool the ice making plate with the refrigerant and freezes the room temperature water sprayed from the surface of the ice making plate. When the ice water is directly defrosted, the evaporation temperature is lowered to cool the COP. (The grade factor of a cooler) fell and it was not able to improve the ice-making efficiency.

In addition, when ice is collected from the ice making plate in a heat storage tank, it becomes a mass of a certain size, and thus it is not possible to accumulate a large amount of ice in the heat storage tank and thus does not improve the overall heat storage efficiency as a heat storage system.

In order to solve the above problems, the present invention connects an ice maker equipped with an ice maker and a heat storage tank collecting ice, and circulates normal temperature water collected in a coaxial heat tank, and supplies a refrigerant to the ice making plate. It is to provide a heat storage system characterized by cooling to water temperature and supplying water having a water temperature of 2 ~ 5 ℃ to the ice maker to form ice and accumulate the ice in the heat storage tank.

In addition, the present invention is characterized in that the ice formed in the ice-making plate is finely broken by sucking the copper refrigerant from the ice-making plate while stopping the supply of the refrigerant to the ice-making plate of the ice maker, and water supply and cooling the ice-making plate.

Hereinafter, the present invention will be described in detail with reference to Examples.

In FIG. 1, reference numeral 1 denotes a heat storage device of the present invention, and the co-heat storage device 1 includes an ice maker 2 for producing ice and water W to accumulate animals W as ice A. It consists of a heat storage tank 3, arrange | positions the heat storage tank 3 below a base, and the ice-making machine 2 is mounted above coaxial heat storage tank 3.

First, the configuration of the ice maker 2 will be described. The ice maker 2 includes a plurality of ice makers 4 and a refrigerator 5 for supplying refrigerant to the ice makers 4, and the ice maker 4 and the refrigerator 5 ) Is connected to the refrigerant circulation pipe (6), and the refrigerant liquefied by the condenser provided in the copper cooler (5) is evaporated at a low temperature through the expansion valve, through the supply pipe (6A) of the copper pipe (6). The gas is sent to the ice making plate 4 to cool the ice making plate 4 and then sucked from the ice making plate 4 to the freezer 5 via the return pipe 6B of the copper pipe 6.

And the liquid (A) is absorbed by the liquid refrigerant sent from the freezer (5) to absorb the heat of water (W) on the surface of the ice-making plate (4).

In addition, the refrigerator 5 is provided with a hot water tank 7, and when the heat medium is cooled to form a refrigerant, when the refrigerant is compressed by the compressor, the discharge gas is about 90 ° C., thus supplying copper gas to the hot water tank 7 to supply about 40 degrees. Collect hot water at ℃. In addition, the refrigerator 5 is connected to the hot water tank 7 through the hot gas discharge pipe 8 and supplies hot gas to the copper tank 7 to convert the water in the copper tank 7 into hot water of about 40 ° C. Doing. The hot water tank 7 is connected to the inside of the ice making plate 4 via a hot water supply pipe 7A having a pump 7B to supply hot water to the inside of the ice making plate 4, and to make the ice making plate with the same temperature. 4) is heated to thaw the ice (A) attached to it to peel off the ice (A) on the surface of the copper ice plate (4). In addition, 7 ° C indicates a hot water plate and receives the hot water flowing out of the ice making plate (4) from the copper hot water plate (7C) and returns to the hot water tank (7).

In this embodiment, the water W is supplied to the surface of each ice making plate 4 via the water supply pipe 9 to the heat storage tank 3, and the pump disposed in the heat storage tank 3 at the base end of the copper pipe 9. (10) is connected and sucked the collected water (W) in the coaxial heat tank (3) by the copper pump (10) to be incubated on the surface of the copper ice making plate (4) from a nozzle installed at the tip of the copper pipe (9) have.

In addition, the water incubated on the surface of the ice making plate 4 is spread to the surface and turned to the heat storage tank 3 disposed below, and gradually cooled to become ice (A) on the surface of the ice making plate 4, and the ice (A ) Is dropped into the heat storage station (3) and collected in the coaxial storage tank (3). In addition, a partition 11 for dividing ice (A) and water (W) is provided inside the heat storage tank (3) and partitioned into an ice water heat storage unit (12) and a cold water unit (13) to form a side wall on the cold water unit (13) side. At the same time, an outlet 14 for supplying cold water to the air conditioner is provided, and at the same time, an inlet 15 is returned from the air conditioner at the side wall of the ice water storage unit 12.

Reference numeral 16 denotes a water supply port installed in the heat storage tank 3, 17 an automatic water supply valve installed in the water supply port 16, 18 an expansion toilet installed in the refrigerant circulation pipe 6, 18 Is the electron valve installed in the copper pipe 6.

Next, the heat storage method by the heat storage device 1 of the present invention will be described.

First, tap water (W) having a temperature of about 18 ° C. is collected in the heat storage tank (3), and a water pump (10) is operated to pump the animal (W) onto the ice making plate (4) and drive the freezer (5) to cool the ice making refrigerant. The water (W) is sent to the ice making plate (4) and the water (W) is cooled on the surface of the ice making plate (4) and returned to the heat storage tank (3) to circulate the water (W). In addition, as the refrigerant from the refrigerator 5 passes through the expansion valve 18 installed in the refrigerant circulation pipe 6, the refrigerant evaporates in the low temperature state, and guides the low temperature refrigerant to the ice making plate 4, When the heat of the water (W) is taken away and the water (W) at room temperature in the heat storage tank (3) is cooled to 2 to 5 ° C, and the water (W) is cooled to 2 to 5 ° C, ice making is performed on the surface of the ice making plate (4). Begins.

After the ice (A) of about 5 to 15 mm is formed on the surface of the ice making plate (4), hot water of the hot water tank (7) is supplied to the ice making plate (4) to heat the ice making plate (4) and the ice making plate Ice (A) is peeled off the surface of (4) and dropped into the heat storage tank 3 to be accumulated in the heat storage tank 3.

In addition, the method of peeling the ice A from the ice making plate 4 according to the present invention will be described. When the ice A is formed on the surface of the ice making plate 4, the supply of water W and the refrigerant for ice making The refrigerator 5 is pulled down while the supply is stopped, and the inside of the ice making plate 4 is further cooled to bring the ice making plate 4 to -25 to 35 ° C., and the copper ice making plate 4 is contracted by such cooling. Gold is applied to the plate-shaped ice A by shrinkage to make it crush finely, and at the same time, the ice-making plate 4 is heated by supply of hot water so that the ice A can be easily peeled from the surface of the ice-making plate 4. It was.

In this embodiment, ice (A) is formed on the surface of the ice making plate (4), and the ice making plate (4) is cooled immediately before the ice is peeled off, and the electromagnetic valve (19) in the refrigerant circulation pipe (6) is locked to the compressor. When the refrigerant is sucked in, the refrigerant inside the ice making plate 4 rapidly evaporates and is quenched. At this time, the frozen ice is distorted by the ice (A) itself due to the shrinkage of the ice making plate (4), and the flat ice (A) attached to the surface of the ice is broken finely.

In addition, the bypass pipe 20 is connected between the refrigerant circulation pipe 6 and the high temperature gas discharge pipe 8 so that the discharge gas is sent from the high temperature gas discharge pipe 8 to the copper ice making plate 4. When the gas in the ice making plate 4 is discharged in order to break the flat ice A, the gas is supplied for 10 to 20 seconds by supplying the discharge gas from the high-temperature gas discharge pipe 8 into the ice making plate 4. By removing, the defrost of the circulation pipe 6 for refrigerant is removed, and sufficient gold is put in the ice A.

Reference numeral 21 is an electromagnetic side of the bypass tube 20.

In the present invention, the amount of ice (A) required in the heat storage tank (3) can be increased by smashing the flat ice (A) formed in the ice making plate (4) finely.

The effects of the present invention are as follows.

In the present invention, when the normal temperature water collected in the heat storage tank is regenerated as ice, first, the water of normal temperature supplied to the ice making plate is sent to the ice making plate, the water temperature of 2 to 5 ° C. is collected in the heat storage tank, and then the water having a water temperature of 2 to 5 ° C. Start deicing on the surface of the ice sheet by supplying it to the ice sheet. After ice is formed in the ice making plate, the ice is collected from the ice making plate in the heat storage tank to accumulate as ice.

In addition, after ice is formed in the ice maker, the ice maker can be further cooled by shrinking the ice maker to further crack the ice maker, thereby cracking the ice and increasing the storage capacity of the heat storage tank.

According to the present invention, the water at room temperature collected in the heat storage tank is first heated to a temperature of about 2 to 5 ° C., and the water at that temperature is used as ice, thereby improving the COP (frost coefficient of the freezer) and making ice at a high evaporation temperature. The overall heat storage efficiency can be improved by improving the efficiency and increasing the storage capacity of the heat storage tank by crushing flat ice formed in the ice making plate.

In addition, the heat storage system of the present invention has advantages in that the device can be miniaturized, the construction cost of the system can be reduced, and the space can be reduced by improving the C.O.P.

Claims (2)

The refrigerant is supplied to the ice making plate 4 while circulating the normal temperature water collected in the coaxial heat storage tank 3 by connecting the ice making machine 2 having the ice making plate 4 and the heat storage tank 3 collecting the ice. A heat storage system characterized by cooling to a water temperature of 5 DEG C and then supplying water having a water temperature of 2 to 5 DEG C to an ice maker (2) to form ice and accumulating the ice in the heat storage tank (3). The ice making plate 4 is rapidly cooled by sucking the copper refrigerant from the ice making plate 4 while stopping the supply of the refrigerant to the ice making plate 4 of the ice making machine 2. Heat storage system characterized by crushing ice formed in the