KR102372910B1 - Constant Temperature and humidity control unit - Google Patents

Abstract

The present invention relates to an energy-saving temperature and humidity-controllable air conditioner, which can increase performance through an optimal configuration and driving conditions, save energy, and ensure durability and safety. The energy-saving temperature and humidity-controllable air conditioner comprises: a compressor for compressing refrigerant; a four-way valve connected to four flow paths to supply circulating refrigerant, controlling the flow of the refrigerant; a first heat exchanger installed on an outer side; a second heat exchanger and a third heat exchanger installed on an inner side; a first expansion valve installed on an inner side to exapand the refrigerant; a second expansion valve installed on an outer side to restrict the refrigerant; a receiver for storing the condensed high-pressure refrigerant; a first line for connecting the compressor and the four-way valve; a second line for connecting the four-way valve and the first heat exchanger; a third line for connecting the first heat exchanger and the receiver; a fourth line for connecting the receiver and the second heat exchanger; a fifth line for connecting the second heat exchanger and the four-way valve; a sixth line for connecting the four-way valve and the compressor; a seventh line for connecting the second heat exchanger and the third heat exchanger; an eighth line for connecting the third heat exchanger and the fourth line; a ninth line for connecting the fourth line between the receiver and an eighth line connection part, and the third line; a tenth line for connecting the fourth line between the receiver and a ninth line connection part, and the second expansion valve; an eleventh line for connecting the third line between the first heat exchanger and the ninth line connection part, and the second expansion valve; and a twelfth line for connecting the fourth line between the second heat exchanger and the eighth line connection part, and the third heat exchanger.

Description

Energy saving type temperature and humidity control unit {Constant Temperature and humidity control unit}

The present invention relates to an energy-saving temperature-humidity control air conditioner, and more specifically, to an energy-saving temperature and humidity control air conditioner that allows heating, cooling, dehumidification, humidification, etc. to all be possible depending on the condition of the bet to maintain the bet in an optimal state. It's about harmonization.

A constant temperature and humidity air conditioner is a device that maintains the temperature and humidity inside a required space at a desired condition. Generally, it cools and dehumidifies through a compression refrigeration device, heats through an electric heater device, or cools and dehumidifies through a plurality of heat pumps. will perform

As an example of such a constant temperature and humidity air conditioner, there is Republic of Korea Patent Publication No. 10-0938820 (announced January 26, 2010), and this technology is composed of a plurality of heat pump-type air conditioners, so that the dehumidification capacity and the degree of temperature drop during dehumidification operation are reduced. Accordingly, any one of the first and second heat pump type air conditioners is driven by cooling operation, and the other is driven by selecting any one of drive stop, heating operation, and dehumidification operation, or the first to second heat pump type It is characterized in that one of the heating and cooling devices is driven by the dehumidifying operation, and the other is driven by selecting any one of the driving stop, the dehumidifying operation, and the heating operation.

However, in this prior art, a plurality of heat pump-type heating and cooling devices must be provided, which increases installation and maintenance costs as well as increases energy consumption. In addition, a separate heating and cooling device must be added to the existing heating and cooling device. Therefore, there is a problem in that the use of space is also a problem, making it difficult to apply.

Republic of Korea Patent Publication No. 10-0938820 (announcement on January 26, 2010)

Invented to solve the above problems, the present invention provides an energy-saving temperature and humidity control air conditioner that improves performance and saves energy while ensuring durability and safety of the device through an optimal configuration and operating conditions. It is intended to provide.

In addition, an object of the present invention is to provide an energy-saving temperature and humidity control air conditioner that enables all of the heating, cooling, dehumidification, and humidification operations to maintain the space to be controlled under optimal conditions.

In addition, an object of the present invention is to provide an energy-saving temperature and humidity control air conditioner that can fundamentally block performance and efficiency degradation and failures caused by the generation and accumulation of frost in the device with a relatively simple configuration.

As a means for solving the above problems, the present invention energy-saving temperature and humidity control air conditioner,

In an energy-saving temperature and humidity control air conditioner that cools and heats by circulating a refrigerant,

compressor to compress the refrigerant,

A four-way valve that controls the flow of refrigerant connected to four flow paths to supply circulating refrigerant;

a first heat exchanger installed on the outdoor side;

A second heat exchanger and a third heat exchanger installed indoors;

a first expansion valve installed indoors to throttle the refrigerant;

a second expansion valve installed on the outdoor side to throttle the refrigerant;

a receiver that stores the condensed high-pressure refrigerant;

a first line connected to the compressor and the four-way valve;

a second line connecting the four-way valve and the first heat exchanger;

a third line connecting the first heat exchanger and the receiver;

a fourth line connecting the receiver and the second heat exchanger;

a fifth line connecting the second heat exchanger and the four-way valve;

a sixth line connecting the four-way valve and the compressor;

a seventh line connecting the second heat exchanger and the third heat exchanger;

an eighth line connecting the third heat exchanger and the fourth line;

a ninth line connecting the fourth line and the third line between the receiver and the eighth line connecting part;

a tenth line connecting the fourth line between the receiver and the ninth line connecting portion and the second expansion valve;

an eleventh line connecting the third line between the first heat exchanger and the ninth line connecting portion and the second expansion valve; and

and a fourth line between the second heat exchanger and the eighth line connecting portion and a twelfth line connecting the third heat exchanger,

The first expansion valve is installed on the fourth line between the second heat exchanger and the twelfth line connection part.

In addition, a first control valve installed on the fourth line between the eighth line connecting portion and the twelfth line connecting portion;

a second control valve installed on the eighth line; and

and a third control valve installed on the seventh line.

In addition, the first control valve is opened during cooling operation and closed during heating and dehumidification operation,

The second control valve is closed during cooling operation and opened during heating and dehumidification operation,

The third control valve is configured to be opened during heating operation and closed during cooling and dehumidification operation.

In addition, a first check valve installed on the third line between the receiver and the 11th line connection part to enable the flow in the receiver direction and block the flow in the reverse direction;

a second check valve installed on the fourth line between the ninth line connection part and the tenth line connection part to enable the flow in the ninth line connection part direction and block the flow in the reverse direction;

a third check valve installed on the ninth line to enable the flow in the third line direction and block the flow in the reverse direction; and

and a fourth check valve installed on the tenth line to enable the flow in the direction of the second expansion valve and block the flow in the reverse direction.

In addition, an indoor fan installed indoors and installed adjacent to the second heat exchanger and the third heat exchanger;

a water supply pipe connected to the indoor fan through the second heat exchanger and the third heat exchanger and having one or more nozzles at the end;

It characterized in that it is configured to further include an anti-corrosion drain system installed in the indoor pan.

In addition, during the cooling operation, the refrigerant is the compressor, the first line, the four-way valve, the second line, the first heat exchanger, the third line, the receiver, the fourth line, the first expansion valve, the fourth line, the second heat exchanger, The fifth line, the four-way valve, the sixth line, circulate in the order of the compressor, and is configured to emit heat in the first heat exchanger and absorb heat in the second heat exchanger,

During heating and humidification operation, the refrigerant is supplied to the compressor, line 1, four-way valve, line 5, heat exchanger 2, line 7, line 3, line 8, line 4, line 9, receiver, line No. Line 4, line 10, second expansion valve, line 11, line 3, first heat exchanger, line 2, four-way valve, line 6, and the compressor circulate in this order, and the second heat exchanger and the second heat exchanger 4 is configured to dissipate heat in the heat exchanger and absorb heat in the first heat exchanger,

During the dehumidification operation, the refrigerant is supplied to the compressor, the first line, the four-way valve, the second line, the first heat exchanger, the third line, the receiver, the fourth line, the eighth line, the third heat exchanger, the 12th line, the fourth line. , the first expansion valve, the fourth line, the second heat exchanger, the fifth line, the four-way valve, the sixth line, and the compressor are circulated in the order, and heat is released from the first heat exchanger and the third heat exchanger, and the second heat exchanger is 2 It is characterized in that it is configured to absorb heat in the heat exchanger.

In addition, a thirteenth line connecting the fifth line and the twelfth line, and

It is configured to further include a fourth control valve installed on the thirteenth line,

The fourth control valve is configured to be opened for a predetermined time when the dehumidification operation is switched to the cooling operation and when the heating operation is switched to the cooling operation.

In addition, a 14th line having one end connected to the first line,

a fifteenth line having one end connected to the other end of the fourteenth line and the other end connected to the eleventh line;

and a 16th line having one end connected to the other end of the 14th line and the other end connected to the connecting portion of the third line and the ninth line through the first heat exchanger.

In addition, a fifth control valve installed on the 15th line and

and a sixth control valve installed on the 16th line.

In addition, a first temperature sensor and a second temperature sensor installed on one side and the other side of the first heat exchanger;

It is configured to further include a humidity sensor installed in the first heat exchanger,

The fifth and sixth control valves are controlled based on absolute humidity calculated through the temperature and relative humidity detected from the first temperature sensor, the second temperature sensor, and the humidity sensor.

In addition, the outdoor fan installed in the first heat exchanger,

a first pressure sensor installed on the third line between the first heat exchanger and the eleventh line connection part; and

and a first control module for controlling the driving of the outdoor fan according to a signal detected from the first pressure sensor.

In addition, a second pressure sensor installed on the third line between the first heat exchanger and the 11th line connection part;

a third pressure sensor installed on the sixth line; and

and a second control module configured to stop the operation of the compressor when the pressure is abnormal through signals detected from the second pressure sensor and the third pressure sensor during the cooling operation.

In addition, a fourth pressure sensor installed on the fourth line between the eighth line connection part and the ninth line connection part,

a fifth pressure sensor installed on the sixth line; and

and a third control module configured to stop the operation of the compressor when the pressure is abnormal through signals detected from the fourth pressure sensor and the fifth pressure sensor during the dehumidification operation.

In addition, the outdoor fan installed on the outdoor side installed in the first heat exchanger,

a sixth pressure sensor installed on the twelfth line; and

and a fourth control module configured to drive the outdoor fan through a signal detected from the sixth pressure sensor during dehumidification operation.

Through the problem solving means as described above, the energy saving type temperature and humidity control air conditioner of the present invention can realize optimal performance and save energy, and has excellent durability and safety of the device, and can operate both heating and cooling, dehumidification and humidification. It maintains the betting of the desired space in the optimal condition, and it is possible to operate a defrost operation with a relatively simple configuration. there is.

1 is a schematic diagram illustrating the configuration of an energy saving type temperature and humidity control air conditioner and a flow of refrigerant according to the present invention.

A preferred embodiment of the energy-saving temperature and humidity control air conditioner according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram illustrating the configuration of an energy saving type temperature and humidity control air conditioner and a flow of refrigerant according to the present invention.

As shown in Fig. 1, the energy-saving temperature and humidity control air conditioner according to the present invention is an energy-saving temperature and humidity control air conditioner that circulates a refrigerant to cool and heat, and perform cooling, heating, dehumidification and humidification. a compressor 11 for compressing , a four-way valve 12 connected to four flow paths to control the flow of refrigerant to supply a circulating refrigerant, a first heat exchanger 13 installed on the outdoor side, and an indoor side The second heat exchanger 14 and the third heat exchanger 15 installed in 2 expansion valve (17), a receiver (18) for storing the condensed high-pressure refrigerant, a first line (21) connecting the compressor (11) and the four-way valve (12), and the four-way valve (12) and a second line 22 connecting the first heat exchanger 13, a third line 23 connecting the first heat exchanger 13 and the receiver 18, and the receiver 18 A fourth line 24 connecting the second heat exchanger 14 to the second heat exchanger 14 , a fifth line 25 connecting the second heat exchanger 14 to the four-way valve 12 , and the four-way valve 12 . ) and a sixth line 26 connecting the compressor 11 , a seventh line 27 connecting the second heat exchanger 14 and the third heat exchanger 15 , and the third heat exchange The eighth line 28 connecting the group 15 and the fourth line 24, the fourth line 24 and the third line between the receiver 18 and the eighth line connecting portion 28' A ninth line 29 connecting 23 and a tenth connecting the second expansion valve 17 and a fourth line 24 between the receiver 18 and the ninth line connecting portion 29' A line 30, a third line 23 between the first heat exchanger 13 and a ninth line connecting portion, and an 11th line 31 connecting the second expansion valve 17, and the second The fourth line 24 between the heat exchanger 14 and the eighth line connecting portion 28' and the twelfth line 32 connecting the third heat exchanger 15 are included.

Here, the first expansion valve 16 is installed on the fourth line 24 between the second heat exchanger 14 and the twelfth line connection part 32'.

And the compressor (11), the four-way valve (12), the first heat exchanger (13), the second expansion valve (17), the receiver (18), the first line (21), the second line (22), the third line 23, the 6th line 26, the 9th line 29, the 10th line 30, and the 11th line 31 are provided in the outdoor unit installed on the outdoor side, and the second heat exchanger 14 ), the third heat exchanger 15 , the first expansion valve 16 , the 7th line 27 , the 8th line 28 , and the 12th line 32 are provided in the indoor unit installed indoors.

In addition, the present invention provides a first control valve 41 installed on the fourth line 24 between the eighth line connecting portion 28 ′ and the twelfth line connecting portion 32 ′, and the eighth line 28 . It further includes a second control valve 42 installed on the upper surface and a third control valve 43 installed on the seventh line 27 .

Here, the first control valve 41 is opened during the cooling operation and closed during the heating and dehumidification operation, the second control valve 42 is closed during the cooling operation and opened during the heating and dehumidification operation, and the third control The side 43 is configured to be opened during heating operation and closed during cooling and dehumidification operation.

And the present invention is installed on the third line 23 between the receiver 18 and the 11th line connection part 31' to enable the flow in the receiver 18 direction, and block the flow in the reverse direction. Installed on the fourth line 24 between the first check valve 51 and the ninth line connection part 29' and the tenth line connection part 30', the flow in the direction of the ninth line connection part 29' is The second check valve 52 is installed on the ninth line 29 to enable the flow in the reverse direction and to block the flow in the reverse direction, and the flow in the third line 23 direction is possible and the flow in the reverse direction is A third check valve 53 for blocking, and a fourth check valve installed on the tenth line 30 to enable the flow in the direction of the second expansion valve 17 and block the flow in the reverse direction ( 54) is further provided.

And the present invention provides an indoor fan (61) installed indoors and adjacent to the second heat exchanger (14) and the third heat exchanger (15), the second heat exchanger (14) and the third heat exchange A water supply pipe 64 connected to the indoor fan 61 via a device 15 and having one or more nozzles 63 at the end thereof, and a corrosion prevention drain system 93 installed in the indoor fan 61 provide more

Here, a water supply control valve 65 is installed in the water supply pipe 64, and during humidification operation, the water supply control valve 65 is opened according to the humidity of the indoor side and the opening degree is adjusted to perform humidification, and to prevent corrosion. The drain system is installed directly on the indoor pan 61 itself to discharge the remaining moisture falling on the indoor pan to the outside to prevent corrosion that may occur in the indoor pan 61 and its peripheral devices.

Specifically, in the present invention, during the cooling operation (blue line), the refrigerant is the compressor 11, the first line 21, the four-way valve 12, the second line 22, the first heat exchanger 13, the second 3 line (23), receiver (18), fourth line (24), first expansion valve (16), fourth line (24), second heat exchanger (14), fifth line (25), four-way valve (12), the sixth line (26), circulates in the order of the compressor (11), and is configured to emit heat in the first heat exchanger (13) and absorb heat in the second heat exchanger (14), During heating and humidification operation (red line), the refrigerant is supplied to the compressor 11, the first line 21, the four-way valve 12, the fifth line 25, the second heat exchanger 14, the seventh line 27 ), the third heat exchanger 15, the eighth line 28, the fourth line 24, the ninth line 29, the receiver 18, the fourth line 24, the tenth line 30, The second expansion valve 17, the 11th line 31, the third line 23, the first heat exchanger 13, the second line 22, the four-way valve 12, the sixth line 26, It circulates in the order of the compressor 11, and is configured to emit heat from the second heat exchanger 14 and the fourth heat exchanger and absorb heat from the first heat exchanger 13, and during the dehumidification operation (green line) ), the refrigerant is in the compressor 11, the first line 21, the four-way valve 12, the second line 22, the first heat exchanger 13, the third line 23, the receiver 18, the second Line 4 (24), line 8 (28), third heat exchanger (15), line 12 (32), line 4 (24), first expansion valve (16), line 4 (24), The second heat exchanger 14, the fifth line 25, the four-way valve 12, the sixth line 26, and the compressor 11 circulate in this order, and the first heat exchanger 13 and the third heat exchange configured to dissipate heat in the group ( 15 ) and absorb heat in the second heat exchanger ( 14 ).

In addition, in the present invention, a thirteenth line (33) connecting the fifth line (25) and the twelfth line (32) and a fourth control valve (44) installed on the thirteenth line (33) are provided. Further, the fourth control valve 44 is configured to be opened for a certain period of time when the dehumidification operation is switched to the cooling operation and when the heating operation is switched to the cooling operation. will prevent

And in the present invention, a 14th line (34) having one end connected to the first line (21), one end connected to the other end of the 14th line (34), and the other end connected to the eleventh line (31) One end is connected to the other end of the 15th line (35) and the 14th line (34), and the other end is connected to the connecting portion of the third line (23) and the ninth line (29) through the first heat exchanger (13) A 16th line 36 is further provided.

In addition, the present invention further includes a fifth control valve 45 installed on the fifteenth line 35 and a sixth control valve 46 installed on the sixteenth line 36 .

In addition, the present invention provides a first temperature sensor 71 and a second temperature sensor 72 installed on one side and the other side of the first heat exchanger 13 , and a humidity sensor installed on the first heat exchanger 13 . (73), wherein the fifth control valve (45) and the sixth control valve (46) are detected from the first temperature sensor (71), the second temperature sensor (72) and the humidity sensor (73). It is configured to be controlled based on absolute humidity calculated through temperature and relative humidity.

That is, the absolute humidity is calculated using the temperature detected from the first temperature sensor 71 and the second temperature sensor 72 and the relative humidity detected from the humidity sensor 73, and compared with the reference absolute humidity. The opening and opening degree of the fifth control valve 45 and the sixth control valve 46 are adjusted, and when the fifth control valve 45 is opened, the 14th line 34 and the 15th line from the compressor 11 are A high-temperature refrigerant is supplied to the 11th line 31 which is the downstream side of the second expansion valve 17 through the line 35 so that the third line 23 and the 11th line 31 are defrosted. When the sixth control valve 46 is opened, a high-temperature refrigerant is supplied from the compressor 11 to the first heat exchanger 13 through the 14th line 34 and the 16th line 36 to produce A defrosting operation is performed in the first heat exchanger (13).

In addition, the present invention provides an outdoor fan 62 installed in the first heat exchanger 13, and on the third line 23 between the first heat exchanger 13 and the 11th line connection part 31'. It further includes an installed first pressure sensor 74 and a first control module 81 for controlling the driving of the outdoor fan 62 according to a signal detected from the first pressure sensor 74 .

Specifically, during the cooling operation with the first control module 81 , the outdoor fan 62 is controlled by detecting the high pressure on the downstream side of the first heat exchanger 13 through the first pressure sensor 74 .

In addition, the present invention provides a second pressure sensor (75) installed on the third line (23) between the first heat exchanger (13) and the eleventh line connection part (31'), and the sixth line (26). The third pressure sensor 76 installed on the top and the signal detected from the second pressure sensor 75 and the third pressure sensor 76 during the cooling operation stop the operation of the compressor 11 when the pressure is abnormal. It further includes a second control module 82 configured to do so.

The second control module 82 forcibly stops the compressor 11 when the pressure in the third line 23 and the sixth line 26 is excessively high during the cooling operation.

In addition, the present invention provides a fourth pressure sensor 77 installed on the fourth line 24 between the eighth line connecting portion 28 ′ and the ninth line connecting portion 29 ′, and the sixth line 26 . The fifth pressure sensor 78 installed on the top and the signal detected from the fourth pressure sensor 77 and the fifth pressure sensor 78 during the dehumidification operation stop the operation of the compressor 11 when the pressure is abnormal. It further includes a third control module 83 that is configured to do so.

The third control module 83 forcibly stops the compressor 11 when the pressure in the fourth line 24 and the sixth line 26 is excessively high during the dehumidification operation.

In addition, in the present invention, the outdoor fan 62 is controlled through a sixth pressure sensor 79 installed on the twelfth line 32 and a signal detected from the sixth pressure sensor 79 during dehumidification operation. A fourth control module 84 for driving is further provided.

The fourth control module 84 detects a high pressure on the twelfth line 32 during dehumidification operation and controls whether or not the outdoor fan 62 is operated and the speed thereof.

Through the configuration as described above, the energy-saving temperature and humidity control air conditioner of the present invention enables optimal performance and energy saving, has excellent durability and safety of the device, and can be operated for heating, cooling, dehumidification and humidification. It maintains the space bet in the optimal condition and enables defrost operation with a relatively simple configuration, which can fundamentally block performance and efficiency degradation and failures caused by the generation and accumulation of frost in the device, and energy-saving temperature and humidity control. There are advantages such as being able to simply configure the air conditioner.

11: Compressor 12: Four-way valve
13: first heat exchanger 14: second heat exchanger
15: third heat exchanger 16: first expansion valve
17: second expansion valve 18: receiver
21: first line 22: second line
23: 3rd line 24: 4th line
25: 5th line 26: 6th line
27: line 7 28: line 8
29: 9th line 30: 10th line
31: line 11 32: line 12
33: line 13 34: line 14
35: 15th line 36: 16th line
28': 8th line connection part 29': 9th line connection part
30': 10th line connection part 31': 11th line connection part
32': 12th line connection part
41: first control valve 42: second control valve
43: third control valve 44: fourth control valve
45: fifth control valve 46: sixth control valve
51: first check valve 52: second check valve
53: third check valve 54: fourth check valve
61: indoor fan 62: outdoor fan
63: nozzle 64: water supply pipe
65: water supply control valve
71: first temperature sensor 72: second temperature sensor
73: humidity sensor 74: first pressure sensor
75: second pressure sensor 76: third pressure sensor
77: fourth pressure sensor 78: fifth pressure sensor
79: sixth pressure sensor
81: first control module 82: second control module
83: third control module 84: fourth control module
91: oil separator 92: accumulator
93: drain system

Claims (14)

In an energy-saving temperature and humidity control air conditioner that cools and heats by circulating a refrigerant,
compressor to compress the refrigerant,
A four-way valve that controls the flow of refrigerant connected to four flow paths to supply circulating refrigerant;
a first heat exchanger installed on the outdoor side;
A second heat exchanger and a third heat exchanger installed indoors;
a first expansion valve installed indoors to throttle the refrigerant;
a second expansion valve installed on the outdoor side to throttle the refrigerant;
a receiver that stores the condensed high-pressure refrigerant;
a first line connected to the compressor and the four-way valve;
a second line connecting the four-way valve and the first heat exchanger;
a third line connecting the first heat exchanger and the receiver;
a fourth line connecting the receiver and the second heat exchanger;
a fifth line connecting the second heat exchanger and the four-way valve;
a sixth line connecting the four-way valve and the compressor;
a seventh line connecting the second heat exchanger and the third heat exchanger;
an eighth line connecting the third heat exchanger and the fourth line;
a ninth line connecting the fourth line and the third line between the receiver and the eighth line connecting part;
a tenth line connecting the fourth line between the receiver and the ninth line connecting portion and the second expansion valve;
an eleventh line connecting the third line between the first heat exchanger and the ninth line connecting portion and the second expansion valve; and
and a fourth line between the second heat exchanger and the eighth line connecting portion and a twelfth line connecting the third heat exchanger,
wherein the first expansion valve is installed on a fourth line between the second heat exchanger and a twelfth line connection part
Energy saving type temperature and humidity control air conditioner
The method according to claim 1,
a first control valve installed on the fourth line between the eighth line connecting portion and the twelfth line connecting portion;
a second control valve installed on the eighth line; and
and a third control valve installed on the seventh line.
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
The first control valve is opened during cooling operation and closed during heating and dehumidification operation,
The second control valve is closed during cooling operation and opened during heating and dehumidification operation,
The third control valve is configured to be opened during heating operation and closed during cooling and dehumidification operation.
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
A first check valve installed on the third line between the receiver and the 11th line connection part to enable the flow in the receiver direction and block the flow in the reverse direction;
a second check valve installed on the fourth line between the ninth line connection part and the tenth line connection part to enable the flow in the ninth line connection part direction and block the flow in the reverse direction;
a third check valve installed on the ninth line to enable the flow in the third line direction and block the flow in the reverse direction; and
and a fourth check valve installed on the tenth line to enable the flow in the direction of the second expansion valve and block the flow in the reverse direction.
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
An indoor fan installed indoors and installed adjacent to the second heat exchanger and the third heat exchanger;
a water supply pipe connected to the indoor fan through the second heat exchanger and the third heat exchanger and having one or more nozzles at the end;
Characterized in that it is configured to further include an anti-corrosion drain system installed in the indoor pan
Energy saving type temperature and humidity control air conditioner
6. The method of claim 5,
During the cooling operation, the refrigerant is the compressor, the first line, the four-way valve, the second line, the first heat exchanger, the third line, the receiver, the fourth line, the first expansion valve, the fourth line, the second heat exchanger, and the fifth line. The line, the four-way valve, the sixth line, circulate in the order of the compressor, and is configured to emit heat in the first heat exchanger and absorb heat in the second heat exchanger,
During heating and humidification operation, the refrigerant is supplied to the compressor, line 1, four-way valve, line 5, heat exchanger 2, line 7, line 3, line 8, line 4, line 9, receiver, line No. Line 4, line 10, second expansion valve, line 11, line 3, first heat exchanger, line 2, four-way valve, line 6, and the compressor circulate in this order, and the second heat exchanger and the second heat exchanger 4 is configured to dissipate heat in the heat exchanger and absorb heat in the first heat exchanger,
During the dehumidification operation, the refrigerant is supplied to the compressor, the first line, the four-way valve, the second line, the first heat exchanger, the third line, the receiver, the fourth line, the eighth line, the third heat exchanger, the 12th line, the fourth line. , the first expansion valve, the fourth line, the second heat exchanger, the fifth line, the four-way valve, the sixth line, and the compressor are circulated in the order, and heat is released from the first heat exchanger and the third heat exchanger, and the second heat exchanger is 2 characterized in that it is configured to absorb heat in the heat exchanger
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
a thirteenth line connecting the fifth line and the twelfth line; and
It is configured to further include a fourth control valve installed on the thirteenth line,
The fourth control valve is configured to be opened for a predetermined time when the dehumidification operation is switched to the cooling operation and when the heating operation is switched to the cooling operation.
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
a 14th line having one end connected to the first line;
a fifteenth line having one end connected to the other end of the fourteenth line and the other end connected to the eleventh line;
and a 16th line having one end connected to the other end of the 14th line and the other end connected to the connecting portion of the third line and the ninth line through the first heat exchanger.
Energy saving type temperature and humidity control air conditioner
9. The method of claim 8,
a fifth control valve installed on the fifteenth line; and
and a sixth control valve installed on the 16th line.
Energy saving type temperature and humidity control air conditioner
10. The method of claim 9,
a first temperature sensor and a second temperature sensor installed on one side and the other side of the first heat exchanger;
It is configured to further include a humidity sensor installed in the first heat exchanger,
The fifth and sixth control valves are controlled based on absolute humidity calculated through the temperature and relative humidity detected from the first temperature sensor, the second temperature sensor, and the humidity sensor.
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
an outdoor fan installed in the first heat exchanger;
a first pressure sensor installed on the third line between the first heat exchanger and the eleventh line connection part; and
characterized in that it further comprises a first control module for controlling the driving of the outdoor fan according to the signal detected from the first pressure sensor
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
a second pressure sensor installed on the third line between the first heat exchanger and the eleventh line connection;
a third pressure sensor installed on the sixth line; and
A second control module configured to stop driving of the compressor when the pressure is abnormal through a signal detected from the second pressure sensor and the third pressure sensor during cooling operation
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
a fourth pressure sensor installed on the fourth line between the eighth line connection part and the ninth line connection part;
a fifth pressure sensor installed on the sixth line; and
A third control module configured to stop the operation of the compressor when the pressure is abnormal through a signal detected from the fourth pressure sensor and the fifth pressure sensor during dehumidification operation
Energy saving type temperature and humidity control air conditioner
3. The method according to claim 2,
An outdoor fan installed on the outdoor side and installed in the first heat exchanger,
a sixth pressure sensor installed on the twelfth line; and
A fourth control module configured to drive the outdoor fan through a signal detected from the sixth pressure sensor during dehumidification operation
Energy saving type temperature and humidity control air conditioner

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