KR102631139B1 - Liquid desiccant ventilation total heat recovery device using heat pump - Google Patents

Abstract

The present invention reduces the occurrence of mold and bacteria due to condensation, enables continuous heat recovery using a humidity control solution, reduces the rate of leakage by completely separating outdoor air and indoor air, and provides cooling, heating, dehumidification, humidification, and air purification. And a liquid humidity control ventilation electric heat recovery device using a heat pump capable of sterilization can be provided.

Description

Liquid humidity control ventilation electric heat recovery device using a heat pump {LIQUID DESICCANT VENTILATION TOTAL HEAT RECOVERY DEVICE USING HEAT PUMP}

The present invention relates to a liquid humidity control ventilation electric heat recovery device using a heat pump.

As heat exchange occurs between internal air and external air in heat recovery ventilators using existing heat exchange elements, condensation may occur in the heat exchange elements, causing mold and bacteria to form, and condensation may occur inside the device, including the heat exchange elements. This may cause rust. In addition, environmental problems may arise due to frequent replacement costs and disposal of the total heat exchange element. In addition, the existing heat recovery ventilation system may not operate due to freezing problems due to condensation in winter. To solve this problem, an electric heater can be installed inside, but this causes the problem of energy waste.

Likewise, there is a rotary ventilation system to solve the problem of condensation and freezing, but the rate at which air discharged from the room mixes with the re-supplied air, that is, the leakage rate is high, so the heat exchange rate is reduced.

The present invention is intended to solve the above problems. It reduces the occurrence of mold and bacteria due to condensation, enables continuous heat recovery using a humidity control solution, reduces the leakage rate by completely separating outdoor air and indoor air, and reduces cooling. The purpose is to provide a liquid-type humidity control ventilation electric heat recovery device using a heat pump capable of heating, dehumidification, humidification, air cleaning, and sterilization.

In order to achieve the above object, the purpose of the present invention is to provide a liquid humidity control ventilation electric heat recovery device using the following heat pump.

In one embodiment of the present invention, an outdoor air unit is provided on one side and introduces outdoor air, an air supply unit is provided on the other side and supplies the outdoor air into the room, and a flow of the outdoor air is formed from the outdoor air unit to the air supply unit. A first fan including a first fan member, provided between the external air unit and the air supply unit, and further comprising a first receiving tank in which the humidity control solution is accommodated, and a first gas-liquid contact part in which the outdoor air and the humidity control solution contact and exchange heat. A processing unit, a ventilation unit provided on the other side and into which indoor air flows, an exhaust unit provided on the one side and exhausting the indoor air to the outdoors, and a second fan member that forms a flow of indoor air from the ventilation unit to the exhaust unit. A second processing unit, the first processing unit further comprising a second receiving tank provided between the ventilation unit and the exhaust unit and containing the humidity control solution, and a second gas-liquid contact unit in which the indoor air and the humidity control solution contact and exchange heat. A plurality of heat exchangers connecting the processing unit and the second processing unit and including a first heat exchanger and a second heat exchanger installed to exchange heat with the humidity control solution, a compressor in which the refrigerant circulating through the plurality of heat exchangers is compressed, and the refrigerant expands A heat pump unit including an expansion valve and a refrigerant line for transferring the refrigerant, a first transfer line for transferring the humidity control solution from the first storage tank to the first heat exchanger by a first pump, and the second storage tank. A second transfer line for transferring the humidity control solution from the tank to the second heat exchanger by a second pump, a third transfer line for transferring the humidity control solution from the first heat exchanger to the second gas-liquid contact part, and the second transfer line for transferring the humidity control solution from the tank to the second heat exchanger by the second pump. It includes a fourth transfer line for transferring the humidity control solution from the heat exchanger to the first gas-liquid contact unit, and a liquid humidity control unit including a transfer unit for transferring the humidity control solution circulating through the first processing unit, the second processing unit, and the heat pump unit. A ventilation electric heat recovery device is provided.

In one embodiment, it is installed on the refrigerant line and may further include a first flow path switching valve that switches the flow path of the refrigerant circulating in the heat pump unit.

In one embodiment, the plurality of heat exchangers are provided in the first processing unit, and a third heat exchanger is installed to exchange heat with the outdoor air passing through the first processing unit and the second processing unit, and the second processing unit It may further include a fourth heat exchanger installed to exchange heat with the indoor air passing through.

In one embodiment, the third heat exchanger is disposed on a flow path of air flowing inside the first processing unit, and is disposed between the first gas-liquid contact part and the air supply unit, and the fourth heat exchanger is inside the second processing unit. It may be disposed on a flow path of air flowing in, and may be disposed between the second gas-liquid contact portion and the exhaust portion.

In one embodiment, it is installed in each of the first to fourth transfer lines and may further include a second flow path switching valve that switches the flow path of the humidity control solution transported through the transfer unit.

In one embodiment, the first processing unit is installed in the external air unit and further includes a first external damper that opens and closes the external air unit, and the second processing unit is installed in the exhaust unit and opens and closes the exhaust unit. It further includes two external dampers, and an internal damper that opens and closes the air flow between the first processing unit and the second processing unit may be installed in at least one of the first processing unit and the second processing unit.

In one embodiment, when the air cleaning mode is operating, the first external damper and the second external damper may be closed and the internal damper may be opened.

In one embodiment, the transfer unit is installed in a bypass line connecting the first accommodating tank and the second accommodating tank and in the first accommodating tank and the second accommodating tank, respectively, and includes a level sensor that detects the level of the humidity control solution. More may be included.

The present invention reduces the occurrence of mold and bacteria due to condensation, enables continuous heat recovery using a humidity control solution, reduces the rate of leakage by completely separating outdoor air and indoor air, and provides cooling, heating, dehumidification, humidification, and air purification. It is possible to provide a liquid type humidity control ventilation electric heat recovery device using a heat pump capable of sterilization.

Figure 1 is a schematic diagram showing a liquid-type humidity control ventilation electric heat recovery device according to an embodiment of the present invention.
Figure 2 is a schematic diagram showing a liquid type humidity control ventilation electric heat recovery device according to another embodiment of the present invention.
Figure 3 is a schematic diagram showing a liquid type humidity control ventilation electric heat recovery device according to another embodiment of the present invention.
Figure 4 is a first modified example of Figure 1.
Figure 5 is a second modified example of Figure 1.

Hereinafter, with reference to the attached drawings, preferred embodiments will be described in detail so that those skilled in the art can easily practice the present invention. However, when describing preferred embodiments of the present invention in detail, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. In addition, the same symbols are used throughout the drawings for parts that perform similar functions and actions. In addition, in this specification, terms such as 'upper', 'top', 'upper surface', 'lower', 'lower', 'lower surface', 'side', etc. are based on the drawings and are actually elements or components. It may vary depending on the direction in which it is placed.

In addition, throughout the specification, when a part is said to be 'connected' to another part, this does not only mean 'directly connected', but also 'indirectly connected' with another element in between. Includes. In addition, 'including' a certain component means that other components may be further included rather than excluding other components, unless specifically stated to the contrary.

Figure 1 shows a liquid-type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention. Hereinafter, with reference to Figure 1, a liquid-type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention is shown. ) is explained in detail.

As shown in FIG. 1, the liquid humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention includes a first processing unit 100, a second processing unit 200, a heat pump unit 300, and a transfer unit 400. ) includes. At this time, the first processing unit 100 allows outdoor air to flow in and supplies air indoors, the second processing unit 200 allows indoor air to flow in and exhausts air to the outdoors, and the heat pump unit 300 The humidity control solution (S) processed in the first processing unit 100 and the second processing unit 200 may exchange heat with the refrigerant circulating in the heat pump unit 300. At this time, the humidity control solution (S) used in the present invention can be an aqueous lithium chloride (LiCl) solution that can simultaneously satisfy the dehumidification/humidification, sterilization, and cleaning functions of the air, and various solutions with other humidity control functions can be used. It can be included.

First, the first processing unit 100 is composed of an outdoor air unit 110 provided on one side and into which outdoor air flows, and an air supply unit 120 provided on the other side and supplied with the outdoor air into the room, and the outdoor air unit ( It includes a first fan member 130 that forms a flow of outdoor air so that outdoor air introduced through 110) is supplied indoors through the air supply unit 120. In addition, the first processing unit 100 is provided between the external air unit 110 and the air supply unit 120 and includes a first storage tank 140 in which the humidity control solution (S) is accommodated, and the outdoor air and the humidity control solution ( S) further includes a first gas-liquid contact portion 150 in contact with which heat is exchanged.

At this time, the first gas-liquid contact part 150 may include a first spray nozzle 151 and a first contact cell 152, and the first spray nozzle 151 evenly sprays the humidity control solution (S). It is a device that maximizes contact efficiency with air and can use at least one of gravity spraying, low pressure spraying, high pressure nozzle spraying, ultrasonic spraying, electrostatic spraying, and centrifugal spraying. In addition, the first contact cell 152 may be installed on the side of the first injection nozzle 151, and more specifically, the first contact cell 152 may be placed below the first injection nozzle 151. The first contact cell 152 can maximize the contact area between the outdoor air introduced into the first processing unit 100 and the humidity control solution (S) sprayed from the first spray nozzle 151. and may have a honeycomb structure.

In addition, the first processing unit 100 may further include a first eliminator 160 provided on the air supply unit 120 side. The first eliminator 160 serves to prevent the humidity control solution (S) from scattering toward the air supply unit 120, and is a scattering removal device that can be used as a filter type, demister, electrostatic type, or any equivalent or higher device. One may apply. Accordingly, corrosion of the first fan member 130 can be prevented.

Furthermore, the first processing unit 100 may further include a first filter unit 170, and the first filter unit 170 may include an external air filter 171 and an air supply filter 172, The external air filter 171 may be installed in the external air unit 110, and the air supply filter 172 may be installed in the air supply unit 120. At this time, the external air filter 171 may be configured to remove coarse particulate matter (insects, fallen leaves, coarse dust, etc.), and the air supply filter 172 may be a HEPA filter configured to remove fine particulate matter. , it is not limited to this as long as the outdoor air can be filtered and fresh air can be supplied indoors.

First, the second processing unit 200 is composed of a ventilation unit 220 provided on the other side and into which indoor air flows, and an exhaust unit 210 provided on one side and exhausting the indoor air to the outdoors. It includes a second fan member 230 that forms a flow of the indoor air so that the indoor air introduced through the unit 220 is exhausted to the outdoors through the exhaust unit 210. In addition, the second processing unit 200 is provided between the exhaust unit 210 and the ventilation unit 220 and includes a second storage tank 240 in which the humidity control solution (S) is accommodated, and the indoor air and humidity control solution ( S) further includes a second gas-liquid contact portion 250 in contact with which heat is exchanged.

At this time, the second gas-liquid contact part 250 may include the second injection nozzle 251 and the second contact cell 252, and the second injection nozzle 251 and the second contact cell 252 are It may be configured in the same way as the first injection nozzle 151 and the first contact cell 152. In addition, the second processing unit 200 may further include a second eliminator 260 provided on the exhaust unit 210 side, and the second eliminator 260 is the first eliminator. It may have the same configuration as the eater 160, and can prevent the humidity control solution (S) from scattering toward the exhaust unit 210. Furthermore, the second processing unit 200 may further include a second filter unit 270, and the second filter unit 270 may be installed in the ventilation unit 220, and the outside air filter 171 ), it can be configured to remove coarse particulate materials (insects, fallen leaves, coarse dust, etc.), thereby preventing foreign substances, etc. from falling or accumulating inside the second processing unit 200.

The heat pump unit 300 connects the first processing unit 100 and the second processing unit 200 to heat exchange the humidity control solution (S), and includes a plurality of heat exchangers 310, a compressor 320, and an expansion valve. (330) and refrigerant line (340). The plurality of heat exchangers 310 include a first heat exchanger 311 and a second heat exchanger 312, and the compressor 320 includes the first heat exchanger 311 and the second heat exchanger 312. By compressing the refrigerant circulating, the pressure of the refrigerant can be increased and the temperature relatively increased, and the expansion valve 330 expands the high-temperature and high-pressure refrigerant to lower the pressure of the refrigerant and relatively lower the temperature. You can.

At this time, the refrigerant line 340 can transport the refrigerant circulating in the heat pump unit 300. The high-temperature and high-pressure refrigerant compressed in the compressor 320 may be transferred to the first heat exchanger 311 through the refrigerant line 340. At this time, the first heat exchanger 311 functions as a condenser. can do. Meanwhile, the refrigerant that has undergone heat exchange in the first heat exchanger 311 passes through the expansion valve 330 and can become a low-temperature and low-pressure refrigerant, and is transferred to the second heat exchanger ( 312), where the second heat exchanger 312 may function as an evaporator, and the refrigerant that has undergone heat exchange in the second heat exchanger 312 may be transferred back to the compressor 320. You can. By this, the heat pump unit 300 can implement a continuous refrigerant cycle. Meanwhile, the first heat exchanger 311 and the second heat exchanger 312 may have the same configuration, and the first heat exchanger 311 functions as an evaporator by the first flow path switching valve 510, which will be described later. And the second heat exchanger 312 can function as a condenser.

The transfer unit 400 includes a first transfer line 410, a second transfer line 420, a third transfer line 430, and a fourth transfer line 440, and the first processing unit 100 and the fourth transfer line 440. 2 The humidity control solution (S) circulating through the processing unit 200 and the heat pump unit 300 can be transferred. At this time, the first transfer line 410 can transfer the humidity control solution (S) from the first receiving tank 140 to the first heat exchanger 311 by the first pump 411, The second transfer line 420 may transfer the humidity control solution (S) from the second receiving tank 240 to the second heat exchanger 312, and the third transfer line 430 may transfer the humidity control solution (S) from the second receiving tank 240 to the second heat exchanger 312. The humidity control solution (S) is transferred from the heat exchanger 311 to the second gas-liquid contact part 250, and the fourth transfer line 440 is operated from the second heat exchanger 312 to the first gas-liquid contact part 150. ) can be used to transfer the humidity control solution (S).

In addition, the transfer unit 400 may further include a bypass line 450 connecting the first storage tank 140 and the second storage tank 240, and the bypass line 450 is the first storage tank 140 and the second storage tank 240. If the water level in any one of the first receiving tank 140 and the second receiving tank 240 is uneven, the water level can be adjusted by transferring the humidity control solution (S). Furthermore, the transfer unit 400 may further include a level sensor (not shown) that detects the water level of the humidity control solution (S). The level sensor (not shown) may be installed in at least one of the first accommodating tank 140 and the second accommodating tank 240, and the first accommodating tank 140 and the second accommodating tank 240 It is possible to control indoor humidity by detecting the water level, and as long as indoor humidity control is possible by detecting the water level, the installation location of the level sensor (not shown) is not limited. In addition, the transfer unit 400 may apply a solution filter (not shown) to at least one of the first to fourth transfer lines 410, 420, 430, and 440 and the bypass line 450, and the A solution filter (not shown) can remove impurities from the humidity control solution (S).

In addition, the liquid-type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention is installed on the refrigerant line 340 and can change the flow path of the refrigerant circulating in the heat pump unit 300. It may further include a first flow path switching valve 510. For example, the first flow path switching valve 510 may be a four-way valve, and in the cooling mode, the high-temperature and high-pressure refrigerant compressed in the compressor 320 is transferred to the first heat exchanger 311. The first heat exchanger 311 functions as a condenser, and as the low-temperature and low-pressure refrigerant expanded in the expansion valve 330 is transferred to the second heat exchanger 312, the second heat exchanger 312 It can function as an evaporator. Conversely, in the heating mode, the high-temperature and high-pressure refrigerant compressed in the compressor 320 is transferred to the second heat exchanger 312 by the first flow path switching valve 510. The second heat exchanger 312 may function as a condenser, and the low-temperature and low-pressure refrigerant expanded in the expansion valve 330 is transferred to the first heat exchanger 311 ( 311) can act as an evaporator.

Hereinafter, the flow of refrigerant, humidity control solution (S), and air in the cooling mode, heating mode, and bypass mode of the liquid humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention will be described, and FIG. 1 It is explained with reference to .

First, in the cooling mode, the high-temperature, high-pressure refrigerant compressed in the compressor 320 is transferred to the first heat exchanger 311 through the first flow path switching valve 510, and the refrigerant is transferred to the first heat exchanger 311. It is condensed by heat exchange with the humidity control solution (S) supplied to the first heat exchanger 311, and the condensed refrigerant passes through the expansion valve 330 and changes into a low-temperature and low-pressure refrigerant. It may be transferred to the second heat exchanger 312 and evaporated while exchanging heat with the humidity control solution (S) supplied to the second heat exchanger 312. The re-evaporated refrigerant may be transferred to the compressor 320 through the first flow path switching valve 510 and compressed.

In addition, in the cooling mode, the humidity control solution (S) is transferred from the first receiving tank 140 to the first heat exchanger 311 through the first transfer line 410 by the first pump 411. The humidity control solution (S), which is transferred and heated by heat exchange with the condensation heat of the refrigerant, is transferred to the second gas-liquid contact part 250 through the third transfer line 430, and is discharged from the second injection nozzle 251. It is sprayed toward the second contact cell 252. At this time, the heated humidity control solution (S) can discharge heat and moisture in contact with the indoor air introduced into the second processing unit 200, and as a result, the temperature is relatively lowered and the humidity control solution (S) has a thickened concentration. S) can be accommodated again in the second storage tank 240. Thereafter, the humidity control solution (S) contained in the second receiving tank 240 is transferred to the second heat exchanger 312 through the second transfer line 420 by the second pump 421, The humidity control solution (S) cooled by heat exchange with the heat of evaporation of the refrigerant is transferred to the first gas-liquid contact part 150 through the fourth transfer line 440, and is transferred to the first gas-liquid contact part 150 through the first injection nozzle 151. It is sprayed toward the contact cell 152. At this time, the cooled humidity control solution (S) can absorb heat and moisture in contact with the outdoor air introduced into the first processing unit 100, and as a result, the temperature is relatively high and the humidity control solution (S) has a diluted concentration. ) can be accommodated in the first storage tank 140. Thereafter, the humidity control solution (S) in the first storage tank 140 may be transferred back to the second storage tank 240 through the bypass line 450.

In addition, in the cooling mode, the air is introduced from the first processing unit 100 through the external air unit 110, passes through the external air filter 171, first removes contaminants, and is then transferred to the first gas-liquid contact unit. Head towards (150). Thereafter, the cooled humidity control solution (S) sprayed from the first spray nozzle 151 comes into contact with the first contact cell 152 to cool and dehumidify, and bacteria and viruses can be removed. Thereafter, the air passes through the first eliminator 160 and can provide fresh, cooled, and dehumidified air to the room through the air supply unit 120. In the second processing unit 200, indoor air introduced through the ventilation unit 220 first removes contaminants through the second filter unit 270 and then heads to the second gas-liquid contact unit 250. At this time, the air comes into contact with the heated humidity control solution (S) sprayed from the second injection nozzle 251 and the contact cell 252, and can absorb heat and moisture of the humidity control solution (S). Thereafter, the air that has absorbed heat and moisture may pass through the second eliminator 260 and be discharged outdoors through the exhaust unit 210.

First, in the heating mode, the refrigerant can be transferred opposite to the cooling mode by the first flow path switching valve 510. That is, as the high-temperature and high-pressure refrigerant compressed in the compressor 320 is transferred to the second heat exchanger 312, the second heat exchanger 312 functions as a condenser, and conversely, the first heat exchanger 312 functions as a condenser. (311) can serve as an evaporator. Therefore, the refrigerant transferred to the second heat exchanger 312 is condensed by heat exchange with the humidity control solution (S) supplied to the second heat exchanger 312, and the condensed refrigerant passes through the expansion valve 330. It changes into a low-temperature and low-pressure refrigerant, and the low-temperature and low-pressure refrigerant is transferred to the first heat exchanger (311) and exchanges heat with the humidity control solution (S) supplied to the first heat exchanger (311) and can be evaporated. . The re-evaporated refrigerant may be transferred to the compressor 320 through the first flow path switching valve 510 and compressed.

In addition, the transfer path of the humidity control solution (S) in the heating mode may be the same as that in the cooling mode, except that the first heat exchanger 311 serves as an evaporator and the second heat exchanger 312 As it functions as a condenser, heat exchange of the humidity control solution (S) may vary. That is, as the humidity control solution (S) supplied from the first receiving tank 140 and heat-exchanged in the first heat exchanger 311 is cooled by heat exchange with the heat of evaporation of the refrigerant, the second gas-liquid contact portion 250 The humidity control solution (S) cooled in can be sprayed, and conversely, the humidity control solution (S) supplied from the second receiving tank 240 and heat-exchanged in the second heat exchanger 312 is combined with the condensation heat of the refrigerant. As it is heated through heat exchange, the humidity control solution (S) heated in the first gas-liquid contact portion 150 may be sprayed.

In addition, the air flow in the heating mode may be the same as that in the cooling mode, but in the first processing unit 100, the outdoor air flows in and exchanges heat with the heated humidification solution (S) to warm and humidify the air. The cooled air can be provided indoors, and the second processing unit 200 can discharge the cooled and dehumidified air outdoors as the indoor air flows in and exchanges heat with the cooled humidity control solution (S).

Meanwhile, in the bypass mode, the liquid humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention operates the first fan member 130 and the second fan member 130 while terminating operation of the heat pump unit 300. The fan member 230 can be operated. At the same time, as the operation of the first pump 411 is terminated and only the second pump 421 is operated, the humidity control solution (S) in the second storage tank 240 is discharged from the heat pump unit 300. It can be directed to the first gas-liquid contact part 150 without heat exchange, is sprayed from the first spray nozzle 151, and comes into contact with outdoor air passing through the first processing part 100 to kill bacteria and viruses. It can be removed. As a result, the liquid humidity control ventilation electric heat recovery device 10 can supply fresh air to the indoor space without heat exchange, and in the second processing unit 200, as the operation of the first pump 411 ends, the indoor air Air can be exhausted outdoors without contact with the humidity control solution (S). Meanwhile, the humidity control solution (S) contained in the first receiving tank 140 is transferred to the second receiving tank 240 through the bypass line 450 to maintain the water level at all times.

According to the liquid-type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention described above, cooling and heating are carried out by contact with the humidity control solution (S), so that heat generated in the plurality of heat exchangers 310 There is no problem of condensation or freezing, and since it does not freeze even in sub-zero temperatures, continuous heat recovery is possible and indoor load can be reduced during ventilation. In addition, the heat pump unit 300 improves cooling and dehumidification performance in summer and heating and humidification performance in winter, and when dehumidification and humidification are required during the rainy season or winter, dehumidified or humidified air can be supplied indoors. there is.

Figure 2 shows a liquid type humidity control ventilation electric heat recovery device 10 according to another embodiment of the present invention. Hereinafter, a liquid type humidity control ventilation electric heat recovery device 10 according to another embodiment of the present invention will be described with reference to FIG. 2, but description of overlapping parts will be omitted and the differences will be mainly explained.

As shown in FIG. 2, the liquid humidity control ventilation electric heat recovery device 10 according to another embodiment of the present invention includes a plurality of heat exchangers 310, the first heat exchanger 311 and the second heat exchanger 312. However, it may further include a third heat exchanger 313 and a fourth heat exchanger 314. At this time, the third heat exchanger 313 is provided in the first processing unit 100 and may be installed to exchange heat with the outdoor air passing through the first processing unit 100, and the fourth heat exchanger 314 ) is provided in the second processing unit 200 and may be installed to exchange heat with the indoor air passing through the second processing unit 200.

At this time, the third heat exchanger 313 is disposed on the flow path of air flowing inside the first processing unit 100, and is disposed between the first gas-liquid contact unit 150 and the air supply unit 120, The fourth heat exchanger 314 may be disposed on a flow path of air flowing inside the second processing unit 200, and may be disposed between the second gas-liquid contact unit 250 and the exhaust unit 210. At this time, the plurality of heat exchangers 310 may be connected by the refrigerant line 340. For example, in the cooling mode, the high-temperature and high-pressure refrigerant compressed by the compressor 320 is connected to the first heat exchanger. It can be transferred to the fourth heat exchanger 314 through 311, and the low-temperature and low-pressure refrigerant expanded in the expansion valve 330 passes through the second heat exchanger 312 and into the third heat exchanger ( 313).

According to this, in the cooling mode, the air flowing inside the first processing unit 100 is cooled and dehumidified by contacting the humidity control solution (S) cooled in the first gas-liquid contact unit 150, and then the third heat exchanger. By exchanging heat with the low-temperature and low-pressure refrigerant flowing through (313), secondary cooled air can be supplied indoors. Likewise, in the heating mode, the air flowing inside the first processing unit 100 is heated and humidified in contact with the humidity control solution (S) heated in the first gas-liquid contact unit 150, and then the third heat exchanger ( 313), secondary heated air can be supplied indoors by heat exchange with the flowing high-temperature and high-pressure refrigerant. As a result, cooling and heating efficiency can be increased, and a continuous circulation cycle can be formed.

Figure 3 shows a part of the liquid-type humidity control ventilation electric heat recovery device 10 according to another embodiment of the present invention, and more specifically, only the configuration in operation in the air cleaning mode is shown. Hereinafter, the description of parts that overlap with the liquid-type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention in FIG. 1 will be omitted, and the differences will be described in detail. As shown in FIG. 3, in the liquid humidity control ventilation electric heat recovery device 10 according to another embodiment of the present invention, the first processing unit 100 is installed in the external air unit 110, and the external air unit 110 ), the second processing unit 200 is installed in the exhaust unit 210, and the second external damper 211 opens and closes the exhaust unit 210. It may further include. In addition, at least one of the first processing unit 100 and the second processing unit 200 has an internal damper 101 and 201 that opens and closes the air flow between the first processing unit 100 and the second processing unit 200. Can be installed.

According to this, in the air cleaning mode, the first external damper 111 and the second external damper 211 of the liquid humidity control ventilation electric heat recovery device 10 are closed and the internal dampers 101 and 201 are open. It can be. At this time, operation of the heat pump unit 300, the second fan member 230, and the first pump 411 is terminated, and only the first fan member 130 and the second pump 421 are operated. In this case, indoor air flows into the second processing unit 200, and the indoor air passes through the internal dampers 101 and 201 and flows into the first processing unit 100. Afterwards, the indoor air passes through the first gas-liquid contact part 150, and bacteria and viruses are removed, allowing fresh air to be supplied. That is, unlike the bypass mode, without the introduction of the outdoor air, the indoor air can be filtered while circulating inside the liquid humidity control ventilation electric heat recovery device 10 and re-supplied with bacteria and viruses removed. . Therefore, the liquid humidity control ventilation electric heat recovery device 10 according to another embodiment of the present invention can provide clean air by circulating only the indoor air when there is a lot of fine dust or the weather outside is bad.

4 to 5 show a modified example of the liquid type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention. More specifically, FIG. 4 is a first modified example of FIG. 1, and FIG. 5 is a second modified example of FIG. 1. Hereinafter, description will be made with reference to FIGS. 4 and 5.

As shown in FIGS. 4 and 5, the liquid humidity control ventilation electric heat recovery device 10 according to the first and second modification examples may include second flow path switching valves 520 and 530. The second flow path switching valves 520 and 530 are installed in the first transfer line 410, the second transfer line 420, the third transfer line 430, and the fourth transfer line 440, respectively. , the flow path of the humidity control solution (S) transported through the transfer unit 400 can be switched.

Referring to FIG. 4, the second flow path switching valve 520 may be a two-way valve, and the first two-way valve 521 installed on two transfer lines branched from the first transfer line 410, the first A second two-way valve 522 installed on two transfer lines branched from the second transfer line 420, a third two-way valve 523 installed on each of the two transfer lines branched from the third transfer line 430, It may include a fourth two-way valve 524 installed in each of the two transfer lines branched from the fourth transfer line 440. In addition, the first two-way valve 521 may be composed of the 1-1 two-way valve 521a and the 1-2 two-way valve 521b, and the second two-way valve 522 may be configured with the second- It may be composed of a 1-way valve (522a) and a 2-2 two-way valve (522b), and the third two-way valve 523 includes the 3-1 two-way valve (523a) and the 3-2 two-way valve (523b). ), and the fourth two-way valve 524 may be composed of the 4-1 two-way valve 524a and the 4-2 two-way valve 524b.

Accordingly, the liquid type humidity control ventilation electric heat recovery device 10 according to the first modification of the present invention changes the transfer direction of the humidity control solution (S) by the second flow path switching valve 520 to the first heat exchanger ( 311) or the second heat exchanger 312, and the transfer direction of the humidity control solution (S) heat-exchanged with the first heat exchanger 311 or the second heat exchanger 312 is set to the first heat exchanger 311 or the second heat exchanger 312. It can be converted to either the gas-liquid contact part 150 or the second gas-liquid contact part 250.

For example, when the first heat exchanger 311 is a condenser and the second heat exchanger 312 is an evaporator, the humidity control solution (S) of the first storage tank 140 in the cooling mode is the second heat exchanger 312. 1-1 As the two-way valve 521a is opened, it can be transferred to the first heat exchanger 311, and the humidity control solution (S) heated by heat exchange with the first heat exchanger 311 is transferred to the third heat exchanger 311. -2 As the two-way valve 523b is opened, it can be transferred to the second gas-liquid contact part 250. Meanwhile, the humidity control solution (S) in the second receiving tank 240 may be transferred to the second heat exchanger 312 as the 2-1 two-way valve 522a is opened, and the second heat exchanger 312 The humidity control solution (S) cooled by heat exchange with 312 may be transferred to the first gas-liquid contact portion 150 as the 4-1 two-way valve 524a is opened. Accordingly, the outdoor air introduced into the first processing unit 100 through the external air unit 110 exchanges heat with the cooled humidity control solution (S), and the cooled and dehumidified air is supplied to the air supply unit 120. It can be supplied indoors through

In addition, in the heating mode, the humidity control solution (S) of the first receiving tank 140 may be transferred to the second heat exchanger 312 as the 1-2 two-way valve 521b is opened, The humidity control solution (S) cooled by heat exchange with the second heat exchanger 312 may be transferred to the second gas-liquid contact portion 250 as the 4-2 two-way valve 524b is opened. Meanwhile, the humidity control solution (S) in the second receiving tank 240 may be transferred to the first heat exchanger 311 as the 2-2 two-way valve 522b is opened, and the first heat exchanger 311 The humidity control solution (S) heated by heat exchange with 311 may be transferred to the first gas-liquid contact portion 150 as the 3-1 two-way valve 523a is opened. Accordingly, the outdoor air introduced into the first processing unit 100 through the external air unit 110 exchanges heat with the heated humidity control solution (S), thereby supplying the heated and humidified air to the air supply unit 120. It can be supplied indoors through

That is, the liquid-type humidity control ventilation electric heat recovery device 10 according to an embodiment of the present invention is one of the first heat exchanger 311 or the second heat exchanger 312 by switching the flow paths of the first to fourth two-way valves. The humidity control solution (S) can be supplied toward any one, and the humidity control solution (S) heat-exchanged with the first heat exchanger 311 or the second heat exchanger 312 is supplied to the first gas-liquid contact part 150 or By supplying to one of the second gas-liquid contact parts 250, the heating mode or the cooling mode can be implemented.

Meanwhile, referring to FIG. 5, in the liquid humidity control ventilation electric heat recovery device 10 according to the second modification of the present invention, the second flow path switching valve 530 may be a three-way valve, and the first transfer line ( A first three-way valve 531 installed in the second transfer line 410, a second three-way valve 532 installed in the second transfer line 420, a third three-way valve 533 installed in the third transfer line 430, and the first three-way valve 531 installed in the second transfer line 420. 4 It may include a fourth three-way valve 534 installed in the transfer line 440.

The first to fourth three-way valves (531, 532, 533, 534), like the first to fourth two-way valves (521, 522, 523, 524), direct the transfer direction of the humidity control solution (S) to the first to fourth two-way valves (521, 522, 523, 524). It can be converted to either the heat exchanger 311 or the second heat exchanger 312, and the transfer direction of the humidity control solution (S) heat-exchanged with the first heat exchanger 311 or the second heat exchanger 312 is changed. It can be converted to either the first gas-liquid contact part 150 or the second gas-liquid contact part 250.

x, the liquid type humidity control ventilation electric heat recovery device 10 according to the first and second modifications of the present invention changes the supply direction of the humidity control solution (S) by the second flow path switching valves (520, 530). It can be switched, thereby implementing the cooling mode or heating mode, and various flow paths can be implemented considering the opening and closing time of the flow path and the size of the facility.

In the above, the present invention has been described focusing on the embodiments, but the present invention is not limited to the above-described embodiments, and may be modified and implemented by those skilled in the art without changing the technical spirit of the present invention as claimed in the claims. Of course.

10: Liquid humidity control ventilation electric heat recovery device 100: First processing unit
101, 201: internal damper 110: external air unit
111: first external damper 120: air supply part
130: first fan member 140: first receiving tank
150: First gas-liquid contact part 151: First injection nozzle
152: first contact cell 160: first eliminator
170: first filter unit 171: external air filter
172: air supply filter 200: second processing unit
210: exhaust unit 211: second external damper
220: ventilation unit 230: second fan member
240: second receiving tank 250: second gas-liquid contact portion
251: second injection nozzle 252: second contact cell
260: second eliminator 270: second filter unit
300: heat pump unit 310: plural heat exchangers
311, 312, 313, 314: first to fourth heat exchangers
320: Compressor 330: Expansion valve
340: Refrigerant line 400: Transfer unit
410, 420, 430, 440: first to fourth transfer lines
411: first pump 421: second pump
450: Bypass line 510: First flow path conversion valve
520, 530: 2nd flow path conversion valve
521, 522, 523, 524: first to fourth two-way valves
531, 532, 533, 534: first to fourth three-way valves
S: Humidity control solution

Claims (20)

It includes an outdoor air unit provided on one side and into which outdoor air flows, an air supply unit provided on the other side and supplying the outdoor air into the room, and a first fan member that forms a flow of the outdoor air from the outdoor air unit to the air supply unit. , a first processing unit provided between the external air unit and the air supply unit and further comprising a first receiving tank in which a humidity control solution is accommodated, and a first gas-liquid contact unit in which the outdoor air and the humidity control solution contact and exchange heat;
It includes a ventilation part provided on the other side and through which indoor air flows, an exhaust part provided on the one side and exhausting the indoor air to the outdoors, and a second fan member that forms a flow of the indoor air from the ventilation part to the exhaust part. and a second processing unit provided between the ventilation unit and the exhaust unit, further comprising a second receiving tank in which the humidity control solution is accommodated, and a second gas-liquid contact unit in which the indoor air and the humidity control solution contact and exchange heat;
A plurality of heat exchangers connecting the first processing unit and the second processing unit and including a first heat exchanger and a second heat exchanger installed to exchange heat with the humidity control solution, a compressor in which the refrigerant circulating through the plurality of heat exchangers is compressed, A heat pump unit including an expansion valve through which the refrigerant expands and a refrigerant line through which the refrigerant is transported; and
A first transfer line that transfers the humidity control solution from the first storage tank to the first heat exchanger by a first pump, and a first transfer line that transfers the humidity control solution from the second storage tank to the second heat exchanger by a second pump. A second transfer line, a third transfer line for transferring the humidity control solution from the first heat exchanger to the second gas-liquid contact part, and a fourth transfer line for transferring the humidity control solution from the second heat exchanger to the first gas-liquid contact part. a transfer unit that includes a line and transfers the humidity control solution circulating through the first processing unit, the second processing unit, and the heat pump unit;
Includes,
The humidity control solution contained in the first storage tank is,
It is transferred to the first heat exchanger to exchange heat, and then transferred to the second gas-liquid contact part to exchange heat with the indoor air,
The humidity control solution contained in the second storage tank is,
A liquid-type humidity control ventilation electric heat recovery device, characterized in that it is transferred to the second heat exchanger to exchange heat, and then transferred to the first gas-liquid contact part to exchange heat with the outdoor air.
According to claim 1,
a first flow path switching valve installed on the refrigerant line and switching the flow path of the refrigerant circulating in the heat pump unit;
A liquid-type humidity control ventilation electric heat recovery device further comprising a.
According to claim 2,
The plurality of heat exchangers,
a third heat exchanger provided in the first processing unit and installed to exchange heat with the outdoor air passing through the first processing unit; and
a fourth heat exchanger provided in the second processing unit and installed to exchange heat with the indoor air passing through the second processing unit;
A liquid-type humidity control ventilation electric heat recovery device further comprising a.
According to claim 3,
The third heat exchanger,
It is disposed on a flow path of air flowing inside the first processing unit, and is disposed between the first gas-liquid contact unit and the air supply unit,
The fourth heat exchanger,
A liquid-type humidity control ventilation electric heat recovery device disposed on a flow path of air flowing inside the second treatment unit and disposed between the second gas-liquid contact unit and the exhaust unit.
According to claim 1,
second flow path switching valves installed in each of the first to fourth transfer lines and switching the flow path of the humidity control solution transferred through the transfer unit;
A liquid-type humidity control ventilation electric heat recovery device further comprising a.
The method according to any one of claims 2 to 5,
The first processing unit,
A first external damper installed in the external air unit and opening and closing the external air unit;
It further includes,
The second processing unit,
A second external damper installed in the exhaust section and opening and closing the exhaust section;
It further includes,
A liquid-type humidity control ventilation electric heat recovery device in which at least one of the first processing unit and the second processing unit is installed with an internal damper that opens and closes the air flow between the first processing unit and the second processing unit.
According to claim 6,
When operating in air purification mode,
A liquid-type humidity control ventilation electric heat recovery device in which the first external damper and the second external damper are closed and the internal damper is open.
According to claim 6,
The transfer unit,
A bypass line connecting the first storage tank and the second storage tank; and
A level sensor installed in each of the first and second storage tanks and detecting the water level of the humidity control solution;
A liquid-type humidity control ventilation electric heat recovery device further comprising a. According to claim 8,
The first gas-liquid contact part,
a first spray nozzle that sprays the humidity control solution; and
a first contact cell disposed below the first spray nozzle and expanding the contact area between the outdoor air introduced into the first processing unit and the humidity control solution sprayed from the first spray nozzle;
Including,
The second gas-liquid contact part,
a second spray nozzle that sprays the humidity control solution; and
a second contact cell disposed below the second spray nozzle and expanding the contact area between the indoor air introduced into the second processing unit and the humidity control solution sprayed from the second spray nozzle;
A liquid humidity control ventilation electric heat recovery device comprising a.
According to clause 9,
The first processing unit,
a first eliminator provided on the air supply side to prevent the humidity control solution from scattering;
It further includes,
The second processing unit,
a second eliminator provided on the exhaust side to prevent the humidity control solution from scattering;
A liquid-type humidity control ventilation electric heat recovery device further comprising a.
It includes an outdoor air unit provided on one side and into which outdoor air flows, an air supply unit provided on the other side and supplying the outdoor air into the room, and a first fan member that forms a flow of the outdoor air from the outdoor air unit to the air supply unit. , a first processing unit provided between the external air unit and the air supply unit and further comprising a first receiving tank in which a humidity control solution is accommodated, and a first gas-liquid contact unit in which the outdoor air and the humidity control solution contact and exchange heat;
It includes a ventilation part provided on the other side and through which indoor air flows, an exhaust part provided on the one side and exhausting the indoor air to the outdoors, and a second fan member that forms a flow of the indoor air from the ventilation part to the exhaust part. and a second processing unit provided between the ventilation unit and the exhaust unit, further comprising a second receiving tank in which the humidity control solution is accommodated, and a second gas-liquid contact unit in which the indoor air and the humidity control solution contact and exchange heat;
A plurality of heat exchangers connecting the first processing unit and the second processing unit and including a first heat exchanger and a second heat exchanger installed to exchange heat with the humidity control solution, a compressor in which the refrigerant circulating through the plurality of heat exchangers is compressed, A heat pump unit including an expansion valve through which the refrigerant expands and a refrigerant line through which the refrigerant is transported;
A first transfer line that transfers the humidity control solution from the first storage tank to the first heat exchanger by a first pump, and a first transfer line that transfers the humidity control solution from the second storage tank to the second heat exchanger by a second pump. A second transfer line, a third transfer line for transferring the humidity control solution from the first heat exchanger to the second gas-liquid contact part, and a fourth transfer line for transferring the humidity control solution from the second heat exchanger to the first gas-liquid contact part. a transfer unit that includes a line and transfers the humidity control solution circulating through the first processing unit, the second processing unit, and the heat pump unit; and
a first flow path switching valve installed on the refrigerant line and switching the flow path of the refrigerant circulating in the heat pump unit;
Includes,
The humidity control solution contained in the first storage tank is,
It is transferred to the first heat exchanger to exchange heat, and then transferred to the second gas-liquid contact part to exchange heat with the indoor air,
The humidity control solution contained in the second storage tank is,
It is transferred to the second heat exchanger to exchange heat, and then transferred to the first gas-liquid contact part to exchange heat with the outdoor air,
A liquid-type humidity control ventilation electric heat recovery device in which the refrigerant flowing through the refrigerant line is transferred in opposite directions between the heating mode and the cooling mode by the first flow path switching valve.
According to claim 11,
The plurality of heat exchangers,
a third heat exchanger provided in the first processing unit and installed to exchange heat with the outdoor air passing through the first processing unit; and
a fourth heat exchanger provided in the second processing unit and installed to exchange heat with the indoor air passing through the second processing unit;
It further includes,
In the cooling mode,
The high-temperature and high-pressure refrigerant compressed in the compressor is transferred to the fourth heat exchanger through the first heat exchanger through the refrigerant line,
A liquid-type humidity control ventilation electric heat recovery device in which the low-temperature and low-pressure refrigerant expanded in the expansion valve is transferred to the third heat exchanger through the second heat exchanger through the refrigerant line.
According to claim 12,
In the heating mode,
The high-temperature and high-pressure refrigerant compressed in the compressor is transferred to the third heat exchanger through the second heat exchanger through the refrigerant line, and the low-temperature and low-pressure refrigerant expanded in the expansion valve is transferred to the first heat exchanger through the refrigerant line. A liquid-type humidity control ventilation electric heat recovery device that is transferred to the fourth heat exchanger through a heat exchanger.
According to claim 13,
In air purification mode,
A liquid-type humidity control ventilation electric heat recovery device in which operation of the heat pump unit, the second fan member, and the first pump is terminated, and the first fan member and the second pump are operated.
According to claim 14,
The first processing unit,
A first external damper installed in the external air unit and opening and closing the external air unit;
It further includes,
The second processing unit,
A second external damper installed in the exhaust section and opening and closing the exhaust section;
It further includes,
An internal damper is installed in at least one of the first processing unit and the second processing unit to open and close the air flow between the first processing unit and the second processing unit,
When operating the air purification mode,
A liquid-type humidity control ventilation electric heat recovery device in which the first external damper and the second external damper are closed and the internal damper is open.
It includes an outdoor air unit provided on one side and into which outdoor air flows, an air supply unit provided on the other side and supplying the outdoor air into the room, and a first fan member that forms a flow of the outdoor air from the outdoor air unit to the air supply unit. , a first processing unit provided between the external air unit and the air supply unit and further comprising a first receiving tank in which a humidity control solution is accommodated, and a first gas-liquid contact unit in which the outdoor air and the humidity control solution contact and exchange heat;
It includes a ventilation part provided on the other side and through which indoor air flows, an exhaust part provided on the one side and exhausting the indoor air to the outdoors, and a second fan member that forms a flow of the indoor air from the ventilation part to the exhaust part. and a second processing unit provided between the ventilation unit and the exhaust unit, further comprising a second receiving tank in which the humidity control solution is accommodated, and a second gas-liquid contact unit in which the indoor air and the humidity control solution contact and exchange heat;
A plurality of heat exchangers connecting the first processing unit and the second processing unit and including a first heat exchanger and a second heat exchanger installed to exchange heat with the humidity control solution, a compressor in which the refrigerant circulating through the plurality of heat exchangers is compressed, A heat pump unit including an expansion valve through which the refrigerant expands and a refrigerant line through which the refrigerant is transported;
A first transfer line that transfers the humidity control solution from the first storage tank to the first heat exchanger by a first pump, and a first transfer line that transfers the humidity control solution from the second storage tank to the second heat exchanger by a second pump. A second transfer line, a third transfer line for transferring the humidity control solution from the first heat exchanger to the second gas-liquid contact part, and a fourth transfer line for transferring the humidity control solution from the second heat exchanger to the first gas-liquid contact part. a transfer unit that includes a line and transfers the humidity control solution circulating through the first processing unit, the second processing unit, and the heat pump unit; and
second flow path switching valves installed in each of the first to fourth transfer lines and switching the flow path of the humidity control solution transferred through the transfer unit;
Includes,
The humidity control solution contained in the first storage tank is,
It is transferred to the first heat exchanger to exchange heat, and then transferred to the second gas-liquid contact part to exchange heat with the indoor air,
The humidity control solution contained in the second storage tank is,
A liquid-type humidity control ventilation electric heat recovery device, characterized in that it is transferred to the second heat exchanger to exchange heat, and then transferred to the first gas-liquid contact part to exchange heat with the outdoor air.
According to claim 16,
The second flow path switching valve is,
A first two-way valve installed in each of the two transfer lines branched from the first transfer line, a second two-way valve installed in each of the two transfer lines branched from the second transfer line, and a second two-way valve installed in each of the two transfer lines branched from the second transfer line. A liquid-type humidity control ventilation electric heat recovery device including a third two-way valve installed in each of the two transfer lines, and a fourth two-way valve installed in each of the two transfer lines branched from the fourth transfer line.
According to claim 17,
The second flow path switching valve is,
A first three-way valve installed in the first transfer line, a second three-way valve installed in the second transfer line, a third three-way valve installed in the third transfer line, and a fourth three-way valve installed in the fourth transfer line. Liquid humidity control ventilation electric heat recovery device.
According to claim 18,
The plurality of heat exchangers,
a third heat exchanger provided in the first processing unit and installed to exchange heat with the outdoor air passing through the first processing unit; and
a fourth heat exchanger provided in the second processing unit and installed to exchange heat with the indoor air passing through the second processing unit;
A liquid-type humidity control ventilation electric heat recovery device further comprising a.
According to claim 19,
The air flowing inside the first processing unit primarily exchanges heat with the humidity control solution in the first gas-liquid contact unit, and then secondarily exchanges heat with the refrigerant flowing through the third heat exchanger,
A liquid-type humidity control ventilation electric heat recovery device in which the air flowing inside the second treatment unit primarily exchanges heat with the humidity control solution in the second gas-liquid contact part and secondarily exchanges heat with the refrigerant flowing through the fourth heat exchanger.

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