JP2002115921A - Freezing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To generate electric power by making use of heat released in a condensation process of a freezer. SOLUTION: A closed speed variable speed pump 54 is provided for feeding a power generating heat exchange medium, and a heat exchanger 38 is provided for heat exchanging heat between the power generating heat exchange medium sent from the closed variable speed pump 54 and a refrigerant of a freezing apparatus 20. Further, there are provided a gas turbine 62 rotated by the power generating heat exchange medium vaporized by heat exchange with a refrigerant and a power generator 64 connected to the gas turbine 62, and further there is provided a condenser 66 for liquefying the vaporized heat exchange medium. The power generating heat exchange medium is sent and circulated with the closed variable speed pump 54 to form a power generation cycle, and power is generated with the power generator 64. As a result, heat discharged by the freezing apparatus 20 is employed for power generation.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a refrigeration system, and more particularly, to a refrigeration system that utilizes heat generated in a condensation step.

[0002]

2. Description of the Related Art As a conventional refrigerating apparatus, there has been proposed a refrigerating apparatus in which heat generated in a condensing step is used for warming water or used for heating. In this apparatus, an object such as water or air is heated by using exhaust heat of a condensation step, thereby achieving effective use of energy.

[0003]

However, in such an apparatus, since the object is heated by using the exhaust heat in the condensation step, its use is limited, and depending on the installation place of the apparatus, this exhaust apparatus is limited. Heat may not be used at all and may be wasted. In this case, effective use of energy cannot be achieved.

[0004] An object of the refrigeration system of the present invention is to generate electric power by using heat generated in a condensing step of a refrigerator. Another object of the refrigeration system of the present invention is to further improve the energy efficiency of the refrigerator.

[0005]

Means for Solving the Problems and Their Functions and Effects The refrigeration system of the present invention employs the following means in order to achieve at least a part of the above object.

A refrigeration system according to the present invention includes a refrigeration system for refrigerating an object to be frozen by a refrigeration cycle including a refrigerant compression step, a condensation step, an expansion step, and an evaporation step. The gist of the present invention is to provide a vaporizing means for vaporizing a part of the heat exchange medium, and a power generating means for generating electric power using the vaporized heat exchange medium.

[0007] According to the refrigeration system of the present invention, it is possible to generate power by utilizing the heat discharged in the condensation step.
Therefore, the power obtained by power generation can be used effectively.

[0008] In such a refrigeration system of the present invention,
A supply amount adjusting means capable of adjusting an amount of supply of the vaporized heat exchange medium to the power generation means may be provided. In this case, it is possible to generate power more efficiently by using the heat discharged in the condensation step.

[0009] The refrigeration system of the present invention may further include power supply means for supplying the electric power generated by the power generation means to the refrigerator. In this case, the energy efficiency of the entire refrigerator can be further improved.

Further, in the refrigeration system of the present invention, it is assumed that the apparatus is capable of selecting a plurality of compressors having different compression capacities in accordance with an object to be frozen in the compression step and compressing the refrigerant in the compression step. You can also. With this configuration, a compressor having a more appropriate compression capacity can be used in accordance with the magnitude of the refrigeration load of the object to be frozen, so that the temperature of the refrigerant in the condensation step can be made more appropriate, and the heat exchange medium can be used. Can be further promoted. As a result, power can be generated more efficiently.

[0011]

Next, embodiments of the present invention will be described with reference to examples. FIG. 1 is a configuration diagram schematically showing the configuration of a refrigeration system 10 according to one embodiment of the present invention. The refrigeration system 10 according to the embodiment generates a refrigeration apparatus 20 that freezes an object to be frozen by a refrigeration cycle of a refrigerant compression step, a condensation step, an expansion step, and an evaporation step, and generates heat using heat discharged from the refrigeration apparatus 20. It includes a power generation device 50 and a power supply device 80 that stores generated power and supplies necessary power to the refrigeration device 20.

The refrigeration system 20 includes an electronic expansion valve 24 for adiabatically expanding a high-pressure refrigerant (for example, liquefied Freon-22) stored in a liquid receiver 22, a refrigerant quenched by adiabatic expansion, and an object to be frozen. , A first compressor 28 and a second compressor 30 for compressing the refrigerant evaporated by the heat exchange, and a heat exchanger 38 (for example, a plate type) for liquefying the compressed refrigerant. Heat exchanger) and heat exchanger 3
And an auxiliary condenser 40 for liquefying the remaining unliquefied refrigerant from 8. Heat exchanger 38 and auxiliary condenser 40
The liquefied refrigerant is stored again in the liquid receiver 22 and circulated, thereby forming a refrigeration cycle. A check valve 34 and a check valve 36 are provided downstream of the first compressor 28 and the second compressor 30 to prevent the refrigerant from flowing backward.

The first compressor 28 and the second compressor 30
Each is configured to have a different compression capacity. In the embodiment, the compression capacity of the first compressor 28 and the second compressor 30
The ratio with the compression capacity was 3: 7, and a small one and a large one were selected, respectively. Further, the first compressor 28 and the second compressor 30 are connected to a three-way valve 32 installed upstream thereof.
Can be switched by using. With the three-way valve 32, the temperature of the refrigerant in the heat exchanger 38 can be adjusted by switching between the first compressor 28 and the second compressor 30 according to the magnitude of the refrigeration load of the object to be frozen. ing.

The power generator 50 is a sealed variable-speed pump 54 capable of adjusting the amount of the heat exchange medium for power generation that is stored in the receiver 52 while delivering the heat exchange medium. The heat exchanger 38 exchanges heat with the refrigerant circulating through the heat exchanger 20, a gas-liquid separator 58 that extracts only the heat-generating heat exchange medium vaporized by the heat exchange, and is rotationally driven by the extracted heat-generating heat exchange medium. The gas turbine 62, a motor-operated valve 60 that adjusts the supply amount of the power generation heat exchange medium to the gas turbine 62, a power generator 64 that generates power with the rotation of the gas turbine 62, and liquefies the vaporized power generation heat exchange medium. And a condenser 66. The liquefied power generation heat exchange medium is again stored in the receiver 52 and circulated, thereby forming a power generation cycle. The heat exchange medium for power generation is a medium that at least partially vaporizes by heat exchange with the refrigerant by the heat exchanger 38, that is, a medium that is easily liquefied at room temperature. In the example, liquefied Freon-134a and liquefied Freon-123 are used as the heat exchange medium for power generation. The power generated by the generator 64 is supplied to the power supply device 80. A check valve 56 is provided downstream of the sealed variable speed pump 54 in order to prevent the backflow of the heat exchange medium for power generation and the liquid hammer. Since the condenser 66 cools and liquefies the vaporized heat exchange medium for power generation, a part of the cool air in the evaporator 26 of the refrigerating apparatus 20 can be used in addition to the normal cooling water. .

The power supply device 80 is supplied by a main power supply 76 as a main power supply source for driving the first compressor 28 and the second compressor 30 of the refrigerating device 20 and a generator 64 of the power generation device 50. Rectifier 68 for rectifying the applied power
A storage battery 70 for storing the rectified power as an auxiliary power supply source for the main power supply 76, an inverter 72 for adjusting the voltage, frequency, waveform, etc. of the stored power and synchronizing with the main power supply 76; The main power source 76 and the storage battery 70 that are the power sources are switched, and the first power source that is the power supply destination is switched.
A changeover switch 74 for switching between the compressor 28 and the second compressor 30;

The operation of the refrigeration system 10 configured as described above, particularly, the operation when power is generated by the heat exchange medium for power generation will be described. In the power generation device 50, the heat exchange medium for power generation sent from the closed-type variable speed pump 54 is first heat-exchanged with the refrigerant circulating in the refrigeration device 20 by the heat exchanger 38 and vaporized. Then, only the power generation heat exchange medium vaporized by the gas-liquid separator 58 is taken out and supplied to the gas turbine 62. Here, this gas turbine 62
The supply amount of the heat-generating heat exchange medium for gasification is controlled by controlling the amount of delivery of the sealed variable-speed pump 54 and the opening / closing amount of the electric valve 60 by a control device (not shown) so that the power generation efficiency is maximized. Is adjusted to Thereafter, the vaporized heat exchange medium for power generation rotates the gas turbine 62, and the power generator 64 rotates to generate electric power.

The electric power generated by the generator 64 is supplied to the rectifier 6
The battery is rectified by 8 and stored in the storage battery 70. on the other hand,
The heat exchange medium for power generation that has passed through the gas turbine 62 is liquefied by the condenser 66, stored in the receiver 52, and sent out again by the sealed variable speed pump 54. Thus,
When the power generation cycle is repeated and power is stored in storage battery 70, inverter 72 and changeover switch 7
Power is supplied to each device of the refrigeration apparatus 20 such as the first compressor 28 and the second compressor 30 via the power supply 4. Thereby, each device of the refrigeration system 20 is driven by using the electric power generated by the power generation device 50.

According to the refrigeration system 10 of the embodiment described above, power can be generated by utilizing heat generated in the condensation step of the refrigeration apparatus 20. In addition, since the supply amount of the heat exchange medium for power generation supplied to the gas turbine 62 by the motor-operated valve 60 is adjusted, power can be generated more efficiently. Further, since the electric power generated by the rotation of the generator 64 accompanying the rotation of the gas turbine 62 is supplied to the refrigeration apparatus 20, the energy efficiency of the entire refrigeration apparatus 20 can be further improved. Further, the first compressor 28 and the second compressor 28 having different compression capacities according to the magnitude of the refrigeration load of the refrigeration object.
Since the switching between the compressor 30 and the three-way valve 32 can be performed, the temperature of the refrigerant in the heat exchanger 38 can be more appropriately adjusted. As a result, the heat exchanger 38
The heat exchange between the refrigerant and the heat exchange medium for power generation is stably performed, and the vaporization of the heat exchange medium for power generation can be promoted, and the power generation efficiency can be further improved.

In the refrigeration system 10 of the embodiment, the electric valve 6
0, the gas turbine 6 of the heat exchange medium for gasified power generation
2, the supply amount of the heat exchange medium for power generation may not be adjusted.

Further, in the refrigeration system 10 of the embodiment, in the compression step of the refrigeration cycle of the refrigeration apparatus 20, two compressors of the first compressor 28 and the second compressor 30 are selected to compress the refrigerant. However, the refrigerant may be compressed by one compressor, or the refrigerant may be compressed by switching three or more compressors.

Further, in the refrigeration system 10 of the embodiment, the electric power generated by the generator 64 is supplied to the first compressor 28 and the second compressor 30 of the refrigeration system 20, but is supplied to other devices. The refrigeration unit 20
It may be used for other purposes without being supplied to the device.

In the refrigeration system 10 of the embodiment, the auxiliary condenser 40 is provided downstream of the heat exchanger 38 to assist the condensation by the heat exchanger 38.
In the case where the refrigerant can be sufficiently condensed by 8, the auxiliary condenser 40 may not be provided.

In the refrigeration system 10 of the embodiment, the power generation heat exchange medium is repeatedly circulated to form a power generation cycle. However, the gas turbine 62 is rotated without circulating the power generation heat exchange medium. Later, it may be discharged.

In the refrigerating system 10 of the embodiment, a so-called vapor compression type refrigerating machine is used as the refrigerating machine. However, if heat exchange with the refrigerant in the condensing step is possible,
It is possible to use any refrigerator, for example, an absorption refrigerator.

The embodiments of the present invention have been described with reference to the embodiments. However, the present invention is not limited to these embodiments, and various embodiments may be made without departing from the scope of the present invention. Of course, it can be carried out.

[Brief description of the drawings]

FIG. 1 is a configuration diagram schematically showing the configuration of a refrigeration system 10 according to one embodiment of the present invention.

[Explanation of symbols]

10 refrigeration system, 20 refrigeration equipment, 22 liquid receiver,
24 electronic expansion valve, 26 evaporator, 28 first compressor, 30 second compressor, 32 three-way valve, 34 check valve,
36 check valve, 38 heat exchanger, 40 auxiliary condenser, 5
0 power generator, 52 receiver, 54 sealed variable speed pump, 56 check valve, 58 gas-liquid separator, 60 motor-operated valve,
62 gas turbine, 64 generator, 66 condenser, 6
8 rectifier, 70 storage battery, 72 inverter, 74
Changeover switch, 76 main power, 80 power supply.

Claims (4)

[Claims] 1. A refrigerating apparatus for refrigerating an object to be frozen by a refrigerating cycle including a compression step, a condensation step, an expansion step, and an evaporation step of a refrigerant, and at least a part of heat exchange by heat exchange with the refrigerant in the condensation step. A refrigeration system comprising: vaporizing means for vaporizing a medium; and power generating means for generating power using the vaporized heat exchange medium. 2. The refrigeration system according to claim 1, further comprising a supply amount adjusting unit capable of adjusting the supply amount of the vaporized heat exchange medium to the power generation unit. 3. The refrigeration system according to claim 1, further comprising an electric power supply unit that supplies electric power generated by the electric power generation unit to the refrigeration apparatus. 4. The apparatus according to claim 1, wherein the refrigerating apparatus is capable of selecting a plurality of compressors having different compression capacities in accordance with an object to be frozen in the compression step and compressing the refrigerant in the compression step. The refrigeration system according to any of the above.