KR20060128130A - Air-condition - Google Patents

Abstract

An air conditioner is provided to quickly cool the indoor air by operating two cooling cycle in a speed cooling mode. An air conditioner comprises a main compressor(60), condenser(62), and expander(64) sequentially pressing, condensing, and expanding a first coolant; a speed cooling compressor(70) compressing a second coolant; an intermediate heat exchanger(80) cooling the air by evaporation heat of the first coolant discharged from the main expander, and condensing a second coolant discharged from the speed cooling compressor; a speed cooling re-condensor(72) condensing again the second coolant condensed at the speed cooling condenser by heat-exchanging with perimeter air; a speed cooling expander(74) expanding the second coolant discharged from the intermediate heat exchanger; and a speed cooling evaporator(76) installed in front of the intermediate heat exchanger to cool again the air passed through the intermediate heat exchanger by the evaporation heat of the second coolant discharged from the speed cooling expander.

Description

Air Conditioner {Air-Condition}

1 is a system diagram of an air conditioning cycle according to the prior art,

2 is a perspective view of an air conditioner according to the present invention;

3 is a system diagram of an air conditioning cycle according to the present invention;

4 is a perspective view of an intermediate heat exchanger of the air conditioner according to the present invention;

5 is a cross-sectional view taken along the line A-A of FIG.

6 is a perspective view showing a part of the rapid cooling evaporator of the air conditioner according to the present invention;

7 is a graph showing an air conditioning cycle diagram according to the present invention.

<Explanation of symbols on main parts of the drawings>

50: indoor unit 52: outdoor unit

60: main compressor 62: main condenser

64: main inflator 66: main evaporator

70: rapid cooling compressor 72: rapid cooling condenser

74: rapid cooling expander 76: rapid cooling evaporator

80: intermediate heat exchanger 90: indoor blower

92: outdoor blower

The present invention relates to an air conditioner, and more particularly, to an air conditioner in which air cooled by heat exchange with a first refrigerant is cooled by heat exchange with a second refrigerant.

In general, the air conditioner is a device for creating a comfortable environment in the room, and has a clean function, a dehumidification function, etc., as well as a cooling / heating function for creating indoor air at a comfortable temperature.

Among the various functions of the air conditioner described above, the cooling function is performed by the following cooling cycles in which indoor air is cooled by heat exchange with a refrigerant.

1 is a block diagram showing a cooling cycle of the air conditioner according to the prior art.

The cooling cycle of the air conditioner shown in FIG. 1 includes a compressor 2 in which vaporized refrigerant is compressed at high pressure, a condenser 4 in which the refrigerant compressed in the compressor 2 is heat-exchanged with air, and condensed at low temperature. And an expander 6 in which the refrigerant condensed in the condenser 4 is expanded at low pressure, and an evaporator 8 in which low-temperature, low-pressure liquid refrigerant expanded in the expander 6 is evaporated by heat exchange with air.

The compressor 2 is divided into a single type composed of one and a multi type composed of at least two compressors. The single type compressor 2 can be divided into an inverter whose compression capacity can be varied according to the load amount, and a constant speed type with a constant compression capacity. In addition, the multi-type compressor 2 is provided such that at least two or more compressors are selectively operated according to the load amount.

The cooling cycle of the air conditioner according to the prior art configured as described above, the indoor air is cooled by the heat of vaporization of the refrigerant in the evaporator (8), the refrigerant vaporized in the evaporator (8) and the compressor (2) Passing through the condenser 4 and the expander 6 in order to circulate back to the low-temperature, low-pressure liquid refrigerant.

However, the air conditioner according to the prior art as described above, if the difference between the current room temperature and the target room temperature, such as when entering the room during the initial operation or in the hot air outside, the load is large, but the cooling capacity is rapidly increased There is a problem that can not provide a cool wind because it is difficult.

The present invention has been made to solve the above problems of the prior art, an object of the present invention is to provide an air conditioner capable of rapid cooling that can provide a cool and comfortable wind even if the load is large.

Air conditioner according to the present invention for solving the above problems is the main compressor is compressed with a first refrigerant; A main condenser for condensing the first refrigerant compressed by the main compressor; A main expander to expand the first refrigerant condensed in the main condenser; A main evaporator in which the first refrigerant discharged from the main expander is exchanged with the ambient air for evaporation, and the air exchanged with the first refrigerant is cooled; By using a second refrigerant that is condensed by heat exchange with the first refrigerant of the main evaporator, it comprises a rapid cooling means having a cooling cycle for cooling the air cooled in the main evaporator again.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view of an air conditioner according to the present invention, FIG. 3 is a schematic diagram of an air conditioning cycle according to the present invention, FIG. 4 is a perspective view of an intermediate heat exchanger of the air conditioner according to the present invention, and FIG. 6 is a cross-sectional view of a rapid cooling evaporator of an air conditioner according to the present invention, and FIG. 7 is a graph showing an air conditioning cycle diagram according to the present invention.

In the air conditioner according to the present invention, the indoor unit 50 is largely structurally cooled by heat exchange with a low temperature and low pressure refrigerant, and the refrigerant exchanged with the indoor air in the indoor unit 50 returns to a low temperature and low pressure state. Can be divided into an outdoor unit (52).

The air conditioner of this structure has a first cooling cycle in which the indoor air is cooled by heat exchange with the first refrigerant, and the indoor air cooled by the first cooling cycle is exchanged with the second refrigerant to be cooled again to a lower temperature. Has a second cooling cycle.

The first cooling cycle may include a main compressor 60 in which the first refrigerant is compressed, a main condenser 62 in which the first refrigerant compressed in the main compressor 60 dissipates heat to condense, and the The main expander 64 in which the first refrigerant condensed in the main condenser 62 is expanded, and the low-temperature, low-pressure first refrigerant discharged from the main expander 64 absorb the surrounding heat, that is, the heat of indoor air. It consists of a main evaporator 66 which is evaporated.

The main compressor 60 may be provided in a single type or a multi type, and in the case of a single type, either an inverter or a constant speed type may be used.

The main evaporator 66 is located in the indoor unit 50 so as to exchange heat with the indoor air. The main condenser 62 condenses the first refrigerant by dissipating heat from the main condenser 62, so that the first refrigerant does not dissipate heat to indoor air in the main condenser 62. ).

The first refrigerant to be applied to the first cooling cycle as described above is a R-23 refrigerant having a condensation temperature of 43.9 ° C. in the main condenser 62 and an evaporation temperature of −16.8 ° C. in the main evaporator 66. desirable.

The second cooling cycle includes a rapid cooling compressor 70 in which the second refrigerant is compressed, and a rapid cooling condenser 72 in which the second refrigerant compressed by the rapid cooling compressor 70 dissipates heat and condenses. And a rapid cooling expander 74 in which the second refrigerant condensed in the rapid cooling condenser 72 is expanded, and a low-temperature, low-pressure second refrigerant discharged from the rapid cooling expander 74 includes the surrounding heat, ie, It consists of a rapid cooling evaporator 76 which absorbs the heat of the indoor air cooled by the main evaporator 66 and evaporates.

Like the main compressor 60, the rapid cooling compressor 70 may be provided in a single type or a multi type, and in the case of a single type, may be provided in an inverter or a constant speed type.

The rapid cooling condenser 72 may be positioned in the indoor unit 50 so that the second refrigerant of the rapid cooling condenser 72 may be condensed by heat exchange with the first refrigerant of the main evaporator 66.

Hereinafter, as described above, the rapid cooling condenser 72 and the main evaporator 66 are provided to allow the second refrigerant of the rapid cooling condenser 72 to condense by heat exchange with the first refrigerant of the main evaporator 66. The sum is referred to as an intermediate heat exchanger (80).

The intermediate heat exchanger 80 has a first refrigerant pipe 82 through which the first refrigerant flows, and a second refrigerant pipe inside the first refrigerant pipe 82 so that the second refrigerant flows inside. 84 may be provided in the form of a double tube located.

At this time, the double tube of the intermediate heat exchanger (80) is preferably piped so that the second refrigerant pipe (84) concentric with the first refrigerant pipe (82), each other in the flow direction of the first refrigerant and the second refrigerant Can be piped to the opposite.

The double tube of the intermediate heat exchanger 80 is formed of a material suitable for heat exchange such that heat exchange between the first refrigerant and the ambient air and the first refrigerant and the second refrigerant can be easily performed, as well as heat exchange with the ambient air. It is preferable that an intermediate heat exchanger heat exchanger fin 86 is provided on the outside of the double tube so that this is achieved.

The intermediate heat exchanger 80 configured as described above allows the second refrigerant pipe 84 to be positioned inside the first refrigerant pipe 82 so that the second refrigerant directly exchanges heat with the air surrounding the intermediate heat exchanger 80. Do not become.

Meanwhile, the second refrigerant discharged from the rapid cooling condenser 72 is condensed again by the rapid cooling recondenser 78 before being expanded in the rapid cooling expander 74.

The rapid cooling material condenser 78 may be provided such that the second refrigerant discharged from the rapid cooling condenser 72 of the intermediate heat exchanger 80 may be condensed again by heat exchange with the hot outdoor air outside.

That is, the rapid cooling recondenser 78 is connected to the rapid cooling condenser 72 of the intermediate heat exchanger 80 and the rapid cooling expander 74, respectively, and the rapid cooling condenser 72 of the intermediate heat exchanger 80. ) And the outdoor air to the sink refrigerant pipe (78a) so that the second refrigerant discharged from the flow through the sink refrigerant pipe (78a) and the second refrigerant in the sink refrigerant pipe (78a) can be condensed again by heat exchange with the outdoor air. It may be made of a sink blower (78b) for blowing.

Since the second refrigerant in the sink refrigerant pipe 78a dissipates heat and condenses, the sink refrigerant pipe 78a prevents the second refrigerant in the sink refrigerant pipe 78a from dissipating heat into the indoor air. 52). In addition, a plurality of sink refrigerant pipe heat exchange fins may be provided outside the sink refrigerant pipe 78a so that heat exchange with the outdoor air is performed well.

The rapid cooling evaporator 76 is positioned in the indoor unit 50 so that the indoor air cooled in the main evaporator 66 may be directly exchanged with the second refrigerant of the rapid cooling evaporator 76 to be cooled again. It is preferably located just in front of the intermediate heat exchanger 80 in the direction of flow of indoor air.

The rapid cooling evaporator 76 positioned immediately before the intermediate heat exchanger 80 includes a rapid cooling evaporator refrigerant pipe 76a through which the second refrigerant flows, and a plurality of rapid cooling evaporator refrigerant pipes 76a located outside the rapid cooling evaporator refrigerant pipe 76a. The rapid cooling evaporator heat exchange fins 76b may be formed. In particular, the plurality of rapid cooling evaporator heat exchange fins 76b may be arranged in the longitudinal direction of the rapid cooling evaporator refrigerant pipe 76a so as to minimize the flow resistance of the indoor air. Can be arranged.

As described above, as the second refrigerant used in the second cooling cycle, the condensation temperature of the second refrigerant in the main evaporator 66 may be condensed by being exchanged with the first refrigerant in the intermediate heat exchanger 80. The R-23 refrigerant is preferred as it must be a substance lower than the heat of evaporation of one refrigerant.

Further, the second cooling cycle may be performed in the intermediate heat exchanger 80 even if the first refrigerant absorbs not only heat of indoor air but also heat of the second refrigerant of the rapid cooling condenser 72 in the intermediate heat exchanger 80. The capacity of the rapid cooling compressor 70 and the rapid cooling compressor 70 is controlled so that the indoor air can be cooled.

On the other hand, the air conditioner is located in the indoor unit 50, the indoor air is sucked and passes through the intermediate heat exchanger 80 and the rapid cooling evaporator 76 in turn, and generates a blowing force to be discharged back to the room The indoor blower 90 may be further included. In addition, the air conditioner may further include an outdoor blower 92 positioned in the outdoor unit 52 to generate a blowing force so that outdoor air may be blown to the main condenser 62.

In addition, the air conditioner may be selectively operated in a general cooling mode in which indoor air is cooled only by a first cooling cycle or in a rapid cooling mode in which indoor air is cooled by the second cooling cycle after the indoor air is cooled in the first cooling cycle. The control unit (not shown) may be further included.

The controller may control to operate in the normal cooling mode or the rapid cooling mode according to the load amount according to the current indoor temperature and the target indoor temperature difference or the user's operation mode selection.

Looking at the cooling action of the air conditioner according to the present invention configured as described above are as follows.

In the normal mode operation, only the first cooling cycle is operated, and the second cooling cycle is stopped.

That is, the first refrigerant is compressed to high pressure in the main compressor 60, the first refrigerant compressed to high pressure in the main compressor 60 is blown by the outdoor blower 92 in the main condenser 62 Heat exchanged with outdoor air to condense at low temperature, and the first refrigerant condensed in the main condenser 62 is expanded at low temperature and low pressure in the main expander 64.

The first refrigerant expanded in the main expander (64) is evaporated by heat exchange with the indoor air blown by the indoor blower (90) in the main evaporator (66) of the intermediate heat exchanger (80). In the main evaporator 66 of 80, the indoor air heat exchanged with the first refrigerant is cooled.

Further, since the second cooling cycle is in a stopped state, there is no heat exchange between the first refrigerant and the second refrigerant in the intermediate heat exchanger 80, and the indoor air cooled by the intermediate heat exchanger 80 is the indoor blower ( 90 is blown to the rapid cooling evaporator 76, but is immediately discharged from the rapid cooling evaporator 76 to the room without heat exchange with the second refrigerant.

 On the other hand, when operating in the rapid cooling mode, both the first and second cooling cycles are operated.

That is, the first refrigerant is circulated through the main compressor 60, the main condenser 62, the main expander 64, and the main evaporator 66 of the intermediate heat exchanger 80 in order. Heat exchanged with the indoor air blown by the indoor blower (90) in the main evaporator (66) of the evaporation. In the main evaporator 66 of the intermediate heat exchanger 80, indoor air is cooled by heat exchange with the first refrigerant.

In addition, the second refrigerant is compressed to a high pressure in the rapid cooling compressor 70, the second refrigerant compressed in the rapid cooling compressor 70 is the rapid cooling condenser 72 of the intermediate heat exchanger (80) Heat exchanged with the first refrigerant of the main evaporator 66 of the intermediate heat exchanger 80 to condense.

The second refrigerant condensed in the rapid cooling condenser 72 of the intermediate heat exchanger 80 is blown out of the rapid cooling ash condenser 78 by the sink blower 78b to the rapid cooling ash condenser 78. Heat exchanged with the air to condense again, and the second refrigerant condensed again in the rapid cooling condenser 78 is expanded in the rapid cooling expander 74.

The low temperature and low pressure second refrigerant expanded in the rapid cooling expander 74 is evaporated by heat exchange with the indoor air cooled in the main evaporator 66 of the intermediate heat exchanger 80 in the rapid cooling evaporator 76. The indoor air is heat-exchanged with the second refrigerant in the rapid cooling evaporator 76, cooled again, and then discharged into the room.

Of course, during the rapid cooling mode operation, the second refrigerant also has the rapid cooling compressor 70, the rapid cooling condenser 72, the rapid cooling ash condenser 78, the rapid cooling expander 74, and the rapid cooling evaporator 76. ) In order to cool the room.

In the air conditioner according to the present invention configured as described above, the indoor air is cooled by heat exchange with the main evaporator of the first refrigerant in the normal cooling mode, and the indoor air is cooled by the main evaporator and the second refrigerant of the first refrigerant in the rapid cooling mode. Since it can be cooled again in the rapid cooling evaporator of the second refrigerant after being cooled by heat exchange with an intermediate heat exchanger made of a rapid cooling condenser, there is an advantage that cool and comfortable rapid cooling can be achieved whenever necessary.

Claims (8)

A main compressor, a main condenser, and a main expander, in which the first refrigerant is sequentially compressed, condensed, and expanded; A rapid cooling compressor in which the second refrigerant is compressed; An intermediate heat exchanger in which ambient air is cooled and the second refrigerant discharged from the rapid cooling compressor is condensed by the heat of vaporization of the first refrigerant discharged from the main expander; A rapid cooling recondenser for condensing the second refrigerant condensed in the rapid cooling condenser again with ambient air; A rapid cooling expander for expanding the second refrigerant discharged from the intermediate heat exchanger; And a rapid cooling evaporator positioned in front of the intermediate heat exchanger such that the air passing through the intermediate heat exchanger is cooled again by the heat of vaporization of the second refrigerant discharged from the rapid cooling expander. The method according to claim 1, The intermediate heat exchanger is provided with a double tube structure in which the first refrigerant flows on the outside and the second refrigerant flows on the inside. The method according to claim 2, The double tube of the intermediate heat exchanger is provided with the first refrigerant and the second refrigerant is characterized in that the opposite flow to each other. The method according to any one of claims 1 to 3, The rapid cooling ash condenser comprises a sink coolant tube through which the second refrigerant flows, and a sink blower configured to generate a blowing force so that the sink refrigerant tube can be condensed by being exchanged with ambient air. The method according to any one of claims 1 to 3, And said rapid cooling evaporator comprises a rapid cooling evaporator refrigerant tube and a plurality of rapid cooling evaporator fins fitted outside said rapid cooling evaporator refrigerant tube. The method according to any one of claims 1 to 3, And the first refrigerant is R-22 refrigerant, and the second refrigerant is R-23 refrigerant. The method according to any one of claims 1 to 3, And the air conditioner further comprises an indoor blower for generating a blowing force such that indoor air passes through the intermediate heat exchanger and the rapid cooling evaporator in turn. The method according to any one of claims 1 to 3, The air conditioner further includes a control unit for allowing air to be cooled by the cooling cycle of the first refrigerant in the normal cooling mode, and allowing the air to be rapidly cooled by the cooling cycle of the first and second refrigerants in the rapid cooling mode. Air conditioner, characterized in that.

Images