KR20190087196A - Hybrid air conditioning apparatus and method for controlling the same - Google Patents

Abstract

The present invention relates to a modular hybrid air conditioner and a control method thereof. According to the present invention, the modular hybrid air conditioner comprises: an outdoor unit having a plurality of outdoor unit modules each having a circulation pipe through which a refrigerant is circulated, a natural air conditioning unit which is disposed on the circulation pipe to cool and circulate the refrigerant by the outside air, and a forced cooling unit which consists of a compressor, a condenser, an expansion valve and an evaporator to forcibly cool and circulate the refrigerant; a plurality of indoor units connected to the plurality of outdoor unit modules, respectively, and provided in different indoor spaces; and a controller selecting an indoor unit which requires cooling among the plurality of indoor units based on the room temperature, selecting at least one outdoor unit module among the plurality of outdoor unit modules, and controlling an operation according to the selected indoor unit so as to control the cooling of the indoor space. Thus, fast cooling can be possible.

Description

TECHNICAL FIELD [0001] The present invention relates to a hybrid air-conditioning system and a control method thereof,

The present invention relates to a modular hybrid cooling apparatus and a control method thereof, and more particularly, to a modular hybrid cooling apparatus and a control method thereof, which are capable of selecting and controlling an outdoor unit module, ≪ / RTI >

A typical air conditioner uses evaporation heat that takes heat away from the surroundings when the refrigerant evaporates.

In this conventional cooling apparatus, a gaseous refrigerant compressed at a high pressure in a compressor is condensed into refrigerant in a liquid state in a high pressure state by heat exchange with the outside air while passing through a condenser, and then discharged through a expansion valve or a capillary tube to a low- .

The low-pressure sprayed refrigerant flows into the evaporator, is evaporated by the heat exchange with the indoor air, and then flows into the compressor again. The cycle of the above-described process is circulated. At this time, the air cooled by the evaporation heat, The air is blown to a predetermined space or a target object to be cooled.

That is, such a general cooling apparatus cools a predetermined space or a target object to be cooled by using a refrigerant whose phase change is easy, such as liquefaction and evaporation.

In particular, in the case of a communication base station or a communication vehicle, a large number of wired / wireless communication devices are installed therein. Such communication devices may cause various malfunctions such as contact failure and device malfunction due to frequent heat generation. The stability of operation can be ensured.

Such a cooling apparatus is generally provided with an outdoor unit and an indoor unit having a capacity corresponding to the size of the indoor space when installed. However, depending on the situation, the indoor space may become larger than that at the time of installation, and the temperature of the indoor space may suddenly increase due to an accident or a change in the weather. In this case, it is difficult to cool the indoor space with the outdoor unit or the indoor unit having the predetermined capacity.

Korean Registered Patent No. 10-0773959 (October 31, 2007)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a modular hybrid cooling apparatus and a control method thereof that can overcome the above-described conventional problems.

Another object of the present invention is to provide a modular hybrid cooling apparatus and a control method thereof that can improve cooling efficiency, reduce power consumption, and enable rapid cooling, thereby contributing to equipment protection and indoor cooling load relief .

According to an embodiment of the present invention, there is provided a modular hybrid cooling apparatus comprising: an outdoor unit having a plurality of outdoor modules each having an outdoor blower and an outdoor heat exchanger; A first cooling unit configured to cool the room using a coolant cooled by outside air; at least one second cooling unit configured by a compressor, a condenser, an expansion valve, and an evaporator to forcibly cool the coolant to cool the room; A plurality of indoor units connected to the plurality of outdoor unit modules and installed in different indoor spaces, respectively; The controller selects an indoor unit requiring cooling of the plurality of indoor units based on the room temperature and controls at least one outdoor unit module among the plurality of outdoor unit modules to correspond to the selected indoor unit, And a controller for controlling the controller.

The controller may control the refrigerant supplied to the indoor unit, which does not require cooling, among the plurality of indoor units to be bypassed.

The controller may vary the number of outdoor units selected for operation among the plurality of outdoor units, corresponding to the room temperature.

The controller increases the number of outdoor modules selected and operated among the plurality of outdoor module modules if the difference between the reference temperature and the room temperature desired to be reached through cooling is greater than a preset reference value, If the difference value of the temperature is smaller than the reference value, the number of the outdoor module modules selected and operated among the plurality of outdoor module modules can be reduced.

Wherein the indoor unit selected by the controller and the selected outdoor unit module are arranged in a natural air conditioning mode in which the first cooling unit operates, a forced air conditioning mode in which the at least one second cooling unit operates, Wherein the controller is operable in any one of the hybrid air conditioning mode in which the first indoor unit and the second indoor unit cooperate with each other and the cooling unit operates in the natural air conditioning mode or the hybrid air conditioning mode, All or a part of the outdoor module may be connected to the indoor unit to control the refrigerant cooled in the outdoor unit to be supplied to the selected indoor unit.

According to another embodiment of the present invention, there is provided a modular hybrid cooling apparatus comprising: an outdoor unit having a plurality of outdoor modules each having an outdoor blower and an outdoor heat exchanger; A first cooling unit configured to cool the room using a coolant cooled by outside air; at least one second cooling unit configured by a compressor, a condenser, an expansion valve, and an evaporator to forcibly cool the coolant to cool the room; A plurality of indoor units connected to the plurality of outdoor unit modules and installed in different indoor spaces, respectively; And a controller for controlling the cooling of the indoor space by selecting at least one outdoor unit module among the plurality of outdoor unit modules based on the outgoing temperature of the outdoor unit and controlling the operation thereof.

The controller may vary the number of outdoor units selected for operation among the plurality of outdoor units in response to the outgoing water temperature.

Wherein the controller increases the number of outdoor module modules selected and operated among the plurality of outdoor module modules if the difference between the outgoing water temperature and the reference outgoing water temperature is greater than a preset reference value, Is smaller than the reference value, it is possible to reduce the number of the outdoor module modules selected and operated among the plurality of outdoor module modules.

According to another embodiment of the present invention, there is provided a method of controlling a modular hybrid cooling apparatus including a plurality of outdoor units having an outdoor fan and an outdoor heat exchanger, A first cooling unit that circulates the refrigerant cooled by the outside air to cool the room, at least one second cooling unit that is composed of a compressor, a condenser, an expansion valve and an evaporator, forcibly cools the refrigerant to cool the room A first step of measuring an indoor temperature of the indoor space in which the indoor unit is located or an outgoing temperature of the outdoor unit, the outdoor unit having an indoor unit connected to the plurality of outdoor unit modules; A second step of selecting at least one outdoor unit module among the plurality of outdoor unit modules corresponding to the measured temperature value; At least one outdoor unit module selected and a natural air conditioning mode in which the first cooling unit operates, the forced air conditioning mode in which the at least one second cooling unit operates, the first cooling unit and the at least one second cooling And a third step of cooling the indoor space by operating the indoor unit in any one of the hybrid air conditioning modes in which the units operate together.

In the third step, when the selected at least one outdoor module and the indoor unit operate in the natural air conditioning mode or the combined air-conditioning mode, all or some of the remaining non-selected outdoor module modules are also connected to the indoor unit And to provide the refrigerant cooled by the indoor unit to the indoor unit.

According to the present invention, an outdoor unit having a plurality of outdoor unit modules and indoor units arranged in a plurality of indoor spaces, respectively, are selected and controlled when necessary to cool the specific indoor space, Can be increased, power consumption can be reduced, and quick cooling can be performed, which contributes to protection of equipment and elimination of an indoor cooling load.

1 is a schematic view of a modular hybrid cooling apparatus according to a first embodiment of the present invention,
2 is an internal schematic view of each of a plurality of outdoor module units constituting the outdoor unit of FIG. 1,
Fig. 3 is an internal schematic view of the indoor unit of Fig. 1,
4 is a schematic view of a modular hybrid cooling apparatus according to a second embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings without intending to intend to provide a thorough understanding of the present invention to a person having ordinary skill in the art to which the present invention belongs.

FIG. 1 is a schematic view of a modular hybrid cooling apparatus according to a first embodiment of the present invention, FIG. 2 is an internal schematic view of an outdoor unit module constituting the outdoor unit of FIG. 1, and FIG. 3 is an internal schematic view of the indoor unit of FIG. 1.

1 to 3, the modular hybrid cooling apparatus 500 according to the first embodiment of the present invention includes an outdoor unit 100, a plurality of indoor units 200, and a controller 300 . Here, water or another refrigerant may be used as the refrigerant circulating between the outdoor unit 100 and the indoor unit 200.

The outdoor unit (100) includes a plurality of outdoor unit modules (150). As shown in FIG. 2, each of the plurality of outdoor module modules 150 includes a circulation pipe 110, an outdoor heat exchanger 120, and an outdoor fan 130 through which refrigerant is circulated. The structures of the circulation pipe 110, the outdoor heat exchanger 120, and the outdoor air blower 130 and their connection structures are well known to those skilled in the art.

Each of the plurality of outdoor modules 150 constituting the outdoor unit 100 may include a plurality of the outdoor heat exchangers 120 or the outdoor fans 130 in order to increase utilization of the outdoor air and increase the efficiency of outdoor heat exchange It is possible.

3, each of the plurality of indoor units 200 includes a circulation pipe 210 through which a refrigerant is circulated, a first cooling unit 220, at least one second cooling unit 230 and 240, A valve 225 is provided.

The circulation pipe 210 is a pipe through which refrigerant is circulated for indoor cooling. The connection structure of the circulation pipe 210 is well known to those of ordinary skill in the art.

The first cooling unit 220 circulates the refrigerant cooled by the outside air to cool the room. For example, when the temperature of the outside air is low as in the winter season, the indoor unit is cooled by circulating the refrigerant cooled by the outside air. Therefore, when the refrigerant cooled by the outside air has a temperature higher than the room temperature, the refrigerant does not operate or the refrigerant is bypassed and discharged to the outside.

The first cooling unit 220 is a unit for cooling the room using outside air. The first cooling unit 220 includes a room air blower 222, a refrigerant circulation pipe 210, A second indoor heat exchanger 226 for secondarily heat-exchanging the refrigerant passing through the first indoor heat exchanger 224 with the condensers 234 and 244, a second indoor heat exchanger 224 for performing a second heat exchange with the refrigerant passing through the first indoor heat exchanger 224, A bypass pipe 228 for circulating the refrigerant cooled by the outside air to the second indoor heat exchanger 226 without passing through the first indoor heat exchanger 224 and a second bypass pipe 228 for bypassing the circulation pipe 210 and the bypass pipe 228 And a bypass valve 225 installed in the bypass valve 225, respectively.

The first bypass valve V1 of the bypass valve 225 is opened during the operation of the first cooling unit 220 so that the refrigerant cooled by the outside air is circulated to the first indoor heat exchanger 224 side The second bypass valve V2 is opened when the first cooling unit 220 does not operate and the refrigerant cooled by the outside air flows through the first indoor heat exchanger 224 without passing through the first indoor heat exchanger 224, (226). The first bypass valve V1 is opened and the second bypass valve V2 is closed so that the refrigerant discharged from the first cooling unit The first bypass valve V1 is closed and the second bypass valve V2 is closed when the indoor cooling can not be performed using outdoor air as in the summer. (V2) is opened.

The bypass valve 225, the indoor heat exchangers 224 and 226 and the indoor air blower 222 may be required in operation of the second cooling units 230 and 240. However, for the sake of convenience, the first cooling unit 220, .

The at least one second cooling unit 230 and 240 includes compressors 232 and 242, condensers 234 and 244 that heat-exchange with the second indoor heat exchanger 226, expansion valves 236 and 246, and evaporators 238 and 248 . The second cooling unit has a mechanism of compressors 232 and 242, condensers 234 and 244, expansion valves 236 and 246 and evaporators 238 and 248 so as to forcibly cool the refrigerant to cool the room. The plurality of second cooling units 230 and 240 may be installed in the first indoor heat exchanger 224 and the second indoor heat exchanger 226, And heat exchange occurs. FIG. 3 shows a case where two of the second cooling units 230 and 240 are provided.

The at least one second cooling unit 230 or 240 operates when it is impossible or difficult to cool the indoor space by using the first cooling unit 220, i.e., outside air. That is, the refrigerant is cooled using the second cooling units 230 and 240 to cool the indoor space. Operation of the second cooling units 230 and 240 composed of the compressors 232 and 242, the condensers 234 and 244, the expansion valves 236 and 246 and the evaporators 238 and 248 is well known to those of ordinary skill in the art and will not be described further.

The indoor unit 200 includes a natural air conditioning mode for cooling the room using only the first cooling unit 220 using outside air, a forced air conditioning mode for cooling the room using the at least one second cooling unit 230 and 240, 1 cooling unit 220 and the at least one second cooling unit 230 and 240 operate together to operate the hybrid air-conditioning mode in which the indoor air is cooled.

Each of the plurality of indoor units 200 is installed in a different indoor space. A plurality of indoor units 200 are installed in a plurality of indoor spaces in a manner that one indoor unit is installed in one indoor space.

Each of the plurality of indoor units 200 is connected to the integrated piping 310 through the circulation piping 210 in parallel and the plurality of outdoor modules 150 are also connected to the indoor units 200 through the circulation piping 110, And is connected in parallel with the integrated piping 310. At least one circulation pump 312 controlled by the controller 300 may be disposed on the integrated piping 310 and a refrigerant tank 315 for supplying refrigerant may be separately disposed.

Each of the plurality of indoor units 200 includes a bypass structure 225 and 228 that can bypass the refrigerant provided through the outdoor unit 100 when the cooling is unnecessary. That is, the bypass piping 228 and the bypass valve 225 are connected to the indoor unit 200 through the outdoor unit 100 when the first cooling unit 220 does not operate and when the indoor units 200 do not require cooling. The function of bypassing the provided refrigerant is also performed. As another example, each of the plurality of indoor units 200 may include a separate shut-off valve (not shown) controlled by the controller 300 when cooling is not required, so that the refrigerant supply through the integrated piping 310 is blocked .

When any one of the plurality of outdoor modules 150 of the outdoor unit 100 operates, the refrigerant cooled through the outdoor unit module 150 may be provided to all of the plurality of indoor units 200 It is possible to provide the air to one selected indoor unit 200. Also, the refrigerant provided to any one of the indoor units 200 may be provided by all the outdoor modules 150 constituting the outdoor unit 100 or may be provided by the specific outdoor unit module 150 . The refrigerant circulation of the outdoor unit module 150 operated with the indoor unit 200 operating in this case is performed through the control of the controller 300.

The controller 300 is divided into an indoor unit controller installed in each indoor unit 200 and a main controller installed in the outdoor unit 100 or an outdoor unit controller installed in each outdoor unit module 150 and a main controller for controlling the indoor unit controller and the outdoor unit controller .

The controller 300 selects an indoor unit 200 requiring cooling of the plurality of indoor units 200 based on the indoor temperature of the indoor space and selects an outdoor unit module 150 corresponding to the selected indoor unit 200 . That is, at least one outdoor unit module 150 among the plurality of outdoor unit modules 150 is selected, and the operation is controlled corresponding to the selected indoor unit, thereby cooling the indoor space.

For example, when cooling for a specific indoor space is required, an indoor unit 200 of a specific indoor space is selected, and at least one outdoor unit module 150 of a plurality of outdoor unit modules 150 is selected from the outdoor unit 100 And the operation is controlled by matching each other. The selection of the at least one outdoor module 150 may be performed by various methods well known to those skilled in the art such as a method of turning on / off the power of the outdoor module 150, .

The controller 300 receives the temperature signal of the indoor temperature sensor provided in each of the indoor spaces and confirms the indoor temperature. If the indoor temperature is higher than the predetermined reference indoor temperature, the controller 300 selects the indoor unit 200 in the indoor space, Thereby performing the cooling operation. In this case, the outdoor unit 100 selects the number of the outdoor unit modules 150 required for cooling the corresponding indoor space, and selects the corresponding number of the outdoor unit modules 150 in the outdoor unit 100 to perform the cooling operation .

In the case of the indoor unit 200 that does not require cooling, the indoor blower 222 can be operated normally so that indoor air is not stagnated. In the case of the indoor unit 200 which does not require cooling, the refrigerant supplied through the outdoor unit module 150 is bypassed or blocked.

The controller 300 sets the maximum number of the outdoor modules 150 that can be selected to correspond to one indoor unit 200 and sets the number of the outdoor modules 150 selected according to the indoor temperature within the maximum number It is possible to do. Generally, it is a common practice to select a larger number of outdoor module modules if fast cooling is desired. Especially, in the natural air conditioning mode, the faster the number of outdoor modules is, the faster the cooling can be performed. It is also possible to reduce the number of outdoor modules in order to prevent the indoor space from being overcooled.

The controller 300 may vary the number of the outdoor units 150 selected for operation among the plurality of outdoor units 150 corresponding to the room temperature. If the difference between the indoor temperature and the reference temperature is greater than a preset reference value based on a reference temperature to be reached through cooling, the number of the outdoor modules 150 selected and operated among the plurality of outdoor modules 150 is increased And if the difference between the room temperature and the reference temperature is smaller than the reference value, the number of outdoor module modules selected and operated among the plurality of outdoor module modules 150 is reduced, .

The indoor unit 200 and the selected outdoor module 150 selected by the controller 300 operate in one of the natural air conditioning mode, the forced air conditioning mode, and the hybrid air conditioning mode. Here, the increase or decrease in the number of the outdoor module 150 may be effective in the natural air conditioning mode or the hybrid air conditioning mode.

The controller 300 operates all or a part of the outdoor blower 130 which is a component of the plurality of outdoor module modules 150 in the outdoor unit 100 to sufficiently utilize the outdoor unit 100 in the natural air conditioning mode and the hybrid air conditioning mode Can be done. For example, when the selected indoor unit 200 operates in the natural air conditioning mode, the remaining outdoor unit modules 150 are used together with the remaining outdoor unit modules 150 in addition to the selected outdoor unit module 150, It is possible to control so as to fully utilize it. Also, when the selected indoor unit 200 operates in the hybrid air conditioning mode, it is possible to control the remaining outdoor units or all or some of the outdoor units 150 to operate together so that the outdoor unit can be fully utilized.

The controller 300 controls only the outdoor blower 130 of the selected outdoor module 150 to operate only in the forced air conditioning mode and the outdoor fan 130 of the remaining outdoor modules 150 not selected Thereby preventing unnecessary use of outside air and controlling power consumption of the outdoor blower.

When the controller 300 selects at least one of the plurality of outdoor module 150 in the outdoor unit 100, the controller 300 may operate only for a specific outdoor module 150 for a long period of time, The order is determined and sequentially selected.

In addition, when a plurality of the circulation pumps 312 are provided in parallel connection, the circulation pump 312 is alternately operated, so that only the specific circulation pump can be operated for a long time or stopped.

4 is a schematic view of a modular hybrid cooling apparatus according to a second embodiment of the present invention.

As shown in FIG. 4, the modular hybrid cooling apparatus 500 according to the second embodiment of the present invention includes an outdoor unit 100, a plurality of indoor units 200, and a controller 300.

The structure of the outdoor unit 100 and the structure of the plurality of indoor units 200 are the same as the present invention except that the circulation pipe 310 is further provided with a temperature sensor 250 for measuring the outflow temperature of the outdoor unit 100. [ The description of which is omitted.

Unlike the first embodiment of the present invention, the controller 300 controls the cooling based on the outflow temperature of the outdoor unit 100 measured through the temperature sensor 350. The outgoing temperature may mean the temperature of the refrigerant supplied to the indoor unit 200 through the integrated piping 310 in the outdoor unit 100. When the outflow temperature is used as a reference, it may be useful when the indoor unit 200 operates in the natural air conditioning mode.

The controller 300 can select the indoor unit 200 requiring cooling of the plurality of indoor units 200 based on the indoor temperature of the indoor space. When the indoor unit 200 is not selected, all the indoor spaces where the entire indoor units 200 are located are cooled.

The controller 300 determines the outflow temperature of the outdoor unit 100 and selects the number of the outdoor unit modules 150 required for cooling in the outdoor unit 100 so as to be maintained lower than a predetermined reference temperature, The number of the outdoor modules 150 is selected and the cooling operation is performed.

The controller 300 can cause the indoor blower 222 to operate normally so that indoor air is not stagnated in the case of the indoor unit 200 that does not require cooling. In the case of the indoor unit 200 which does not require cooling, the refrigerant supplied from the outside is bypassed or blocked.

The controller 300 can set the maximum number of selectable outdoor module 150 and set the number of the outdoor module 150 selected according to the outgoing temperature within the maximum number. Generally, when rapid cooling is desired, it is common to select a larger number of outdoor module 150.

The controller 300 may vary the number of the outdoor units 150 selected for the operation among the plurality of outdoor units 150 corresponding to the outflow temperature. (150) that is selected and operated among the plurality of outdoor module modules (150) if the difference between the outgoing temperature and the reference outgoing temperature is greater than a predetermined reference value based on a reference outgoing water temperature to be reached through cooling And the number of the outdoor module modules selected and operated among the plurality of outdoor module modules 150 is decreased if the difference between the outgoing water temperature and the reference outgoing water temperature is smaller than the reference value, Cooling can be performed.

Here, the number of outdoor modules 150 can be increased as the number of indoor units (or the number of indoor spaces desired to be cooled) operating among the plurality of indoor units 200 is greater.

When the indoor unit 200 and the selected outdoor unit module 150 operate in the natural air conditioning mode, the controller 300 can fully utilize the outdoor air by operating all of the outdoor fans 130 in the outdoor unit 100 , And it is also possible to partially operate only partially. For example, when the selected indoor unit 200 operates in the natural air conditioning mode, only the entire or a part of all the outdoor units 150 except for the selected outdoor unit module 150 can be operated in the natural air conditioning mode, It is possible to save power consumption.

In addition, when the indoor unit 200 operates in the hybrid air conditioning mode, all of the outdoor blowers 130 in the outdoor unit 100 can be operated to fully utilize the outdoor air. For example, when the selected outdoor module 150 operates in the hybrid air conditioning mode, it is possible to control the remaining outdoor modules 150 or some of the outdoor modules 150 to be operated so as to utilize the outside air sufficiently Do.

When the indoor unit 200 operates in the forced air conditioning mode, the controller 300 operates only the outdoor blower 120 of the selected outdoor module 150, The blower 120 is not operated so as to prevent unnecessary use of outside air and to control the power consumption of the outdoor blower.

When the controller 300 selects at least one of the plurality of outdoor module 150 in the outdoor unit 100, the controller 300 may operate only for a specific outdoor module 150 for a long period of time, In order to prevent such a problem, it is sequentially selected and operated.

In addition, when a plurality of the circulation pumps 312 are provided in parallel connection, the circulation pump 312 is alternately operated, so that only the specific circulation pump can be operated for a long time or stopped.

As described above, according to the present invention, there is provided an outdoor unit having a plurality of outdoor unit modules and indoor units disposed in the plurality of indoor spaces, respectively, to select and operate an outdoor unit module, The cooling efficiency can be increased, the power consumption can be reduced, and quick cooling can be performed, which is advantageous in protecting the equipment and solving the indoor cooling load.

The foregoing description of the embodiments is merely illustrative of the present invention with reference to the drawings for a more thorough understanding of the present invention, and thus should not be construed as limiting the present invention. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the basic principles of the present invention.

100: outdoor unit 150: outdoor unit module
200: indoor unit 300: controller

Claims (10)

An outdoor unit having a plurality of outdoor modules each having an outdoor blower and an outdoor heat exchanger;
A first cooling unit configured to cool the room using a coolant cooled by outside air; at least one second cooling unit configured by a compressor, a condenser, an expansion valve, and an evaporator to forcibly cool the coolant to cool the room; A plurality of indoor units connected to the plurality of outdoor unit modules and installed in different indoor spaces, respectively;
The controller selects an indoor unit requiring cooling of the plurality of indoor units based on the room temperature and controls at least one outdoor unit module among the plurality of outdoor unit modules to correspond to the selected indoor unit, And a controller for controlling the air conditioning unit. The method according to claim 1,
Wherein the controller controls the refrigerant supplied to the indoor units that do not require cooling of the plurality of indoor units to be bypassed. The method according to claim 1,
Wherein the controller changes the number of outdoor units selected for operation among the plurality of outdoor units in response to the room temperature. The method of claim 3,
The controller increases the number of outdoor modules selected and operated among the plurality of outdoor module modules if the difference between the reference temperature and the room temperature desired to be reached through cooling is greater than a preset reference value, And decreasing the number of the outdoor module modules selected and operated among the plurality of outdoor module modules if the temperature difference value is smaller than the reference value. The method according to claim 1,
Wherein the indoor unit selected by the controller and the selected outdoor unit module are arranged in a natural air conditioning mode in which the first cooling unit operates, a forced air conditioning mode in which the at least one second cooling unit operates, And the combined air conditioning mode in which the two cooling units operate together,
When the selected indoor unit and the selected outdoor unit module operate in the natural air conditioning mode or the hybrid air conditioning mode, all or some of the non-selected outdoor unit modules are connected to the indoor unit, And to supply the indoor air to the indoor unit. An outdoor unit having a plurality of outdoor modules each having an outdoor blower and an outdoor heat exchanger;
A first cooling unit configured to cool the room using a coolant cooled by outside air; at least one second cooling unit configured by a compressor, a condenser, an expansion valve, and an evaporator to forcibly cool the coolant to cool the room; A plurality of indoor units connected to the plurality of outdoor unit modules and installed in different indoor spaces, respectively;
And a controller for controlling the cooling of the indoor space by selecting at least one outdoor unit module among the plurality of outdoor unit modules based on the outgoing temperature of the outdoor unit and controlling the operation of the outdoor unit module. The method of claim 6,
Wherein the controller changes the number of outdoor units selected for operation among the plurality of outdoor units in response to the outgoing water temperature. The method of claim 7,
Wherein the controller increases the number of outdoor module modules selected and operated among the plurality of outdoor module modules if the difference between the outgoing water temperature and the reference outgoing water temperature is greater than a preset reference value, Is smaller than the reference value, the number of the outdoor module modules selected and operated among the plurality of outdoor module modules is reduced. An outdoor unit having a plurality of outdoor unit modules each having an outdoor blower and an outdoor heat exchanger; a first cooling unit for circulating the refrigerant cooled by the outside air to cool the room; a first cooling unit comprising a compressor, a condenser, an expansion valve and an evaporator, And at least one second cooling unit for cooling the room by forcibly cooling the indoor air, and an indoor unit connected to the plurality of outdoor unit modules, the control method comprising the steps of:
A first step of measuring the indoor temperature of the indoor space in which the indoor unit is located or the outgoing temperature of the outdoor unit;
A second step of selecting at least one outdoor unit module among the plurality of outdoor unit modules corresponding to the measured temperature value;
At least one outdoor unit module selected and a natural air conditioning mode in which the first cooling unit operates, the forced air conditioning mode in which the at least one second cooling unit operates, the first cooling unit and the at least one second cooling And a third step of cooling the indoor space by operating one of the hybrid air conditioning modes in which the units operate together. The method of claim 9,
In the third step, when the selected at least one outdoor module and the indoor unit operate in the natural air conditioning mode or the combined air-conditioning mode, all or some of the remaining non-selected outdoor module modules are also connected to the indoor unit Wherein the control unit controls the indoor unit to provide the refrigerant cooled by the outdoor unit to the indoor unit.

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