JPS63197854A - Ice making cold storage machine - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] [Industrial application field] This invention relates to an ice-making regenerator.

[Conventional technology]

A direct expansion type ice making regenerator is known that stores cold by utilizing latent heat when a substance changes from a solid phase to a liquid phase.

The problem with such a regenerator is to improve heat storage efficiency.

FIG. 4 is a system diagram showing an example of a conventional ice making regenerator using latent heat, and FIG. 5 is an enlarged longitudinal sectional view of the regenerator. As shown in FIGS. 4 and 5, the refrigerant, which has been pressurized by the compressor 23 and becomes a high-pressure gas, passes through the conduit 24 and becomes a high-pressure liquid by the condenser 25.
26 and then enters the expansion valve 27 into a low liquid state. The low-pressure liquid refrigerant is evaporated by the cold storage coil 28 as a heat exchanger, and 30 tons of water as a liquid heat storage material in the cold storage 29 is evaporated.
- Freeze and store cold.

However, as heat storage progresses, ice 31 shown by dotted lines adheres to the cold storage coil 28 and impedes heat transfer 4.

There is a problem that heat storage efficiency decreases.

FIG. 6 is a system diagram showing another example of a conventional ice making regenerator using latent heat. As shown in FIG. 6, the refrigerant, which has been pressurized by the compressor 32 and becomes a high-pressure gas, passes through the conduit 33 and becomes a high-pressure liquid by the condenser 34.
The expansion valve 35 turns the liquid into a low-temperature liquid. The low-pressure liquid refrigerant is evaporated by the cold storage coil 36 as a heat exchanger.

On the other hand, the heat storage tank 37 is an open type with an open top surface, and water 38 as a heat storage material is supplied inside the tank.

The cold storage coil 3 is connected to the cold storage coil 3 via the air conditioner 40 by the circulation pump 39.
The water is pumped up to the spray nozzle 41 located above the spray nozzle 6. Then, the pumped water is sent to spray nozzle 4.
The refrigerant is sprayed from 1 to the inside of the heat storage tank 37 and toward the cold storage coil 36, and is cooled and frozen on the surface of the cold storage coil 36 by the refrigerant that evaporates in the cold storage coil 36.

As heat storage progresses, ice will adhere around the cold storage coil 36, so in order to melt it, a condenser 34 is installed in the middle of the conduit 33.
and a branch pipe 42 through which the refrigerant does not pass through the expansion valve 25,
The solenoid valve 43 is switched at regular intervals to send the high-temperature, high-pressure gaseous refrigerant compressed by the compressor 32 to the cold storage coil 36 via the branch pipe 42.

This melts the ice attached around the cold storage coil 36 and causes it to fall into the heat storage tank 37. 44 is ice.

As mentioned above, ice attached around the cold storage coil 36 is
Since the cold storage coil 36 is removed at regular intervals and the ice making ability of the cold storage coil 36 is maintained at a good level, it is possible to prevent the functional deterioration of the cold storage machine due to ice adhering to the cold storage coil 36.

[Problem that the invention seeks to solve]

However, the conventional ice making regenerator mentioned above.

After melting the ice adhering to the cold storage coil 36, extra energy is required to refreeze the melted water, resulting in a low heat storage efficiency when looking at the benefits and losses of energy comprehensively.

There are ice storage machines that use electric heaters instead of high-temperature gaseous refrigerants to melt ice, but they require extra energy.

Therefore, an object of the present invention is to provide an ice-making cold storage machine that can significantly improve heat storage efficiency without energy loss.

[Failure to solve the problem]

This invention includes two heat exchangers: a compressor, a condenser connected to the compressor by a conduit, and a reservoir for making ice for a heat storage liquid connected to each of the compressor and the condenser by a conduit. and two expansion valves provided in parallel in the middle of a conduit connecting the two heat exchangers to each other, and a conduit connecting each of the compressor and the condenser to each of the two heat exchangers. It was set up in the middle of. The heat exchanger is characterized by comprising a switching valve for switching the flow of refrigerant through the conduit to cause the two heat exchangers to alternately function as a supercooler or an evaporator.

Next, the present invention will be explained with reference to the drawings.

FIG. 1 is a system diagram showing one embodiment of the present invention. As shown in FIG. 1, conduits 2a and 2b through which refrigerant circulates through the compressor 1 and condenser 3 are provided with a four-way switching valve 4. The four-way switching valve 4 is connected to conduits 2c and 2d for connecting the compressor 1 and the condenser 3 to the coiled first heat exchanger 19 and second heat exchanger 20, respectively. .

A first expansion valve 6 and a second expansion valve 9 are provided in parallel in the middle of a conduit 2e that connects the first heat exchanger 19 and the second heat exchanger 20 to each other. The compressor 1 and the condenser 3 are connected by a conduit 2.

A first check valve 5 is provided between the first heat exchanger 19 and the first expansion valve 6, and a second check valve 5 is provided between the second heat exchanger 20 and the second expansion valve 9.
A check valve 8 is connected to each.

The first check valve 5 connects the second heat exchanger 20 to the first heat exchanger 19.
The second check valve 8 restricts the flow of refrigerant from the first heat exchanger 19 to the second heat exchanger 20, respectively.

21 is a temperature-sensitive needle of the second expansion valve 9;

22 is a temperature-sensitive needle of the first expansion valve 6.

Below the first heat exchanger 19 and the second heat exchanger 20,
A heat storage tank 11 to which water 12 as a heat storage liquid is supplied is installed inside with an open top.

Above the first heat exchanger 19 and the second heat exchanger 20,
A spray nozzle 16 is installed.

Water 12 in the heat storage tank 11 is pumped up through the cold water conduit 15 by the circulation pump 14 and sent to the spray nozzle 16, and from the spray nozzle 16 to the first heat exchanger 19 and the second heat exchanger 20. The heat storage tank 1 is sprayed again.
Fall within 1.

The four-way switching valve 4 has conduits 2a and 2C and conduits 2b and 2d.
or connect conduits 2a and 2d and conduits 2b and 2
Connect 0.

When conduits 2a and 2c and conduits 2b and 2d are connected by four-way switching valve 4, compressor 1, condenser 3. First heat exchanger 19. First expansion valve 6 and second heat exchanger 20t-
A circulation line is formed which passes through this sequence and returns to the compressor I.

The four-way switching valve 4 allows the conduits 2a and 2d and the conduit 2b to
and 20, compressor 1° condenser 3, 2nd
Heat exchanger 20. A circulation line is formed that passes through the second expansion valve 9 and the first heat exchanger 19 in this order and returns to the compressor 1.

[For production]

FIGS. 2 and 3 are system diagrams showing the flow of refrigerant.

The flow of the refrigerant operates as follows when the four-way switching valve 4 connects the conduits 2a and 2c and the conduits 2b and 2d.

As shown in FIG. 2, the refrigerant that has become a high-pressure liquid in the condenser 3 flows through conduits 2a and 2Qk to the first heat exchanger 1.
9, and the ice attached to the coil of the first heat exchanger 19 is melted by supercooling. After that, it flows through the conduit 2e and the first
The refrigerant that has reached the expansion valve 6 becomes a low-pressure liquid by the first expansion valve 6 and reaches the second heat exchanger 20 . Then, the water 12 that is evaporated in the second heat exchanger 20 and sprayed from the spray nozzle 16 is frozen, and the produced ice 13 is transferred to the heat storage tank 1.
Ice is stored in 1.

The gaseous refrigerant evaporated in the coil of the second heat exchanger 20 reaches the compressor 1 through the conduits 2d and 2b and repeats the circulation again.

On the other hand, as shown in FIG. 3, when the conduits 2a and 2d and the conduits 2b and 2C are connected by the four-way switching valve 4, the flow of the refrigerant is switched by the four-way switching valve 4, and the refrigerant flow is reversed. The ice attached to the coil of the second heat exchanger 2o is melted by supercooling, and ice is made in the first heat exchanger 19.

In this way, if the four-way switching valve 4 is switched off at regular intervals, ice making and melting are performed alternately in the first heat exchanger 19 and the second heat exchanger 20.

Ice making progresses with high efficiency.

At this time, the amount of heat released to melt the ice by the heat exchanger that performs supercooling is recovered when ice is made by the heat exchanger that performs evaporation, and the gain and loss of heat of the refrigerant are the same. Therefore, the loss of heat due to melting the ice is zero, and ice can be made continuously without using any wasted energy.

Note that when there is no need to melt ice, such as when starting cold storage, the two heat exchangers 2z can also be used as evaporators. In this case, a conduit is provided in both of the two heat exchangers so that the refrigerant, which has become a low-pressure liquid, flows directly from the condenser through the expansion valve, and the refrigerant is switched to flow through this conduit.

Next, the present invention will be explained with reference to examples.

〔Example〕

Conduits 2a and 2c and conduit 2b are controlled by four-way switching valve 4.
The change in temperature of the refrigerant when the ice making regenerator of the present invention was operated by connecting the refrigerant and 2d was investigated and is shown in FIG. 2 along with the flow of the refrigerant. On the other hand, the conduit 2a is similarly controlled by the four-way switching valve 4.
Fig. 3 shows the change in temperature of the refrigerant when the ice making regenerator of the present invention is operated by connecting the pipes 2d and 2d and the conduits 2b and 2C, and the changes in the refrigerant temperature are shown together with the flow of the refrigerant.

As shown in FIGS. 2 and 3, in the first heat exchanger 19 shown in FIG. 2 and the second heat exchanger 20 shown in FIG. The heat exchanger acts as a supercooler and completely melts the ice attached to the coil. In the second heat exchanger 20 shown in FIG. 2 as an evaporator and the first heat exchanger 19 shown in FIG. 3,
The refrigerant froze water at a temperature of 0°C.

〔Effect of the invention〕

As explained above, according to the ice making regenerator of the present invention,
without expending extra energy.

Since heat storage efficiency can be greatly improved, industrially useful effects such as cost reduction and increase in refrigeration capacity can be obtained.

[Brief explanation of the drawing]

FIG. 1 is a system diagram showing one embodiment of this invention, FIGS. 2 and 3 are system diagrams showing one embodiment of this invention, and FIG. 4 is a system diagram showing an example of a conventional ice making regenerator. Figure 5 is the 4th
FIG. 6 is an enlarged vertical sectional view of the regenerator shown in the figure, and FIG. 6 is a system diagram showing another example of the conventional ice regenerator. In the drawing. 1... Compressor. 2, 2 a, 2 b, 2 C) 2 d,
2 e 09. Conduit, 3... Condenser, 4
...Four-way switching valve. 5... First check valve, 6... First expansion valve. 8... Second check valve, 9... Second expansion valve, 11
...Heat storage tank, 12...Water. 13...Ice, 14...Circulation pump. 15...Cold water guide! , 16... Spray nozzle. 19...First heat exchanger, 20...Second heat exchanger. 21.22...Thermometer, 23...Compressor. 24... conduit, 25... condenser. 26... Receiver-627... Expansion valve. 28... Cold storage coil, 29... Cold storage device. 30...Water, 31...Ice. 32... Compressor, 33... Conduit. 34... Condenser, 35... Expansion valve. 36... Cold storage coil, 37... Heat storage tank, 38...
・Water, 39...Circulation pump. 40...Empty Kek, 41...Spray nozzle. 42... Branch pipe, 43... Solenoid valve. 44...Ice.

Claims (1)

[Claims] a compressor, a condenser connected to the compressor by a conduit, two heat exchangers for making ice from a heat storage liquid connected to each of the compressor and the condenser by a conduit; two expansion valves provided in parallel in the middle of a conduit connecting the two heat exchangers to each other; and two expansion valves provided in the middle of a conduit connecting each of the compressor and the condenser to each of the two heat exchangers. and a switching valve for switching the flow of refrigerant through the conduit to cause the two heat exchangers to alternately function as a supercooler or an evaporator.