KR101188258B1 - Heat-pump system - Google Patents

Abstract

The present invention is configured to use a heat source by geothermal or river water, etc. to increase the energy use effect, as well as to the heat pump system to maximize the heat exchange efficiency by the super-cooling capacitor to which the refrigerant flow is applied according to the cooling and heating mode It is about.
According to the present invention, a first heat exchanger (31) provided to perform heat exchange with the heat source (1) side including geothermal or river water, and refrigerant lines (40, 41) in the first heat exchanger (31) The second heat exchanger 32 and the refrigerant line 40 to be located between the first heat exchanger 31 and the second heat exchanger 32 are connected to each other and at the same time to exchange heat with cold or hot water. A heat pump unit 30 including a subcooling capacitor 37 interconnected by; A heat source supply line 50 connected between the first heat exchanger 31 and the heat source 1 and extending to circulate the heat exchange medium; It is connected between the second heat exchanger 32 and the place of use (2) or the cold and hot water storage tank (3) is extended to circulate cold water or hot water, the second heat exchanger (32) via the subcooling capacitor (37) Provided is a heat pump system including a cold and hot water line (60) through which cold water or hot water is introduced.

Description

Heat Pump System

The present invention relates to a heat pump system, and more particularly, it is configured to use a heat source by geothermal or river water, etc. to increase the energy use effect, as well as by a supercooling capacitor to which a refrigerant flow is applied according to a cooling and heating mode. The present invention relates to a heat pump system capable of maximizing heat exchange efficiency.

In general, a heat pump is a device (or system) including a compressor, a condenser, an evaporator, and an expansion valve to absorb or release heat through a phase change of a circulating refrigerant to supply hot / cold water or heating and cooling. An example of cold and hot water and a cooling and heating supply system using the drawings will be described below.

As shown in FIG. 1, the compressor 11, the first heat exchanger 12, the second heat exchanger 13, and the expansion valve 14 which are interconnected by the circulation line 20 to form a circulation cycle of the refrigerant. 15 is provided, and a four-way valve 16 capable of switching the refrigerant flow according to cooling (or cold water) and heating (or hot water) is provided, and a bypass pipe for changing the flow of the refrigerant according to cooling and heating ( 17) and check valves 18 and 19 provided in the bypass pipe 17.

In this configuration, the first heat exchanger 12 and the second heat exchanger 13 is operated as a condenser or an evaporator according to a cooling mode or a heating mode, and the expansion valves 14 and 15 are used for cooling and heating. Accordingly, the cooling expansion valve 14 and the heating expansion valve 15 are respectively provided, and the bypass pipe 17 is circulated by expanding the refrigerant by the expansion valves 14 and 15 according to the cooling and heating mode. Are combined to build.

However, according to such a conventional heat pump system, when the heating and cooling (or cold and hot water) is supplied by the first heat exchanger 12, the condensation of the first heat exchanger 12 and the second heat exchanger 13 or It does not have a separate heat exchange means or configuration that can increase the evaporation efficiency has a disadvantage of lowering the heating and cooling efficiency.

In addition, the conventional heat pump system can not supply enough hot water at a desired time only by the heat pump due to the low efficiency, it is necessary not only to install an auxiliary system such as a boiler, but also the operation of the auxiliary system becomes frequent, thereby consuming energy In addition to the increase, there is a problem that can not expect any effect to save energy by using a heat pump.

In addition, the conventional heat pump system has one of the functions of the cooling function and the heating function is excellent while the other function is a relatively disadvantageous disadvantage, thereby having difficulty in meeting the cooling and heating at the same time.

The present invention is to solve the problems as described above, the present invention is configured to use a heat source by geothermal heat or river water by the optimized device can not only increase the energy use effect of the refrigerant in accordance with the heating and cooling mode It is to provide a heat pump system that can maximize the heat exchange efficiency by the super-cooling capacitor to which the flow is applied, and also to satisfy the cooling function and heating function by the optimized configuration.

According to a feature of the invention, the first heat exchanger 31 is provided so that heat exchange with the heat source (1) side including geothermal or river water, and the refrigerant line (40, 41) in the first heat exchanger (31) The second heat exchanger 32 and the switching valve 35 is provided on the refrigerant lines 40 and 41 to be connected to each other and the heat exchange with the cold or hot water at the same time, and to convert the flow of the refrigerant ) And the first heat exchanger 31 and the second heat exchanger 32 so as to cool the refrigerant discharged from the first heat exchanger 31 or the second heat exchanger 32. A heat pump unit 30 including a subcooling capacitor 37 interconnected by refrigerant lines 40 and 41;

A heat source supply line 50 connected between the first heat exchanger 31 and the heat source 1 and extending to circulate the heat exchange medium;

It is connected between the second heat exchanger 32 and the place of use (2) or the cold and hot water storage tank (3) is extended to circulate cold water or hot water, the second heat exchanger (32) via the subcooling capacitor (37) It comprises a cold and hot water line 60 to be introduced into the cold water or hot water;

The refrigerant lines 40 and 41 may be connected to the first heat exchanger 31 and the second heat exchanger 32 by a first refrigerant line 40 and the subcooling capacitor 37. A second refrigerant line 41 connecting the heat exchanger 31 and the second heat exchanger 32;

 An expansion valve 34 for expanding the refrigerant and a plurality of check valves 45 to 48 for controlling the flow of the refrigerant in one direction on the first refrigerant line 40 or the second refrigerant line 41;

The check valves 45 to 48 are controlled to flow the refrigerant onto the first refrigerant line 40 to supply cold water or cooling to the use place 2 or the cold / hot water storage tank 3 or the second refrigerant line. A heat pump system is provided, characterized in that the refrigerant is flowed onto the 41 to supply hot water or heating to the use place 2 or the cold / hot water storage tank 3.

According to another feature of the invention, the heat source supply line 50 or the cold and hot water line 60 is located on the inlet and outlet side of the first heat exchanger 31 or the second heat exchanger 32, the heat exchange medium or cold water B) first circulation pumps 51 and 61 and second circulation pumps 52 and 62 configured to circulate hot water;

A check valve (54, 55, 64, 65) positioned at the outlet of each of the circulation pumps (51, 52, 61, 62) to control the flow of heat exchange medium or cold water or hot water in one direction;

Bypass pipes 53 and 63 connected to the front and rear ends of the first circulation pumps 51 and 61 or the second circulation pumps 52 and 62 and the heat exchange medium located on the bypass pipes 53 and 63. Or it is provided a heat pump system characterized in that the opening and closing valves 56, 57, 66, 67 to control the flow of cold or hot water.

According to another feature of the present invention, on the cold and hot water line 60, the bypass line 68 for connecting the front and rear ends of the subcooling capacitor 37 and the control of the flow of cold or hot water on the bypass line (68) A heat pump system is provided, which is further provided with an on / off valve 69.

According to another feature of the invention, the first heat exchanger 31 is provided so that heat exchange with the heat source (1) side including geothermal or river water, and the refrigerant line 40 in the first heat exchanger (31) The second heat exchanger 32 and the switching valve 35 is provided on the coolant line 40 to be connected to each other and the heat exchange with the cold water or hot water at the same time, and to convert the flow of the coolant and The refrigerant line is located between the first heat exchanger 31 and the second heat exchanger 32 to cool the refrigerant discharged from the first heat exchanger 31 or the second heat exchanger 32. A heat pump unit (30) comprising subcooling capacitors (36,37) interconnected by (40,41);

A heat source supply line 50 connected between the first heat exchanger 31 and the heat source 1 and extending to circulate the heat exchange medium;

A cold / hot water line (60) connected between the second heat exchanger (32) and the place of use (2) or the cold / hot water storage tank (3) so as to circulate cold water or hot water;

The subcooling capacitors 36 and 37 are connected to the first heat exchanger 31 by the heat source supply line 50 and the second heat exchanger by the cold and hot water line 60. A second subcooling capacitor 37 connected to the machine 32;

The refrigerant lines 40 and 41 may include a first refrigerant line 40 directly connecting the first heat exchanger 31 and the second heat exchanger 32 via the first subcooling capacitor 36. A second refrigerant line (41) connecting the first heat exchanger (31) and the second heat exchanger (32) via a second subcooling capacitor (37);

 An expansion valve 34 for expanding the refrigerant and a plurality of check valves 45 and 46 for controlling the flow of the refrigerant in one direction on the first refrigerant line 40 or the second refrigerant line 41;

The check valves 45 and 46 are controlled to flow the refrigerant onto the first refrigerant line 40 to supply cold water or cooling to the place of use 2 or the cold / hot water storage tank 3 or the second refrigerant line. A heat pump system is provided, characterized in that the refrigerant is flowed onto the 41 to supply hot water or heating to the use place 2 or the cold / hot water storage tank 3.

According to another feature of the invention, on the heat source supply line 50 or the cold and hot water line 60 is located on the inlet and outlet side of the first heat exchanger 31 or the second heat exchanger 32 or the heat exchange medium or First and second circulation pumps 52 and 62 configured to circulate cold or hot water;

A check valve (54, 55, 64, 65) positioned at the outlet of each of the circulation pumps (51, 52, 61, 62) to control the flow of heat exchange medium or cold water or hot water in one direction;

Bypass pipes 53 and 63 connected to the front and rear ends of the first circulation pumps 51 and 61 or the second circulation pumps 52 and 62 and the heat exchange medium located on the bypass pipes 53 and 63. Or it is provided a heat pump system characterized in that the opening and closing valves 56, 57, 66, 67 to control the flow of cold or hot water.

According to another feature of the invention, the bypass line 58 for connecting the front and rear ends of the first sub-cooling capacitor 36 or the second sub-cooling capacitor 37 on the heat source supply line 50 or the cold and hot water line 60. 68 and the on-off valve 59,69 for controlling the flow of cold water or hot water on the bypass lines 58, 68 are provided.

As described above, according to the present invention, the heat source supply line 50 that heat-exchanges the first heat exchanger 31 in the bottom pump unit 30 including the first heat exchanger 31 and the second heat exchanger 32. ) Can use the heat source (1), such as geothermal and river water can reduce the waste of energy and environmental pollution caused by the use of fossil raw materials, increase the evaporation or condensation efficiency of the first heat exchanger (31) As a result, the heat exchange efficiency by the second heat exchanger 32 is increased to amplify the cooling and heating supply effect.

In addition, the present invention is provided with a subcooling capacitor (37) separately from the heat exchangers (31, 32), it is possible to further increase the heat exchange efficiency by the second heat exchanger (32) by preheating the supply water during heating. Under abnormal load such as when the amount of water supplied is reduced, the condensation pressure of the second heat exchanger 32 is prevented from increasing, thereby preventing burnout of the device (especially the compressor 33) and at the same time maintaining the stability of the device. There is an advantage to increase.

In addition, as the subcooling capacitor 37 is provided, the evaporation efficiency of the first heat exchanger 31 may be increased by increasing the subcooling degree of the refrigerant discharged from the second heat exchanger 32. As described above, there is an advantage that can increase the overall cooling and heating performance by increasing the efficiency at the time of cooling as well as heating.

 In particular, the subcooling capacitor (36,37) is located on the heat source (1) side, the first subcooling capacitor (36) connected to the first heat exchanger (31), the place of use (2) or cold and hot water storage tank (3) side The second subcooling condenser 37 is disposed at the second heat exchanger 32 and connected to the second heat exchanger 32, so that the heat exchange medium on the heat source supply line 50 may be mixed with cold water or hot water on the cold / hot water line 60. Thereby, there is no fear that the cold or hot water supplied to the place of use (2) or the cold and hot water storage tank (3) is contaminated by the heat exchange medium.

In addition, when hot water or heating is supplied by the second heat exchanger 32, the supply water of the cold / hot water line 60 that is heat-exchanged to the second heat exchanger 32 is provided to pass through the supercooling capacitor 37. After the water is preheated in advance, the second heat exchanger 32 is provided to be introduced to further increase the heating effect of the hot water.

In addition, when cold water or cooling is supplied by the second heat exchanger 32, the heat source supply line 50 is provided to exchange heat with the first heat exchanger 31 via the first subcooling capacitor 36. In addition to improving the cooling capacity by the second heat exchanger 32, it is possible to further improve the coefficient of performance.

In addition, a plurality of circulation pumps (51, 52, 61, 62) and check valves (54, 55, 64, 65) are provided on the heat source supply line (50) or the cold / hot water line (60), and the refrigerant line according to the cooling and heating mode. When the refrigerant on the 40 and 41 is switched, the circulation pumps 51, 52, 61 and 62 and the check valves 54, 55, 64 and 65 are provided to change the flow of the heat exchange medium or the feed water. Accordingly, the flow of the heat exchange medium or the feed water flows in the opposite direction to the flow of the refrigerant, so that heat exchange is performed by counter-flow to further increase the efficiency and simultaneously counter flow in the heating mode and the cooling mode. The heat exchange by the has the advantage that can increase both the cooling and heating efficiency.

In addition, bypass lines 58 and 68 are further provided on the heat source supply line 50 and the cold / hot water line 60 to prevent the heat exchange medium or the supply water from passing through the supercooling capacitors 36 and 37 in the heating mode or the cooling mode. As a result, the power loss of the circulation pumps 51, 52, 61, and 62 may be prevented by reducing the resistance caused by passing the heat exchange medium or the supply water to the subcooling capacitors 36 and 37.

1 is a configuration diagram showing an example of a conventional heat pump system
2 is a block diagram according to an embodiment of the present invention
3 is another configuration diagram according to an embodiment of the present invention;
4 is another configuration diagram according to an embodiment of the present invention;
5 is a configuration diagram according to another embodiment of the present invention
6 is another configuration diagram according to another embodiment of the present invention
7 is another configuration diagram according to another embodiment of the present invention

The objects, features and advantages of the present invention will become more apparent from the following detailed description. Hereinafter, description will be made with reference to the accompanying drawings.

2 to 7 illustrate a configuration according to various embodiments of the present invention. As shown in FIG. 2, one embodiment of the present invention includes a first heat exchanger 31, a second heat exchanger 32, which are interconnected by refrigerant lines 40 and 41 in one case 4. A heat pump unit 30 including a compressor 33 and an expansion valve 34 is provided to perform heat exchange by the phase change of the refrigerant circulated through the refrigerant lines 40 and 41.

In this configuration, the first heat exchanger 31 is provided to increase the heat exchange efficiency by using a heat source 1 such as geothermal heat. For this purpose, a portion of the first heat exchanger 31 is embedded in the ground. A heat source supply line 50 extending to the outside of the case 4 so as to be connected is provided, and a circulation pump 51 is provided on the heat source supply line 50 to circulate a heat exchange medium such as water or brine. While the heat exchange is made by the first heat exchanger (31).

In addition, the second heat exchanger 32 is connected to the cold and hot water line 60 through which cold water or hot water (hereinafter referred to as "supply water") flows in and out of the case 4, and is connected to the cold and hot water line 60. ) Is provided with a circulation pump (61) and the supply water is circulated to exchange heat with the second heat exchanger (32) to the cold or hot water or heating and cooling to the destination (2) or cold and hot water storage tank (3) connected to the cold and hot water line (60) I can supply it.

Here, a switching valve 35 such as a four-way valve capable of switching the flow of the refrigerant is provided on the refrigerant lines 40 and 41, and the refrigerant flow is switched by the switching valve 35. The first heat exchanger 31 and the second heat exchanger 32 are operated as an evaporator or a condenser to supply cold / hot water (or air-conditioning), for example, when hot water and heating such as winter are required (in heating mode). The first heat exchanger 31 is operated as an evaporator, the second heat exchanger 32 is operated as a condenser, and when cold water or cooling is required (in the cooling mode), such as in summer, the first heat exchanger 31 is operated as a condenser, and the second heat exchanger 32 is operated as an evaporator.

In addition to the above configuration, the case 4 is provided with a subcooling capacitor 37 on the refrigerant lines 40 and 41 located between the first heat exchanger 31 and the second heat exchanger 32. To cool the refrigerant discharged from the first heat exchanger 31 or the second heat exchanger 32, and according to the subcooling capacitor 37, the first heat exchanger 31 or the second heat exchanger ( The refrigerant passing through the 32 is further cooled to increase the condensation efficiency, and the cold / hot water line 60 is connected to pass through the subcooling capacitor 37 so as to flow into the second heat exchanger 32. It is supposed to preheat the number.

At this time, the refrigerant lines 40 and 41 pass through the first refrigerant line 40 directly connecting the first heat exchanger 31 and the second heat exchanger 32 and the subcooling capacitor 37. It consists of a second refrigerant line 41 connecting the first heat exchanger 31 and the second heat exchanger 32, the heat exchanger on the first refrigerant line 40 and the second refrigerant line 41. Expansion valve 34 for expanding the refrigerant condensed from the air (31, 32) is provided and at the same time to control the flow of the refrigerant on the first refrigerant line 40 or the second refrigerant line 41 in accordance with the heating and cooling mode A plurality of check valves 45 to 48 are provided.

Here, the first refrigerant line 40 and the second refrigerant line 41 are interconnected by a common line 42, the expansion valve 34 is located on the common line 42, the check The valves 45 to 48 are provided on the first refrigerant line 40 so as to be positioned before and after the expansion valve 34, and the first and fourth check valves 45 and 48 and the second refrigerant line 41 are provided. ) And second and third check valves 46 and 47.

The operation of the heating mode and the cooling mode by the configuration as described above is as follows. In the heating mode, the refrigerant flows on the second refrigerant line 41 so that the supply water passing through the subcooling capacitor 37 is preheated by heat exchange with the refrigerant. The first and fourth check valves 45 and 48 provided on the upper portion are in a closed state (a state in which the flow of refrigerant is blocked) and the second and third check valves provided on the second refrigerant line 41. 46 and 47 are in an open state (a state in which refrigerant can flow), and the refrigerant is passed through the second heat exchanger 32 (operated as a condenser) and the subcooling capacitor 37 by the switching valve 35. The first heat exchanger 31 (operated by an evaporator) flows to the side. By the flow of the refrigerant, the supply water passing through the subcooling capacitor 37 is supplied to the second heat exchanger 32 in a preheated state, thereby increasing a heating effect.

In addition, in the cooling mode, the refrigerant is controlled to flow on the first refrigerant line 40 such that the refrigerant does not flow in the subcooling capacitor 37. For this purpose, the refrigerant provided on the first refrigerant line 40 is provided. The first and fourth check valves 45 and 48 are opened, the second and third check valves 46 and 47 provided on the second refrigerant line 41 are closed, and the refrigerant is The switching valve 35 flows directly from the first heat exchanger 31 (operated by a condenser) to the second heat exchanger 32 (operated by an evaporator). In the cooling mode, the control of the refrigerant from flowing in the subcooling capacitor 37 is performed by the subcooling condenser 37 because the supply water is supplied to the second heat exchanger 32 in a preheated state. This is because the adverse effect of lowering the heat exchange efficiency according to 32) is exhibited.

The expansion valve 34 is provided on the common line 42 to which the first refrigerant line 40 and the second refrigerant line 41 are connected to each other, and the expansion valve 34 is the check valve ( 45 to 48 are provided to pass through the refrigerant in the heating mode or the cooling mode, but the expansion valve 34 may be provided with a plurality to be operated in the heating mode and the cooling mode, respectively, by the drawings shown The explanation is as follows.

As shown in FIG. 3, the expansion valve 34 is provided as a heating expansion valve 34a and a cooling expansion valve 34b on the first refrigerant line 40 and the second refrigerant line 41, respectively. The check valves 45 and 46 are provided on the first refrigerant line 40 and the second refrigerant line 41, respectively, and the first check valve 45 controls the refrigerant to flow in opposite directions. A second check valve 46 is provided.

According to this configuration, in the heating mode, after the refrigerant flows through the second heat exchanger 32 and the subcooling capacitor 37 by the second check valve 46, the second refrigerant line 41 is on the second refrigerant line 41. The refrigerant flows to the first heat exchanger 31 through the heating expansion valve 34a provided in the heating unit. In the cooling mode, the refrigerant flows through the first heat exchanger 31, and then the first check valve. Refrigerant flows to the second heat exchanger 32 through a cooling expansion valve 34b provided on the first refrigerant line 40 by 34a. In the cooling mode, the subcooling capacitor The second check valve 46 is positioned in front of the subcooling capacitor 37 so that refrigerant does not flow to the 37 side.

According to the present invention, the first refrigerant line 40 and the second refrigerant line 41 is provided to change the flow of the refrigerant in the cooling mode or heating mode, each of the refrigerant lines 40, 41 according to the cooling and heating mode It is possible to easily change the flow of the refrigerant so that the coolant is applied to the subcooling capacitors 36 and 37 by a plurality of check valves 45 to 48 provided on the upper surface thereof, thereby simultaneously supplying the cooling supply capability and the heating supply capability. It can be increased.

In addition, as shown in Figure 4, in one embodiment of the present invention, in addition to the above-described configuration, the heat exchange medium or the supply water flow in accordance with the cooling mode and heating mode on the heat source supply line 50 and the cold and hot water line 60 In order to further increase the heat exchange efficiency, for this purpose, the inlet and outlet sides of the first heat exchanger 31 and the second heat exchanger 32 on the heat source supply line 50 and the cold and hot water line 60. The first circulation pump (51, 61) and the second circulation pump (52, 62) are provided so as to be located at the same time at the discharge port side of the first circulation pump (51, 61) and the second circulation pump (52, 62) Check valves 54, 55, 64, and 65 are provided to control the flow of the heat exchange medium or the feed water in one direction, and the front and rear of the first and second circulation pumps 51 and 61 and 52 and 62, respectively. Bypass pipes 53 and 63 connecting the stages and on / off valves 56, 57, 66 and 67 are provided on the bypass pipes 53 and 63.

According to this configuration, in the heating mode, the supply water is pumped by the first circulation pump 61 provided on the cold / hot water line 60, and the supply water is circulated to the second heat exchanger 32 via the subcooling capacitor 37. In addition, the heat exchange medium is pumped by the first circulation pump 51 provided on the heat source supply line 50 to pass through the first heat exchanger 31. At this time, the cold / hot water line 60 and the heat source The open / close valves 56 and 66 positioned on the first circulation pumps 51 and 61 of the supply line 50 are closed, and the open / close valves located on the second circulation pumps 52 and 62 are provided. 57, 67 are in an open state.

This is to form a counter-flow in which the heat exchange medium and the feed water flow in the opposite direction to the flow of the refrigerant to form a counter-flow. In the case of heat exchange by the counter flow, the heat exchange target flows in the same direction. Considering that heat exchange efficiency is relatively superior to parallel flow where heat exchange takes place (in case of parallel flow, the heat transfer efficiency of the refrigerant decreases since the temperature difference between the refrigerant and the hot and cold water at the outlet of the heat exchanger is small). By the same configuration as the invention, it is possible to further increase the heating efficiency.

In more detail, the flow of the refrigerant flows from the first port 32c of the second heat exchanger 32 to the second port 32d, and then the second port 37d of the subcooling capacitor 37. It is introduced through and discharged to the first port (37c), wherein the flow of the feed water flows from the first port (37a) of the subcooling capacitor (37) to the second port (37b), the second heat exchanger A discharge of the refrigerant and the supply water in the second heat exchanger 32 and the subcooling capacitor 37 forms an opposite flow through the second port 32b of the first port 32a.

In addition, the flow of the refrigerant in the first heat exchanger 31 flows from the second port 31d to the first port 31c, whereas the heat exchange medium on the heat source supply line 50 is the first heat exchanger 31. It flows from the second port 31b of) to the first port 31a to form a counter flow.

In addition, in the cooling mode, the supply water is pumped by the second circulation pump 62 provided on the cold / hot water line 60, and the supply water is circulated to the second heat exchanger 32 (at this time, the supercooling capacitor 37 has a refrigerant Since the water does not flow, the feed water is passed without heat exchange in the supercooling capacitor 37), and the heat exchange medium is pumped by the second circulation pump 52 provided on the heat source supply line 50, so that the first heat exchanger ( 31, wherein the on-off valves 57 and 67 located at the second circulation pumps 52 and 62 of the cold / hot water line 60 and the heat source supply line 50 are closed. The check valves 56 and 66 positioned on the first circulation pumps 51 and 61 are in an open state.

Similarly to the heating mode described above, in the cooling mode, the heat exchangers 31 and 32 and the subcooling capacitor 37 form counter flows in which the refrigerant and the heat exchange medium or the supply water flow in opposite directions. In the heating mode, the refrigerant flows in the heat exchangers 31 and 32 and the supplying hot and cold water flow in opposite directions to form a counter-flow where heat exchange occurs. Since the flow of cold and hot water for supply flows in the same direction to form a parallel flow (Parallel-flow) in which heat exchange occurs, there is a problem that the cooling efficiency is lower than the heating efficiency. However, in the present invention, since the heat exchange between the refrigerant and the heat exchange medium or the feed water is performed by the counter flow in both the heating mode and the cooling mode as described above, the heating and cooling efficiency can be increased at the same time.

In addition, in the cooling mode of the present invention, the supply water on the cold / hot water line 60 is simply passed through the subcooling capacitor 37 without heat exchange. In this case, the supply water flow resistance in the subcooling capacitor 37 is generated. Loss may occur in power of the second circulation pump 62. In order to prevent this, a bypass line 68 is further provided on the cold / hot water line 60 to connect the front and rear ends of the subcooling capacitor 37, and the flow of the supply water can be controlled on the bypass line 68. Open / close valve 69 may be provided, whereby the supply water passes through the subcooling capacitor 37 in the heating mode, and the supply water is circulated without passing through the subcooling capacitor 37 in the cooling mode.

In one embodiment as described above, the subcooling capacitor 37 is connected to the second heat exchanger 32 by the cold / hot water line 60, but the subcooling capacitor 37 is provided with a plurality of heat source supply lines, respectively. 50 and the cold and hot water line 60 may be provided to be connected to the first heat exchanger 31 and the second heat exchanger 32, which will be described with reference to the drawings.

As shown in FIG. 5, the subcooling capacitors 36 and 37 may be provided to be connected to the first heat exchanger 31 and the second heat exchanger 32, respectively. Is the first subcooling capacitor (36) located on the heat source (1) side and the second subcooling capacitor (37) located on the use (2) or cold and hot water storage tank (3) side, the first subcooling capacitor 36 is connected to the first heat exchanger 31 by the heat source supply line 50 so as to purify the heat exchange medium, and the second supercooling capacitor 37 is connected to the cold / hot water line 60 by the cold / hot water line 60. It is connected to the second heat exchanger 32 is provided to circulate the feed water.

Referring to the operation state in the cooling and heating mode by this configuration is as follows. In the heating mode, the refrigerant is controlled to flow on the second refrigerant line 41 to exchange heat with the refrigerant by the second subcooling capacitor 37 to preheat the supply water. The first and fourth check valves 45 and 48 provided on the line 40 are closed, and the second and third check valves 46 and 47 provided on the second refrigerant line 41. Is opened, and the refrigerant is transferred to the first heat exchanger 31 (evaporator) through the second heat exchanger 32 (operated as a condenser) and the second subcooling capacitor 37 by the switching valve 35. Operation) side. At this time, the first supercooling capacitor 36 connected to the first heat exchanger 31 by the heat source supply line 50 is controlled by the first check valve 45 so that no refrigerant flows.

In addition, in the cooling mode, the refrigerant is controlled to flow on the first refrigerant line 40 such that the refrigerant does not flow in the second subcooling capacitor 37. For this purpose, the refrigerant is provided on the first refrigerant line 40. The first and fourth check valves 45 and 48 are opened, and the second and third check valves 46 and 47 provided on the second refrigerant line 41 are closed. Is flowed from the first heat exchanger 31 (operated by a condenser) to the second heat exchanger 32 (operated by an evaporator) by the switching valve 35. At this time, as the refrigerant flows in the first subcooling capacitor 36, the heat exchange medium on the heat source 1 side is preheated and supplied to the first heat exchanger 31 side.

In this case, since the heat exchange medium passing through the heat source 1 is preheated while passing through the first subcooling capacitor 36, heat exchange is performed by the first heat exchanger 31. At the same time as the condensation efficiency of) increases, thereby increasing the cooling capacity of the second heat exchanger 32, it is possible to improve the overall coefficient of performance of the device.

In the above-described expansion valve 34 is provided on the common line 42 as described above is provided to pass through the refrigerant in the heating mode or cooling mode by the check valve (45 ~ 48), such As shown in FIG. 6, the expansion valve 34 may be provided in plural numbers so as to be operated in the heating mode and the cooling mode, respectively. As shown, the expansion valve 34 is provided with a heating expansion valve 34a and a cooling expansion valve 34b on the first refrigerant line 40 and the second refrigerant line 41, respectively. The valves 45 and 46 are provided on the first refrigerant line 40 and the second refrigerant line 41, respectively, and the first check valve 45 and the second check valve to control the refrigerant to flow in opposite directions. 46 is provided.

According to this configuration, in the heating mode, after the refrigerant flows through the second heat exchanger 32 and the second subcooling capacitor 37 by the second check valve 46, the second refrigerant line 41 is formed. Refrigerant flows to the first heat exchanger (31) side through the heating expansion valve (34a) provided on the), and in the cooling mode, after the refrigerant flows through the first heat exchanger (31), the first Refrigerant flows through the cooling expansion valve 34b provided on the first refrigerant line 40 by the check valve 45 to the second heat exchanger 32. In the cooling mode, Instead of the refrigerant flowing to the first subcooling capacitor 36, the refrigerant does not flow to the second subcooling capacitor 37.

In addition, as shown in Figure 7, in another embodiment of the present invention, in addition to the above-described configuration, on the heat source supply line 50 and the cold and hot water line 60 of the heat exchange medium or the supply water according to the cooling mode and heating mode In order to further increase the heat exchange efficiency by changing the flow, the inlet and the outlet of the first heat exchanger 31 and the second heat exchanger 32 on the heat source supply line 50 and the cold and hot water line 60 for this purpose. The first circulation pumps 51 and 61 and the second circulation pumps 52 and 62 are provided so as to be located at the side, and the discharge port side of the first circulation pumps 51 and 61 and the second circulation pumps 52 and 62 is provided. Check valves 54, 55, 64, 65 for controlling the flow of the heat exchange medium or the feed water in one direction, and the first circulation pumps 51, 61 and the second circulation pumps 52, 62, respectively. Bypass pipes 53 and 63 connecting the front and rear ends and on / off valves 56, 57, 66 and 67 are provided on the bypass pipes 53 and 63.

According to this configuration, it is operated in the same manner as in FIG. 4 described above to form an opposite flow in the heating and cooling mode to exert an effect of increasing the heat exchange efficiency, if there is a difference in configuration compared to Figure 4 the cold and hot water line ( In addition to the bypass line 68 and the on-off valve 69 provided therein, which connects the front and rear ends of the second subcooling capacitor 37 connected to the second heat exchanger 32 by the heat exchanger supply line 60, The first subcooling capacitor 36 connected to the first heat exchanger 31 by the heat source supply line 50 is further provided on the bypass line connecting the front and rear ends of the first subcooling capacitor 36. (58) and an on / off valve (59) are further provided on the bypass line (58).

Accordingly, in the heating mode, the heat exchange medium is circulated through the bypass line 58 so that the heat exchange medium does not pass through the first subcooling capacitor 36. In the cooling mode, the supply water is supplied to the second subcooling capacitor 37. Instead of being passed through, the heat exchange medium passes through the first subcooling capacitor 36 to exchange heat with the refrigerant.

In the above description, the subcooling capacitors 36 and 37 are provided at the heat source 1 and the load side (the use place 2 or the cold / hot water storage tank 3), respectively, and pass through the subcooling capacitors 36 and 37. There is no fear that the and supply water may be mixed with each other, whereby clean supply water that is not contaminated by the heat exchange medium can be supplied to the load side.

In addition, as the subcooling capacitors 36 and 37 are provided, the refrigerant passing through the first heat exchanger 31 or the second heat exchanger 32 may be further cooled to increase the condensation efficiency as well as the cold and hot water. Since the supply water of the line 60 is preheated to increase the heating effect, and the subcooling capacitor 37 is provided, the load on the compressor 33 side can be reduced, so that the compressor 33 having a relatively small capacity can be reduced. It becomes usable.

In addition, when the heat exchange medium passing through the heat source 1 is preheated while passing through the first subcooling capacitor 36, and the heat exchange is performed by the first heat exchanger 31, the first heat exchanger 31 As the condensation efficiency increases, the cooling capacity of the second heat exchanger 32 increases, thereby improving the overall coefficient of performance of the apparatus. If it is assumed to be about 7 ~ 8 ℃, in the configuration as described above it can be supplied to about 5 ~ 6 ℃ lower by about 1 ~ 2 ℃, thereby, such as the pump capacity and piping when supplying the cooling of the same capacity Its size can be reduced, reducing equipment costs by approximately 30-40%.

In the above embodiment, the first heat exchanger 31 has been described a supply system for recovering heat from the geothermal heat, the heat source (1) in addition to the geothermal heat source to recover the waste heat from the river water or waste hot water or even by external air Naturally, it can be supplied (1), the present invention can reduce the waste of energy by recovering heat from natural or waste heat sources such as geothermal or river water or waste water or external air, not electricity or fossil fuel In addition, the energy saving effect can be greatly improved. In addition, hot water as well as air-conditioning can be selectively supplied as needed, and the compact configuration allows easy installation without changing the configuration according to the use (2). By doing so, it is possible to supply hot and air-conditioning capacity to the right place. It is possible to provide the system.

The present invention described above is not limited to the above-described configuration and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be apparent to those who have knowledge.

Claims (6)

The first heat exchanger 31 provided to exchange heat with the heat source 1 side including geothermal or river water, and the first heat exchanger 31 are connected to each other by the refrigerant lines 40 and 41 and cold water. Or a second heat exchanger 32 provided to exchange heat with hot water, a switching valve 35 provided on the refrigerant lines 40 and 41 to convert a flow of refrigerant, and the first heat exchanger. The refrigerant lines 40 and 41 so as to be located between the first heat exchanger 31 and the second heat exchanger 32 so as to cool the refrigerant discharged from the air 31 or the second heat exchanger 32. A heat pump unit 30 including a subcooling capacitor 37 interconnected by;
A heat source supply line 50 connected between the first heat exchanger 31 and the heat source 1 and extending to circulate the heat exchange medium;
It is connected between the second heat exchanger 32 and the place of use (2) or the cold and hot water storage tank (3) is extended to circulate cold water or hot water, the second heat exchanger (32) via the subcooling capacitor (37) It comprises a cold and hot water line 60 to be introduced into the cold water or hot water;
The refrigerant lines 40 and 41 may be connected to the first heat exchanger 31 and the second heat exchanger 32 by a first refrigerant line 40 and the subcooling capacitor 37. A second refrigerant line 41 connecting the heat exchanger 31 and the second heat exchanger 32;
An expansion valve 34 for expanding the refrigerant and a plurality of check valves 45 to 48 for controlling the flow of the refrigerant in one direction on the first refrigerant line 40 or the second refrigerant line 41;
The check valves 45 to 48 are controlled to flow the refrigerant onto the first refrigerant line 40 to supply cold water or cooling to the use place 2 or the cold / hot water storage tank 3 or the second refrigerant line. The heat pump system, characterized in that the refrigerant is controlled to flow over the (41) to supply hot water or heating to the place of use (2) or the cold and hot water storage tank (3).
According to claim 1, On the heat source supply line 50 or the cold and hot water line 60 is located at the inlet and outlet side of the first heat exchanger 31 or the second heat exchanger 32, the heat exchange medium or cold water or hot water First and second circulation pumps 52 and 62 configured to circulate the pump;
A check valve (54, 55, 64, 65) positioned at the outlet of each of the circulation pumps (51, 52, 61, 62) to control the flow of heat exchange medium or cold water or hot water in one direction;
Bypass pipes 53 and 63 connected to the front and rear ends of the first circulation pumps 51 and 61 or the second circulation pumps 52 and 62 and the heat exchange medium located on the bypass pipes 53 and 63. Or a heat pump system characterized in that the opening and closing valve (56, 57, 66, 67) for controlling the flow of cold or hot water.
According to claim 1 or 2, On the cold and hot water line 60, the bypass line 68 connecting the front and rear ends of the subcooling capacitor 37 and the flow of cold water or hot water on the bypass line 68 Heat pump system, characterized in that further provided with an on-off valve for controlling.
The first heat exchanger 31 provided to perform heat exchange with the heat source 1 side including geothermal or river water, and the first heat exchanger 31 connected to the first heat exchanger 31 by the refrigerant line 40, and at the same time cold water or hot water A second heat exchanger 32 provided to perform heat exchange with the switch, a switching valve 35 provided on the refrigerant line 40 to change the flow of the refrigerant, and the first heat exchanger 31. Or interconnected by the refrigerant lines 40 and 41 so as to be located between the first heat exchanger 31 and the second heat exchanger 32 so as to cool the refrigerant discharged from the second heat exchanger 32 more. A heat pump unit 30 including subcooling capacitors 36 and 37;
A heat source supply line 50 connected between the first heat exchanger 31 and the heat source 1 and extending to circulate the heat exchange medium;
A cold / hot water line (60) connected between the second heat exchanger (32) and the place of use (2) or the cold / hot water storage tank (3) so as to circulate cold water or hot water;
The subcooling capacitors 36 and 37 are connected to the first heat exchanger 31 by the heat source supply line 50 and the second heat exchanger by the cold and hot water line 60. A second subcooling capacitor 37 connected to the machine 32;
The refrigerant lines 40 and 41 may include a first refrigerant line 40 connecting the first heat exchanger 31 and the second heat exchanger 32 via the first subcooling capacitor 36, and the second refrigerant line 40. A second refrigerant line (41) connecting the first heat exchanger (31) and the second heat exchanger (32) via a subcooling capacitor (37);
An expansion valve 34 for expanding the refrigerant and a plurality of check valves 45 and 46 for controlling the flow of the refrigerant in one direction on the first refrigerant line 40 or the second refrigerant line 41;
The check valves 45 and 46 are controlled to flow the refrigerant onto the first refrigerant line 40 to supply cold water or cooling to the place of use 2 or the cold / hot water storage tank 3 or the second refrigerant line. The heat pump system, characterized in that the refrigerant is controlled to flow over the (41) to supply hot water or heating to the place of use (2) or the cold and hot water storage tank (3).
According to claim 4, On the heat source supply line 50 or the cold and hot water line 60 is located at the inlet and outlet side of the first heat exchanger 31 or the second heat exchanger 32, the heat exchange medium or cold water or hot water First and second circulation pumps 52 and 62 configured to circulate the pump;
A check valve (54, 55, 64, 65) positioned at the outlet of each of the circulation pumps (51, 52, 61, 62) to control the flow of heat exchange medium or cold water or hot water in one direction;
Bypass pipes 53 and 63 connected to the front and rear ends of the first circulation pumps 51 and 61 or the second circulation pumps 52 and 62 and the heat exchange medium located on the bypass pipes 53 and 63. Or a heat pump system characterized in that the opening and closing valve (56, 57, 66, 67) for controlling the flow of cold or hot water.
According to claim 4 or 5, Bypass line for connecting the front and rear ends of the first subcooling capacitor 36 or the second subcooling capacitor (37) on the heat source supply line (50) or cold and hot water line (60). 58, 68 and an on / off valve (59, 69) for controlling the flow of cold or hot water on the bypass line (58, 68).

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