KR100187774B1 - A regenerative cooling system - Google Patents

Abstract

The present invention relates to an ice storage and cooling system, and more particularly, to an ice storage and cooling system in which cold water cooled in a cold water evaporator is directly supplied to a cooling load during single operation of a freezer and in parallel operation of a storage tank, The power consumption of the brine pump can be reduced by stopping the operation of the brine pump.

The present invention is characterized in that a compressor (1), an air-cooled or water-cooled condenser (2), a dryer and filter (3), an expansion valve (4) and a brine evaporator (5) are connected by a conduit (6) The brine cooling coils 8 and the ice making coils 8 'are built in the heat storage tank 7 and connected to the supply conduit B and the return conduit 9' The three-way valve 22 and the cold water pump 23 are provided on the supply side of the heat storage tank 7 and the heat exchanger 20 by the cold water conduit 21 and the three sides 22, And a bypass conduit 24 is provided on the return side of the conduit 21.

The cold water evaporator 26 is connected to the conduit 6 in parallel with the brine evaporator 5 by the branch plates 25 and 25 'and the branch conduit 25 is connected to the solenoid valve 27, A solenoid valve 27 'is provided in front of the expansion valve 4 of the conduit 6 and a cooling coil 28 is installed in the cold water evaporator 26 to cool the cold water supply conduit 29 The cold water supply conduit 29 is connected to the cooling load 30 through the cold water return conduit 29 'and the cold water supply conduit 29 is connected to the heat exchanger 20 and the cold water supply conduit 29 is bypassed to the heat exchanger 20 A solenoid valve 31 'is connected between the connecting point of the bypass conduit 32 and the heat exchanger 20 and a cold water valve 31' is connected to the rear end of the connection end point, And a pump 33 is installed.

Description

Heat storage cooling system

FIG. 1 is a system diagram of a regenerative cooling system according to an embodiment of the present invention; FIG.

Fig. 2 is a system diagram of a conventional regenerative cooling system.

DESCRIPTION OF THE REFERENCE NUMERALS

1: compressor 2: condenser

5: Brine evaporator 7: Heat storage tank

8: Brine cooling coil 8 ': Ice-making coil

9: supply conduit 9 ': return conduit

10: brine pump 20: heat exchanger

22: Three sides 23, 33: Cold water pump

26: cold water evaporator 28: cooling coil

29: Cold water supply conduit 30: Cooling load

32: Bypass conduit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat storage cooling system, and more particularly to an ice storage and cooling system using nighttime power.

As known in the art, the ice and water cooling system is used for ice making using low-priced nighttime power, and the ice is melted in the day during which the cooling load is great, and cooling is performed by using cold water of low temperature or cooling by using the cold water and small- It is a cooling system that saves energy.

The conventional ice and water column cooling system is constituted by connecting the compressor 1, the condenser 2, the dryer / filter 3, the expansion valve 4 and the evaporator 5 via the conduit 6 as shown in FIG. And the brine cooling coil 8 and the ice making coil 8 'are built in the evaporator 5 and the heat storage tank 7 and connected to the supply pipe 9 and the return pipe 9' The brine pump 10 and the heat exchanger 11 are installed in the return conduit 9 'and the supply conduit 9 and the return conduit 9' are connected to the bypass conduit 12, And a bypass conduit 14 is installed behind the brine pump 10 of the return conduit 9 'and bypasses the heat exchanger 11 and is provided with a solenoid valve 15 At the same time, a solenoid valve 15 'is provided in the rear of the bypass conduit 14 and in front of the heat exchanger 11, and a load 16 is connected to the heat exchanger 11, The concatenation of the conduit (17).

Reference numeral 19 denotes an air supply means.

The above-mentioned ice-cooled thermal cooling system operates as follows.

① Night heat storage (deicing) operation

The refrigerant compressed in the compressor 1 driven by the nighttime power is condensed and liquefied by a cooling fan or cooling tower (not shown) in the condenser 2, decompressed in the expansion valve 4 and then introduced into the evaporator 5, And the cycle of being sucked into the compressor 1 in a gaseous state is repeated.

On the other hand, when the refrigerant is evaporated in the evaporator 5, the brine flowing through the brine cooling coil 8 is cooled by the evaporation heat, and at the same time, the brine pump 10 cools the supply conduit 9, the icemaker 8 ' The water stored in the heat storage tank 7 is de-iced while the a port of the three sides 13 is closed so that the entire amount of the brine is circulated to the ice-making coil 8 ' And the solenoid valve 15 'is closed to prevent the heat exchanger 11 from freezing.

② Weekly freezing operation

단 Independent operation of heat storage tank

When the operation of the refrigeration cycle is stopped and the brine pump 10 is operated in a state in which the solenoid valve 15 is closed, when the throttle tank is used for the seawater operation mode in which the cooling tank is low or the outside air temperature is relatively low The brine is circulated through the heat exchanger 11 and the ice-making coil 8 ', and the brine and the cold water flowing through the cooling load 16 are heat-exchanged by the operation of the cold water pump 18 to perform cooling. ) Is that the port a and the port b are selectively opened and closed by the cooling load.

단 Single operation of refrigerator

The refrigeration cycle and the brine pump 10 are operated when the sea ice operation of the thermal storage tank 7 is forcibly delayed or the thermal storage tank 7 is completely discharged, and the three sides 13 are connected to the port a and the port c The solenoid valve 15 is closed to circulate the entire amount of the brine to the heat exchanger 11 and at the same time the cold water pump 18 is driven to perform the cooling operation of the cooling load. At this time, the load is controlled by the compressor 1 do.

병 Parallel operation of refrigerator and heat storage tank

The operation of the compressor 1 and the simultaneous use of the ice storage heat of the heat storage tank 7 when the peak load can not be coped with by only the refrigerating cycle or the heat storage tank 7 can be solved, And the solenoid valve 15 is closed to allow the brine to pass through the heat exchanger 11 and the three sides 13 to open and close the a port and the b port in accordance with the variation of the cooling load, To maintain a constant temperature.

However, in the above-mentioned ice and water column cooling system, the brine cooled in the evaporator (5) can not be used for the direct cooling load during the single operation of the freezer for the daytime cooling or parallel operation of the refrigerator and the storage tank, The heat efficiency is lowered due to heat loss in the heat exchanger and the like, and since the brine pump 10 must be operated during the inter-day cooling operation, the power consumption due to the operation of the brine pump is increased, (5) uses an aqueous solution of calcium chloride, an aqueous solution of sodium, an ethylene glycol or the like, and since the ratio of the brine is smaller than water, Q = G · C · Δt (G) must be increased more than water when the heat quantity (Q) and the temperature difference (Δt) are constant at a constant temperature According to which this would be of the greater problem of large, the capacity and the pipe diameter of the brine pump equipment.

The present invention corrects the above-mentioned problem and provides chilled water cooled by the cold water evaporator at the time of direct operation of the chiller or in parallel operation of the chiller and the storage tank in order to increase the efficiency and reduce the volume of the equipment And to provide a storage and cooling system capable of cooling and heating the air.

Another object of the present invention is to provide a heat storage cooling system capable of reducing power consumption by interrupting the operation of a brine pump in a daytime cooling operation.

In order to achieve the above-mentioned object, the present invention provides a refrigerator having a compressor, a condenser, an expansion valve, and a brine evaporator connected by a conduit, a brine cooling coil and an icemaker installed in the brine evaporator and the storage tank, The cooling water evaporator is connected to the heat storage tank and the heat exchanger by a cold water conduit. The cold water evaporator is connected to the brine evaporator in parallel with the conduit. A cooling coil is installed in the cold water evaporator to connect the cooling water supply conduit and the cooling water return conduit It is done.

Hereinafter, embodiments will be described with reference to the drawings.

The present invention is characterized in that a compressor 1, an air-cooled or water-cooled condenser 2, a dryer-and-filter 3, an expansion valve 4 and a brine evaporator 5 are connected by a conduit 6 , The brine cooling coil 8 and the icemaker 8 'are built in the brine evaporator 5 and the heat storage tank 7 and connected to the supply conduit 9 and the return conduit 9' 9 ', a brine pump 10 is installed, the heat storage tank 7 and the heat exchanger 20 are connected by a cold water conduit 21, three sides 22 and a cold water pump 23 are installed on the supply side thereof , And the bypass conduit (24) is provided on the return side of the three sides (22) and the cold water conduit (21).

The cold water evaporator 26 is connected to the conduit 6 in parallel with the brine evaporator 5 and the solenoid valve 27 and the expansion valve 25 are connected to the branch conduit 25, A solenoid valve 27 'is provided in front of the expansion valve 4 of the conduit 6 and a cooling coil 28 is installed in the cold water evaporator 26 to cool the cold water supply conduit 29 The cold water supply conduit 29 is connected to the cooling load 30 by the cold water return conduit 29 'and the cold water supply conduit 29 is connected to the heat exchanger 20 and the cold water supply conduit 29 is bypassed by the heat exchanger 20 A solenoid valve 31 'is connected between the connecting point of the bypass conduit 32 and the heat exchanger 20 and a cold water pump 31' is connected to the rear end point of the solenoid valve 31 ' (33).

Reference numeral 19 denotes an air supply means.

Next, the operation of the present invention will be described.

① Night heat storage (deicing) operation

The refrigerant compressed in the compressor 1 is condensed and liquefied in the condenser 2, decompressed in the expansion valve 4, introduced into the brine evaporator 5, evaporated, and then sucked into the compressor 1 in a gaseous state.

On the other hand, when the refrigerant is evaporated in the brine evaporator 5, the brine flowing through the brine cooling coil 8 is cooled by the evaporation heat, and at the same time, the brine pump 10 cools the supply conduit 9, The water stored in the heat storage tank 7 is de-iced while circulating the conduit 9 ', and at this time, the solenoid valve 27 is also closed so that the refrigerant can not flow into the cold water evaporator 26.

② Weekly cooling operation

단 Independent operation of heat storage tank

When the operation of the compressor 1 and the brine pump 10 is stopped and the cold water pumps 23 and 33 are operated, the cold water in the heat storage tank 7 and the cold water on the cooling load 30 side are heated by the heat exchanger 20 The cold water in the freezing load side is cooled to a necessary temperature and cooled. At this time, the a and b ports of the three sides 22 are opened and closed according to the variation of the load, and the temperature of the cold water supplied to the c port side is kept constant.

단 Single operation of refrigerator

When the compressor 1 is operated and the solenoid valve 27 'is closed so that the refrigerant flows into the cold water evaporator 26, the cold water flowing through the cold water cooling coil 28 is cooled by the evaporation heat, 29 and bypass conduit 32 to the cooling load 30 to perform a cooling function.

At this time, the solenoid valve 31 'is closed and the cold water is directly supplied to the cooling load without passing through the heat exchanger 20, so that the cooling efficiency is enhanced and the brine pump 10 is not driven, Can be made smaller than the diameter of the brine used.

When the cooling load is smaller than the capacity of the compressor 1, the load is adjusted as the compressor 1.

병 Parallel operation of refrigerator and heat storage tank

A method for operating a compressor (1) to introduce refrigerant into a cold water evaporator (26) and simultaneously using ice storage heat of a heat storage tank (7) So that the cold water passes through the heat exchanger (20).

At this time, the cooling load 30 is mainly processed by the cold water cooled by the cooling coil 28. The insufficient amount of the cooling coil 28 is obtained by connecting the a port and the b port of the three sides 22, The solenoid valve 31 is closed and the operation method of the brine pump 10 is controlled so that the operation of the brine pump 10 is stopped. The power consumption is reduced and the cold water cooled by the cooling coil 28 is supplied to the cooling load, so that the diameter of the pipe can be reduced, so that the volume of the facility can be reduced.

As described above, according to the present invention, the cold water cooled by the cold water evaporator is supplied directly to the cooling load without passing through the heat exchanger during the single operation of the freezer to prevent heat loss in the heat exchanger, The heat exchanger exchanges the cold water of the heat storage tank with the cold water of the cooling load side so as to cool the brine in the conventional evaporator and heat exchange the cold water of the brine and the cooling load side. The diameter of the piping can be reduced, and the volume of the equipment can be reduced, so that the system can be downsized.

In addition, the operation of the brine pump is stopped at the time of the main cooling operation, and the operation cost can be reduced by reducing the power consumption.

Claims (5)

A condenser, a condenser, an expansion valve, and a brine evaporator are connected to each other by a conduit, and the brine evaporator and the heat storage tank are respectively connected to the supply conduit and the return conduit by incorporating a brine cooling coil and an icemaker. And connecting the cold water evaporator to the conduit in parallel with the brine evaporator, and also incorporating a cooling coil in the cold water evaporator to connect the cold water supply conduit and the cooling water return conduit to the cooling load. The system according to claim 1, wherein the cooling fluid of the cold water evaporator is water. 2. The regenerative cooling system according to claim 1, wherein the brine evaporator and the cold water evaporator selectively inflow the refrigerant during operation of the compressor. The heat storage / cooling system according to claim 1, wherein the heat exchange fluid of the heat exchanger is all water. The system of claim 1, wherein the cold water supply conduit is provided with a bypass conduit bypassing the heat exchanger.