KR20140091947A - Air handing unit - Google Patents

Abstract

An air conditioner of the present invention includes: a casing having an air inlet and an air outlet; a water cooling chiller for cooling the air inhaled to the air inlet as coolant supplied in a cooling tower passes through a condenser and is heat-exchanged with a refrigerant and a cooling coil is arranged in the casing; a preheating heat exchanger installed in the casing and in which air heat-exchanged with the cooling coil is heat-exchanged with the coolant heat-exchanged with the refrigerant in the condenser; and an electric heater installed in an air flow direction next to the preheating heat exchanger and in which the air passing through the preheating heat exchanger is heated. The power consumption of the electric heater can be reduced.

Description

Air handing unit

The present invention relates to an air conditioner, and more particularly, to an air conditioner in which a chiller cools air.

Generally, an air conditioner is used to cool and heat a room by using a refrigerating cycle of a refrigerant composed of a compressor, a condenser, an expansion mechanism, and an evaporator in order to create a more comfortable indoor environment for the user.

 The air conditioner connects the air handling unit and the chiller and sucks the room air into the air handling unit to change at least one of the temperature and the humidity and then discharge the air from the air handling unit again to the room .

The chiller may include a compressor in which the refrigerant is circulated, a condenser, an expansion mechanism, and an evaporator, and the heat of the air passing through the air handling unit may be absorbed by the chiller and the chiller may emit the absorbed heat .

KR 10-2010-0119646 (2010.11.10)

The air conditioner according to the prior art is provided with an electric heater for heating the air deprived of heat by the chiller so that the air whose temperature is lowered by the chiller is heated again by the electric heater and then discharged to the room, When the temperature is lowered to the dew point temperature, there is a problem that the electric power consumption of the electric heater may excessively increase.

According to an aspect of the present invention, there is provided an air conditioner comprising: a casing having an air inlet and an air outlet; A water-cooled chiller which cools the air sucked into the air inlet by arranging a cooling coil inside the casing, while the cooling water supplied from the cooling tower passes through the condenser and heat-exchanges with the refrigerant; A preheating heat exchanger installed in the casing and having heat exchanged with the cooling coil for heat exchange with cooling water heat exchanged with refrigerant in the condenser; And an electric heater installed inside the casing and heating the air passing through the preheat heat exchanger.

The preheat heat exchanger may be connected to an outflow pipe through which the cooling water passing through the condenser is guided to the cooling tower among the water pipes connecting the cooling tower and the condenser.

And a cooling water control valve for controlling the cooling water exiting the preheat heat exchanger.

 An air conditioner according to the present invention includes: a casing having an air inlet and an air outlet; A water-cooled chiller which cools the air sucked into the air inlet by arranging a cooling coil inside the casing, while the cooling water supplied from the cooling tower passes through the condenser and heat-exchanges with the refrigerant; A preheating compressor in which the refrigerant is compressed; A preheat heat exchanger installed in the casing and having heat exchanged with the cooling coil for heat exchange with the refrigerant compressed in the preheat compressor; A preheat expansion mechanism for expanding the refrigerant condensed in the preheat heat exchanger; A preheating evaporator in which the refrigerant expanded in the preheat expansion mechanism is evaporated; And an electric heater installed inside the casing and heating the air passing through the preheat heat exchanger.

The preheating evaporator may be a water-refrigerant heat exchanger in which the cooling water heat-exchanged with the refrigerant in the condenser evaporates the refrigerant.

The preheating evaporator may be connected to an outflow pipe through which the cooling water passing through the condenser is guided to the cooling tower among the water pipes connecting the cooling tower and the condenser.

And an outdoor fan for blowing outdoor air to the preheating evaporator.

The present invention has the advantage that the electric power of the electric heater can be minimized since the air whose temperature is lowered by the water-cooled chiller is primarily heated by the preheat heat exchanger and then secondarily heated by the electric heater.

Further, since the waste heat of the cooling water that has passed through the condenser is used in the preheat heat exchanger, the efficiency is high.

In addition, there is an advantage that the cooling water whose temperature is reduced while passing through the preheat heat exchanger flows into the cooling tower, and the load of the cooling tower can be minimized.

1 is a view showing a configuration of an embodiment of an air conditioner according to the present invention,
2 is a view showing a configuration of another embodiment of an air conditioner according to the present invention,
3 is a view showing the configuration of another embodiment of an air conditioner according to the present invention.

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

1 is a view showing a configuration of an embodiment of an air conditioner according to the present invention.

The air conditioner may include an air conditioning unit (AHU), a water-cooled chiller (C), and a cooling tower (T).

The air conditioning unit AHU sucks air in the indoor space and lowers the temperature to the dew point temperature by using a water-cooled chiller C, and then adjusts temperature and humidity by using the electric heater 32 and the humidifier 34 have. The air conditioning unit (AHU) is capable of supplying air having adjusted temperature and humidity to the indoor space. The air conditioning unit (AHU) can be installed in a machine room or a basement other than the room where the temperature and humidity are to be controlled. The air conditioning unit (AHU) is connected to the room to adjust the temperature and humidity and the suction duct and the discharge duct, It is possible to discharge through the discharge duct after controlling the temperature and the humidity. The air conditioning unit (AHU) includes a preheat heat exchanger (30) for heating the air flowing toward the electric heater (32), so that the electric power consumption of the electric heater (32) can be reduced. The preheat heat exchanger (30) can heat the air flowing toward the electric heater (32) using waste heat generated in the air conditioner.

The water-cooled chiller (C) can be cooled to lower the air drawn into the air-conditioning unit (AHU) down to the dew point temperature, and installed in a machine room or a basement other than the room where temperature and humidity are to be controlled.

The air conditioner includes a casing (6) having an air inlet (2) and an air outlet (4); The cooling water supplied from the cooling tower T exchanges heat with the refrigerant while passing through the condenser 16 and the cooling coil 20 is disposed inside the casing 6 to cool the air sucked into the air inlet 2, )Wow; A preheating heat exchanger (30) installed in the casing (6) and having heat exchanged with the cooling coil (20) is heat - exchanged with cooling water heat exchanged with the refrigerant in the condenser (16); An electric heater (32) for heating the air passing through the preheating heat exchanger (30); And a humidifier (34) for humidifying the air that has passed through the electric heater (32).

The air conditioner causes indoor air to be sucked into the casing 6 through the air inlet port 2 and causes the air sucked into the air inlet port 2 to pass through the inside of the casing 6 to be discharged to the air outlet port 4 And may include at least one blower fan 36. The blowing fan 36 may be installed inside the casing 6, and may be provided in a single or plural number. When a plurality of air blowing fans 36 are installed, the air blowing fan 36 is installed between the air intake port 2 and the cooling coil 20 in the air flow direction and sucks the room air into the casing 6 and blows the air to the cooling coil 20 And a supply fan that is installed between the humidifier port 34 and the air discharge port 4 in the direction of air flow and blows the air whose temperature and humidity have changed in the casing 6 to the air discharge port 4 . When the blowing fan 36 is driven, the room air can be sucked into the air suction port 2, and the air sucked into the air suction port 2 can be lowered in temperature and humidity while passing through the cooling coil 20. The air whose temperature and humidity are lowered by the cooling coil 20 can be heated by the preheat heat exchanger 30 to be primarily heated and then heated by the electric heater 32 to be secondarily heated . The air sequentially heated by the preheating heat exchanger (30) and the electric heater (32) is humidified by the humidifier (34) and can be discharged to the air outlet (4).

The casing 6 can form the appearance of the air conditioning unit (AHU). The air conditioning unit (AHU) is disposed in a room where temperature and humidity are to be controlled, and is capable of sucking in air to adjust temperature and humidity, and then discharging the conditioned air.

The water-cooled chiller C may include a compressor 11, a condenser 14, an expansion mechanism 16, and a cooling coil 20. The water-cooled chiller (C) can constitute a refrigeration cycle circuit in which the compressor (11), the condenser (14), the expansion mechanism (16), and the cooling coil (20) cool the air using the cooling water.

The compressor (11) can compress the refrigerant. The compressor 11 may be connected to a compressor suction passage 12 through which the refrigerant is sucked into the compressor 11 and a compressor discharge passage 13 through which the refrigerant compressed by the compressor 11 is discharged.

The condenser 14 may be a water-cooled heat exchanger for heat-exchanging the refrigerant compressed in the compressor 11 with the cooling water. The refrigerant flowing through the refrigerant passage and the cooling water passing through the refrigerant passage can be heat-exchanged by the heat transfer member have. The condenser 14 is connected to the cooling tower T via the water pipes 21 and 22 and the refrigerant compressed in the compressor 12 can be heat-exchanged with the cooling water to be condensed. The cooling tower T may supply low-temperature cooling water to the condenser 14 of the water-cooling chiller C so that the refrigerant passing through the condenser 14 of the water-cooling chiller C may be condensed by the cooling water. The cooling tower T can be installed outside the building such as the roof of the building and can cool the cooling water using outdoor air. The water pipes 21 and 22 for connecting the cooling tower T and the condenser 14 are connected to each other by an inlet pipe 21 through which the cooling water of the cooling tower T is guided to the condenser 14, And an outflow pipe (22) guided to the cooling tower (T). At least one of the water inlet pipe 21 and the water outlet pipe 22 may be provided with a cooling water pump 23 for circulating cooling water. When the cooling water pump 23 is driven, the cooling water flows to the cooling tower T and is cooled in the cooling tower T. The cooling water at the low temperature cooled in the cooling tower T flows through the intake pipe 21 to the condenser 14 . The cooling water is heated by the refrigerant while passing through the condenser 14 and the cooling water of the high temperature heated by the condenser 14 flows to the cooling tower T through the outflow pipe 22. The condenser (14) may be connected to a condenser-expansion mechanism connecting passage (15) through which the refrigerant heat-exchanged with the cooling water and condensed is guided to the expansion mechanism (16).

The expansion mechanism 16 may expand the refrigerant condensed in the condenser 14. The expansion mechanism 16 may be constituted by a capillary tube or an electronic expansion valve such as an LEV or EEV capable of adjusting the opening degree.

The cooling coil 20 may be installed inside the casing 6. [ The cooling coil 20 may be constituted by an air-refrigerant heat exchanger in which the refrigerant expanded by the expansion mechanism 16 is heat-exchanged with the air sucked into the air inlet 2 and evaporated. In this case, the cooling coil 20 can be connected by the expansion mechanism 16 and the expansion mechanism-cooling coil connection flow path 17, and can be connected to the compressor 11 and the compressor suction flow path 12, It can function as an evaporator. The refrigerant can flow in the order of the compressor 11, the condenser 14, the expansion mechanism 14, the cooling coil 20 and the compressor 11 in this order. The refrigerant can be heat-exchanged with the cooling water passing through the condenser 14 and condensed. The refrigerant can be heat-exchanged with the air sucked into the air inlet 2 from the cooling coil 20 and evaporated.

It is possible that the air conditioner includes a cooling coil 20 and a separate evaporator (not shown). It is possible that the air conditioner constitutes the compressor 11, the condenser 14, the expansion mechanism 16, the evaporator and the cooling coil 20 constitute a water-cooled chiller. The evaporator may include a cold water-refrigerant heat exchanger connected to the cooling coil 20 through a cold water inlet pipe and a cold water outlet pipe to exchange heat between the refrigerant and the cold water. The evaporator may be connected to the expansion mechanism (16) through an expansion mechanism-cooling coil connection path, and may be connected to the compressor (11) and the compressor suction path (12). The evaporator may be provided with a refrigerant passage through which the refrigerant expanded in the expansion mechanism 16 passes and a cold water passage through which the cold water flowing in the cooling coil 20 passes. The refrigerant passing through the refrigerant passage passes through the cold water passage It can be evaporated by heat exchange with cold water. The cold water can be discharged to the refrigerant while passing through the evaporator, and can flow to the cooling coil 20 through the cold water inlet pipe. The cold water flowing into the cooling coil 20 can absorb heat of air passing through the cooling coil 20 while passing through the cooling coil 20. The cold water that has passed through the cooling coil 20 can flow to the evaporator through the cold water outflow pipe.

The preheat heat exchanger (30) may be installed prior to the electric heater (32) in the air flow direction. The preheating heat exchanger 30 is connected to the outflow pipe 22 through which the cooling water having passed through the condenser 14 among the water pipes 21 and 22 connecting the cooling tower T and the condenser 14 is guided to the cooling tower T Can be connected. The preheat heat exchanger (30) may include a tube having a cooling water flow passage through which cooling water passes. The preheat heat exchanger (30) may be composed of a water-air heat exchanger for exchanging heat between the cooling water and air. The preheating heat exchanger 30 may be installed inside the casing 6 and the water outlet pipe 22 may be disposed outside the casing 6. The preheat heat exchanger 30 is connected to the water inlet pipe 22 (42) and an outlet pipe (44). The cooling water that has been heat-exchanged with the refrigerant in the condenser 14 can be heated by the refrigerant and the hot water that has been heated in the condenser 14 can flow to the preheat heat exchanger 30 through the water inlet pipe 42. The high-temperature cooling water flowing into the preheating heat exchanger (30) is heat-exchanged with the air passing through the casing (6) while passing through the preheating heat exchanger (30) to heat the air. The cooling water of the preheat heat exchanger (30) can flow to the outflow pipe (22) through the water outlet pipe (44). The cooling water of the preheating heat exchanger 30 can flow into the water outlet pipe 44 while being deprived of heat by the air passing through the casing 6 and flows from the water outlet pipe 44 to the water outlet pipe 22, T). ≪ / RTI >

 The air conditioner may include a cooling water regulating valve 46 for regulating the cooling water exiting the preheat heat exchanger 30. The cooling water control valve 46 is capable of interrupting the high temperature cooling water flowing into the preheating heat exchanger 30 from the outflow pipe 22 by installing a single one in one of the water inlet pipe 42 and the water outlet pipe 44. The cooling water control valve 46 may be constituted by an electromagnetic valve such as a solenoid valve. In the air conditioner, it is possible that the cooling water control valve 46 is installed in the water outflow pipe 22, the cooling water control valve 46 is constituted by a three-way valve, and the water intake pipe 42 is connected to the cooling water control valve 46 . The cooling water control valve 46 may have a preheating heat exchanger supply mode in which the cooling water flowing out of the condenser 14 to the outlet pipe 22 flows to the preheating heat exchanger 30 and then flows to the cooling tower T, The preheating heat exchanger bypass mode in which the cooling water flowing out from the heat exchanger 14 to the outflow pipe 22 bypasses the preheat heat exchanger 30 and flows to the cooling tower T can be obtained.

 An electric heater 32 may be provided after the preheat heat exchanger 30 in the air flow direction to further heat the air primarily heated in the preheat heat exchanger 30. [

The humidifying device 34 can supply moisture between the electric heater 32 and the air outlet 4 in the flow direction of the room air. The humidifier device 34 may be an ultrasonic humidifier device that generates ultrasonic waves and splits the water into small particles and blows them out into the casing 6. [ The humidifier mechanism 34 may be constituted by a heating humidifier which boils water to spray the generated water vapor into the casing 6. The humidifier unit 34 may be a spray type humidifier unit for spraying the water into the casing 6 by automation. The humidifying device 34 can be composed of a natural humidifier having a humidifying filter containing moisture and being humidified while air passes through the inside of the casing 6. The humidifying device 34 may include at least one humidifying nozzle 35 for supplying moisture to the air passing through the electric heater 32 when the humidifying device 34 comprises an ultrasonic humidifier, a heating humidifier, or a spray type humidifier. The air heated by the electric heater 32 is humidified by the humidifier 34 and then can be discharged to the air discharge port 4. When the humidifier 34 is operated, The humidity of the room can be controlled by this.

 The air conditioner may further include a temperature sensor (not shown) for sensing the temperature of the room to be air conditioned and a humidity sensor (not shown) for sensing the humidity of the room to be air conditioned.

The air conditioner may further include an air conditioning unit controller (not shown) for controlling the electric heater 32, the humidifier mechanism 34, and the blower fan 36 according to the detection results of the temperature sensor and the humidity sensor.

Hereinafter, the operation of the present invention will be described.

First, the air conditioner can be operated such that the compressor 11 can be driven, the cooling water pump 23 and the cooling tower T can be driven, the blowing fan 36 can be driven, and the electric heater 32 can be turned on And the humidifier opening 34 can be turned on.

When the compressor 11 is driven, the refrigerant is compressed by the compressor 11, passes through the condenser 14, and is heat-exchanged with the cooling water of the condenser 14 to be condensed. After being expanded in the expansion mechanism 16, Can be exchanged with air in the casing (6) while passing through the evaporator (20) and evaporated. The refrigerant evaporated in the cooling coil 20 can be sucked into the compressor 11 and the refrigerant circulates through the compressor 11 and the condenser 14, the expansion mechanism 16 and the cooling coil 20, , Expanded, and evaporated.

During the operation of the cooling tower T and the cooling water pump 23, the cooling water cooled in the cooling tower T can be introduced into the condenser 14 through the intake pipe 21 and is supplied to the condenser 14 The heat of the refrigerant passing through the heat exchanger can be absorbed. The cooling water of the condenser 14 can be heated more than when it is introduced into the condenser 14 and can be discharged to the outflow pipe 22. The high temperature cooling water exiting to the water outlet pipe 22 can flow from the water outlet pipe 22 to the water inlet pipe 42 and flow into the preheat heat exchanger 30. The high temperature cooling water flowing into the preheating heat exchanger (30) can raise the temperature of the air in the casing (6) while passing through the preheating heat exchanger (30). The cooling water of the preheating heat exchanger 30 is absorbed by the air of the casing 6 and changes to low temperature and can flow to the water outlet pipe 22 through the water outlet pipe 44. The cooling water flowing into the water outlet pipe 22 may be introduced into the cooling tower T and may be introduced into the cooling tower T at a lower temperature than before passing through the preheating heat exchanger 30. [ When the high temperature cooling water exiting from the condenser 14 flows into the cooling tower T after passing through the preheat heat exchanger 30, the cooling water is supplied to the cooling tower T at a temperature lower than the case where the cooling water bypasses the preheat heat exchanger 30 And the load of the cooling tower T can be reduced if the high temperature cooling water exiting from the condenser 14 flows into the cooling tower T after passing through the preheating heat exchanger 30. [

When the blowing fan 36 is driven, air in the room is sucked into the air intake port 2 and can be heat-exchanged with the cooling coil 20. The air may be deprived of heat to the cooling coil 20 so that the temperature and humidity may be lowered and then flowed to the preheating heat exchanger 30. [ The air that has flowed into the preheat heat exchanger (30) can be heated by heat exchange with the hot water passing through the preheat heat exchanger (30), and then can flow to the electric heater (32). The air that has flowed to the electric heater 32 can be heated by the electric heater 32 and can be heated and then flowed toward the air outlet 4. The on-state humidifier opening 34 of the humidifier opening 34 can humidify the air flowing from the electric heater 32 toward the air discharge opening 4. [ The air humidified by the humidifier opening (34) can be discharged to the room through the air discharge opening (4). Since the air cooled by the cooling coil 20 is first heated by the waste heat and then heated by the electric heater 32, the air cooled by the cooling coil 20 is heated by the preheat heat exchanger 30, The load and the power consumption of the electric heater 32 can be reduced as compared with the case where the electric heater 32 is heated by the electric heater 32 without passing through the electric heater 32. [

2 is a view showing the configuration of another embodiment of the air conditioner according to the present invention.

The air conditioner of this embodiment includes a preheat compressor 51 in which a refrigerant is compressed; A preheat heat exchanger (30 ') installed in the casing (6) and exchanging heat with the refrigerant compressed in the preheat compressor (51) by the heat exchanged air with the cooling coil (30); A preheat expansion mechanism (56) for expanding the refrigerant condensed in the preheat heat exchanger (30 '); And a preheating evaporator 60 in which the refrigerant expanded in the preheat expansion mechanism 56 is evaporated. The air conditioner of the present embodiment has the same structure and function as those of the present invention except for the preheating compressor 51, the preheating heat exchanger 30 ', the preheating expansion mechanism 56 and the preheating evaporator 60 The same reference numerals are used and detailed description thereof will be omitted.

The preheating compressor 51, the preheating heat exchanger 30 ', the preheating expansion mechanism 56 and the preheating evaporator 60 can constitute a refrigeration cycle circuit independent of the water-cooled chiller C, And an air-cooled type heater that heats the air in the casing 6 using the high-temperature cooling water waste heat. The preheating compressor 51, the preheating heat exchanger 30 ', the preheating expansion mechanism 56 and the preheating evaporator 60 may be a preheating cycle circuit for preheating the air to be heated by the electric heater 32. It is possible that the refrigerant of the preheating cycle circuit is the same as or different from the refrigerant of the water-cooling type chiller (C). When the refrigerant of the water-cooled chiller (C) is the first refrigerant, the refrigerant of the preheating cycle circuit may be the second refrigerant, and the first refrigerant and the second refrigerant may independently flow so as not to be mixed with each other. The refrigerant compressed in the preheating compressor 51 can be condensed by heat exchange with the air inside the casing 6 while passing through the preheating heat exchanger 30 'and expanded in the preheat expansion mechanism 56. The refrigerant expanded in the preheat expansion mechanism (56) can be evaporated by heat exchange with the cooling water exiting from the condenser (14) while passing through the preheating evaporator (60).

The preheater compressor 51 may be connected to a preheater compressor suction duct 52 through which the refrigerant is sucked into the preheater 51 and a preheater compressor discharge duct 53 through which the refrigerant compressed by the preheater 51 is discharged.

The preheat heat exchanger 30 'may be a refrigerant-air heat exchanger in which the refrigerant is heat-exchanged with air, unlike the preheat heat exchanger 30 of the embodiment of the present invention. The installation position of the preheat heat exchanger 30' And may be installed between the cooling coil 20 and the electric heater 32. The preheat heat exchanger 30 'can function as an air-cooled condenser in which the air cooled by the cooling coil 20 condenses the refrigerant compressed in the preheating compressor 51. In the preheat heat exchanger 30 ', a refrigerant passage through which the refrigerant compressed in the preheating compressor 51 passes may be formed, and a preheating compressor discharge passage 53 may be connected to the refrigerant passage. The preheat heat exchanger 30 'may be connected to the preheat expansion mechanism 56 and the preheat heat exchanger-preheat expansion mechanism connection channel 55.

The preheat expansion mechanism 56 may expand the condensed refrigerant in the preheat heat exchanger 30 '. The preheat expansion mechanism 56 may be constituted by a capillary tube or an electronic expansion valve such as an LEV or EEV capable of controlling the opening degree.

The preheating evaporator (60) may be installed outside the casing (6). The preheating evaporator 60 is connected to an outflow pipe 22 through which the cooling water passing through the condenser 14 among the water pipes 21 and 22 connecting the cooling tower T and the condenser 14 is guided to the cooling tower T . The preheating evaporator 60 can be constituted by a refrigerant-water heat exchanger in which the refrigerant expanded by the preheat expansion mechanism 56 is heat-exchanged with the high temperature cooling water exiting from the condenser 14 to evaporate. The preheating evaporator 60 may be formed with a coolant flow passage through which the refrigerant expanded in the preheat expansion mechanism 56 passes and a coolant flow passage through which the high temperature coolant discharged from the condenser 14 passes. The preheating evaporator 60 may be connected to the preheat expansion device 56 and the preheat expansion mechanism-preheat evaporator connection flow path 57 and may be connected to the preheat compressor 51 and the preheat compressor suction flow path 52.

In the air conditioner of this embodiment, when the compressor 11 is driven, the preheating compressor 51 may be driven. The refrigerant compressed in the compressor (11) is condensed in the condenser (14), expanded in the expansion mechanism (16) and evaporated in the cooling coil (20). The refrigerant compressed in the preheating compressor 51 is condensed in the preheat heat exchanger 30 ', expanded in the preheat expansion device 56, and evaporated in the preheat evaporator 60.

The cooling water cooled in the cooling tower (T) absorbs the heat of the refrigerant compressed by the compressor (11) while passing through the condenser (14) and is heated, and then exits to the outflow pipe (22). The high temperature cooling water exiting to the water outlet pipe 22 passes through the preheating evaporator 60 and is radiated to the refrigerant expanded in the preheat expansion mechanism 56 and becomes lower in temperature than before it passes through the preheating evaporator 60.

3 is a view showing the configuration of another embodiment of an air conditioner according to the present invention.

  The air conditioner of the present embodiment further includes an outdoor fan 62 for blowing outdoor air to the preheating evaporator 60 'and the other components and actions other than the preheating evaporator 60' and the outdoor fan 62, The same reference numerals are used and the detailed description thereof will be omitted.

The air conditioner can evaporate the refrigerant using the outdoor air without the preheating evaporator 60 'being connected to the inlet pipe 21 and the outlet pipe 22. The air conditioner may include a water-cooled chiller C, a preheating compressor 51, a preheat heat exchanger 30 'and a preheat expansion mechanism 56, as in the other embodiments of the present invention, and the preheat evaporator 60' May be the same or similar to the other embodiments of the present invention, except that the water supply pipe 22 is not connected to the outflow pipe 22.

In the air conditioner of this embodiment, when the compressor 11 is driven, the preheating compressor 51 may be driven. The refrigerant compressed in the compressor (11) is condensed in the condenser (14), expanded in the expansion mechanism (16) and evaporated in the cooling coil (20). The refrigerant compressed in the preheating compressor 51 is condensed in the preheat heat exchanger 30 ', expanded in the preheat expansion device 56, and heat-exchanged with the outdoor air in the preheat evaporator 60' to be evaporated.

The cooling water cooled in the cooling tower (T) absorbs the heat of the refrigerant compressed in the compressor (11) while passing through the condenser (14), and is then raised to the outflow pipe (22). The high temperature cooling water exiting to the water outlet pipe 22 can be introduced into the cooling tower T without passing through the preheating evaporator 60 '.

2: air inlet port 4: air outlet port
6: casing 11: compressor
14: condenser 16: expansion device
20: cooling coil 21: incoming pipe
22: an outflow pipe 23: a cooling water pump
30: preheat heat exchanger 32: electric heater
34: Humidifier AHU: Air handling unit
C: Water cooled chiller T: Cooling tower

Claims (7)

A casing having an air inlet and an air outlet;
A water-cooled chiller which cools the air sucked into the air inlet by arranging a cooling coil inside the casing, while the cooling water supplied from the cooling tower passes through the condenser and heat-exchanges with the refrigerant;
A preheating heat exchanger installed in the casing and having heat exchanged with the cooling coil for heat exchange with cooling water heat exchanged with refrigerant in the condenser;
And an electric heater installed after the preheat heat exchanger in the air flow direction and heated by the air passing through the preheat heat exchanger. The method according to claim 1,
Wherein the preheat heat exchanger is connected to an outflow pipe through which cooling water having passed through the condenser among the water pipes connecting the cooling tower and the condenser is guided to the cooling tower. The method according to claim 1,
And a cooling water control valve for controlling the cooling water flowing into and out of the preheat heat exchanger. A casing having an air inlet and an air outlet;
A water-cooled chiller which cools the air sucked into the air inlet by arranging a cooling coil inside the casing, while the cooling water supplied from the cooling tower passes through the condenser and heat-exchanges with the refrigerant;
A preheating compressor in which the refrigerant is compressed;
A preheat heat exchanger installed in the casing and having heat exchanged with the cooling coil for heat exchange with the refrigerant compressed in the preheat compressor;
A preheat expansion mechanism for expanding the refrigerant condensed in the preheat heat exchanger;
A preheating evaporator in which the refrigerant expanded in the preheat expansion mechanism is evaporated;
And an electric heater installed after the preheat heat exchanger in the air flow direction and heated by the air passing through the preheat heat exchanger. The method of claim 3,
Wherein the pre-heating evaporator is a water-refrigerant heat exchanger in which the cooling water heat-exchanged with the refrigerant in the condenser evaporates the refrigerant. 6. The method of claim 5,
Wherein the preheating evaporator is connected to an outflow pipe through which cooling water passing through the condenser is guided to the cooling tower among water pipes connecting the cooling tower and the condenser. The method of claim 3,
And an outdoor fan for blowing outdoor air to the preheating evaporator.

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