KR101969228B1 - Air control system - Google Patents

Abstract

According to the outside air control system according to an embodiment of the present invention, in the outside air control system for adjusting the target space to a set temperature and humidity, the outside air is introduced and flows, the first air is introduced into the target space discharged to the target space; A first case providing one space; A second case into which predetermined air is introduced and flowed, and providing a second space through which the introduced air is discharged to the outside; A dehumidifying unit disposed on the first space and the second space to absorb moisture contained in the outside air introduced into the first case and then discharge the absorbed moisture into the air flowing in the second space; When the current flows in the first direction, the first part, which is a part, absorbs heat of outside air flowing in the first space, and the second part, which is a part different from the first part, emits heat, and the current is a second part. Direction when the first portion is to discharge heat to the outside air flowing in the first space and the second portion is a temperature control unit for absorbing heat; And a first heat exchanger configured to exchange heat with the air on the second portion and the second space by using a fluid that is heat exchanged with the air on the second portion and the second space. When the current flows to the temperature control unit in the first direction, the heat emitted from the second portion is received and transfers heat to the air flowing in the second space, the current is supplied to the temperature control unit in the second When flowing in the direction can receive heat from the air flowing in the second space can be transferred to the second portion.

Description

Air control system {Air control system}

The present invention relates to an outside air conditioning system, and more particularly to an outside air conditioning system for controlling supply of ventilation and humidity required for a building without using a refrigerant required for heating and cooling by using a thermoelectric element and a dehumidification wheel.

People feel great discomfort if the temperature and humidity of the outside air deviate from certain standards. In order to solve this problem, generally, an air conditioning system for converting outside air into temperature and humidity at which people feel comfortable is used.

There are various types of air conditioning systems depending on the components or the principle of operation. Among them, one of the air conditioning systems that are popularly used is a system that controls the humidity of the outside air with a dehumidifying agent and a temperature of the outside air with a temperature control device.

Here, a temperature control device including an evaporator and a condenser is widely used as the temperature control device. However, the temperature control device including the evaporator and the condenser has a problem that the size of the system increases due to the additional pipe installation. In order to solve this problem, a method of using a thermoelectric element that can control the temperature of air even with a small structure and a small size is being studied.

However, in order to control the temperature of the outside air, the thermoelectric element absorbs heat on one side, and absorbs heat on one side, and emits heat on the other side. The heat change generated on one side is used to control the temperature of the outside air, but the heat change generated on the other side is thrown into the atmospheric state. This waste heat has a problem of expressing the low efficiency of the air conditioning system.

An object of the present invention is to provide an outside air control system that can utilize the waste heat generated in the thermoelectric element in order to solve the above problems.

The problem to be solved by the present invention is not limited to the above-described problem, the objects that are not mentioned will be clearly understood by those skilled in the art from the present specification and the accompanying drawings. .

According to the outside air control system according to an embodiment of the present invention, in the outside air control system for adjusting the target space to a set temperature and humidity, the outside air is introduced and flows, the first air is introduced into the target space discharged to the target space; A first case providing one space; A second case into which predetermined air is introduced and flowed, and providing a second space through which the introduced air is discharged to the outside; A dehumidifying unit disposed on the first space and the second space to absorb moisture contained in the outside air introduced into the first case and then discharge the absorbed moisture into the air flowing in the second space; When the current flows in the first direction, the first part, which is a part, absorbs heat of outside air flowing in the first space, and the second part, which is a part different from the first part, emits heat, and the current is a second part. Direction when the first portion is to discharge heat to the outside air flowing in the first space and the second portion is a temperature control unit for absorbing heat; And a first heat exchanger configured to exchange heat with the air on the second portion and the second space by using a fluid that is heat exchanged with the air on the second portion and the second space. When the current flows to the temperature control unit in the first direction, the heat emitted from the second portion is received and transfers heat to the air flowing in the second space, the current is supplied to the temperature control unit in the second When flowing in the direction can receive heat from the air flowing in the second space can be transferred to the second portion. The first heat exchange part may include a pipe through which the fluid flows and a heating part that heats the fluid flowing on the pipe.

In addition, when the humidity of the outside air introduced into the first case is higher than a predetermined humidity, current flows in the first direction to the temperature control unit, and the pipe is heat that the fluid is discharged from the second portion. Receiving the guide to guide the fluid to transfer heat to the air flowing on the second case, the dehumidifying unit is heated by the air received the heat, it can discharge the moisture to the air.

In addition, when the humidity of the outside air flowing into the first case is higher than a predetermined humidity, the heating unit is to absorb heat emitted from the second portion to transfer heat to the air flowing in the second space. Heating the fluid flowing, and the pipe guides the fluid so that the fluid receives heat emitted from the second portion and the heating part and transfers heat to the air flowing in the second space, The dehumidifying unit may be heated by the air, which has received heat, to discharge moisture into the air.

In addition, when the humidity of the outside air introduced into the first case is lower than a preset humidity, and the temperature of the outside air introduced into the first case is higher than a preset temperature, the temperature adjusting part may include a current in a first direction. Flows to the pipe, the fluid receives heat released from the second portion, flows into the second case, and transfers heat to the air discharged from the second case without passing through the dehumidifying unit, The fluid can be guided.

The apparatus may further include a second heat exchanger configured to exchange heat between the outside air flowing in the first space and the air flowing in the second space.

The second heat exchanger may exchange heat between the air discharged from the dehumidifying unit in the first space and flown to the temperature controller and the air flowing into the dehumidifying unit in the second space.

In addition, the humidity of the outside air flowing into the first case is lower than a preset humidity, the temperature of the outside air flowing into the first case is lower than a preset temperature, the temperature of the second portion is the second heat exchange unit When the temperature is higher than the temperature of the air discharged from the heat exchanger, the current flows in the second direction to the temperature control unit, and the pipe receives heat from the fluid and the heat is transferred to the second part. The fluid may be guided to deliver.

In addition, the humidity of the outside air flowing into the first case is lower than a preset humidity, the temperature of the outside air flowing into the first case is lower than a preset temperature, the temperature of the second portion is the second heat exchange unit When the temperature is lower than the temperature of the air discharged by the heat exchanger, the current flows in the second direction to the temperature control unit, and the pipe receives heat from the air in which the fluid is cooled in the second heat exchange unit. The fluid can be guided to transfer heat to the second portion.

According to the air conditioning system according to the present invention, the configuration of the system can be simplified.

In addition, according to the air conditioning system of the present invention, the size of the system can be reduced, thereby accelerating the commercialization step.

In addition, according to the present invention, it is possible to prevent the function of the dehumidifying agent from being lowered due to the high temperature.

In addition, according to the present invention, the heating capacity and the cooling capacity can be precisely controlled.

In addition, no freezer and boiler are required, making the system easy to manufacture, install and operate.

In addition, according to the present invention, a refrigerant is not used and it is environmentally friendly.

In addition, according to the present invention, the efficiency can be increased.

In addition, according to the present invention, energy can be saved.

The effects of the present invention are not limited to the above-described effects, and effects that are not mentioned will be clearly understood by those skilled in the art from the present specification and the accompanying drawings.

1 is an overall perspective view of the outside air conditioning system according to an embodiment of the present invention
2 is a cross-sectional view taken along line X-X 'of FIG.
3 is a view of the temperature control unit provided in the outside air conditioning system according to an embodiment of the present invention
Figure 4 is an operation algorithm of the outside air conditioning system according to an embodiment of the present invention
5 is a graph illustrating an area in an operation algorithm of an outside air conditioning system according to an embodiment of the present invention.
6 is a view for explaining a process that is operated when the outside air flowing into the outside air conditioning system according to an embodiment of the present invention at high temperature and high humidity
7 is a view for explaining a process that is operated when the outside air flowing into the outside air control system according to an embodiment of the present invention at high temperature drying
8 is a view for explaining a process that is operated when the outside air introduced to the outside air conditioning system according to an embodiment of the present invention is cryogenic dry
9 is a view for explaining another process operated when the outside air introduced into the outside air conditioning system according to an embodiment of the present invention is dried at low temperature.

Hereinafter, with reference to the drawings will be described in detail a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention may deteriorate other inventions or the present invention by adding, modifying, or deleting other elements within the scope of the same idea. Other embodiments that fall within the scope of the inventive concept may be readily proposed, but they will also be included within the scope of the inventive concept.

In addition, the components with the same functions within the scope of the same idea shown in the drawings of each embodiment will be described using the same reference numerals.

In the present specification, when it is determined that a detailed description of a known configuration or function related to the present invention may obscure the gist of the present invention, a detailed description thereof will be omitted.

1 is an overall perspective view of an outside air conditioning system according to an embodiment of the present invention.

Referring to FIG. 1, in an outside air control system for controlling a target space according to an embodiment of the present invention to a set temperature and humidity, the outside air conditioning system is flowed by outside air, and the outside air introduced into the target air flows. A first case 100 for providing a first space (S100) discharged to the space, a second case for providing a second space (S200) in which a predetermined air is introduced and flows, the introduced air is discharged to the outside 200 may be included.

Here, the target space may be a space to adjust the temperature and humidity.

In addition, the predetermined air may be outside air or may be air in the target space.

In addition, the outside air may be air in a space other than the target space.

Hereinafter, air may refer to air introduced into the second case 200.

The first case 100 includes a first main body 110 providing the first space S100, an outside air inflow unit 120 providing a passage through which outside air flows into the first space S100, and the The outdoor air discharge unit 130 may provide a passage through which the outdoor air on the first space S100 is discharged to the target space.

In addition, the second case 200 has a second main body 210 for providing the second space (S200), the air inlet 220 for providing a passage through which air is introduced into the second space (S200). The air discharge part 230 through which the air on the second space S200 is discharged to the outside and the air bypass unit 240 through which the air on the second space S200 is discharged to the outside may be provided. .

The first case 100 and the second case 200 may provide a space in which components necessary for operating the air conditioning system according to an embodiment of the present invention are arranged.

Hereinafter, technical features of the above components will be described in detail.

2 is a cross-sectional view taken along line X-X 'of FIG. 1, and FIG. 3 is a view of a temperature control unit 400 provided to an outside air conditioning system according to an embodiment of the present invention.

Referring to FIG. 2, the outside air control system according to an embodiment of the present invention includes outdoor air flowing into the first case 100 and disposed on the first space S100 and the second space S200. After absorbing the moisture, the dehumidifying unit 300 for discharging the absorbed moisture to the air flowing in the second space (S200), when the current flows in the first direction, the first portion is a portion Absorbs the heat of the outside air flowing in the space (S100) and the second portion, which is a part different from the first portion, emits heat, and when the current flows in the second direction, the first portion is the first space (S100). The heat is discharged to outside air flowing in the above) and the second portion absorbs heat using the temperature control part 400 and the fluid that is heat exchanged with the air on the second portion and the second space (S200). Under heat exchange with the second portion and the air on the second space (S200). The may include including a first heat exchange unit 500.

The apparatus may further include a second heat exchanger 600 for exchanging heat between the air flowing in the first space S100 and the air flowing in the second space S200.

In addition, it may further include a fan for generating a flow of the air flowing on the first case 100 and the air flowing on the second case 200.

The apparatus may further include a sensor unit for providing information necessary for controlling the outside air conditioning system.

In addition, the damper unit for changing the flow of air flowing in the second space (S200) may be further included.

The control unit may further include a control unit for controlling the dehumidifying unit 300, the first heat exchange unit 500, the second heat exchange unit 600, the fan, the sensor unit, and the damper unit.

The dehumidifying unit 300 may absorb moisture contained in the air flowing through the dehumidifying unit 300 (here, the meaning of air may refer to commonly used air).

For example, the dehumidifying unit 300 may be a solid dehumidifying agent.

In addition, the dehumidifying unit 300 may be made of a silica gel and the like wound alternately flat ceramic paper and corrugated paper. However, the present invention is not limited thereto and may include all dehumidifying agents that can be used at a level obvious to those skilled in the art.

The dehumidifier 300 may exist on the first space S100 and the second space S200.

The dehumidifying unit 300 may perform a dehumidifying process of absorbing moisture present in the outside air flowing in the first space S100.

In addition, the dehumidifying unit 300 may discharge moisture absorbed in the first space S100 as the air flowing in the second space S200.

To this end, the dehumidifying unit 300 may be rotatably disposed on the first space S100 and the second space S200.

For example, the dehumidifying part 300 may be disposed between the air discharge part 230 and the air bypass part 240.

Referring to FIG. 3, the temperature controller 400 may include a thermoelectric element 410 and a heat pipe 460.

The thermoelectric element 410 may include a first surface 411 and a second surface 412 that generate a thermal difference when a current flows through the thermoelectric element 410.

By using the thermoelectric element 410 it is possible to reduce the volume of the air conditioning system.

In addition, when the thermoelectric element 410 is used, the system reaction speed is fast, and thus convenience may be improved in terms of usability of the air conditioning system.

However, the temperature control unit 400 is not limited to having the thermoelectric element 410, and various modifications can be made at a level apparent to those skilled in the art.

The heat pipe 460 may be formed to extend from the first surface 411.

The heat pipe 460 may receive heat from the first surface 411 or transfer heat to the first surface 411.

Hereinafter, the first surface 411 and the heat pipe 460 may be referred to as a first portion.

In addition, the second surface 412 may be referred to as a second portion.

The first portion may be disposed on the first space S100 and may be heat exchanged with the outside air flowing on the first space S100.

The second portion may be disposed outside the first space S100 and may not be heat exchanged with the outside air flowing on the first space S100.

The second portion may be heat exchanged with the fluid flowing on the first heat exchanger 500.

The second portion may be heat exchanged with air flowing in the second space S200 by a fluid flowing on the first heat exchange part 500.

When a current flows in the first direction in the temperature controller 400, the first portion may be cooled, and the second portion may be heated as the first portion is cooled.

In addition, when a current flows in the second direction, the first portion is heated, and the second portion may be cooled as the first portion is heated.

For example, the temperature control part 400 may be disposed between the second heat exchange part 600 and the outside air discharge part 130.

The first heat exchange part 500 is a pipe through which a fluid that exchanges heat with the air on the second portion and the second space S200 flows, and a control valve that controls the flow rate and / or flow of the fluid flowing in the pipe. And a heating unit 530 for heating the fluid.

Piping is the water jacket 511, the heat exchange pipe 512, the first moving pipe 513, the second moving pipe 514, the third moving pipe 515, the first connection pipe 516 through which the fluid flows. And a second connection pipe 517.

In addition, the pipe may be provided with a pump (not shown) to allow the fluid to flow.

In one example, the fluid may be water. Since water has a higher specific heat than air, the waste heat of the second portion of the temperature controller 400 may be effectively treated.

In addition, by effectively treating the waste heat of the second portion, it is possible to improve the efficiency of the thermoelectric element 410.

The fluid may transfer heat to the air flowing in the second space S200 by receiving heat emitted from the second portion when a current flows in the first direction to the temperature controller 400.

In addition, when the current flows in the second direction to the temperature controller 400, the fluid may receive heat from the air flowing on the second space S200 and transfer heat to the second portion.

Referring to FIG. 3, the water jacket 511 may provide a space in which the fluid can be accommodated.

The water jacket 511 may surround the second portion.

The fluid may be introduced onto the water jacket 511 to provide a space in which the fluid is heat exchanged with the second portion.

The heat exchange pipe 512 may exchange heat with the air in which the fluid flows on the second space S200.

The heat exchange pipe 512 may be disposed on the second space S200.

For example, the heat exchange pipe 512 may be disposed between the dehumidifying unit 300 and the second heat exchange unit 600.

In addition, the heat exchange pipe 512 may be disposed between the air bypass unit 240 and the second heat exchange unit 600.

The first moving pipe 513 may connect the water jacket 511 and the heat exchange pipe 512 to each other.

The fluid may flow from the heat exchange pipe 512 to the water jacket 511 by the first moving pipe 513.

In addition, the fluid may flow from the water jacket 511 to the heat exchange pipe 512 by the first moving pipe 513.

The second moving pipe 514 may connect the water jacket 511 and the heating unit 530 to each other.

The fluid may flow from the water jacket 511 to the heating unit 530 by the second moving pipe 514.

In addition, the fluid may flow from the heating part 530 to the water jacket 511 by the second moving pipe 514.

The third moving pipe 515 may connect the heating unit 530 and the heat exchange pipe 512 to each other.

The fluid may flow from the heating part 530 to the heat exchange pipe 512 by the third moving pipe 515.

In addition, the fluid may flow from the heat exchange pipe 512 to the heating unit 530 by the third moving pipe 515.

The first connection pipe 516 may connect the first moving pipe 513 and the second moving pipe 514 to each other.

The fluid flows from the first moving pipe 513 by the first connecting pipe 516 and then to the second connecting pipe 517 to the heating unit 530 and / or the water jacket 511. Can be flowed into.

The second connection pipe 517 may connect the first moving pipe 513 and the third moving pipe 515 to each other.

The fluid flows from the first moving pipe 513 by the first connection pipe 516 to the third connection pipe and flows to the heating unit 530 and / or the heat exchange pipe 512. Can be.

If the fluid flows from the heat exchange pipe 512 to the water jacket 511 by the first moving pipe 513, the first connection pipe 516 and the first moving pipe 513 The connection point may be located downstream from the point where the second connection pipe 517 and the second moving pipe 514 is connected.

The control valve is a first control valve 521 for controlling whether or not the flow of the fluid flowing on the first moving pipe 513, the first control valve for controlling the flow of the fluid flowing on the first moving pipe 513 2 control valve 522, whether or not the flow of the fluid flow on the third control valve 523 and the second connection pipe 517 to control the flow of the fluid flowing on the third moving pipe 515. It may be provided with a fourth control valve (524) to adjust.

Here, the control valve is not limited to controlling the flow of the fluid, it is also possible to adjust the flow rate of the fluid.

The first control valve 521 is disposed on the first moving pipe 513 between the point where the first connecting pipe 516 and the first moving pipe 513 are connected and the water jacket 511. Can be.

The second control valve 522 may be disposed on the first moving pipe 513 between the point where the second connection pipe 517 and the first moving pipe 513 are connected and the heat exchange pipe 512. Can be.

The third control valve 523 may be disposed on the third moving pipe 515 between the point where the second connecting pipe 517 and the third moving pipe 515 are connected and the heat exchange pipe 512. Can be.

The fourth control valve 524 may be disposed on the second connection pipe 517.

The heating unit 530 may heat the fluid.

The heating unit 530 may include all heating means capable of generating heat.

For example, the heating unit 530 may be a heating means that is operated by electricity, may be a heating means that is operated by a combustion material.

The heating unit 530 may be located between the water jacket 511 and the heat exchange pipe 512.

The heating unit 530 may be connected to the second moving pipe 514 and the third moving pipe 515.

The heating unit 530 is a point where the first connecting pipe 516 and the second moving pipe 514 is connected, and the second connecting pipe 517 and the third moving pipe 515 is connected. It can be located between.

The fluid may flow from the water jacket 511 to the heat exchange pipe 512 through the second moving pipe 514, the heater, and the third moving pipe 515.

In addition, the fluid may flow from the heat exchange pipe 512 to the water jacket 511 through the third moving pipe 515, the heater, and the second moving pipe 514.

The heating unit 530, the control valve, the first moving pipe 513, the second moving pipe 514, the third moving pipe 515, the first connecting pipe 516 and the second The connection pipe 517 may be located outside the first case 100 and the second case 200.

The outside air flowing in the first space S100 may flow in the second heat exchange part 600, and the air flowing in the second space S200 may flow, so that the outside air and the air flow. Can be heat exchanged with each other.

The second heat exchange part 600 may be disposed on the first space S100 and the second space S200.

The second heat exchange part 600 is discharged from the dehumidifying unit 300 in the first space (S100) and the dehumidifying unit in the outside air and the second space (S200) flowing to the temperature control unit 400. The air flowing to 300 may be heat exchanged with each other.

For example, the second heat exchange part 600 may be disposed between the dehumidifying part 300 and the temperature control part 400.

For example, the outside air is heat exchanged in the second heat exchanger 600 before entering the temperature controller 400, thereby improving the efficiency of the temperature controller 400 and at the same time the second heat exchanger. Heat exchange efficiency of 600 can be improved.

In addition, the second heat exchange part 600 may be disposed between the air fan 760 to be described later and the heat exchange pipe 512 to be described later.

The fan is an outside air fan 710 and the air to the outside air is introduced into the first case 100, flows in the first space (S100) and discharged from the first case 100 and the second case An air fan 760 may be provided to flow into the 200 and flow on the second space S200 to be discharged from the second case 200.

The outside fan 710 may be disposed at a portion at which the outside air is introduced into the first case 100, and the air fan 760 is disposed at a portion at which the air is introduced into the second case 200. However, the present invention is not limited thereto and can be variously modified at a level apparent to those skilled in the art.

For example, the outside fan 710 may be disposed between the outside air inlet 120 and the dehumidifying unit 300.

In addition, the air fan 760 may be disposed between the second heat exchange part 600 and the air inlet 220.

Sensor unit The first sensor unit 810 for providing information about the temperature of the outside air flowing into the first space (S100), providing information about the temperature of the outside air flowing into the first space (S100) The temperature of the fluid accommodated in the second sensor unit 820, the third sensor unit 830 and the water jacket 511 for providing information about the temperature of the air via the second heat exchange unit 600. It may be provided with a fourth sensor unit 840 for providing information about.

The fourth sensor unit 840 may provide information regarding the temperature of the water jacket 511.

In addition, the fourth sensor unit 840 may provide information regarding the temperature of the second portion.

The position of the sensor unit can be variously arranged at a level apparent to those skilled in the art.

For example, the first sensor unit 810 and / or the second sensor unit 820 may be disposed on the first space S100, and a portion into which the outside air flows from the first case 100. Can be placed in.

In addition, the third sensor unit 830 may be disposed on the second space S200, and may be disposed between the second heat exchange unit 600 and the heat exchange pipe 512.

In addition, the fourth sensor unit 840 may be disposed on an outer surface of the water jacket 511 or may be disposed in a space provided to the water jacket 511.

The damper unit controls whether the air flowing in the second space S200 flows to the dehumidifying unit 300 and the air flowing in the first damper 910 and the second space S200 is the air. It may be provided with a second damper 960 for controlling whether the flow to the bypass unit 240.

When the first damper 910 is opened, the air after the heat exchange in the heat exchange pipe 512 may flow to the dehumidifying part 300.

In addition, when the first damper 910 is closed, the air after the heat exchange in the heat exchange pipe 512 may not flow to the dehumidifier 300.

When the second damper 960 is opened, the air that has completed the heat exchange in the heat exchange pipe 512 may be discharged to the outside through the air bypass unit 240.

In addition, when the second damper 960 is closed, the air that has completed the heat exchange in the heat exchange pipe 512 may not be discharged to the outside through the air bypass unit 240.

The first damper 910 and the second damper 960 may adjust the flow amount of the air. This may be implemented through the opening and closing degree of the first damper 910 and the second damper 960.

For example, the first damper 910 may be disposed on the second space S200, and may be located between the dehumidifying part 300 and the air bypass part 240.

In addition, the second damper 960 may be disposed on the second space S200 and may be located on the air bypass unit 240.

The control unit may receive various information such as a storage unit storing information provided by the sensor unit, an operation unit determining whether a predetermined condition is satisfied based on the information stored in the storage unit, information provided from the sensor unit, and the like. And a transmitter capable of transmitting various signals capable of controlling the aforementioned components.

In addition, the control unit may further include a configuration required to perform various control functions at a level obvious to those skilled in the art, without being limited to the above-described configuration.

The controller may be disposed in the first case 100 and / or the second case 200.

In addition, the control unit may be disposed in all configurations in the first case 100 and / or the second case 200, and may be disposed in only some components.

In this case, the components of the controller may be capable of wired / wireless communication with each other.

Hereinafter, a method of controlling the above-described configuration corresponding to the state of the outside air will be described in detail.

4 is an operation algorithm of the outside air conditioning system according to an embodiment of the present invention, and FIG. 5 is a graph for explaining an area in the operation algorithm of the outside air conditioning system according to an embodiment of the present invention.

2 to 5, the air conditioning system according to an embodiment of the present invention includes the first sensor unit 810, the second sensor unit 820, the third sensor unit 830, and the first sensor unit. 4 may be controlled based on the information provided from the sensor unit 840.

Providing information about the temperature of the outside air to the controller using the first sensor unit 810, and providing information about the humidity of the outside air to the controller using the second sensor unit 820, The third sensor unit 830 is used to provide the control unit with information about the temperature of the second air that is heat exchanged and discharged from the second heat exchange unit 600, and the fourth sensor unit 840 is provided. Using the temperature of the fluid accommodated in the water jacket 511 (or the temperature that can be sensed by the fourth sensor unit 840 described above, for example, the temperature of the second portion) is provided to the controller. (S100)

For example, the first sensor unit 810 may provide information regarding the dry bulb temperature of the outside air, but is not limited thereto. The first sensor unit 810 may provide information about the wet bulb temperature of the outside air. can do.

For example, the second sensor unit 820 may provide information regarding the relative humidity of the outside air, but is not limited thereto, and the second sensor unit 820 may provide information regarding the absolute humidity of the outside air. can do.

If the second sensor unit 820 provides the control unit with information on the relative humidity of the outside air, the control unit uses the information on the relative humidity provided by the second sensor unit 820 to determine the absolute of the outside air. Information about humidity may be calculated, and the absolute humidity may be used to determine in which region the outside air is described below.

The humidity (X_OA) of the outside air flowing into the first space (S100) through the outside air inlet unit 120 may be compared with a predetermined humidity (X_set) (S200).

라고 표기할 수 있다.Hereinafter, reference numeral X_OA of the humidity of the outside air is

Can be written.

이라고 표기할 수 있다.In addition, reference numeral X_set of the preset humidity is

Can be written as

The preset humidity X_set may be a humidity stored in advance in the controller, or may be a humidity stored by an input by a user. In addition, the preset humidity X_set may be a temperature at which a person in the target space starts to feel wet (or uncomfortable).

When the humidity X_OA of the outside air flowing into the first space through the outside air inflow unit 120 is higher than a preset humidity X_set, the controller may control the dehumidifying unit in a manner specified in the first region R10. 300, the first damper 910, the second damper 960, and the temperature controller 400 may be controlled (S210).

For example, the control unit is a part of the dehumidifying unit 300 is located on the second space (S200) when a part of the dehumidifying unit 300 disposed on the first space (S100) exceeds the amount of dehumidification. In order to perform the regeneration process, the dehumidifying unit 300 may be controlled to rotate the dehumidifying unit 300.

The control unit may adjust the set temperature of the dehumidifying unit 300 in the second space (S200) to the temperature of the second portion of the temperature control unit 400 and the heat amount of the heating unit 530, The heating unit 530, the temperature control unit 400, and the first control valve 521 may be controlled.

In addition, the control unit opens the first damper 910 so that the air flowing in the second space (S200) flows to the dehumidifying unit 300 to perform the regeneration process, the air discharge unit May be discharged to 230.

In addition, the controller may close the second damper 960 to prevent the air flowing in the second space S200 from flowing to the air bypass unit 240.

In addition, the control unit may allow the heating unit 530 to operate so that the fluid flowing in the pipe is heated.

In addition, the control unit may control the current to flow in the first direction to the temperature control unit 400.

On the contrary, when the humidity X_OA of the outside air introduced into the first space S100 through the outside air inlet 120 is lower than a preset humidity X_set, the first air inlet 120 may be used. It may be compared (S300) whether the temperature (T_OA) of the outside air introduced into the space (S100) is higher than the preset temperature (T_set).

라고 표기할 수 있다.Hereinafter, reference numeral T_OA of the temperature of the outside air is

Can be written.

이라고 표기할 수 있다.Further, reference numeral T_set of the preset temperature is

Can be written as

The preset temperature T_set may be a temperature previously stored in the controller, or may be a temperature stored by an input by a user. In addition, the preset temperature T_set may be a temperature at which a person in the target space starts to feel hot.

The humidity X_OA of the outside air introduced into the first space S100 through the outside air inlet 120 is lower than a preset humidity X_set, and the first space S100 through the outside air inlet 120. When the temperature T_OA of the external air introduced into the air is higher than the preset temperature T_set, the dehumidifying part 300, the first damper 910, and the second method are designated in the second region R20. The damper 960 and the temperature control unit 400 may be controlled (S310).

For example, the controller may close the first damper 910 to prevent the air flowing on the second space S200 from flowing to the dehumidifying part 300.

In addition, the control unit may open the second damper 960 to allow the air flowing in the second space S200 to flow to the air bypass unit 240.

In addition, the controller may control the current to flow in the second direction in the temperature control unit 400.

Unlike this, the humidity X_OA of the outside air introduced into the first space S100 through the outside air inlet 120 is lower than a preset humidity X_set, and the first space through the outside air inlet 120. When the temperature T_OA of the outside air flowing into the step S100 is lower than a preset temperature T_set, the temperature T_ (TEM, 2) of the fluid accommodated in the water jacket 511 is the second heat exchange part. It is possible to compare (S400) whether the temperature is higher than the temperature T_ (SHE, out) of the second air discharged by heat exchange at 600.

라고 표기할 수 있다.Hereinafter, reference numeral T_ (TEM, 2) of the temperature of the fluid accommodated in the water jacket 511 is

Can be written.

이라고 표기할 수 있다.In addition, reference numeral T_ (SHE, out) of the temperature of the second air discharged by heat exchange in the second heat exchange part 600 is

Can be written as

The humidity X_OA of the outside air introduced into the first space S100 through the outside air inlet 120 is lower than a preset humidity X_set, and the first space S100 through the outside air inlet 120. The temperature (T_OA) of the outside air introduced into is lower than the preset temperature (T_set), and the temperature (T_ (TEM, 2)) of the fluid accommodated in the water jacket 511 is in the second heat exchange part (600). When the temperature is higher than the temperature T_ (SHE, out) of the second air discharged through the heat exchange, the controller is configured in the third region R30 by using the dehumidifying unit 300 and the first damper 910. ), The second damper 960 and the temperature control unit 400 may be controlled (S410).

For example, the controller may close the first damper 910 to prevent the air flowing on the second space S200 from flowing to the dehumidifying part 300.

In addition, the control unit may open the second damper 960 to allow the air flowing in the second space S200 to flow to the air bypass unit 240.

In addition, the control unit may allow the heating unit 530 to operate so that the fluid flowing in the pipe is heated.

In addition, the controller may control the current to flow in the second direction in the temperature control unit 400.

Unlike this, the humidity X_OA of the outside air introduced into the first space S100 through the outside air inlet 120 is lower than a preset humidity X_set, and the first space through the outside air inlet 120. The temperature T_OA of the outside air flowing into the step S100 is lower than a preset temperature T_set, and the temperature T_ (TEM, 2) of the fluid accommodated in the water jacket 511 is the second heat exchanger. When the temperature is lower than the temperature T_ (SHE, out) of the second air that is discharged by heat exchange at 600, the control unit may specify the dehumidifying unit 300 and the first method by a method specified in the fourth region R40. The damper 910, the second damper 960, and the temperature controller 400 may be controlled (S420).

For example, the controller may close the first damper 910 to prevent the air flowing on the second space S200 from flowing to the dehumidifying part 300.

In addition, the control unit may open the second damper 960 to allow the air flowing in the second space S200 to flow to the air bypass unit 240.

In addition, the controller may control the current to flow in the second direction in the temperature control unit 400.

Hereinafter, a process of operating the outside air control system according to the above-described control method will be described.

6 is a view for explaining a process that is operated when the outside air flowing into the outside air conditioning system according to an embodiment of the present invention at high temperature and high humidity.

When the humidity X_OA of the outside air introduced into the first case 100 is higher than a preset humidity X_Set, current flows in the first direction in the temperature controller 400, and the pipe is connected to the fluid. Receives heat emitted from the second portion to guide the fluid to transfer the heat to the air flowing on the second case 200, the dehumidifying unit 300 is heated by the air received heat Moisture may be discharged into the air.

When the humidity X_OA of the outside air flowing into the first case 100 is higher than a preset humidity X_set, the heating unit 530 absorbs heat emitted from the second portion and the second space ( Heat the fluid flowing to transfer heat to the air flowing on the S200, and the pipe receives the heat discharged from the second portion and the heating unit 530 the second space (S200) Guide the fluid to transfer heat to the air flowing in the), the dehumidification unit 300 may be heated by the air received the heat, to discharge moisture into the air.

Such an operation process may be a process operated when the outside air a1 flowing into the first case 100 exists in the first region R10.

In detail, the outside air a1 may be introduced onto the first case 100 through the outside air inlet 120 by the outside air fan 710.

The outside air a1 may be dehumidified while passing through the dehumidifying part 300 on the first space S100. The outside air a1 may be elevated in temperature while passing through the dehumidifying unit 300 by a dehumidifying process by the dehumidifying unit 300.

The outside air a1 passing through the dehumidifying part 300 may flow to the second heat exchange part 600. The outside air a1 may transfer heat from the second heat exchange part 600 to the air a2 flowing in the second space S200. The outside air a1 may be cooled while passing through the second heat exchange part 600.

The outside air a1 passing through the second heat exchange part 600 may be further cooled while passing through the first portion of the temperature control part 400.

Here, the temperature controller 400 may have an appropriate temperature so that the temperature of the target space is changed to the temperature desired by the user by the outside air a1 flowing into the target space. To this end, the control unit may adjust the amount of current flowing in the temperature control unit 400.

The outside air a1 cooled by the temperature controller 400 may flow into the target space through the outside air discharge unit 130.

Air a2 may be introduced onto the second case 200 through the air inlet 220 by the air fan 760.

The air a2 may flow to the second heat exchange part 600. The air a2 may receive heat from the outside air a1 flowing in the first space S100 in the second heat exchange part 600. The air a2 may be heated while passing through the second heat exchange part 600.

The outside air a1 passing through the second heat exchange part 600 may be further heated while passing through the heat exchange pipe 512.

The air a2 received from the heat exchange pipe 512 may flow to the dehumidifying part 300. The air heated through the heat exchange pipe 512 and the heating part 530 may flow to the dehumidifying part 300 to allow the moisture contained in the dehumidifying part 300 to evaporate. (Playback process)

The air a2 passing through the dehumidifying part 300 may be discharged to the outside through the air discharge part 230.

When the controller exceeds the amount of dehumidification allowed by the dehumidifying unit 300 in the first space S100, the dehumidifying unit 300 in the first space S100 is disposed on the second space S200. The dehumidifying unit 300 may be rotated to make it possible. The dehumidifying part 300 in which the dehumidification process is performed on the first space S100 may be moved to the second space S200, and a regeneration process may be performed by the air.

Heat generated in the second portion may be used in the regeneration process to reduce the load of the boiler and to reduce energy.

The first control valve 521, the second control valve 522, and the third control valve 523 may be opened to perform the above-described operation, and the fourth control valve 524 may be closed. Can be.

The fluid f may flow from the heat exchange pipe 512 to the water jacket 511 through the first moving pipe 513.

In addition, the fluid f may flow from the water jacket 511 to the heat exchange pipe 512 through the second moving pipe 514, the heating unit 530, and the third moving pipe 515. Can be.

The fluid f may transfer heat from the heat exchange pipe 512 to the air a2, and the fluid f may receive heat from the second portion of the water jacket 511.

The controller may control the amount of heat received from the second portion by controlling whether the first control valve 521 is opened or closed and / or the degree of opening and closing.

The controller controls whether the first control valve 521 is opened or closed and / or the degree of opening / closing so that the fluid f receives heat released from the second portion and flows in the second space S200. You can control the amount of heat transfer to the air.

Specifically, the controller may control the first control valve 521 to adjust the amount of the fluid f flowing from the heat exchange pipe 512 to the water jacket 511.

The greater the amount of fluid f flowing into the water jacket 511, the greater the amount of heat the fluid f receives from the second portion of the water jacket 511. As the amount of the fluid f flowing into the water jacket 511 is smaller, the amount of heat that the fluid f receives from the second portion of the water jacket 511 may be smaller.

As the amount of fluid f flowing into the water jacket 511 increases, the amount of heat transferred to the air a2 may increase. As the amount of the fluid f flowing into the water jacket 511 is smaller, the amount of heat transferred to the air a2 may be smaller.

When the first control valve 521 is partially closed, a part of the fluid f discharged to the heat exchange pipe 512 flows into the water jacket 511 and is discharged from the heat exchange pipe 512. A portion of the fluid f may flow to the heating part 530 through the first connection pipe 516.

7 is a view for explaining a process that is operated when the outside air flowing into the outside air control system according to an embodiment of the present invention at high temperature drying.

The humidity X_OA of the outside air introduced into the first case 100 is lower than the preset humidity X_set, and the temperature T_OA of the outside air introduced into the first case 100 is a preset temperature T_set. When the temperature is higher, current flows in the first direction in the temperature controller 400, and the pipe receives the heat discharged from the second portion and flows into the second case 200 to be dehumidified. The fluid may be guided to transfer heat to the air discharged from the second case 200 without passing through 300.

Such an operation process may be a process operated when the outside air a1 flowing into the first case 100 exists in the second region R20.

In detail, the outside air a1 may be introduced onto the first case 100 through the outside air inlet 120 by the outside air fan 710.

The outside air a1 passing through the dehumidifying part 300 may flow to the second heat exchange part 600. The outside air a1 may transfer heat from the second heat exchange part 600 to the air a2 flowing on the second space S200. The outside air a1 may be cooled while passing through the second heat exchange part 600.

The outside air a1 passing through the second heat exchange part 600 may be further cooled while passing through the first portion of the temperature control part 400.

Here, the function of the temperature control unit 400 can be omitted from the overlapping limit.

The outside air a1 cooled by the temperature controller 400 may flow into the target space through the outside air discharge unit 130.

Air a2 may be introduced onto the second case 200 through the air inlet 220 by the air fan 760.

The air a2 may flow to the second heat exchange part 600. The air a2 may receive heat from the outside air a1 flowing in the first space S100 in the second heat exchange part 600. The air a2 may be heated while passing through the second heat exchange part 600.

The air a2 passing through the second heat exchange part 600 may be further heated while passing through the heat exchange pipe 512.

The air a2 passing through the heat exchange pipe 512 may be discharged to the outside through the air bypass unit 240.

The dehumidifying unit 300 may be prevented from being damaged by the air a2 heated through the flow process.

The first control valve 521, the second control valve 522, and the third control valve 523 may be opened to perform the above-described operation, and the fourth control valve 524 may be closed. Can be.

The fluid f may flow from the heat exchange pipe 512 to the water jacket 511 through the first moving pipe 513.

In addition, the fluid f may flow from the water jacket 511 to the heat exchange pipe 512 through the second moving pipe 514, the heating unit 530, and the third moving pipe 515. Can be.

The fluid f may transfer heat from the heat exchange pipe 512 to the air a2, and the fluid f may receive heat from the second portion of the water jacket 511.

In addition, the control unit may control whether the first control valve 521 is opened or closed and / or the degree of opening and closing, and a detailed description thereof may be omitted from the overlapping limit.

8 is a view for explaining a process that is operated when the outside air introduced to the outside air conditioning system according to an embodiment of the present invention is cryogenic dry.

The humidity X_OA of the outside air introduced into the first case 100 is lower than the preset humidity X_set, and the temperature T_OA of the outside air introduced into the first case 100 is a preset temperature T_set. Lower than, when the temperature T_ (TEM, 2) of the second portion is higher than the temperature T_ (SHE, out) of the air discharged by heat exchange in the second heat exchange unit 600, the temperature An electric current flows to the control unit 400 in a second direction, and the pipe may guide the fluid to receive heat from the heating unit 530 and transfer heat to the second part.

This operation process may be a process operated when the outside air flowing into the first case 100 exists in the third region R30.

In detail, the outside air a1 may be introduced into the first case 100 through the outside air inlet 120 by the outside air fan 710.

The outside air a1 passing through the dehumidifying part 300 may flow to the second heat exchange part 600. The outside air a1 may receive heat from the air a2 flowing on the second space S200 to the second heat exchange part 600. The outside air a1 may be heated while passing through the second heat exchange part 600.

The outside air a1 passing through the second heat exchange part 600 may be further heated while passing through the first portion of the temperature control part 400.

Here, the function of the temperature control unit 400 can be omitted from the overlapping limit.

The outside air a1 heated by the temperature control unit 400 may flow into the target space through the outside air discharge unit 130.

Air a2 may be introduced onto the second case 200 through the air inlet 220 by the air fan 760.

The air a2 may flow to the second heat exchange part 600. The air a2 may transfer heat from the second heat exchange part 600 to the outside air a1 flowing in the first space S100. The air a2 may be cooled while passing through the second heat exchange part 600.

The outside air a1 may be rapidly cooled by the outside air a1 that is cryogenic in the second heat exchange part 600. Thus, the temperature T_ (SHE, out) of the air a2 passing through the second heat exchange part 600 may be lower than the temperature T_ (TEM, 2) of the second portion.

The outside air a1 passing through the second heat exchange part 600 may be discharged to the outside through the air bypass part 240 via the heat exchange pipe 512.

In order to perform the above-described operation process, the first control valve 521 and the fourth control valve 524 may be opened, and the second control valve 522 and the third control valve 523 may be closed.

The fluid f may flow from the water jacket 511 to the heating unit 530 through the second moving pipe 514. The fluid f heated by the heating unit 530 may flow to the water jacket 511 through the third moving pipe 515, the second connecting pipe 517, and the first moving pipe 513. Can be.

Here, since the third control valve 523 is closed, the fluid f discharged from the heating unit 530 does not flow from the third moving pipe 515 to the heat exchange pipe 512 and the The second connection pipe 517 may flow.

The fluid f flowing in the second connection pipe 517 does not flow from the first moving pipe 513 to the heat exchange pipe 512 because the second control valve 522 is closed. It may flow to the water jacket 511.

The fluid f may transfer heat from the water jacket 511 to the second portion, and the fluid f may receive heat from the heating unit 530.

The control unit may control the amount of heat transferred from the water jacket 511 to the second portion by controlling whether the first control valve 521 is opened or closed and / or the degree of opening and closing.

The control unit may control whether the fluid f is transmitted from the heating unit 530 by controlling whether the first control valve 521 is opened or closed and / or the degree of opening and closing.

In detail, the control unit controls the first control valve 521 to adjust the amount of the fluid f heated in the heating unit 530 to the water jacket 511. .

The greater the amount of fluid f flowing into the water jacket 511, the greater the amount of heat the fluid f transfers to the second portion. On the contrary, as the amount of the fluid f flowing into the water jacket 511 is smaller, the amount of heat transferred by the fluid f to the second portion may be smaller.

As the amount of oil flowing into the water jacket 511 increases, the amount of heat received by the fluid f in the heating unit 530 may increase. On the contrary, the smaller the amount of the fluid f flowing into the water jacket 511, the less the amount of heat that the fluid f receives from the heating unit 530.

When the first control valve 521 is partially closed, part of the fluid f discharged from the heating part 530 may be the third moving pipe 515, the second connecting pipe 517, and the The first moving pipe 513 and the first connection pipe 516 may be flowed back to the heating unit 530. In addition, a portion of the fluid f discharged from the heating part 530 is transferred to the water jacket through the third moving pipe 515, the second connecting pipe 517, and the first moving pipe 513. 511).

9 is a view for explaining another process operated when the outside air introduced into the outside air conditioning system according to an embodiment of the present invention is dried at low temperature.

The humidity X_OA of the outside air introduced into the first case 100 is lower than the preset humidity X_set, and the temperature T_OA of the outside air introduced into the first case 100 is a preset temperature T_set. Lower and when the temperature T_ (TEM, 2) of the second portion is lower than the temperature T_ (SHE, out) of the air discharged by heat exchange in the second heat exchange unit 600, the temperature An electric current flows in the control unit 400 in the second direction, and the pipe receives the fluid so that the fluid receives heat from the air cooled in the second heat exchange unit 600 and transfers heat to the second part. I can guide you.

This operation process may be a process operated when the outside air flowing into the first case 100 exists in the fourth region R40.

In detail, the outside air a1 may be introduced into the first case 100 through the outside air inlet 120 by the outside air fan 710.

The outside air a1 passing through the dehumidifying part 300 may flow to the second heat exchange part 600. The outside air a1 may receive heat from the air a2 flowing on the second space S200 to the second heat exchange part 600. The outside air a1 may be heated while passing through the second heat exchange part 600.

The outside air a1 passing through the second heat exchange part 600 may be further heated while passing through the first portion of the temperature control part 400.

Here, the function of the temperature control unit 400 can be omitted from the overlapping limit.

The outside air a1 heated by the temperature control unit 400 may flow into the target space through the outside air discharge unit 130.

Air a2 may be introduced into the second case 200 through the air inlet 220 by the air fan 760.

The air a2 may flow to the second heat exchange part 600. The air a2 may transfer heat from the second heat exchange part 600 to the outside air a1 flowing in the first space S100. The air a2 may be cooled while passing through the second heat exchange part 600.

The air a2 passing through the second heat exchange part 600 may be further cooled while passing through the heat exchange pipe 512.

The air a2 passing through the heat exchange pipe 512 may be discharged to the outside through the air bypass unit 240.

The first control valve 521, the second control valve 522, and the third control valve 523 may be opened to perform the above-described operation, and the fourth control valve 524 may be closed. Can be.

The fluid f may flow from the heat exchange pipe 512 to the water jacket 511 through the first moving pipe 513.

In addition, the fluid f may flow from the water jacket 511 to the heat exchange pipe 512 through the second moving pipe 514, the heating unit 530, and the third moving pipe 515. Can be.

The fluid f may receive heat from the air a2 in the heat exchange pipe 512, and the fluid f may transfer heat from the water jacket 511 to the second portion.

The controller may control the amount of heat transferred by the fluid f to the second part by controlling whether the first control valve 521 is opened or closed and / or the degree of opening and closing.

The controller controls whether the first control valve 521 is opened or closed and / or the degree of opening / closing so that the fluid f transfers heat to the second portion and the air flowing in the second space S200 ( The amount of heat received from a2) can be controlled.

Specifically, the controller may control the first control valve 521 to adjust the amount of the fluid f flowing from the heat exchange pipe 512 to the water jacket 511.

The greater the amount of fluid f flowing into the water jacket 511, the greater the amount of heat the fluid f transfers to the second portion. As the amount of the fluid f flowing into the water jacket 511 is smaller, the amount of heat transferred by the fluid f to the second portion may be smaller.

The greater the amount of fluid f flowing into the water jacket 511, the greater the amount of heat the fluid f receives from the air a2. The smaller the amount of the fluid f flowing into the water jacket 511, the less the amount of heat that the fluid f receives from the air a2.

When the first control valve 521 is partially closed, a part of the fluid f discharged to the heat exchange pipe 512 flows into the water jacket 511 and is discharged from the heat exchange pipe 512. A portion of the fluid f may flow to the heating part 530 through the first connection pipe 516.

In order to more clearly express the technical spirit of the present invention, the accompanying drawings are briefly expressed or omitted for the components that are not relevant or inferior to the technical spirit of the present invention.

In the above described the configuration and features of the present invention based on the embodiment according to the present invention, the present invention is not limited to this, it can be variously changed or modified within the spirit and scope of the present invention It will be apparent to those skilled in the art that such changes or modifications fall within the scope of the appended claims.

100: first case 200: second case
300: dehumidifying unit 400: temperature control unit

Claims (11)

In the air conditioning system for adjusting the target space to a set temperature and humidity,
A first case in which outside air flows into and flows and provides a first space in which the introduced outside air is discharged into the target space;
A second case into which predetermined air is introduced and flowed, and providing a second space through which the introduced air is discharged to the outside;
A dehumidifying unit disposed on the first space and the second space to absorb moisture contained in the outside air introduced into the first case and then discharge the absorbed moisture into the air flowing in the second space;
A first portion positioned in the first space to absorb heat from the outside air flowing into the first space or emitting heat to the outside air, and a second portion located outside the first space and extending from the first portion A temperature controller configured to generate a thermal difference between the first part and the second part according to a moving direction of the current; And
And a first heat exchange part through which a fluid that exchanges heat with the air on the second portion and the second space flows.
The second portion exchanges heat with the fluid flowing on the first heat exchanger, and the fluid flowing on the first heat exchanger exchanges heat with air flowing on the second space,
And the first heat exchange part is configured to flow a fluid that is heat-exchanged with the air on the second portion and the second space, selectively according to a predetermined condition.
The method of claim 1,
The first heat exchanger,
A pipe through which the fluid flows; And a heating unit for heating the fluid flowing in the pipe selectively according to the predetermined condition.
The method of claim 2,
When the humidity of the outside air flowing into the first case is higher than a predetermined humidity,
In the temperature control unit,
The current flows in a first direction—the first direction absorbs heat from the outside air that flows on the first space, and the second portion flows in the direction of the current to release heat;
The pipe is,
Directs the fluid to receive heat released from the second portion and to transfer heat to the air flowing on the second case,
The dehumidifying unit,
The outside air conditioning system characterized in that the heated by the air is transferred, the moisture is discharged to the air.
The method of claim 3,
When the humidity of the outside air flowing into the first case is higher than a predetermined humidity,
The heating unit,
Heat the fluid flowing to absorb heat emitted from the second portion and transfer heat to the air flowing on the second space,
The pipe is,
Guides the fluid so that the fluid receives heat emitted from the second portion and the heating portion and transfers heat to the air flowing in the second space,
The dehumidifying unit,
The outside air conditioning system characterized in that the heated by the air is transferred, the moisture is discharged to the air.
The method of claim 3,
When the humidity of the outside air introduced into the first case is lower than a preset humidity, and the temperature of the outside air introduced into the first case is higher than a preset temperature,
In the temperature control unit,
Current flows in the first direction,
The pipe is,
The fluid is guided to receive the heat discharged from the second portion to enter the second case to transfer heat to the air discharged from the second case without passing through the dehumidifying unit. Air conditioning system.
The method of claim 5,
A second heat exchanger disposed between the dehumidifying unit and the temperature control unit and exchanging heat between the outside air flowing in the first space and the air flowing in the second space; Regulation system.
The method of claim 6,
The second heat exchanger,
The outside air conditioning system of claim 1, wherein the air discharged from the dehumidifying unit in the first space and flows to the temperature control unit and the air flowing into the dehumidifying unit in the second space are heat exchanged.
The method of claim 7, wherein
The humidity of the outside air introduced into the first case is lower than a preset humidity, the temperature of the outside air introduced into the first case is lower than a preset temperature, and the temperature of the second portion is heated in the second heat exchange part. When it is higher than the temperature of the air discharged and exchanged,
In the temperature control unit,
The current flows in a second direction, the second direction in which the first portion releases heat to the outside air flowing in the first space, and the second portion flows in the direction of the current to absorb heat;
The piping
And the fluid guides the fluid to receive heat released from the heating portion and to transfer heat to the second portion.
The method of claim 7, wherein
The humidity of the outside air introduced into the first case is lower than a preset humidity, the temperature of the outside air introduced into the first case is lower than a preset temperature, and the temperature of the second portion is heated in the second heat exchange part. When it is lower than the temperature of the air exchanged and discharged,
In the temperature control unit,
Current flows in the second direction,
The pipe is,
And the fluid guides the fluid to receive heat from the air cooled in the second heat exchanger to transfer heat to the second portion.

According to claim 1,
The predetermined condition is
A first condition in which the humidity of the outside air introduced into the first case is higher than a preset humidity;
A second condition in which the humidity of the outside air introduced into the first case is lower than a preset humidity, and the temperature of the outside air introduced into the first case is higher than a preset temperature;
The humidity of the outside air introduced into the first case is lower than a preset humidity, the temperature of the outside air introduced into the first case is lower than a preset temperature, and the temperature of the second portion is heat exchanged in the second heat exchange unit. A third condition higher than the temperature of the air being discharged; And
The humidity of the outside air flowing into the first case is lower than a predetermined humidity, the temperature of the outside air flowing into the first case is lower than a predetermined temperature, the temperature of the second portion is heat in the second heat exchange unit A fourth condition lower than the temperature of the air exchanged and discharged; Air conditioning system that satisfies at least any one of.
According to claim 1,
The first heat exchanger,
A first path through which the fluid flows such that heat exchange occurs between the second portion and the second space; And
And a second path through which the fluid flows such that heat exchange is cut off between the second portion and the second space.
The movement of the fluid in the first heat exchanger is determined by the path of either the first path or the second path according to the predetermined condition.

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