KR101127758B1 - Hot and cool water, heating and cooling supply system - Google Patents

Abstract

The present invention can provide both cold and hot water (or cooling and heating) at the same time, as well as continuous operation without a separate defrosting operation, so that the cold and hot water and cooling and heating supply system of a new structure capable of stable operation without degrading the supply capacity of cold and hot water and heating and cooling It is about.

According to the present invention, it comprises a compressor 31, a condenser 32, expansion valves (33, 34, 35), evaporator 36 which are interconnected by a circulation line 20 provided to circulate the heat exchange medium ; On the circulation line 20, a first auxiliary heat exchanger 37 for recondensing the heat exchange medium condensed by the condenser 32, and a second vaporizing medium for the heat exchange medium through the first auxiliary heat exchanger 37. An auxiliary heat exchanger 38 is provided; The first subsidiary heat exchanger 37 and the second subsidiary heat exchanger 38 are disposed in close proximity to each other, and at the same time, the heat discharged by the first subsidiary heat exchanger 37 is blown to the second subsidiary heat exchanger 38. A blower 39 is provided; The condenser 32 is supplied with hot water or heating, and the evaporator 36 is provided with cold / hot water and cooling / heating supply system in which cold water or cooling is supplied.

Compressor, condenser, evaporator, expansion valve, auxiliary heat exchanger

Description

Hot and cool water, heating and cooling supply system

The present invention relates to cold and hot water and cooling and heating supply system, and more particularly, it is possible to provide cold and hot water (or cooling and heating) at the same time, as well as continuous operation without a separate defrosting operation so that supply capacity of cold and hot water and heating and cooling is not deteriorated. The present invention relates to a cold and hot water and heating and cooling supply system of a new structure that can be operated stably.

In general, a heat pump is a device (or system) that absorbs or releases heat through a phase change of a refrigerant circulating through a compressor, a condenser, an evaporator, and an expansion valve to supply hot / cold water or heating and cooling. And an example of the air-conditioning supply system with reference to the drawings shown as follows.

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.

The hot and cold water and air-conditioning supply system 10 using the conventional heat pump exhibits a remarkable difference in operating capacity due to seasonal factors (outdoor temperature). In particular, the outdoor temperature is increased during heating (or during hot water production) in winter. Due to the low temperature, an accumulation of heat is generated in the first heat exchanger 12 or the second heat exchanger 13 that is installed outdoors, and thus, the heating capacity is drastically lowered or a separate defrosting operation for defrosting is performed. In addition, there is a disadvantage that a separate device such as an auxiliary heater must be further provided to improve the defrosting or heating capacity.

In addition, conventionally, the reversible cycle by the four-way valve 16 is operated only in one of the cooling mode and the heating mode is a structure that can not supply the hot and cold water (or cooling and heating) at the same time, and also when the external air is lowered according to the season It requires a separate defrosting operation in the continuous cold and hot water (or heating and cooling) is difficult to supply the disadvantage that the production capacity is reduced.

The present invention is to solve the problems as described above, the present invention can not only provide the hot and cold water (or heating and cooling) at the same time, but also produce the hot and cold water (or heating and cooling) at the same time automatically defrosting is not necessary separate defrosting operation It is possible to continuously operate, thereby providing a stable operation without deteriorating the supply capacity of hot and cold water and heating and cooling, as well as to provide a new structure of cold and hot water and heating and cooling supply system capable of stable operation without significant influence on seasonal factors.

According to a feature of the invention, it comprises a compressor (31), a condenser (32), an expansion valve (33, 34, 35), an evaporator (36) interconnected by a circulation line (20) provided to circulate a heat exchange medium. Is done by;

On the circulation line 20, a first auxiliary heat exchanger 37 for recondensing the heat exchange medium condensed by the condenser 32, and a second vaporizing medium for the heat exchange medium through the first auxiliary heat exchanger 37. An auxiliary heat exchanger 38 is provided;

The first subsidiary heat exchanger 37 and the second subsidiary heat exchanger 38 are disposed in close proximity to each other, and at the same time, the heat discharged by the first subsidiary heat exchanger 37 is blown to the second subsidiary heat exchanger 38. A blower 39 is provided;

The condenser 32 is supplied with hot water or heating, and the evaporator 36 is provided with cold or hot water and cooling and heating supply system, characterized in that the cooling water or cooling is supplied.

According to another feature of the invention, the bypass line 50 and the bypass line 50 for bypassing the heat exchange medium between the condenser 32 and the auxiliary heat exchangers 37 and 38 on the circulation line 20. Is further provided with an expansion valve (35);

Each auxiliary heat exchanger (37, 38) is provided with a hot and cold water and heating and heating supply system, characterized in that the heat exchange medium to the same as the heat exchange medium flows on the bypass line (50).

As described above, according to the present invention, the first auxiliary heat exchanger 37 and the second auxiliary heat exchanger 37 for recondensing the heat exchange medium condensed by the condenser 32 on the circulation line 20 through which the heat exchange medium is circulated ( 38 are arranged in close proximity to each other and are provided to blow heat discharged by the first auxiliary heat exchanger 37 by the blower 39 to the second auxiliary heat exchanger 38, so that an external temperature is maintained as in winter. In the case of low, there is an advantage that can be prevented from dropping to the second auxiliary heat exchanger 38 to reduce the deterioration of the evaporation efficiency, and the defrosting operation by the auxiliary heat exchangers (37, 38) is continuously hot water (or Since heating is automatically enabled in the process of producing, there is an advantage in that it is possible to continuously maintain the supply capacity of cold and hot water (or cooling and heating) by enabling continuous operation.

In addition, the supply system of the present invention has the advantage that it is possible to supply cold water (or cooling) and hot water (or heating) at the same time by operating in a non-reversible cycle instead of the reversible cycle by the four-way valve 16 as in the prior art.

In addition, on the circulation line 20 between the condenser 32 and the auxiliary heat exchangers 37 and 38, a bypass line 50 for bypassing the heat exchange medium and an expansion valve 35 on the bypass line 50. Further, the first auxiliary heat exchanger 37 is provided to recondensate or evaporate the heat exchange medium according to the presence or absence of the bypass of the heat exchange medium by the bypass line 50. Evaporation function can be selectively performed, thereby enabling stable operation regardless of seasonal factors and improving evaporation efficiency.

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

2 and 3 illustrate various embodiments of the present invention. The present invention according to each embodiment is described below.

As shown in FIG. 2, an embodiment of the present invention provides a compressor 31, a condenser 32, and an expansion valve 33 interconnected by a circulation line 20 provided to circulate a heat exchange medium such as a refrigerant. 34, 35 and evaporator 36, which is similar to that of a conventional heat pump.

In an embodiment of the present invention, a first auxiliary heat exchanger 37 is provided on the circulation line 20 to recondense the heat exchange medium condensed from the condenser 32, and the first auxiliary heat exchanger 37 is provided. A second auxiliary heat exchanger (38) is provided to evaporate the heat condensing medium recondensed.

In addition, the first subsidiary heat exchanger 37 and the second subsidiary heat exchanger 38 are arranged to be in close proximity to each other, which are each provided separately and are arranged in close proximity to each other or integrally provided in a state in which they are adjacent to each other. The blower 39 may be provided at one side of the subsidiary heat exchangers 37 and 38 to blow heat discharged by the first subsidiary heat exchanger 37 toward the second subsidiary heat exchanger 38.

With this arrangement, the heat exchange medium recondensed by the first auxiliary heat exchanger 37 can be evaporated by the evaporator 36 or by the second auxiliary heat exchanger 39, for this purpose On the circulation line 20, control valves 41 and 42 such as solenoid valves capable of changing or controlling the flow of the heat exchange medium are provided, and the first auxiliary heat exchange is performed by the operation of the control valves 41 and 42. The heat exchange medium recondensed by the gas 37 flows into the evaporator 36 or the second subsidiary heat exchanger 38, and also from the first subsidiary heat exchanger 37 to the evaporator 36 or the first sub-exchange. 2 When the heat exchange medium flows to the auxiliary heat exchanger 38, the expansion valves 33 and 34 are respectively passed.

According to this embodiment, the condenser 32 is connected to a hot water tank or a hot water tank to enable heating using the hot water by the discharged heat, and the evaporator 36 is thereby connected to A cooling line is connected to the cold water tank or the cold water tank to absorb cold water and cool the water using the cold water, and the heat exchange medium recondensed by the first auxiliary heat exchanger 37 is the evaporator 36. In the case of flow through (the control valve 41 on the side of the first subsidiary heat exchanger 38 is closed) to produce hot and cold water (or air conditioning) at the same time, the heat exchange recondensed by the first subsidiary heat exchanger (37) When the medium flows to the second auxiliary heat exchanger 38 (the control valve 41 on the evaporator 36 side is closed), only hot water (or heating) can be produced.

In addition, the auxiliary heat exchangers (37, 38) can be selectively operated according to the season at the same time to control the supply capacity of cold and hot water (or air-conditioning), especially when the external temperature is low, such as winter, the first auxiliary The second auxiliary heat exchanger 38 using the heat generated by the heat exchanger 37 is automatically defrosted so as not to perform a separate defrosting operation, thereby enabling continuous operation to provide hot water (or heating) supply capacity. It does not deteriorate.

In another embodiment, as shown in FIG. 3, a bypass line capable of bypassing the flow of the heat exchange medium on the circulation line 20 between the condenser 32 and the auxiliary heat exchangers 37 and 38. An expansion valve 35 may be further provided on the bypass line 50 and the first auxiliary heat exchanger 37 may be provided to recondense or evaporate the heat exchange medium. Will be.

In more detail, in the case where the heat exchange medium is recondensed by the first auxiliary heat exchanger 37, the control of the flow of the heat exchange medium by the bypass line 50 controls the flow of the heat exchange medium. Is provided with a control valve 42), which causes the heat exchange medium to normally flow through the circulation line 50 to the first subsidiary heat exchanger 37, and to the first subsidiary heat exchanger 37. The heat condensing medium which has been recondensed by this is to be evaporated by the evaporator 36 or the second auxiliary heat exchanger 38. This is similar to the above-described embodiment, it is possible to determine the opening and closing of the control valve (41, 42) according to the case of producing hot and cold water (or heating and cooling) at the same time and only the case of producing hot water (or heating).

In the drawing, the opening and closing state of the control valves 41 to 46 when the heat exchange medium is recondensed by the first auxiliary heat exchanger 37 will be described in more detail. Some control valves 41 and 44 of the control valves 41 to 46 are opened, and the remaining control valves 42, 43, 45 and 46 are closed, and when only hot water is produced, the control valve ( Some of the control valves 42, 44 are open, and the remaining control valves 41, 43, 45, 46 are closed.

In addition, when the heat exchange medium is evaporated by the first auxiliary heat exchanger 37, the heat exchange medium flows directly on the circulation line 20 instead of the heat exchange medium flows by the bypass line 50. (A control valve 44 for controlling the flow of the heat exchange medium is provided on the circulation line 50 for this purpose), and the circulation line 20 is connected to each of the auxiliary heat exchangers 37 and 38. Branched to flow at the same time, the heat exchange medium through the bypass line 50 is introduced into each of the auxiliary heat exchangers (37, 38) in an expanded state through the expansion valve 35, the respective auxiliary heat exchangers (37, 38) simultaneously evaporate the heat exchange medium.

When the heat exchange medium is evaporated by the first auxiliary heat exchanger 37 as described above, it is limited to the case where only hot water is produced, and the opening and closing states of the control valves 41 to 46 at this time will be described in more detail. Among the control valves 41 to 46, some control valves 43, 45, and 46 are opened, and the remaining control valves 41, 42, and 44 are closed.

According to the present invention as described above, depending on the case where the first auxiliary heat exchanger (37) is provided to recondensate the heat exchange medium and the case to be evaporated, the defrosting operation while producing hot and cold water at the same time or only producing hot water This will come true.

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.

1 is a configuration diagram showing an example of a conventional supply system

2 is a block diagram showing an embodiment of the present invention

3 is a block diagram showing another embodiment of the present invention

Claims (2)

  A compressor (31), a condenser (32), expansion valves (33, 34, 35), and an evaporator (36) interconnected by a circulation line (20) provided to circulate the heat exchange medium; On the circulation line 20, a first auxiliary heat exchanger 37 for recondensing the heat exchange medium condensed by the condenser 32, and a second vaporizing medium for the heat exchange medium through the first auxiliary heat exchanger 37. An auxiliary heat exchanger 38 is provided; The first subsidiary heat exchanger 37 and the second subsidiary heat exchanger 38 are disposed in close proximity to each other, and at the same time, the heat discharged by the first subsidiary heat exchanger 37 is blown to the second subsidiary heat exchanger 38. A blower 39 is provided; Hot water or heating is supplied by the condenser 32, and cold water or cooling is supplied by the evaporator 36; The bypass line 50 bypasses the heat exchange medium between the condenser 32 and the auxiliary heat exchangers 37 and 38 on the circulation line 20 and the expansion valve 35 on the bypass line 50. Is further provided; Each of the auxiliary heat exchangers (37, 38) is provided to evaporate the heat exchange medium in the same way as the heat exchange medium flows on the bypass line (50), characterized in that the hot and cold water and cooling and heating supply system. delete

Images