KR102621570B1 - System for Constant Temperature and Humidity - Google Patents

Abstract

The present invention relates to a constant temperature and humidity system that can reduce the overload of the outdoor unit by controlling the temperature of the indoor air passing through the heating water and dehumidification rotor by utilizing the refrigerant circulating in a plurality of outdoor units, and is specifically provided on the indoor floor. It is connected to the heating unit where the heating water circulates, and is connected to the dehumidifying unit, which removes moisture contained in the indoor air as it rotates by power, and the dehumidifying unit and the heating unit, respectively. As the refrigerant circulates, the indoor air and a heat exchange unit that controls the temperature of the heating water.

Description

System for Constant Temperature and Humidity}

The present invention relates to a constant temperature and humidity system that can reduce overload of outdoor units by controlling the temperature of indoor air passing through heating water and dehumidification rotors using refrigerant circulating in a plurality of outdoor units.

Patent Document 001 discloses that a case that can be erected vertically is divided into a dry channel and a wet channel by a vertical partition, a supply air blower, an indirect evaporative cooler, and an evaporator are installed in the dry channel, and a condenser and a wet channel are installed in the wet channel. , a heating coil and an exhaust blower are installed, a dehumidifying rotor is installed at the bottom of the vertical bulkhead, and an intake port, a supply port, a cooler exhaust port, and a first outside air intake port are formed on the gun channel side of the enclosure, respectively. , a dehumidifying and cooling device in which an exhaust port and a second outdoor air intake port are formed on a wet channel side of the enclosure, respectively; a first damper installed at the intake port of the dehumidifying air conditioning device to open and close the intake port; a second damper installed in a duct connected to the cooler exhaust port of the dehumidifying air conditioning device to open and close the cooler exhaust port; a third damper installed in a duct connected to the second outside air intake port of the dehumidifying air conditioning device to open and close the second outside air intake port; a fourth damper provided in an intake duct branched from a duct connected to a second outdoor air intake port of the dehumidifying air conditioning device to intake indoor air, and sucking indoor air into or blocking the second outdoor air intake port; and a controller that controls the first to fourth dampers to perform cooling operation or ventilation operation according to the operation mode set by the user.

Patent document 002 includes a dehumidifying cooling passage through which air passes, a dehumidifying rotor disposed on one side of the dehumidifying cooling passage to allow air to pass through and remove moisture from the air, and a dehumidifying rotor disposed downstream of the dehumidifying rotor in the dehumidifying cooling passage. A dehumidifying air conditioner equipped with a cooler that cools the high-temperature, low-humidity air dehumidified while passing through it, a compressor that compresses the refrigerant, and a dehumidifying air conditioner arranged on the downstream side of the cooler in the dehumidifying cooling passage sequentially pass through the dehumidifying rotor and the cooler to dehumidify and cool the air. A condenser arranged to be cooled by air to condense the refrigerant flowing inside, an expansion valve to expand the refrigerant condensed by the condenser, evaporate the refrigerant expanded by the expansion valve, and then deliver the refrigerant to the compressor. A vapor compression air conditioner is provided with an evaporator that supplies cooling to the air conditioned space using latent heat of evaporation. The evaporator is placed in a separate space outside the dehumidifying air conditioner, and the vapor compression air conditioner is placed inside the dehumidifying air conditioner. A technology is proposed that includes a refrigerant pipe connecting a condenser and an evaporator located in a separate space outside the dehumidifying air conditioner.

Patent document 003 is formed in the form of a square enclosure to be installed on the ceiling of an apartment building, and is divided into a dry channel, a wet channel, and an exhaust air discharge channel by a partition wall on the inside, and has an outside air intake port and exhaust port on one side to communicate with the wet channel. Main bodies each formed, each having an air supply port formed on one side of the side to communicate with the gun channel, an air exhaust port formed on one side of the side to communicate with the air exhaust channel, and an intake grill formed on one side of the upper surface; a dehumidifying rotor installed to rotate around the partition wall to be positioned between the dry channel and the wet channel within the main body; a hot water coil installed at the bottom of the dehumidifying rotor in the wet channel of the main body to supply district heating water; a regenerative blower installed at the top of the dehumidifying rotor in the wet channel of the main body; an indirect evaporative cooler installed to be inclined in the gun channel of the main body and discharging humid air generated during dehumidification into the extraction discharge channel; a small cooling unit that cools the air in the gun channel of the main body; An air supply blower installed at the bottom of the dehumidifying rotor in the gun channel of the main body; And a technology including a blower for extracting air installed in the extracting exhaust channel is proposed.

Patent invention 004 is a ventilation dehumidifying cooling system including an outdoor unit that dehumidifies and cools incoming outside air and an indoor unit connected to the outdoor unit for ventilation, wherein the outdoor unit includes a dehumidifying rotor; Evaporative cooler; Evaporative condenser; ventilation damper; heating unit; and a control module that controls the operation and stop of at least one of the dehumidifying rotor, evaporative cooler, evaporative condenser, ventilation damper, and heating unit.

KR 10-1361099 B1 (February 4, 2014) KR 10-2016-0088846 A (July 26, 2016) KR 10-1392456 B1 (April 29, 2014) KR 10-2022-0083585 A (June 20, 2022)

The present invention relates to a constant temperature and humidity system that can reduce overload of outdoor units by controlling the temperature of indoor air passing through heating water and dehumidification rotors using refrigerant circulating in a plurality of outdoor units.

It is intended to solve the problems of prior inventions, and the present invention relates to a constant temperature and humidity system, which includes a heating unit 200 formed on the floor of an indoor room through which heating water circulates; A dehumidifying unit (300) connected to the heating unit (200) and rotating by power to remove moisture contained in the indoor air; It is connected to the dehumidifying unit 300 and the heating unit 200, respectively, and includes a heat exchange unit 500 that adjusts the temperature of indoor air and heating water as the refrigerant circulates.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit 500; a heating device 210 formed in the heating unit 200 and controlling the temperature of the heating water; A heating pipe (220) connected to the heating device (210) and installed on the indoor floor; A circulation pipe 230 extending from the heating pipe 220 and circulating heating water to the dehumidification unit 300 is added.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit 500; a housing 310 formed on the dehumidifying unit 300 and coupled to a duct 100 extending indoors; A dehumidifying passage 320 formed to penetrate the inside of the housing 310 and through which indoor air and outdoor air pass, respectively; A dehumidifying rotor 400 is formed at the center of the dehumidifying passage 320 and rotates by power to adsorb moisture contained in indoor air.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention includes a heat exchange unit 500; a frame 410 formed on the dehumidifying rotor 400 and fixed to the inside of the housing 310; A dehumidifying member 420 that is inserted into the center of the frame 410 and absorbs moisture; A rotating member 460 that rotates the dehumidifying member 420 and is installed on the frame 410 and rotates by power is added.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit (500); a circulation passage (321) formed in the dehumidifying passage (320) through which indoor air circulates; A regeneration passage 322 formed at a position corresponding to the circulation passage 321 and through which outdoor air passes; A blower 330 is formed in each of the circulation passage 321 and the regeneration passage 322 and circulates indoor air and outdoor air, respectively.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; A cooling device 340 formed in the circulation passage 321 and lowering the temperature by evaporating the refrigerant supplied from the heat exchange unit 500 by circulating indoor air; A heating device 350 is formed in the regeneration passage 322 and increases the temperature of the outdoor air circulated by the two blowers 330.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit 500; a first heat exchange device 510 formed in the heat exchange unit 500 and connected to the dehumidification unit 300 to circulate the condensed refrigerant outdoors; A second heat exchange device 530 formed integrally with or separate from the first heat exchange device 510 and connected to the heating unit 200 to adjust the temperature of the heating water by circulating refrigerant condensed outdoors; is added.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit 500; a first outdoor unit 511 formed in the first heat exchange device 510 and installed outdoors to compress and condense the refrigerant; a first expansion valve 512 formed to be spaced apart from the first outdoor unit 511 and expanding the refrigerant delivered to the cooling device 340 of the dehumidifier 300 to low pressure; A control member 520 is formed between the first outdoor unit 511 and the first expansion valve 512 and transmits the refrigerant to the heating unit 200.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit 500; a circulation pipe 521 formed on the control member 520 and connected to the heating unit 200 to circulate the refrigerant; A first heat exchanger 522 is formed at the end of the circulation pipe 521 and is connected to the heating pipe 220 of the heating unit 200 to exchange heat between the heating water and the refrigerant.

The present invention relates to a constant temperature and humidity system, and includes the heating unit 200 presented above; Dehumidifying unit 300; The invention consists of a heat exchange unit 500; a second outdoor unit 531 formed in the second heat exchange device 530 and installed outdoors to compress and condense the refrigerant; a second expansion valve 532 formed to be spaced apart from the second outdoor unit 531 and expanding the refrigerant delivered to the heating pipe 220 to low pressure; A second heat exchanger 533 is connected to the second expansion valve 532 and connected to the heating pipe 220 to control the temperature of the heating water.

The present invention can remove moisture from indoor air that circulates as the dehumidifying rotor rotates.

In the present invention, a heating pipe through which heating water flows is connected to heat outdoor air in order to regenerate a dehumidifying rotor in which moisture is adsorbed.

In the present invention, indoor air from which moisture has been removed in a dehumidifying rotor is cooled by evaporation of the refrigerant in a cooling device.

The present invention allows the temperature of the indoor floor in summer to be controlled by controlling the temperature of the heating water in the heat exchange unit.

In the present invention, the heating unit and the heat exchange unit are connected to control the refrigerant temperature of the heat exchange unit, thereby reducing the overload of the outdoor unit.

Figure 1 is an exemplary diagram showing a generation to which the constant temperature and humidity system of the present invention is applied.
Figure 2 is a conceptual diagram of the constant temperature and humidity system of the present invention.
Figure 3 is a cross-sectional view of the dehumidifying unit of the present invention.
Figure 4 is a perspective view of the dehumidifying rotor of the present invention.
Figure 5 is an exemplary diagram showing a household in which the detuser of the present invention is installed.
Figure 6 is an exemplary diagram showing the diffuser shown in Figure 5.
Figure 7 is a perspective view showing the duct of the present invention.
8 to 9 are exemplary diagrams showing ducts in which conductive members of the present invention are installed.
Figure 10 is a cross-sectional view showing the blowing duct of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described in detail in order to enable those skilled in the art to easily practice the present invention.

Numbers cited in the examples below are not limited to the objects of citation and can be applied to all examples. An object that has the same purpose and effect as the configuration presented in the examples is an equivalent replacement object. The high-level concept presented in the examples includes low-level concept objects that are not described.

(Example 1-1) The present invention provides a constant temperature and humidity system, comprising: a heating unit 200 formed on an indoor floor and circulating heating water; A dehumidifying unit (300) connected to the heating unit (200) and rotating by power to remove moisture contained in the indoor air; It includes a heat exchange unit 500 that is connected to the dehumidifying unit 300 and the heating unit 200, and adjusts the temperature of indoor air and heating water as the refrigerant circulates.

(Example 1-2) In Example 1-1, the constant temperature and humidity system of the present invention includes that the heating unit 200 is formed in each of a plurality of rooms formed indoors.

(Example 1-3) In Example 1-2, the constant temperature and humidity system of the present invention is formed in the heating unit 200 and includes a distribution device that distributes heating water to each room.

(Example 1-4) In Example 1-3, the constant temperature and humidity system of the present invention includes, wherein the dehumidifying unit 300 is formed on the floor or ceiling of the room.

(Example 1-5) In Example 1-4, the constant temperature and humidity system of the present invention includes at least one heat exchange unit 500.

The present invention relates to a constant temperature and humidity system, and specifically, a constant temperature and humidity system can simultaneously perform indoor ventilation, dehumidification and cooling. Referring to FIG. 1, in this constant temperature and humidity system, the heating unit 200, which is formed on the floor of the room and circulates heating water, is connected to the dehumidifying unit 300, which removes moisture from the indoor air, thereby absorbing moisture from the dehumidifying unit 300. Moisture can be removed, and the temperature of the indoor air circulating through the dehumidifier 300 can be lowered as the heat exchange unit 500 and the dehumidifier 300, which are formed through a refrigeration cycle, are connected. At this time, the heating unit 200 is installed in a zigzag manner in each indoor room, and each room is distributed and controlled through a distribution device.

In addition, the heating unit 200 can cool the indoor floor in the summer by cooling the heated water whose temperature has risen in the summer by the outdoor air passing through the dehumidifying unit 300.

In addition, the dehumidifying unit 300 may be installed on the indoor floor or ceiling, and is formed inside the heating unit 200 by extending it, and as indoor air passes through in one direction and outdoor air passes through in the other direction, indoor air Dehumidifies and circulates indoors, and the outdoor air evaporates the moisture absorbed from indoor air. At this time, the dehumidifying unit 300 cools the dehumidified indoor air and supplies it indoors, and the temperature is controlled by the heat exchange unit 500.

In addition, the heat exchange unit 500 may be formed as one or in plural and connected to the dehumidifying unit 300 and the heating unit 200, respectively. The heat exchange unit 500 is connected to the heating unit 200 to control the temperature of the circulating refrigerant. By lowering it, it is possible to prevent overload from occurring in the heat exchange unit 500.

Therefore, the constant temperature and humidity system of the present invention can perform dehumidification and cooling as the heat exchanger 500, which is connected to the heating water circulating on the indoor floor and the outdoor unit to cool the refrigerant, is connected to the dehumidification unit 300, and the refrigerant It is connected to the heating unit 200 and has the feature of preventing overload of the heat exchange unit 500.

(Example 2-1) The present invention relates to a constant temperature and humidity system, and in Example 1-1, a heating device 210 formed in the heating unit 200 and controlling the temperature of heating water; A heating pipe (220) connected to the heating device (210) and installed on the indoor floor; It extends from the heating pipe 220 and includes a circulation pipe 230 that circulates heating water to the dehumidification unit 300.

(Example 2-2) In the constant temperature and humidity system of the present invention, in Example 2-1, the heating device 210 is formed as a boiler that heats and supplies heating water with one selected from gas, electricity, and oil; Includes.

(Example 2-3) In Example 2-2, the constant temperature and humidity system of the present invention is formed in the heating pipe 220 and is made of one selected from copper, copper, synthetic resin, and rubber.

(Example 2-4) In Example 2-1, the constant temperature and humidity system of the present invention includes that the heating pipe 220 is formed in a zigzag pattern on the indoor floor.

(Example 2-5) In Example 2-5, the constant temperature and humidity system of the present invention is formed at a location where the circulation pipe 230 and the heating pipe 220 are in contact, and is configured to adjust the flow path of heating water. Includes valve 231.

The present invention relates to a heating unit 200, and specifically, the heating unit 200 is installed on the floor of a room and circulates heating water. Referring to FIG. 2, this heating unit 200 is formed with a heating device 210 that controls and supplies the temperature of heating water at the same time. The heating device 210 is formed as a boiler and is heated by gas, electricity, oil, etc. Heat the heating water. In addition, the heating device 210 has a circulation pump to circulate the heating water with or without heating it. In addition, the heating device 210 is formed with a heating pipe 220 installed to be buried in the floor of an indoor room, and a circulation pipe 230 is extended at the end of the heating pipe 220 to heat the inside of the dehumidification unit 300. Rotate the numbers. At this time, the heating pipe 220 and the circulation pipe 230 are made of various materials such as copper, copper, synthetic resin, and rubber, and the heating pipe 220 is preferably formed in a zigzag pattern on the indoor floor. In addition, the circulation pipe 230 is arranged in a zigzag manner inside the dehumidification unit 300 to allow outdoor air to pass through, and is installed inside the dehumidification unit 300 by penetrating the dehumidification unit 300.

And, as the heating water formed inside the circulation pipe 230 formed in the heating unit 200 is formed to be higher than the external temperature in summer, the temperature of the outdoor air passing through the dehumidifying unit 300 increases. This is because the temperature of the heating pipe 220 embedded in the floor rises compared to the indoor temperature as the exterior wall and floor of the building rises due to the external temperature in the summer, so outdoor air passes through the circulation pipe 230 connected to the heating pipe 220. The temperature of is rising.

In addition, a control valve 231 is formed at the location where the circulation pipe 230 and the heating pipe 220 are in contact, and the control valve 231 allows heating water to flow to the dehumidifier 300 in the summer. In winter, when heating water is circulated and dehumidification and cooling are not performed, the heating water is heated so that the heating water is not circulated through the circulation pipe 230.

(Example 3-1) The present invention relates to a constant temperature and humidity system, and in Example 2-1, a housing 310 formed in the dehumidifying unit 300 and coupled with a duct 100 extending indoors ; A dehumidifying passage 320 formed to penetrate the inside of the housing 310 and through which indoor air and outdoor air pass, respectively; It includes a dehumidifying rotor 400 that is formed at the center of the dehumidifying passage 320 and rotates by power to adsorb moisture contained in indoor air.

(Example 3-2) In Example 3-1, the constant temperature and humidity system of the present invention includes that the duct 100 is formed so that indoor air and outdoor air pass through each.

(Example 3-3) In Example 3-1, the constant temperature and humidity system of the present invention includes that the housing 310 is installed on the floor or ceiling of the room.

(Example 3-4) In Example 3-1, the constant temperature and humidity system of the present invention is formed inside the housing 310 and measures selected one of the temperature, humidity, and pressure of indoor air and outdoor air. Includes a measuring sensor.

(Example 3-5) In Example 3-1, the constant temperature and humidity system of the present invention is formed in the housing 310 and includes a fixing device for fixing the dehumidification rotor 400.

(Example 3-6) In Example 3-1, the constant temperature and humidity system of the present invention is formed in the housing 310 and includes a filtration filter that filters indoor air and outdoor air.

The present invention relates to a dehumidifying unit 300, and specifically, the dehumidifying unit 300 circulates indoor air and simultaneously controls moisture contained in indoor air. Referring to FIG. 3, the dehumidifying unit 300 is installed on the floor or ceiling of the room where outdoor air is supplied and discharged. As the dehumidifying rotor 400 rotates, it adsorbs moisture and simultaneously discharges the adsorbed moisture. . At this time, a housing 310 is formed into which the duct 100 connected to the indoor ceiling is coupled, and an opening is formed in the housing 310 to which the duct 100 is coupled, and the location of the opening is that of the dehumidifying passage 320. It may be formed at each end or on the side of the housing 310.

And the housing 310 is formed in the shape of a box or cylinder, and the inside is open. In addition, a measurement sensor that measures temperature and humidity is formed in the dehumidification passage 320, and the measurement sensor measures the temperature, humidity, and pressure of indoor air and outdoor air before and after penetrating the dehumidification rotor 400.

In addition, a filtration filter is formed in the dehumidification passage 320, and the filtration filter is formed at a location where indoor air and outdoor air are introduced to prevent foreign substances along with moisture from being adsorbed on the dehumidification rotor 400. And a fixing device to which the dehumidifying rotor 400 is fixed is formed inside the housing 310, and the fixing device is formed at the center of the housing 310.

In addition, the dehumidifying rotor 400 is fixed to a fixing device formed inside the housing 310, and the dehumidifying rotor 400 is fixed to the center of the housing 310 so that the indoor air and outdoor air pass through each other. When connected, indoor air passes through half of the dehumidifying rotor 400 and outdoor air passes through the remaining half, adsorbing moisture, and at the same time, moisture is removed in the regeneration passage 322 and the dehumidifying rotor 400 is regenerated.

In this way, the control device controls the rotation speed of the dehumidifying rotor 400 and the temperatures of indoor air and outdoor air according to the temperature and humidity measured by the measurement sensor.

Therefore, the dehumidifying unit 300 of the present invention has the characteristic of adsorbing moisture and dehumidifying when indoor air is circulated.

(Example 3-7) In Example 3-1, the constant temperature and humidity system of the present invention includes a diffuser 110 formed at the end of the duct 100 and installed on the ceiling.

(Example 3-8) In Example 3-7, the constant temperature and humidity system of the present invention is formed in the diffuser 110 and includes an enclosure 111 installed on the ceiling, and is formed inside the enclosure 111. , suction unit 112 for sucking exhaust air; It is formed on the outer peripheral surface of the suction part 112 and includes a discharge part 113 that discharges incoming air.

(Example 3-9) In Example 3-8, the constant temperature and humidity system of the present invention includes a partition box 114 dividing the suction part 112 and the discharge part 113; It is formed to penetrate the partition box 114 and includes a rotating device 120 for sucking and discharging air.

(Example 3-10) In the constant temperature and humidity system of the present invention in Example 3-9, the rotating device 120 includes a penetrating shaft 121 penetrating the enclosure 111 and the partition enclosure 114; A rotating box 122 that rotates by the through shaft 121 and rotates in the partition box 114; It includes a blade 123 that is coupled to the through shaft 121 and the rotating box 122 and rotates by the through shaft 121.

(Example 3-11) In the constant temperature and humidity system of the present invention in Example 3-10, the blade 123 includes a first blade coupled to the through shaft 121 and sucking air; It includes a second blade that is formed at a different angle from the first blade and discharges air as it is coupled to the rotating housing 122.

(Example 3-12) In Example 3-7, the constant temperature and humidity system of the present invention includes a cover 124 coupled to one surface of the enclosure 111 and exposed to the room.

The present invention relates to a diffuser (110). Specifically, the diffuser 110 intakes and exhausts air to improve the air quality in each room. Referring to Figures 5 and 6, this diffuser 110 is formed as an enclosure 111 installed on the ceiling, and the enclosure 111 is formed so that one side is exposed to the room. And the enclosure 111 is formed as a cylinder to intake and discharge air, and the sucked air is delivered to the dehumidifier 300, and the indoor air whose moisture and temperature are adjusted in the dehumidifier 300 is circulated and discharged into the room. will be. At this time, the housing 111 is preferably injection molded, and contains copper powder to prevent bacteria from entering.

The diffuser 110 has an intake portion 112 and an discharge portion 113 formed inside the enclosure 111 so that air can be sucked in and discharged simultaneously. The suction part 112 and the discharge part 113 are partitioned by a partition box 114, and the partition box 114 is formed through the rotating device 120. The rotating device 120 has a penetrating shaft 121 that penetrates from the outside of the enclosure 111 to the compartment enclosure 114. At this time, the through shaft 121 is rotated by a motor outside the enclosure 111, and one end of the through shaft 121 extends to the inside of the compartment enclosure 114. And the penetrating shaft 121 is connected to a rotary enclosure 122 that rotates at the center of the partition enclosure 114 by a bearing, etc., and rotates the rotary enclosure 122 to rotate the plurality of blades 123. At this time, the blade 123 is formed of a first blade formed in the suction part 112 and a second blade formed in the discharge part 113. The first blade is formed inside the rotating housing 122 or is coupled to one end of the through shaft 121, and the second blade is formed outside the rotating housing 122. At this time, since the first blade and the second blade are formed at different angles, air can be sucked in and discharged simultaneously when the through shaft 121 rotates in one direction. In addition, the suction unit 112 is formed inside the partition box 114, is bent to one side, and is delivered to the dehumidifying unit 300. And the discharge part 113 is formed on the outside of the partition box 114, and is bent on one side to surround the suction part 112, so that the indoor air circulated in the dehumidification part 300 is delivered.

In this way, a cover 124 is formed on the enclosure 111 so that air is sucked and discharged through the suction part 112 and the discharge part 113, and the cover 124 includes the suction cover 124 and the discharge cover 124. The discharge cover 124 is formed to face the wall of the room separately from the ceiling, and the suction cover 124 is formed inside the discharge port so that air is sucked in from the center.

Therefore, the diffuser 110 of the present invention is installed on the indoor ceiling and has the characteristic of circulating indoor air and outdoor air.

(Example 3-13) In Example 3-8, the constant temperature and humidity system of the present invention includes a suction duct 130 formed in the duct 100 and connected to the suction part 112; an discharge duct 140 formed to surround the outside of the suction duct 130 and through which dehumidified indoor air is discharged; It includes a spacer 150 formed between the suction duct 130 and the discharge duct 140.

(Example 3-14) In Example 3-13, the constant temperature and humidity system of the present invention includes a conductive member 131 formed in the suction duct 130 and protruding outward and inward to conduct heat. do.

(Example 3-15) In Example 3-13, the constant temperature and humidity system of the present invention includes that the suction duct 130 and the discharge duct 140 are formed separately.

(Example 3-16) In Example 3-13, the constant temperature and humidity system of the present invention includes a fixing member 141 that protrudes to the outside of the discharge duct 140 and is fixed by fixing hardware.

The present invention relates to a duct (100). Specifically, the duct 100 is connected to the diffuser 110 and is a passage through which indoor air moves to the dehumidifying unit 300. Referring to FIGS. 7 to 9, this duct 100 is formed with a suction duct 130 connected to the suction part 112 of the diffuser 110, and an exhaust duct (130) is formed to surround the outside of the suction duct 130. 140) is formed. At this time, a spacer 150 is formed between the suction duct 130 and the discharge duct 140, and the spacer 150 is formed between the insertion frame 410 and the discharge duct ( A discharge frame 410 is formed to be in contact with the inner peripheral surface of 140). In addition, the insertion frame 410 and the discharge frame 410 are spaced by a plurality of intervals to guide the deformation of the discharge duct 140 and the position of the suction duct 130.

In addition, the suction duct 130 and the discharge duct 140 can be formed by being separated in half, and the half-separated suction duct 130 and discharge duct 140 are attached to the fixing member 141 fixed by the fixing hardware. is fixed by To explain this in detail, it is easy to move and store as the suction duct 130 and the discharge duct 140 are formed separately, and the suction duct 130 is placed to face each other and then inserted into the spacer 150 to change the shape. The shape of the discharge duct 140 is maintained by combining the upper and lower portions of the discharge duct 140 on the outside of the spacer 150, respectively. In addition, both ends of the suction duct 130 and the discharge duct 140 are formed to have a step, so that they can be easily joined, and separation of indoor air and outdoor air can be prevented.

In addition, the suction duct 130 is formed with a conducting member 131, and the conducting member 131 is formed with a conductive plate that is respectively coupled to the outer and inner peripheral surfaces of the suction duct 130 and a conductive protrusion that protrudes outward from the conductive plate. Heat exchange is performed between the outdoor air moving through the intake duct 130 and the discharge duct 140.

(Example 3-17) In Example 3-13, the constant temperature and humidity system of the present invention includes a blowing duct 160 that is formed in the duct 100 and moves indoor air as it rotates.

(Example 3-18) In Example 3-13, the constant temperature and humidity system of the present invention includes a clamp 161 formed in the blowing duct 160 and connecting a plurality of the discharge ducts 140; A first blowing duct 162 formed inside the clamp 161 and close to the suction duct 130; It includes a second blowing duct 163 formed outside the first blowing duct 162 and close to the end of the discharge duct 140.

(Example 3-19) In Example 3-16, the constant temperature and humidity system of the present invention is formed inside the clamp 161 and includes a blowing magnet 142 formed on the outer peripheral surface of the second blowing duct 163. It includes an electromagnet 164 formed to face.

(Example 3-20) In Example 3-16, the constant temperature and humidity system of the present invention is formed inside the first blowing duct 162 and the second blowing duct 163, and flows in different directions. Includes a blowing blade 165 that is installed and formed.

The present invention relates to a blowing duct (160). Specifically, the blowing duct 160 is formed as a module, and the blowing duct 160 is formed between the plurality of ducts 100. Referring to FIG. 10, this blowing duct 160 rotates between a plurality of ducts 100 to move indoor air in both directions. At this time, the blowing duct 160 is formed with a clamp 161 that connects the plurality of discharge ducts 140, and the clamp 161 is formed to surround the flange formed at the end of the discharge duct 140.

And an electromagnet 164 is formed inside the clamp 161, and the amount of current of the electromagnet 164 is determined by a control device. And the electromagnet 164 is formed to be inclined and rotates the first blowing duct 162 and the second blowing duct 163 formed inside the clamp 161, thereby forming an electromagnet ( The blowing magnet 142 is formed to face the 164). The blowing magnet 142 is formed at an angle and size corresponding to the electromagnet 164. When current is supplied to the electromagnet 164 and magnetic force is formed, the blowing magnet 142 is formed with the same pole as the electromagnet 164. It rotates. In addition, the first blowing duct 162 is formed closely to the suction duct 130 and the second blowing duct 163 is formed close to the discharge duct 140 to prevent indoor air from crossing each other.

And blowing blades 165 are formed in the first blowing duct 162 and the second blowing duct 163, and each blowing blade 165 is inclined in different directions, so that the first blowing duct 162 and the second blowing duct 163 are formed. The flow of air can be induced in the second blowing duct 163.

(Example 4-1) The present invention relates to a constant temperature and humidity system, and in Example 3-1, a frame 410 is formed on the dehumidifying rotor 400 and fixed to the inside of the housing 310; A dehumidifying member 420 that is inserted into the center of the frame 410 and absorbs moisture; It rotates the dehumidifying member 420, and includes a rotating member 460 installed on the frame 410 and rotating by power.

(Example 4-2) In Example 4-1, the constant temperature and humidity system of the present invention is formed in the frame 410 and includes an insertion groove 411 into which the dehumidifying member 420 is inserted.

(Example 4-3) In Example 4-2, the constant temperature and humidity system of the present invention is installed vertically or horizontally on the outside of the insertion groove 411, and includes a support 412 that supports the dehumidifying member 420. ); It is formed at the center of the support 412 and includes a rotation hinge 413 that guides the rotation of the dehumidifying member 420.

(Example 4-4) In Example 4-2, the constant temperature and humidity system of the present invention includes that the dehumidifying member 420 is formed to protrude outward from the frame 410.

(Example 4-5) In the constant temperature and humidity system of the present invention in Example 4-4, the rotating member 460 includes a rotary motor 461 that rotates by power; It includes a belt 463 connected to the rotation motor 461 and formed to surround the outside of the dehumidifying member 420.

(Example 4-6) In Example 4-5, the constant temperature and humidity system of the present invention includes a rotation gear 462 formed on the rotation motor 461 and rotating the belt 463.

The present invention relates to a dehumidifying rotor 400, and specifically, the dehumidifying rotor 400 is fixed inside the housing 310 to adsorb moisture circulating with indoor air. Referring to FIG. 4, the dehumidifying rotor 400 is formed with a frame 410 fixed to the inside of the housing 310. The frame 410 is made of a metal material and is deformed by the pressure of indoor air and outdoor air. Make sure it doesn't happen. And the frame 410 is formed in a box-shaped cross-sectional shape, and an insertion groove 411 in which the dehumidifying member 420 is accommodated is formed at the center. At this time, the insertion groove 411 is formed in a circular shape to accommodate the dehumidifying member 420 as the dehumidifying member 420 is formed in a circular shape, and a support for supporting the dehumidifying member 420 is provided on the outside of the insertion groove 411. (412) is formed. The support 412 is formed to protrude vertically or horizontally from the outside of the frame 410, and the support 412 is preferably coupled to a partition support inside the housing 310. And the support 412 is formed to protrude from the frame 410, and the dehumidifying member 420 is formed to protrude to the outside of the frame 410. In this way, a circulation passage 321 and a regeneration passage 322, which will be described later, are formed based on the support 412.

And a rotating hinge 413 is formed at the center of the support 412, and the dehumidifying member 420 rotates smoothly by the rotating hinge 413. In addition, a rotating member 460 is formed to rotate the dehumidifying member 420 coupled to the rotating hinge 413, and the rotating member 460 is formed at a corner of the frame 410 and rotates by power. A rotation gear 462 is formed that is coupled to the motor 461 and one end of the rotation motor 461 and rotates. And a belt 463 is formed to surround the rotating gear 462 and the dehumidifying member 420 and rotates the dehumidifying member 420 when the rotating gear 462 rotates.

(Example 4-7) In Example 4-1, the constant temperature and humidity system of the present invention includes a winding member formed on the dehumidifying member 420 and wound around the rotating member 460; It includes an adsorption material that is attached to one surface of the winding member and absorbs moisture.

(Example 4-8) In Example 4-7, the constant temperature and humidity system of the present invention includes a rotating shaft 430 formed on the winding member and coupled to the rotating hinge 413; It is formed to be spaced apart from the rotating shaft 430 and includes a rotating plate 440 formed on the outer peripheral surface of the winding member.

(Example 4-9) In Example 4-8, the constant temperature and humidity system of the present invention connects the rotating shaft 430 and the rotating plate 440 and prevents the dehumidifying member 420 from separating. Includes member 450;

(Example 4-10) In Example 4-8, the constant temperature and humidity system of the present invention includes a seating groove formed on the rotating plate 440 and into which the belt 463 is seated.

(Example 4-11) In Example 4-1, the constant temperature and humidity system of the present invention includes a first winding member formed on the winding member and having protrusions; It includes a second winding member formed to be spaced apart from the first winding member.

(Example 4-12) In Example 4-11, the constant temperature and humidity system of the present invention includes a bead formed on the first winding member and protruding in a short side direction; It includes a plurality of winding protrusions formed between the plurality of beads and protruding from one surface.

(Example 4-13) In Example 4-7, the constant temperature and humidity system of the present invention includes that the winding member is formed of one selected from PP (PolyPropylene), PS (PolyStyrene), and PC (polycarbonate). .

The present invention relates to a dehumidifying member 420, and specifically, the dehumidifying member 420 is inserted into the insertion groove 411 of the frame 410 to absorb moisture. Referring to FIG. 4, this dehumidifying member 420 has a rotating shaft 430 coupled to the rotating hinge 413 formed on the support 412, and a winding member coupled to the outside of the rotating shaft 430. . The winding member is formed of various synthetic resins such as PP (PolyPropylene), PS (PolyStyrene), and PC (polycarbonate). The winding member is a first winding member in which a plurality of protrusions are formed and a first winding member that is formed to overlap and be spaced apart from the first winding member. Two winding members are formed. At this time, a space is formed between the first winding member and the second winding member, and moisture is adsorbed. And the first winding member has beads that protrude in the short side direction, and the beads are formed at equal intervals. Such beads are formed to protrude from both sides at adjacent positions, thereby separating the first winding member and the second winding member. A plurality of winding protrusions are formed between the plurality of beads, and the winding protrusions each protrude from one or both sides of the first winding member, and are formed to protrude regularly or irregularly. At this time, moisture is adsorbed by the beads and the winding protrusions without the winding members contacting each other. And, unlike the first winding member, the second winding member is formed as a flat surface, and as it is wound, it is spaced apart from the first winding member that is in contact with each other by beads and winding protrusions.

In this way, when the winding member is wound around the rotating shaft 430, a rotating plate 440 is formed on the outside of the winding member to prevent the winding member from coming off, and a seating groove is formed in the rotating plate 440 so that the belt 463 is seated and the belt ( When 463) rotates, the dehumidifying member 420 rotates. Additionally, a separation prevention member 450 is formed between the rotation shaft 430 and the rotation plate 440 and prevents the winding member from being separated.

In addition, the winding member is fan-shaped and is formed into a module by stacking the first and second winding members on top of each other. As the winding members formed as modules are assembled together, if the winding member is damaged, it can be easily repaired.

(Example 5-1) The present invention relates to a constant temperature and humidity system, and in Example 4-1, a circulation passage 321 formed in the dehumidification passage 320 through which indoor air circulates; A regeneration passage 322 formed at a position corresponding to the circulation passage 321 and through which outdoor air passes; It includes a blower 330 formed in the circulation passage 321 and the regeneration passage 322, respectively, and circulating indoor air and outdoor air, respectively.

(Example 5-2) In Example 5-1, the constant temperature and humidity system of the present invention is formed in the dehumidifying passage 320 and includes a partition plate separating the circulation passage 321 and the regeneration passage 322. (323); Includes.

(Example 5-3) In Example 5-2, the constant temperature and humidity system of the present invention is formed in the blower 330 and is formed at one end of the circulation passage 321 to circulate indoor air. 1 blower (331); It is formed at one end of the regeneration passage 322 and includes a second blower 332 that discharges outdoor air.

(Example 5-4) In the constant temperature and humidity system of the present invention in Example 5-3, the first blower 331 is formed at the outlet of the circulation passage 321 and is a blower fan that rotates by power. Formed by; includes.

(Example 5-5) In the constant temperature and humidity system of the present invention in Example 5-1, the second blower 332 is formed at the outlet of the regeneration passage 322 and is a blower fan that rotates by power. Formed by; includes.

The present invention relates to a dehumidifying passage 320, and specifically, the dehumidifying passage 320 is formed on both sides of the housing 310, which is formed with an open interior, through which indoor air and outdoor air pass. Referring to FIG. 3, this dehumidifying passage 320 is formed in a position corresponding to the circulation passage 321 through which indoor air circulates, and a regeneration passage 322 through which outdoor air passes is formed. do. In addition, the dehumidifying passage 320 is formed with a partition plate 323 that separates the circulation passage 321 and the regeneration passage 322 to prevent indoor air and outdoor air from crossing each other. At this time, the circulation passage 321 is formed with an opening so that indoor air flowing in from one side or one end of the housing 310 can be discharged to one side or the other end of the housing 310, and the opening is formed with an inlet and an outlet. . And the regeneration passage 322 is discharged to the other side or lower part of the outdoor gogga housing 310, which is introduced from the other side or upper part of the housing 310.

In addition, a blower 330 is formed in the dehumidifying passage 320 to pass indoor air and outdoor air into the housing 310, and the blower 330 is a blowing fan located at the outlet of the circulation passage 321. The first blowing device 331 is formed. And a second blower 332 is formed at the first blower 331 and the other end regeneration passage 322.

In this way, the flow rate and flow rate of indoor air and outdoor air are adjusted by the blower 330 to pass through the dehumidifying passage 320.

(Example 6-1) The present invention relates to a constant temperature and humidity system. In Example 5-1, indoor air formed in the circulation passage 321 and circulating the refrigerant supplied from the heat exchange unit 500 A cooling device 340 that lowers the temperature by evaporation; It includes a heating device 350 formed in the regeneration passage 322 and increasing the temperature of the outdoor air circulated by the two blowers 330.

(Example 6-2) In Example 6-1, the constant temperature and humidity system of the present invention includes that the cooling device 340 is formed as an evaporator that absorbs heat from indoor air.

(Example 6-3) In Example 6-2, the constant temperature and humidity system of the present invention includes that the heating device 350 is formed as a condenser that heats outdoor air.

(Example 6-4) In Example 6-3, the constant temperature and humidity system of the present invention includes the heating device 350 whose temperature is controlled by current.

The present invention relates to a dehumidifying passage 320, and specifically, the dehumidifying passage 320 is formed with a cooling device 340 that cools indoor air circulating indoors. Referring to FIG. 3, this cooling device 340 is installed in the circulation passage 321 through which indoor air from which moisture has been removed circulates and uses refrigerant supplied by the heat exchange unit 500 formed outside the dehumidifying unit 300. The temperature can be lowered by evaporating. And the cooling device 340 is formed as an evaporator that absorbs heat from indoor air.

In addition, a heating device 350 is formed in the regeneration passage 322, and the heating device 350 heats the outdoor air, absorbs moisture from the dehumidifying rotor 400, and heats the moisture in the rotating dehumidifying member 420. Remove. At this time, the heating device 350 may be formed as a condenser that is connected to the cooling device 340 and heats outdoor air, or may be formed as an electric heating device 350 whose temperature is controlled by current. In addition, the heating device 350 can reduce the overload of the heating device 350 by increasing the temperature of the outdoor air by the heating unit 200 and then passing the outdoor air through the heating device 350.

(Example 7-1) The present invention relates to a constant temperature and humidity system. In Example 6-1, it is formed in the heat exchange unit 500 and is connected to the dehumidification unit 300 to cool the refrigerant condensed outdoors. A first heat exchange device for circulation (510); A second heat exchange device 530 formed integrally with or separate from the first heat exchange device 510 and connected to the heating unit 200 to adjust the temperature of the heating water by circulating refrigerant condensed outdoors; Includes.

(Example 7-2) In Example 7-1, the constant temperature and humidity system of the present invention is formed in the second heat exchange device 530 and includes a second outdoor unit 531 installed outdoors to compress and condense the refrigerant. Includes ;

(Example 7-3) In Example 7-2, the constant temperature and humidity system of the present invention is formed to be spaced apart from the second outdoor unit 531 and expands the refrigerant delivered to the heating unit 200 to low pressure. Includes a second expansion valve 532.

(Example 7-4) In Example 7-3, the constant temperature and humidity system of the present invention is connected to the second heat exchange device 530 and the heating pipe 220 is connected to control the temperature of the heating water. Includes a second heat exchanger (533).

(Example 7-5) In Example 7-1, the constant temperature and humidity system of the present invention includes that the second heat exchanger 533 is formed as a plate heat exchanger.

The present invention relates to the heat exchange unit 500, and specifically, the heat exchange unit 500 is connected to the dehumidification unit 300 and the heating unit 200 to circulate refrigerant. Referring to FIG. 2, this heat exchange unit 500 is connected to the cooling device 340 of the dehumidification unit 300 to form a first heat exchange device 510 that circulates the condensed refrigerant outdoors. 510 is formed to compress and condense the refrigerant. In addition, a second heat exchange device 530 is formed integrally with or separately from the first heat exchange device 510 and is connected to the heating unit 200 to regulate the temperature of the heating water by circulating the condensed refrigerant outdoors. In addition, the second heat exchange device 530 is installed outdoors to form a second outdoor unit 531 that compresses and condenses the refrigerant, and a second expansion valve 532 is formed in the second outdoor unit 531 to compress and condense the refrigerant. can be inflated. At this time, a refrigerant pipe 501 through which the refrigerant circulates is formed in the second heat exchange device 530, and the refrigerant pipe 501 is connected to the second heat exchanger 533 with the heating pipe 220 of the heating unit 200. connected to And the second heat exchanger 533 is formed as a plate heat exchanger, so that the refrigerant circulated in the refrigerant pipe 501 is circulated, and a heating pipe 220 is connected to the other end of the refrigerant pipe 501 to perform heat exchange by the refrigerant. By adjusting the temperature of the heating water, the indoor floor temperature can be adjusted.

(Example 8-1) The present invention relates to a constant temperature and humidity system. In Example 7-1, a first outdoor unit is formed in the first heat exchange device 510 and is installed outdoors to compress and condense the refrigerant. (511); a first expansion valve 512 formed to be spaced apart from the first outdoor unit 511 and expanding the refrigerant delivered to the cooling device 340 of the dehumidifier 300 to low pressure; It includes a control member 520 formed between the first outdoor unit 511 and the first expansion valve 512 and through which the refrigerant is delivered to the heating unit 200.

(Example 8-2) In Example 8-1, the constant temperature and humidity system of the present invention is formed in the first heat exchange device 510 and includes a refrigerant pipe 501 through which the refrigerant circulates.

(Example 8-3) In Example 8-2, the constant temperature and humidity system of the present invention includes a circulation pipe 521 formed in the control member 520 and connected to the heating unit 200 to circulate the refrigerant. ; A first heat exchanger 522 is formed at the end of the circulation pipe 521 and is connected to the heating pipe 220 of the heating unit 200 to exchange heat between the heating water and the refrigerant.

(Example 8-4) In Example 8-3, the constant temperature and humidity system of the present invention includes a circulation valve 513 connected to the refrigerant pipe 501 to control the circulation direction of the refrigerant.

(Example 8-5) In Example 8-4, the constant temperature and humidity system of the present invention is formed in the circulation pipe 521, and the first heat exchanger 522 is formed as a plate heat exchanger. do.

The present invention relates to the first heat exchange device 510. Specifically, the first heat exchange device 510 is installed outdoors to circulate the temperature of the refrigerant and is connected to the heating unit 200 to reduce overload of the outdoor unit. There is. Referring to FIG. 2, this first heat exchange device 510 is installed outdoors to form a first outdoor unit 511 that compresses and condenses the refrigerant, and the first outdoor unit 511 is a refrigerant pipe 501 through which the refrigerant circulates. ) is connected to the cooling device 340 of the dehumidifying unit 300.

In addition, a first expansion valve 512 is formed in the refrigerant pipe 501 to expand the refrigerant at low pressure, and the refrigerant pipe 501 formed between the first expansion valve 512 and the first outdoor unit 511 is An adjustment member 520 is formed. At this time, the control member 520 is formed with a circulation pipe 521 connecting the refrigerant pipe 501 and the heating pipe 220, and the circulation pipe 521 is fastened to the heating pipe 220 to allow heating water and refrigerant to flow. A first heat exchanger 522 that exchanges heat with each other is formed. The first heat exchanger 522 is formed as a plate heat exchanger, and heat exchange occurs as the heating pipe 220 and the refrigerant pipe 501 are combined and circulated inside the plate heat exchanger. In addition, the circulation pipe 521 is formed with a circulation valve 513 at a position in contact with the refrigerant pipe 501, and the circulation valve 513 circulates the refrigerant to the heating pipe 220 and the heating pipe 220 according to the load of the first outdoor unit 511. Encourage heat exchange.

To explain this in more detail, if the temperature of the refrigerant supplied from the first outdoor unit 511 is high in the summer, overload of the first outdoor unit 511 may occur, so the refrigerant is used in the dehumidifier 300 for heating whose temperature is lowered by the outdoor air. The temperature of the refrigerant supplied to the first expansion valve 512 is lowered by heat exchange with the water flowing heating pipe 220. Thus, the heating water is prevented from being overcooled as its temperature increases due to the refrigerant, and the first outdoor unit 511 can prevent overload to lower the temperature of the refrigerant.

Therefore, the first heat exchanger 522 of the present invention has the feature of controlling the temperature of the refrigerant and exchanging heat with heating water to prevent overload.

100: duct 110: diffuser
111: enclosure 112: suction part
113: discharge unit 114: compartment box
120: Rotating device 121: Penetrating shaft
122: Rotating housing 123: Blade
124: Cover 130: Suction duct
131: Conducting member 140: Discharge duct
141: Fixing member 142: Blowing magnet
150: Spacer 160: Blowing duct
161: Clamp 162: First blowing duct
163: Second blowing duct 164: Electromagnet
165: blowing blade 200: heating unit
210: Heating device 220: Heating pipe
230: circulation pipe 231: control valve
300: dehumidification unit 310: housing
320: Dehumidification passage 321: Circulation passage
322: Regeneration passage 323: Partition plate
330: Blowing device 331: First blowing device
332: second blower 340: cooling device
350: Heating device 400: Dehumidifying rotor
410: Frame 411: Insertion groove
412: Support 413: Rotating hinge
420: Dehumidifying member 430: Rotating shaft
440: Rotating plate 450: Separation prevention member
460: Rotating member 461: Rotating motor
462: Rotating gear 463: Belt
500: heat exchange unit 501: refrigerant piping
510: first heat exchange device 511: first outdoor unit
512: first expansion valve 513: circulation valve
520: Control member 521: Circulation pipe
522: first heat exchanger 530: second heat exchange device
531: Second outdoor unit 532: Second expansion valve
533: Second heat exchanger

Claims (10)

A heating unit 200 formed on the indoor floor and through which heating water circulates;
A dehumidifying unit (300) connected to the heating unit (200) and rotating by power to remove moisture contained in indoor air;
A heat exchange unit 500 connected to the dehumidifying unit 300 and the heating unit 200, respectively, and adjusting the temperature of indoor air and heating water as the refrigerant circulates;
A first heat exchange device 510 formed in the heat exchange unit 500 and connected to the dehumidification unit 300 to circulate the condensed refrigerant outdoors;
A second heat exchange device 530 formed integrally with or separate from the first heat exchange device 510 and connected to the heating unit 200 to adjust the temperature of the heating water by circulating refrigerant condensed outdoors; A constant temperature and humidity system including.
In claim 1,
A heating device 210 formed in the heating unit 200 and controlling the temperature of the heating water;
A heating pipe (220) connected to the heating device (210) and installed on the indoor floor;
A constant temperature and humidity system comprising a circulation pipe (230) extending from the heating pipe (220) and circulating heating water to the dehumidification unit (300).
In claim 2,
A housing 310 formed in the dehumidifying unit 300 and coupled with a duct 100 extending indoors;
A dehumidifying passage 320 formed to penetrate the inside of the housing 310 and through which indoor air and outdoor air pass, respectively;
A constant temperature and humidity system comprising a dehumidifying rotor (400) formed at the center of the dehumidifying passage (320) and rotating by power to adsorb moisture contained in indoor air.
In claim 3,
A frame 410 formed on the dehumidifying rotor 400 and fixed to the inside of the housing 310;
A dehumidifying member 420 that is inserted into the center of the frame 410 and absorbs moisture;
A constant temperature and humidity system comprising a rotating member 460 that rotates the dehumidifying member 420 and is installed on the frame 410 and rotated by power.
In claim 3,
A circulation passage 321 formed in the dehumidifying passage 320 through which indoor air circulates;
A regeneration passage 322 formed at a position corresponding to the circulation passage 321 and through which outdoor air passes;
A constant temperature and humidity system comprising a blower (330) formed in the circulation passage (321) and the regeneration passage (322), respectively, to circulate indoor air and outdoor air, respectively.
In claim 5,
A cooling device 340 formed in the circulation passage 321 and lowering the temperature of the refrigerant supplied from the heat exchanger 500 by evaporating it with circulating indoor air;
A constant temperature and humidity system comprising a heating device (350) formed in the regeneration passage (322) and increasing the temperature of the outdoor air circulated by the blower (330).
delete In claim 1,
A first outdoor unit 511 formed in the first heat exchange device 510 and installed outdoors to compress and condense the refrigerant;
a first expansion valve 512 formed to be spaced apart from the first outdoor unit 511 and expanding the refrigerant delivered to the cooling device 340 of the dehumidifier 300 to low pressure;
A constant temperature and humidity system comprising a control member (520) formed between the first outdoor unit (511) and the first expansion valve (512) and through which refrigerant is delivered to the heating unit (200).
In claim 8,
A circulation pipe 521 formed on the control member 520 and connected to the heating unit 200 to circulate the refrigerant;
A constant temperature and humidity system comprising a first heat exchanger (522) formed at an end of the circulation pipe (521) and connected to the heating pipe (220) of the heating unit (200) to exchange heat between heating water and refrigerant.
In claim 2,
A second outdoor unit (531) formed in the second heat exchange device (530) and installed outdoors to compress and condense the refrigerant;
a second expansion valve 532 formed to be spaced apart from the second outdoor unit 531 and expanding the refrigerant delivered to the heating pipe 220 to low pressure;
A constant temperature and humidity system comprising a second heat exchanger (533) connected to the second expansion valve (532) and connected to the heating pipe (220) to control the temperature of the heating water.