KR101940991B1 - Complex heat exchange heat storage type heat pump system - Google Patents

Abstract

A combined heat exchange regenerative heat pump system is disclosed.
The disclosed composite heat exchange regenerative heat pump system comprises: a compressor capable of compressing refrigerant; A condenser for condensing the compressed refrigerant via the compressor; A hot water side expansion valve capable of expanding the condensed refrigerant via the condenser; A geothermal exchange member in which geothermal exchange water exchanges heat with the ground; A combined heat exchanger evaporator in which the refrigerant can be evaporated while heat exchange between the geothermal heat exchanged water heat exchanged with the earth and the refrigerant passed through the hot water side expansion valve is made in the geothermal exchange member; A hot water storage tank for condensing the refrigerant evaporated via the multiple heat exchange evaporator and storing heat generated by the condenser, thereby forming hot water; A cold water side expansion valve capable of expanding the condensed refrigerant via the condenser; A cold water side evaporator through which the refrigerant passed through the cold water side expansion valve passes and which absorbs heat; And a cold water storage tank in which cold water is circulated between the evaporator and the cold water evaporator and cold water is accumulated while being radiated from the cold water evaporator.
According to the disclosed composite heat exchange regenerative heat pump system, the complex heat exchange regenerative heat pump system includes a compressor, a condenser, a hot water side expansion valve, a geothermal heat exchanger, a composite heat exchange evaporator, a hot water storage tank, a cold water side expansion valve, The cold water evaporator and the cold water heat storage tank, it is possible to efficiently operate while simultaneously producing cold / hot water by using various heat sources such as geothermal heat and waste heat.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a heat pump system,

The present invention relates to a composite heat exchange regenerative heat pump system.

The regenerative heat pump system consists of a compressor, an evaporator, a condenser, an expansion valve, etc., and uses a heat or condensation heat of a refrigerant to transfer a low temperature heat source to a high temperature or to transfer a high temperature heat source to a low temperature. Or to supply hot water or cold water.

As a result of the increase in the oil price, a hybrid heat exchange regenerative heat pump system using a variety of heat sources is increasingly used in farmhouses such as poultry farms as means for replacing existing oil boilers.

However, in the conventional heat exchanger type heat pump system, various heat sources are simply used individually, and it is difficult to utilize various heat sources to improve the efficiency of the system.

Patent No. 10-1297764, filed on Mar. 23, 2013, entitled " Direct circulation geothermal source heat pump system "

It is an object of the present invention to provide a heat exchanger heat pump system of a multiple heat exchange regenerative type that can efficiently operate while simultaneously producing cold and hot water using various heat sources.

A composite heat exchange regenerative heat pump system according to an aspect of the present invention includes: a compressor capable of compressing a refrigerant; A condenser for condensing the compressed refrigerant via the compressor; A hot water side expansion valve capable of expanding the condensed refrigerant via the condenser; A geothermal exchange member in which geothermal exchange water exchanges heat with the ground; A combined heat exchanger evaporator in which the refrigerant can be evaporated while heat exchange between the geothermal heat exchanged water heat exchanged with the earth and the refrigerant passed through the hot water side expansion valve is made in the geothermal exchange member; A hot water storage tank for storing hot water to generate heat by condensing the refrigerant in the condenser; A cold water side expansion valve capable of expanding the condensed refrigerant via the condenser; A cold water side evaporator through which the refrigerant passed through the cold water side expansion valve passes and which absorbs heat; And a cold water storage tank in which cold water is circulated between the evaporator and the cold water evaporator, and cold water is accumulated while being radiated from the cold water evaporator,
Wherein the pipe through which the refrigerant passed through the condenser flows is branched into a pipe directed to the hot water side expansion valve and a pipe directed to the cold water side expansion valve so that the refrigerant passed through the condenser flows through the hot water side expansion valve and the cold water side expansion valve And the refrigerant directed to the hot water side expansion valve is evaporated in the composite heat exchanger evaporator to obtain heat, and after passing through the compressor in such a state, heat is discharged from the condenser, and refrigerant flowing toward the cold water side expansion valve The hot water is evaporated in the cold water side evaporator to obtain heat, and the heat is discharged from the condenser after passing through the compressor in such a state. In this process, hot water is formed by the heat radiated from the compressor and stored in the hot water storage tank And the cold water is formed while the heat is lost in the heat exchange process in the cold water side evaporator And is stored in the cold water storage tank.

According to an aspect of the present invention, there is provided a composite heat exchange regenerative heat pump system including a compressor, a condenser, a hot water side expansion valve, a geothermal heat exchanger, a composite heat exchange evaporator, a hot water storage tank, Side evaporator, the cold water side evaporator, and the cold water storage tank, it is possible to efficiently operate while simultaneously producing cold / hot water using a variety of heat sources such as geothermal heat and waste heat.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of a heat exchanger type heat pump system according to an embodiment of the present invention; FIG.
FIG. 2 is an enlarged view of a part of the structure of a heat exchanger heat pump system according to an embodiment of the present invention; FIG.

Hereinafter, a composite heat exchange regenerative heat pump system according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a view showing the construction of a composite heat exchange regenerative heat pump system according to an embodiment of the present invention. FIG. 2 is an enlarged view of a part of the structure of a composite heat exchange regenerative heat pump system according to an embodiment of the present invention. to be.

1 and 2, the composite heat exchanger heat pump system 100 according to the present embodiment includes a compressor 155, a condenser 120, a hot water side expansion valve 135, a geothermal exchange member A cold water side expansion valve 165, a cold water side evaporator 170, and a cold water storage tank 180. The cold storage side evaporator 140, the hot water storage tank 110, the cold water side expansion valve 165,

Wherein the compressor 155 is capable of compressing the refrigerant and the condenser 120 is capable of condensing the compressed refrigerant via the compressor 155 and the hot water side expansion valve 135 is connected to the condenser 120 to expand the condensed refrigerant.

In addition, the cold water side expansion valve 165 is capable of expanding the refrigerant condensed through the condenser 120, and the cold water side evaporator 170 is configured to expand the refrigerant passing through the cold water side expansion valve 165 And endothermically.

The pipe 204 through which the refrigerant passed through the condenser 120 flows is connected to the pipe 194 directed to the hot water side expansion valve 135 and the pipe 196 directed to the cold water side expansion valve 165 ).

Off valves 210 and 215 are provided on the respective pipes 194 and 196 so that the flow of the refrigerant can be controlled while the pipes 194 and 196 are selectively opened or closed simultaneously.

Reference numeral 125 denotes a receiver installed on the pipe 204 through which the refrigerant passed through the condenser 120 flows.

The geothermal exchange member 115 is buried in the ground and the geothermal exchange water flows, and the geothermal exchange water is heat-exchanged with the ground.

Reference numeral 103 denotes a supply pump capable of discharging the geothermal exchange water via the geothermal exchange member 115.

The geothermal heat exchanger (140) exchanges heat between geothermal heat exchanged with the ground and the refrigerant passing through the hot water side expansion valve (135), so that the refrigerant can be evaporated.

In detail, the combined heat exchange evaporator 140 includes a geothermal exchange water flow pipe 141 through which the geothermal exchange water flowing along the pipe 192 through which the geothermal exchange water supplied from the geothermal exchange member 115 flows, A coolant flow pipe 142 through which the coolant flows through the expansion valve 135, a heat sink 143 through which the geothermal heat exchange water flow pipe 141 and the coolant flow pipe 142 pass together, 141), a flow fan (144) capable of forming an air flow toward the refrigerant flow tube (142) and the heat sink (143).

The geothermal exchange water flow pipe 141 and the refrigerant flow pipe 142 are formed in a zigzag shape and are arranged to overlap with each other to improve heat exchange efficiency.

The geothermal heat exchange water flow pipe 141 and the refrigerant flow pipe 142 are intertwined together so that the geothermal exchange water flow pipe 141 and the refrigerant flow pipe 142 are not only convection but also the heat radiating plate 143 And the cooling fan 144 may be operated to cool the heat radiating plate 143 so that the heat radiating plate 143 is not heated excessively.

The geothermal exchange water that has lost heat through the multiple heat exchange evaporator 140 is returned to the geothermal exchange member 115 along the pipe 193 connecting the multi-heat exchanger evaporator 140 and the geothermal exchange member 115, And the refrigerant obtained by heating the refrigerant through the multiple heat exchange evaporator 140 flows toward the compressor 155 along a pipe 195 connecting the multiple heat exchange evaporator 140 and the compressor 155.

Reference numeral 150 denotes a gas-liquid separator installed on a pipe 195 connecting the multiple heat exchanger evaporator 140 and the compressor 155. Reference numeral 190 denotes a gas-liquid separator which connects the compressor 155 and the condenser 120 It is piping.

In the present embodiment, the geothermal heat exchanging water of the multiple heat exchange regenerative heat pump system 100 via the geothermal heat exchanging member 115 is cooled by the refrigerant flowing from the condenser 120 to the hot water side expansion valve 135 And a geothermal and supercooling member (130) for supercooling the refrigerant flowing from the condenser (120) to the hot water side expansion valve (135) while exchanging heat.

The geothermal supercooling member 130 is disposed on a pipe 194 connecting the condenser 120 and the hot water side expansion valve 135 and is connected to a piping 194 through which the geothermal exchange water supplied from the geothermal exchange member 115 flows, The geothermal heat exchanging member 115 is connected to the geothermal supercooling member 130 so that the geothermal exchange water supplied from the geothermal heat exchanging member 115 passes through the geothermal supercooling member 130, It is possible to supercool.

The geothermal heat exchanged water passed through the geothermal supercooling member 130 flows to the composite heat exchanger evaporator 140 along a pipe 191 connecting the geothermal supercooling member 130 and the multiple heat exchange evaporator 140.

The hot water storage tank 110 condenses the refrigerant evaporated through the combined heat exchanger evaporator 140 and condenses in the condenser 120 to accumulate the heat released to form hot water.

Reference numeral 185 denotes a pipe for allowing hot water in the hot water storage tank 110 to flow from the hot water storage tank 110 to the condenser 120. Reference numeral 186 denotes a pipeline through the condenser 120, And the resulting hot water is returned to the hot water storage tank (110).

Here, the hot water forming water is the same material as the hot water, for example, water, and has a temperature difference only.

A supply pump 102 and a condenser 120 are connected to the hot water storage tank 110 and the condenser 120 so that hot water in the hot water storage tank 110 flows toward the condenser 120 from the hot water storage tank 110. [ Water-side three-way valve 101 capable of returning at least a part of the hot water forming water flowing into the hot water storage tank 110 to the hot water storage tank 110 is provided.

The hot water return pipe 187 extends from the hot water side three-way valve 101 toward the hot water storage tank 110, so that the hot water can be returned.

The hot water storage tank 110 is provided with an upper diffuser 111, an intermediate diffuser 112 and a lower diffuser 113 at different heights in the vertical direction.

A pipe 185 for allowing the hot water in the hot water storage tank 110 to flow from the hot water storage tank 110 to the condenser 120 is connected to the upper diffuser 111. In the intermediate diffuser 112, And a pipe 186 connected to the lower diffuser 113 through the condenser 120 to convert the hot water formed by the hot water forming water heat to the hot water storage tank 110 is connected do.

The upper diffuser 111 is connected to the heating bottom coil 107 formed on the floor of the customer 10 through a pipe 189 so that hot water in the hot water storage tank 110 is supplied to the heating bottom coil 107 So that the floor heating can be supplied to the demander.

Reference numeral 188 denotes a pipe for allowing hot water passed through the bottom coil for heating 107 to be returned through the lower diffuser 113 in the hot water storage tank 110.

The multiple heat exchange regenerative heat pump system 100 is installed on a pipe 195 connecting the multiple heat exchanger evaporator 140 and the compressor 155 so that the refrigerant discharged from the multiple heat exchanger evaporator 140 to the compressor 155 Side check valve 145 for preventing the reverse flow of the refrigerant flowing in the hot water side check valve 145.

The cold water storage tank 180 circulates cold water formed between the evaporator 170 and the cold water evaporator 170, and the cold water is accumulated while the cold water evaporator 170 radiates heat.

Reference numeral 201 denotes a pipe through which the cold water formed in the cold water storage tank 180 flows into the cold water storage tank 180 toward the cold water side evaporator 170. Reference numeral 200 denotes a pipeline through the cold water side evaporator 170, And the cold water formed by dissipating heat from the formed water is returned to the cold water storage tank 180.

Here, the cold water forming water is the same as the cold water, for example, water, and has a temperature difference only.

A supply pump 105 is provided on the piping 201 for causing the cold water forming water in the cold water storage tank 180 to flow from the cold water storage tank 180 toward the cold water side evaporator 170, A cold water-side three-way valve 106 capable of returning at least a portion of the cold water formed in the water flowing into the evaporator 170 to the cold water storage tank 180 is installed.

The cold water return pipe 199 extends from the cold water side three-way valve 106 toward the cold water storage tank 180 so that the cold water can be returned.

An upper diffuser 181, an intermediate diffuser 182, and a lower diffuser 183 are installed at different heights in the vertical direction in the cold water storage tank 180.

A pipe 201 is connected to the upper diffuser 181 so that the cold water forming water in the cold water storage tank 180 flows from the cold water storage tank 180 toward the cold water side evaporator 170. In the intermediate diffuser 182, The evaporator 180 is connected to the cold water return pipe 199 and is connected to the lower diffuser 183 through the cold water evaporator 170 to discharge the cold water formed by radiating the heat to the cold water storage tank 180 200 are connected.

As described above, when the cold water is formed, the refrigerant obtained heat by heat exchange in the cold water side evaporator 170 flows through the pipe 198 connecting the cold water side heat exchanger and the compressor 155, 120 can transfer heat to the hot water storage tank 110 so that the waste heat generated during the operation for storing the cold water in the cold water storage tank 180 can contribute to the formation of hot water in the hot water storage tank 110 , The operation efficiency of the heat exchanger heat pump system 100 can be improved.

The lower diffuser 183 is connected to the fan coil 108 installed on the customer 10 or the like through a pipe 202 so that the cold water in the cold water storage tank 180 flows through the fan coil 108 It is possible to supply the cold water to the customer 10.

Reference numeral 203 denotes a piping for allowing cold water passing through the fan coil 108 to be circulated through the upper diffuser 181 in the cold water storage tank 180. Reference numeral 104 denotes a pipe for circulating the lower diffuser 183, Is a feed pump installed on a pipe 202 connecting the feed pipe 108 to the feed pipe.

The combined heat exchange and storage heat pump system 100 is installed on a piping 198 connecting the cold water side heat exchanger and the compressor 155 and flows from the cold water side evaporator 170 to the compressor 155 And a cold water side check valve 175 for preventing reverse flow of the refrigerant.

Meanwhile, in the multi-heat exchanger heat pump system 100, the cold water formed through the cold water storage tank 180 is heat-exchanged with the refrigerant flowing from the condenser 120 to the cold water side expansion valve 165, And a cold water supercooling member 160 for supercooling the refrigerant flowing to the cold water side expansion valve 165.

The cold water supercooling member 160 is disposed on a pipe 196 connecting the condenser 120 and the cold water side expansion valve 165 and is disposed in the cold water storage tank 180 toward the cold water side evaporator 170 The pipe branched from the pipe 201 for flowing the cold water forming water in the cold water storage tank 180 is connected to the cold water subcooling member 160 so that the cold water forming water supplied from the cold water storage tank 180 is supplied to the cold water supercooling member 160 The refrigerant passing through the cold water supercooling member 160 can be supercooled.

The cold water formed through the cold water supercooling member 160 flows into the cold water storage tank 180 along the pipe 197 connecting the cold water supercooling member 160 and the intermediate diffuser 182 of the cold water storage tank 180 Flow.

Hereinafter, operation of the heat exchanger heat pump system 100 according to the present embodiment will be described with reference to the drawings.

First, the refrigerant passed through the condenser 120 flows into the hot water side expansion valve 135 and the cold water side expansion valve 165.

The refrigerant directed toward the hot water side expansion valve 135 is evaporated in the composite heat exchanger evaporator 140 to obtain heat and in that state passes through the compressor 155 and then releases heat from the condenser 120.

The refrigerant directed toward the cold water side expansion valve 165 is evaporated in the cold water side evaporator 170 to obtain heat, and in that state, passes through the compressor 155 and then releases heat from the condenser 120.

In this process, hot water is formed by the heat radiated from the compressor 155 and is stored in the hot water storage tank 110.

On the other hand, during the heat exchange in the cold water side evaporator 170, cold water is formed while the heat is lost, and the cold water is stored in the cold water storage tank 180.

The combined heat exchanger heat pump system 100 includes the compressor 155, the condenser 120, the hot water side expansion valve 135, the geothermal heat exchanger 115, the combined heat exchanger evaporator 140, Water evaporator 170, and the cold water storage tank 180, various kinds of heat sources such as geothermal heat and waste heat are used in combination to supply hot and cold water at the same time Efficient operation can be achieved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the following claims And can be changed. However, it is intended that the present invention covers the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

According to the composite heat exchange regenerative heat pump system according to one aspect of the present invention, it is possible to operate efficiently while simultaneously producing cold / hot water using various heat sources, and therefore, the industrial applicability is high.

100: Combined heat exchange regenerative heat pump system
110: Hot water storage tank
115: Geothermal heat exchanger
120: condenser
135: Hot water side expansion valve
140: Combined Heat Exchanger Evaporator
155: Compressor
165: cold water side expansion valve
170: cold water evaporator
180: cold water storage tank

Claims (3)

delete A compressor capable of compressing refrigerant;
A condenser for condensing the compressed refrigerant via the compressor;
A hot water side expansion valve capable of expanding the condensed refrigerant via the condenser;
A geothermal exchange member in which geothermal exchange water exchanges heat with the ground;
A combined heat exchanger evaporator in which the refrigerant can be evaporated while heat exchange between the geothermal heat exchanged water heat exchanged with the earth and the refrigerant passed through the hot water side expansion valve is made in the geothermal exchange member;
A hot water storage tank for storing hot water to generate heat by condensing the refrigerant in the condenser;
A cold water side expansion valve capable of expanding the condensed refrigerant via the condenser;
A cold water side evaporator through which the refrigerant passed through the cold water side expansion valve passes and which absorbs heat;
A cold water storage tank in which cold water is circulated between the cold water evaporator and the cold water evaporator, and cold water is accumulated in the cold water evaporator; And
And a geothermal and supercooling member for supercooling the refrigerant flowing from the condenser to the hot water side expansion valve while exchanging heat with the refrigerant flowing from the condenser to the hot water side expansion valve via the geothermal exchange member,
Wherein the pipe through which the refrigerant passed through the condenser flows is branched into a pipe directed to the hot water side expansion valve and a pipe directed to the cold water side expansion valve so that the refrigerant passed through the condenser flows through the hot water side expansion valve and the cold water side expansion valve Lt; / RTI >
The refrigerant directed toward the hot water side expansion valve is evaporated in the composite heat exchange evaporator, and heat is obtained, and the refrigerant is passed through the compressor in such a state, and then heat is discharged from the condenser,
The refrigerant directed toward the cold water side expansion valve is evaporated in the cold water side evaporator, and heat is obtained, and the refrigerant is passed through the compressor in such a state, and then heat is discharged from the condenser,
In this process, hot water is formed by the heat radiated from the compressor and stored in the hot water storage tank. In the heat exchange process in the cold water side evaporator, cold water is formed while being stored in the cold water storage tank,
The geothermal supercooling member is disposed on a pipe connecting the condenser and the hot water side expansion valve, and a pipe through which the geothermal exchange water supplied from the geothermal exchange member is connected is connected to the geothermal heat exchanger, The geothermal exchange water passing through the geothermal supercooling member can also supercool the refrigerant passing through the geothermal supercooling member,
Wherein the geothermal heat exchanged water passed through the geothermal super-cooling member flows to the composite heat exchanger evaporator along a pipe connecting the geothermal super-cooling member and the multiple heat exchange evaporator. A compressor capable of compressing refrigerant;
A condenser for condensing the compressed refrigerant via the compressor;
A hot water side expansion valve capable of expanding the condensed refrigerant via the condenser;
A geothermal exchange member in which geothermal exchange water exchanges heat with the ground;
A combined heat exchanger evaporator in which the refrigerant can be evaporated while heat exchange between the geothermal heat exchanged water heat exchanged with the earth and the refrigerant passed through the hot water side expansion valve is made in the geothermal exchange member;
A hot water storage tank for storing hot water to generate heat by condensing the refrigerant in the condenser;
A cold water side expansion valve capable of expanding the condensed refrigerant via the condenser;
A cold water side evaporator through which the refrigerant passed through the cold water side expansion valve passes and which absorbs heat;
A cold water storage tank in which cold water is circulated between the cold water evaporator and the cold water evaporator, and cold water is accumulated in the cold water evaporator; And
And a cold water supercooling member for supercooling the refrigerant flowing from the condenser to the cold water side expansion valve while exchanging heat with the refrigerant flowing from the condenser to the cold water side expansion valve via the cold water storage tank,
Wherein the pipe through which the refrigerant passed through the condenser flows is branched into a pipe directed to the hot water side expansion valve and a pipe directed to the cold water side expansion valve so that the refrigerant passed through the condenser flows through the hot water side expansion valve and the cold water side expansion valve Lt; / RTI >
The refrigerant directed toward the hot water side expansion valve is evaporated in the composite heat exchange evaporator, and heat is obtained, and the refrigerant is passed through the compressor in such a state, and then heat is discharged from the condenser,
The refrigerant directed toward the cold water side expansion valve is evaporated in the cold water side evaporator, and heat is obtained, and the refrigerant is passed through the compressor in such a state, and then heat is discharged from the condenser,
In this process, hot water is formed by the heat radiated from the compressor and stored in the hot water storage tank. In the heat exchange process in the cold water side evaporator, cold water is formed while being stored in the cold water storage tank,
Wherein the cold water supercooling member is disposed on a pipe connecting the condenser and the cold water side expansion valve and the pipe branched from the pipe for causing the cold water forming water in the cold water storage tank to flow from the cold water storage tank toward the cold water side evaporator, So that the cold water forming water supplied from the cold water storage tank can pass through the cold water supercooling member and can also supercool the refrigerant passing through the cold water and supercooling member,
And the cold water forming water passing through the cold water supercooling member flows to the cold water storage tank along a pipe connecting the cold water supercooling member and the intermediate diffuser of the cold water storage tank.

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