JPH0933073A - Vacuum vaporization type ice heat storage device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain an ice heat storage device which is capable of producing ice without handling inconvenience and without using refrigerant which is harmful to natural environment, and enhance safety of the device and protect the environment from destruction. SOLUTION: A tray 5 is provided in a heat storage tank so as to store water and ice therein. A water inlet nozzle, which feeds ice making water to the tray 5, is provided in the heat storage tank 3. A drain nozzle is provided in the tank 3 so as to discharge the water which overflows from the tray 5. A pressure reduction device 19, which reduces the pressure in the heat storage tank 3, is connected to the heat storage tank 3. A cold air inlet nozzle, which lets the air from a load side to flow into the storage tank 3, and a cold air outlet nozzle, which feeds air in the heat storage tank 3 to the load side, are connected to the tank 3.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention does not use a CFC-based refrigerant and depressurizes the inside of the heat storage tank to evaporate a part of the water held in the heat storage tank and generate ice by the heat of evaporation. The present invention relates to a vacuum evaporation type ice heat storage device.

[0002]

2. Description of the Related Art Conventionally, ice-making systems for ice heat storage tanks are roughly classified into two types: static type and dynamic type. Furthermore,
The static type has an ice-on-coil method of making ice on a heat transfer tube, a method of freezing the water in the capsule, and the dynamic type has a method of making slurry ice by using supercooled water and brine. There is a method to generate sherbet-like ice using.

As described above, there are various types of ice-making systems for the ice heat storage tank, and in any of the systems, a refrigerator by the vapor compression refrigeration method is used as the heat source. The vapor compression refrigeration method utilizes the evaporation action of liquefied gas, and performs the refrigeration action by absorbing the latent heat of evaporation from the object to be cooled. In the vapor compression refrigeration method,
It is characterized in that the vaporized gas is liquefied again and a continuous refrigeration action is performed as a cycle of repeating evaporation and condensation.

In this refrigeration cycle, the evaporation pressure and the condensation pressure are preferably as close to atmospheric pressure as possible. Conventionally, Freon has been exclusively used for such a working fluid, that is, a refrigerant.

[0005]

However, in recent years, chlorofluorocarbon has been recognized as a causative substance that destroys the ozone layer, and it has been called for its abolition at an early stage from the viewpoint of natural environmental problems. The present invention has been made in view of the above circumstances, provides an ice heat storage device that can generate ice without using a refrigerant that is inconvenient to handle or that is harmful to the natural environment, and improves safety and environmental damage. The purpose is to prevent

[0006]

A vacuum evaporation type ice heat storage device according to the present invention for achieving the above object has a heat storage tank having a strength capable of withstanding an internal vacuum pressure, and water and water provided in the heat storage tank. A tray that stores ice, a water inlet nozzle that is connected to the heat storage tank to supply ice making water to the tray, and drainage that is connected to the lower portion of the heat storage tank and discharges water overflowing from the tray from the heat storage tank to the outside. A nozzle, a pressure reducing device connected to the heat storage tank via an exhaust nozzle to reduce the pressure in the heat storage tank, and a cold air inlet nozzle connected to the heat storage tank for allowing air from the load side to flow into the heat storage tank, A cold air outlet nozzle that is connected to the heat storage tank and supplies air in the heat storage tank to the load side is provided. Then, in the vacuum evaporation type ice heat storage device, when the pressure of the heat storage tank is reduced by the pressure reducing means, the water stored in the tray is evaporated and cooled, and all the water stored on the tray becomes ice. In the heat dissipation process, the air that has flowed into the heat storage tank through the cold air inlet nozzle passes through the air passage sandwiched between the trays where ice is generated,
Heat is directly exchanged by contact with the ice to become cold air, which is supplied from the cold air outlet nozzle to the load side.

[0007]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A preferred embodiment of a vacuum evaporation type ice heat storage device according to the present invention will be described below with reference to the drawings. 1 is a schematic configuration diagram of a vacuum evaporation type ice heat storage device according to the present invention, FIG. 2 is an enlarged view of a heat storage tank used in the vacuum evaporation type ice heat storage device according to the present invention, and FIG. 3 is a tray opening portion provided in the heat storage tank. FIG. 4 is a diagram illustrating a position, FIG. 4 is a schematic configuration diagram of a steam ejector, and FIG. 5 is a schematic configuration diagram of a vacuum pump. The vacuum evaporation type ice heat storage device 1 according to the present invention is, for example,
It has a heat storage tank 3 formed in a hexahedral shape (square shape). The heat storage tank 3 is preferably manufactured to have a strength to withstand the internal vacuum pressure, and is preferably manufactured to have a heat insulating structure.
The shape of the heat storage tank 3 is not limited to the rectangular shape, and may be a cylindrical shape or the like.

As shown in FIG. 2, a plurality of trays 5 are provided inside the heat storage tank 3 at intervals in the vertical direction. Odd-numbered first tray 5a, third tray 5c, fifth tray 5
e is provided in contact with one inner wall surface of the heat storage tank 3, while the even-numbered second trays 5b and fourth trays 5d are provided in contact with the other inner wall surface of the heat storage tank 3 (FIG. 3). reference). Therefore, a vertical crank-shaped air passage 7 partitioned by the tray 5 is formed inside the heat storage tank 3. The tray 5 is formed in a box shape with an open top, and is configured to store water or ice 9.

A water inlet nozzle 11 is provided above the heat storage tank 3. The water inlet nozzle 11 penetrates the heat storage tank 3 from the outside and is supplied by the water supply pump 13 to the uppermost first tray 5a.
Water for ice making can be supplied. Further, a drain nozzle 15 is provided on the lower surface of the heat storage tank 3, and the drain nozzle 15 drains the water overflowing at the bottom of the heat storage tank 3 to the outside. Therefore, the ice making water supplied from the water inlet nozzle 11 sequentially overflows from the uppermost first tray 5a to the lower tray 5 and finally overflows from the lowermost fifth tray 5e, and the drainage nozzle 15 It is designed to be drained from.

An exhaust nozzle 17 is provided above the heat storage tank 3, and the exhaust nozzle 17 is connected to a steam ejector 19 which is a pressure reducing device. As shown in FIG. 4, the steam ejector 19 ejects water vapor from the nozzle 19a to the suction chamber 19b, causes the suction chamber 19b having a low pressure to suck the air from the exhaust nozzle 17 as a wake, and diffuses the steam from the diffuser 19c. The structure is such that the air in the heat storage tank 3 is exhausted. That is, the heat storage tank 3 can be degassed by the steam ejector 19.

To degas the heat storage tank 3, a vacuum pump may be used instead of the steam ejector 19 described above. As shown in FIG. 5, the vacuum pump 21 includes, for example, two eyebrows-shaped rotors 21a and 21b.
Are rotated in opposite directions at a constant speed, and a roots pump structure or the like is used which sucks and exhausts air from the intake / exhaust ports 21d and 21e opened on both sides of the casing 21c.

A cold air inlet nozzle 23 is connected to the lower portion of the heat storage tank 3, and the cold air inlet nozzle 23 is connected to the lower end of the air passage 7 in the heat storage tank 3. Further, a cold air outlet nozzle 25 is provided above the heat storage tank 3, and the cold air outlet nozzle 25 communicates with the upper end of the air passage 7 in the heat storage tank 3. Air from the load side whose temperature has risen is sent from the cold air inlet nozzle 23 to the heat storage tank 3 by the blower 27. Therefore, the air introduced from the cold air inlet nozzle 23 passes through the air passage 7 and is supplied from the cold air outlet nozzle 25 to the load side.

Although not shown, all the nozzles connected to the heat storage tank 3 (water inlet nozzle 11, drain nozzle 1)
5, the exhaust nozzle 17, the cold air inlet nozzle 23, the cold air outlet nozzle 25) is provided with a closing valve.

Next, the operation of the heat storage device 1 thus constructed will be described. In the heat storage device 1, before the start of ice making, first, the water supply pump 13 supplies the ice making water to the uppermost first tray 5a. When the first tray 5a becomes full, the ice making water overflows and is supplied to the second tray 5b. When the lower tray 5 becomes full and the bottom fifth tray 5e becomes full, the drainage nozzle The water is discharged from the heat storage tank 3 from 15. At this point, the water supply pump 13 is stopped.

Next, the closing valves of all the nozzles other than the exhaust nozzle 17 are closed, and the steam in the steam ejector 19 is ventilated so that the air in the heat storage tank 3 is degassed from the exhaust nozzle 17. The internal pressure in the heat storage tank 3 is a constant value, that is,
When the water reaches the flash point, the water stored in the tray 5 starts to evaporate and cool rapidly. When the internal pressure reaches 4.6 mmHg, the water stored in the tray 5 becomes 0
It will vaporize at ° C. The evaporation latent heat of about 600 kcal is absorbed for the evaporation of 1 kg of water. On the other hand, 1k
1 g of water releases about 80 kcal of latent heat of solidification
Becomes ice. That is, by evaporating 1 kg of water,
About 7.5 kg of ice will be produced. When all the water stored on the tray 5 becomes ice, the steam ejector 19 is stopped and the heat storage process is ended. After the heat storage process is completed, the closing valve of the exhaust nozzle 17 is closed.

The means for detecting that the water on the tray 5 has turned into ice will be further described. The fact that the water on the tray 5 has turned into ice can be known, for example, as an indirect means by the operating time of the steam ejector 19 after the internal pressure in the heat storage tank 3 reaches 4.6 mmHg. For example, assuming that the total amount of water accumulated on the tray 5 before depressurization is 1000 kg, as described above, 1 kg of water
Since 7.5 kg of ice is generated by evaporation of water, the amount of water evaporated is finally 1000 × 1 / (1 + 7.5) = 117.
7 kg ice making amount = 1000 × 7.5 / (1 + 7.5) = 882.
It will be 3 kg. Here, when the internal pressure of the heat storage tank is about 4.6 mmHg, the specific volume of water vapor is 206.3 m ³ / kg, so that the total evaporation capacity is 117.7 × 206.3 = 24271 m ³ . The pump speed of the steam ejector 19 is 3000
Assuming m ³ / h, it is calculated that exhaust time = 24271/3000 = 8.09 (hour). Therefore, in this example, it can be determined that the entire amount of ice has been consumed in about 8 hours after the pressure in the heat storage tank reached about 4.6 mmHg.

In addition to the above, as a means for determining that the water on the tray has become ice, it is conceivable to use a direct means for detecting by the principle that the electric resistances of water and ice are different.

Next, in the heat radiation process of the heat storage tank 3, the closing valves of only the cold air inlet nozzle 23 and the cold air outlet nozzle 25 are opened, and the blower 27 is started. As a result, the air on the load side whose temperature has risen passes through the cold air inlet nozzle 23 and enters the heat storage tank 3
Flows into. The air that has flowed into the heat storage tank 3 passes through the air passage 7 sandwiched between the trays 5 in which ice is generated, and is directly heat-exchanged by contact with the ice to become cold air, which is loaded from the cold air outlet nozzle 25. Will be supplied to the side.

According to the heat storage device 1 described above, ice is generated by utilizing the heat of evaporation, so that cold heat is stored in the heat storage tank 3 without using a conventional refrigerator using freon which causes environmental damage. Can store heat. In addition, since heat is exchanged by direct contact without using a heat exchanger between cold water and air, heat exchange efficiency is improved, and cooler cold air can be obtained. Further, since the ice and the cold air directly exchange heat with each other, the thermal resistance is reduced and the heat transfer amount per unit time (the melting amount of ice) is increased, so that the followability to the load change can be improved. Further, as the cold heat storage using the direct steam, only the cold water heat storage by the absorption chiller requiring large equipment has been conventionally used. However, the above-mentioned heat storage device 1 enables the ice heat storage, so the heat storage is possible. It is possible to significantly reduce the tank capacity.

[0020]

As described above in detail, according to the vacuum evaporation type ice heat storage device of the present invention, ice is generated by utilizing the heat of evaporation, so that the conventional CFC which causes environmental damage can be eliminated. Cold heat can be stored in the heat storage tank without using the used refrigerator. As a result, it is possible to avoid the inconvenience of handling or to use a refrigerant that is harmful to the natural environment, improve safety, and prevent environmental damage.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of a vacuum evaporation type ice heat storage device according to the present invention.

FIG. 2 is an enlarged view of a heat storage tank used in the vacuum evaporation type ice heat storage device according to the present invention.

FIG. 3 is a diagram illustrating a position of a tray opening provided in the heat storage tank.

FIG. 4 is a schematic configuration diagram of a steam ejector.

FIG. 5 is a schematic configuration diagram of a vacuum pump.

[Explanation of symbols]

 1 vacuum evaporation type ice heat storage device 3 heat storage tank 5 tray 7 air passage 11 water inlet nozzle 15 drainage nozzle 17 exhaust nozzle 19 steam ejector (pressure reducing device) 21 vacuum pump (pressure reducing device) 23 cold air inlet nozzle 25 cold air outlet nozzle

Claims (3)

[Claims] 1. A heat storage tank having a strength to withstand an internal vacuum pressure, a tray provided in the heat storage tank for storing water and ice, and a water inlet connected to the heat storage tank for supplying ice making water to the tray. A nozzle; a drainage nozzle connected to the lower part of the heat storage tank to discharge water overflowing from the tray to the outside from the heat storage tank; and a drain nozzle connected to the heat storage tank via an exhaust nozzle to reduce the pressure in the heat storage tank. A pressure reducing device, a cold air inlet nozzle connected to the heat storage tank for allowing air from the load side to flow into the heat storage tank, and a cold air outlet nozzle connected to the heat storage tank for supplying air in the heat storage tank to the load side. A vacuum evaporation type ice heat storage device characterized in that 2. The vacuum evaporation type ice heat storage device according to claim 1, wherein the decompression device is either a steam ejector or a vacuum pump. 3. The vacuum evaporation type ice heat storage device according to claim 1, wherein the trays are provided in a plurality of stages in the vertical direction with a gap therebetween, and the air passages are formed by the gaps.