KR200214014Y1 - Regeneration-compound cooling and heating system by one cycle - Google Patents

Abstract

The present invention relates to a regenerative combined air-conditioning system by a single circuit, the waste heat discharged from the outdoor unit is heat exchanged through a single waste heat exchanger so that the configuration of the system can be simplified, and a bypass circuit is provided on the pipeline. It is possible to prevent damage to the pipeline or overload of the compressor due to blockage of the pipeline, and to form a valve for switching the cooling and heating integrally to switch the cooling and heating to a single drive source.

Description

Regeneration-compound cooling and heating system by one cycle

The present invention relates to a regenerative combined air-conditioning system by a single circuit, and more particularly, the heat of waste discharged from the outdoor unit can be exchanged through one waste heat exchanger to simplify the configuration of the system. It is equipped with a pass circuit to prevent damage to the pipeline or overload of the compressor due to blockage of the pipeline, and to integrally form each valve for switching of cooling and heating so that the switching of cooling and heating can be clearly performed by one driving source. It is for the purpose.

In general, in the hot season such as summer, the air conditioner is used to lower the indoor temperature to secure a comfortable indoor environment.In the cold season, such as winter, the air conditioner is used to increase the indoor temperature to ensure a comfortable indoor environment. have.

On the other hand, in each home, office, or factory, air conditioners and heating devices are provided and used separately. However, in recent years, air conditioning and heating can be selectively used as needed. The use is increasing.

In general, the air-conditioning device as described above is provided with a heater for heating the refrigerant or a separate burner in the conventional air-conditioning device, but can be selectively used according to the season, the conventional air-conditioning as described above Since the device should be provided with a separate heater or burner, there was a problem that the efficiency is rapidly lowered in the heating process.

Accordingly, a cooling and heating system has been developed and used to increase the cooling and heating efficiency by utilizing the waste heat of the refrigerant discharged to the indoor unit.

The air conditioning and heating system which increases the utilization rate of waste heat as described above is an indoor and outdoor unit installed indoors, an outdoor unit installed outdoors, a compressor for pumping refrigerant, and heat exchange with the waste heat discharged from the indoor unit to improve cooling and heating ability. It is composed of a plurality of valves for controlling the flow of the refrigerant in accordance with the exchange unit, the heating waste heat exchange unit and air conditioning.

Conventional cooling and heating system as described above is cooled by using the waste heat of the refrigerant that is pumped in the compressor and cooled in the outdoor unit during the cooling operation by using the waste heat of the refrigerant discharged from the indoor unit in the air conditioning waste heat exchanger to maximize the temperature of the refrigerant supplied to the indoor unit to the maximum It is lowered to improve the cooling efficiency.In the heating operation, it absorbs the heat from the outside to the compressor and heats it again by using the waste heat of the refrigerant discharged from the indoor unit in the heating waste heat exchanger to supply it to the compressor. By increasing the temperature of the supplied refrigerant to increase the temperature of the refrigerant discharged from the compressor to the maximum to improve the heating efficiency.

However, in the conventional air-conditioning system using waste heat as described above, the waste heat exchange unit using waste heat discharged from the indoor unit is provided separately according to cooling and heating, and thus, the configuration of the pipe is complicated, resulting in a reduction in production cost and productivity. .

In addition, there is a problem such that the bypass pipe is not formed on the air conditioning heating line due to the blockage of the pipe, and thus, if the pipe is blocked, the system may be damaged or the compressor may be broken.

In addition, the conventional air-conditioning system as described above is configured so that a plurality of valves for switching the air conditioning is operated by a drive source that receives a signal independently of each other, the operation is not made uniformly, the failure of some valve drive source or When the signal line is damaged, there is a problem that the switching of cooling and heating is not made clearly, causing problems such as system failure, and because the valve is distributed, the pipeline is complicated and the production cost is increased.

Thus, the present invention is devised to solve the above problems, to make the heat exchange of the waste heat to one waste heat exchanger to simplify the configuration of the conduit, and to provide a bypass circuit on the furnace, It is possible to prevent the breakage of the compressor or the overload of the compressor, and to form the respective valves for switching of heating and cooling integrally to switch the cooling and heating to a single drive source.

1 is in the cooling and heating system according to the present invention

Main configuration showing cooling operation.

2 is in the cooling and heating system according to the present invention

Major diagram showing heating operation status.

3 is according to another embodiment of the present invention

Main configuration showing cooling operation status in air conditioning system.

4 is according to another embodiment of the present invention

Major configuration showing heating operation status in air conditioning system.

5 is a perspective view showing an embodiment of a valve according to the present invention.

<Explanation of symbols for main parts of the drawings>

10: compressor 20: indoor unit 30: outdoor unit

41: waste heat exchanger 42: expansion heat exchanger

43: heat dissipation extension 44: endothermic extension

50: heat exchange promoting unit

61: air conditioner selection valve 62: heat radiation line inlet selection valve

63: heat radiation line inlet selection valve 64: endothermic line selection valve

65 drive unit

70: bypass part

71: solenoid valve 72: cooling unit

81: refrigerant heat dissipation line 82: refrigerant heat dissipation line 90: temperature sensor

Hereinafter, described in detail by the accompanying drawings as follows.

The present invention simplifies the configuration of the system by constructing the waste heat exchanger of cooling and heating into a single waste heat exchanger, configures a bypass circuit to ensure the safety of the system, and integrates a plurality of valves to clearly switch between heating and cooling. A cooling and heating system comprising: an indoor unit, an outdoor unit installed outdoors, a compressor for pumping refrigerant, and a plurality of valves for controlling the flow of the refrigerant in accordance with cooling and heating; A compressor 10 for pumping refrigerant, an indoor unit 20 for cooling indoor air through heat exchange with the introduced refrigerant during cooling, and an indoor unit 20 for heating indoor air through heat exchange with the introduced refrigerant during heating, and The outdoor unit 30 cools the refrigerant introduced through heat exchange with the outdoor air and heats the refrigerant introduced through heat exchange with the outdoor air during heating, and the indoor unit 20 and the outdoor unit in the compressor 10 according to cooling and heating. Cooling and heating selection valve 61 to control the refrigerant flow to the 30 to selectively perform the heating and cooling, the refrigerant heat dissipation line 81 for dissipating heat energy contained in the refrigerant, and the heat dissipated from the refrigerant heat dissipation line A heat exchanger (41) for exchanging heat between the refrigerant heat absorbing line (82), the refrigerant in the refrigerant heat dissipating line (81) and the refrigerant in the refrigerant heat absorbing line (82), and the heat dissipation in the indoor unit (20). LINE (81) A heat radiation line inlet selection valve 62 for selectively controlling the refrigerant flow to the former side and the refrigerant flow from the outdoor unit 30 to the inlet side of the refrigerant heat dissipation line 81 according to the cooling and heating, and an outlet side of the refrigerant heat dissipation line 81. And the heat radiation line outlet selection valve 63 for selectively controlling the refrigerant flow to the indoor unit 20 and the refrigerant flow from the outlet side of the refrigerant heat dissipation line 81 to the outdoor unit 30 according to the cooling and heating, and the indoor unit 20 The endothermic line selection valve 64 is configured to selectively control the refrigerant flow to the refrigerant absorption line 82 and the refrigerant flow to the outdoor unit 30 to the refrigerant absorption line 82 according to cooling and heating.

Here, the air-conditioning selection valve 61, the heat radiation line inlet selection valve 62, the heat radiation line outlet selection valve 63, and the heat absorption line selection valve 64 are connected to one drive unit 65 controlled by a conventional controller. It can be configured to be carried out integrally to be driven by the one that is made to switch the cooling and heating is clear and fast, the waste heat exchange unit 41 is one or more heat exchange tube and the heat exchange tube circulating the refrigerant of the refrigerant heat radiation line 81 This housing is made of a housing through which the refrigerant of the refrigerant absorbing line 82 is circulated.

On the other hand, another embodiment of the present invention can be implemented by having an expansion heat exchanger (42) consisting of a plurality of heat exchange tubes for promoting the cooling of the refrigerant in the refrigerant heat dissipation line (81), the expansion heat exchanger ( By forming the refrigerant in the refrigerant absorbing line 82 to be circulated around the heat exchange tube of 42), the cooling effect of the refrigerant can be increased.

In another embodiment of the present invention, a heat dissipation extension part 43 is formed at the front end of the waste heat exchange part 41 to extend the refrigerant, and between the waste heat exchange part 41 and the heat dissipation expansion part 43. The heat exchange promotion unit 50 which draws out the refrigerant from the refrigerant heat dissipation line 81 and cools it through a heat exchanger made of a plurality of capillaries, supplies it to the heat dissipation expansion unit 43, and cools the refrigerant extended by the heat dissipation expansion unit 43. It can be provided with.

In addition, another embodiment of the present invention is provided to be connected to the refrigerant heat absorbing line 82 in the refrigerant heat dissipation line 81, the bypass operated in conjunction with the temperature of the temperature sensor 90 provided in the compressor 10 It is provided with a portion 70, the bypass portion 70 is to cool the refrigerant passing through the solenoid valve 71 and the solenoid valve 71 operated by the temperature sensor 90 of the compressor (10). It can be obtained by obtaining a cooling unit 72 made of a plurality of capillaries.

Meanwhile, in the bypass unit 70, an endothermic expansion unit 44 diffuses the refrigerant in the refrigerant absorption line 82, and the bypass unit 70 is connected to the endothermic expansion unit 44. It can be configured and implemented.

Hereinafter, the cooling process and the heating process according to the present invention will be described.

As described above, the indoor unit 20, the outdoor unit 30, the air conditioner selection valve 61, the waste heat exchanger 41, the refrigerant heat dissipation line 81, the refrigerant heat absorbing line 82, and the heat dissipation line inlet selection valve ( Referring to the cooling process according to the present invention consisting of 62) and the heat radiation line outlet selection valve 63 and the heat absorption line selection valve 64 are as follows.

When the cooling is selected by a conventional controller, the controller controls the drive unit 65 so that the system is operated in a cooling manner, the cooling and heating selection valve 61 and the heat radiation line inlet selection valve 62 and the heat radiation line outlet which are integrally formed. The selection valve 63 and the endothermic line selection valve 64 are switched to the cooling state.

As described above, when the system is operated in a state in which the valves 61, 62, 63, and 64 are switched to the cooling state, the refrigerant compressed by the compressor 10 is supplied to the outdoor unit 30 through the air conditioning selection valve 61. The coolant is cooled through a heat exchange process with the outdoor air, and the coolant cooled in the outdoor unit 30 passes through the heat radiation line inlet selection valve 62 opened from the outdoor unit 30 to the coolant heat dissipation line 81. 81 is supplied to the refrigerant heat dissipation line 81, and the refrigerant is discharged from the indoor unit 20 in the waste heat exchanger 41 and dissipates heat through heat exchange with the refrigerant circulated to the refrigerant heat absorbing line 82. And the cooled refrigerant is supplied to the indoor unit 20 through the heat radiation line outlet selection valve 63 opened from the refrigerant heat dissipation line 81 to the indoor unit 20, and cooled in the waste heat exchange unit 41. The refrigerant undergoes a heat exchange process with the indoor air in the indoor unit (20). Through cooling the indoor air is to maintain a comfortable indoor environment.

As described above, the refrigerant that cools the indoor air through the heat exchange process with the indoor air in the indoor unit 20 is the refrigerant absorption line through the endothermic line selection valve 64 opened from the indoor unit 20 to the refrigerant absorption line 82 side. It is supplied to the (82) to cool the refrigerant in the refrigerant heat dissipation line 81 through the heat exchange process in the waste heat exchange unit 41 is supplied to the compressor (10) to complete one cycle for cooling.

Hereinafter, the heating process using the present invention will be described.

When the heating is selected by a conventional controller, the controller controls the drive unit 65 so that the system is operated by heating, and the heating and cooling selection valve 61, the heat radiation line inlet selection valve 62 and the heat radiation line outlet are integrally formed. The selection valve 63 and the endothermic line selection valve 64 are switched to the heating state.

As described above, when the system is operated while the valves 61, 62, 63, and 64 are switched to the heating state, the refrigerant compressed by the compressor 10 is supplied to the indoor unit 20 through the air conditioning selection valve 61. Thus, the indoor air is maintained comfortably by heating the indoor air through a heat exchange process with the indoor air.

As described above, the refrigerant that heats the indoor air through the heat exchange process with the indoor air in the indoor unit 20 radiates the refrigerant through the heat radiation line inlet selection valve 62 opened from the indoor unit 20 to the refrigerant heat dissipation line 81. The refrigerant supplied to the line 81 and supplied to the refrigerant heat dissipation line 81 is discharged from the indoor unit 20 in the waste heat exchange unit 41 and heats through heat exchange with the refrigerant circulated to the refrigerant absorption line 82. Radiant heats the refrigerant of the refrigerant absorption line 82, and the refrigerant heating the refrigerant of the refrigerant absorption line 82 is a heat radiation line outlet selection valve opened from the refrigerant radiation line 81 to the outdoor unit 30 ( 63 is supplied to the outdoor unit 30 through the heat exchange process with the outdoor air, the refrigerant heated in the outdoor unit 30 is the endothermic line selection valve opened from the outdoor unit 30 to the refrigerant absorption line 82 To the refrigerant absorption line (82) through (64) The refrigerant supplied to the refrigerant absorbing line 82 from the outdoor unit 30 is supplied to the compressor 10 in a heated state through a heat exchange process in the waste heat exchanger 41, thereby completing one cycle for heating. Will be.

On the other hand, by providing an expansion heat exchanger 42 on the refrigerant heat dissipation line 81 as in another embodiment of the present invention, the heat dissipation of the refrigerant is made smoothly in the refrigerant heat dissipation line 81, and the expansion heat exchanger 42 The refrigerant in the refrigerant absorbing line 82 is circulated in the cooling medium so that the refrigerant in the refrigerant absorbing line 82 is smoothly heated.

In addition, the heat dissipation of the refrigerant is made more smoothly by being configured to diffusely mix with the refrigerant cooled in the heat exchange promotion unit 50 on the refrigerant heat dissipation line 81.

In addition, since the bypass unit 70 is connected to the refrigerant absorbing line 82 from the refrigerant heat dissipating line 81, the compressor 10 is provided in the compressor 10 when the temperature of the compressor 10 is increased due to the blockage of the pipe. The solenoid valve 71 of the bypass unit 70 is operated by the temperature sensor 90, so that the refrigerant of the refrigerant heat dissipation line 81 is directly supplied to the refrigerant heat dissipation line 82, so that Damage is prevented, and at this time, the refrigerant is cooled through the cooling unit 72 to be supplied to the compressor 10.

In addition, as in another embodiment of the present invention, the endothermic expansion part 44 is provided on the refrigerant absorption line 82 to allow the refrigerant to be supplied through the bypass part 70, and thus the cooling is more smoothly performed.

Therefore, the present invention allows the waste heat discharged from the outdoor unit to be exchanged through one waste heat exchanger, thereby simplifying the system configuration and miniaturizing the size of the system, thereby reducing the production process and the production cost.

In addition, by providing a bypass portion connected from the refrigerant heat dissipation line to the refrigerant heat dissipation line, and by providing a cooling part in the bypass part, the compressor is prevented from being damaged due to blockage of the pipeline in the operation of the system, thereby securing the safety of the system. will be.

In addition, the air conditioner controller is formed on the air-conditioning system by integrally forming the air-conditioning selection valve for switching of air-conditioning, the heat radiation line inlet selection valve, the heat radiation line outlet selection valve, and the heat absorption line selection valve. It is very useful that the switching of cooling and heating is made through a single control by a single control, and the line of the pipeline is simplified because it does not have a separate valve for each line, so that productivity and production cost and compactness are achieved.

Claims (5)

An air conditioning system comprising: an indoor unit, an outdoor unit installed outdoors, a compressor for pumping refrigerant, and a plurality of valves for controlling the flow of refrigerant in accordance with air conditioning; A compressor 10 for pumping the refrigerant; An indoor unit 20 for cooling indoor air through heat exchange with the introduced refrigerant during cooling and heating the indoor air through heat exchange with the introduced refrigerant during heating; An outdoor unit 30 for cooling the refrigerant introduced through heat exchange with outdoor air during cooling and heating the refrigerant introduced through heat exchange with outdoor air during heating; A cooling and heating selection valve 61 for controlling cooling of the refrigerant from the compressor 10 to the indoor unit 20 and the outdoor unit 30 according to cooling and heating to selectively perform cooling and heating; A refrigerant heat dissipation line 81 for dissipating heat energy contained in the refrigerant; A refrigerant absorbing line 82 absorbing heat radiated from the refrigerant radiating line 81; A waste heat exchange part 41 for exchanging heat between the refrigerant of the refrigerant heat dissipation line 81 and the refrigerant of the refrigerant heat dissipation line 82; An expansion heat exchanger (42) formed of a plurality of heat exchange tubes for promoting cooling of the refrigerant in the refrigerant heat dissipation line (81); Radiation line inlet selection valve 62 for selectively controlling the refrigerant flow from the indoor unit 20 to the inlet side of the refrigerant radiating line 81 and the refrigerant flow from the outdoor unit 30 to the inlet side of the refrigerant radiating line 81 according to cooling and heating. Wow; Radiation line outlet selection valve for selectively controlling the refrigerant flow from the outlet side of the refrigerant heat dissipation line 81 to the indoor unit 20 and the refrigerant flow from the outlet side of the refrigerant heat dissipation line 81 to the outdoor unit 30 according to cooling and heating ( 63); And a heat absorption line selection valve 64 for selectively controlling the refrigerant flow from the indoor unit 20 to the refrigerant absorption line 82 and the refrigerant flow from the outdoor unit 30 to the refrigerant absorption line 82 according to cooling and heating. A regenerative combined heating and cooling system using a single circuit. The method of claim 1; The air-conditioning selection valve 61, the heat radiation line inlet selection valve 62, the heat radiation line outlet selection valve 63, and the heat absorption line selection valve 64 are driven by one drive unit 65 controlled by a conventional controller. Regenerative combined air-conditioning system by a single circuit, characterized in that integrally configured. The method of claim 1; Regenerated complex cooling and heating system by a single circuit characterized in that the refrigerant in the refrigerant absorbing line 82 is formed to circulate around the heat exchange tube of the expansion heat exchanger (42). The method of claim 1; A heat dissipation extension part 43 is formed at the front end of the waste heat exchange part 41, and the refrigerant is discharged from the refrigerant heat dissipation line 81 between the waste heat exchange part 41 and the heat dissipation expansion part 43. A single circuit comprising a heat exchange facilitator 50 for drawing and cooling through a heat exchanger made of a plurality of capillaries to supply to the heat dissipation extension 43 to cool the refrigerant expanded in the heat dissipation extension 43. Regeneration composite air conditioning system by The method of claim 1; It is provided to be connected to the refrigerant heat absorbing line 82 in the refrigerant heat dissipation line (81) is provided with a bypass unit 70 which operates in conjunction with the temperature of the temperature sensor 90 provided in the compressor 10, The bypass unit 70 includes a solenoid valve 71 operated by the temperature sensor 90 of the compressor 10, and a cooling unit including a plurality of capillaries for cooling the refrigerant passing through the solenoid valve 71. A regenerative combined air conditioning system using a single circuit, characterized by comprising (72).