KR20200092221A - An air conditioning system - Google Patents

Abstract

Disclosed is an air conditioning system. According to the present invention, constructed is a desiccant air conditioning system of a recirculation method which discharges indoor air only to the indoors and discharges outdoor air only to the outdoors unlike the conventional desiccant air conditioning system with an external air crossing method which introduces all outdoor air into the indoors and discharges all indoor air to the outdoors. The present invention is able to use latent heat energy in the air to increase the evaporation temperature of a refrigerant and reduce the condensation temperature. The differences in temperature between the entrance and the exit passing through a heat exchanger using an all-external-air method can be very great such that the heat exchange load is great. On the other hand, since the recirculation method has a relatively very low temperature on the entrance and the exit of a heat exchanger, and the heat exchange load is low, the work of the refrigerant compressor can be remarkably reduced, thereby innovatively maximizing the heat efficiency of the air conditioning system. A partial ventilation function is provided so that a certain volume of the air introduced through the internal air inlet is discharged to the outdoors through an exhaust hole by controlling a damper, and a certain volume of the air introduced through the external air inlet is introduced into the indoors through an air supply hole by controlling the damper. Accordingly, the air conditioning of a partial ventilation method is possible and thus, the CO2 in the indoors can be managed without an additional ventilation apparatus. Since the moisture adsorbed by an adsorption-type heat exchanger can be cross-evaporated, natural humidification can be conducted in winter without an additional humidifier apparatus. In summer, unlike the conventional cooling/dehumidifying apparatus requiring the existing reheating apparatus, the air conditioning system provided by the present invention is able to realize a much more convenient, efficient dehumidifying function.

Description

Air conditioning system {AN AIR CONDITIONING SYSTEM}

The present invention relates to an air conditioning system, and more particularly, to an air conditioning system composed of a refrigerant circuit, an adsorbent capable of adsorbing moisture in the air and releasing moisture into the air, and an airflow conversion damper device.

In general, the air conditioning system includes a heating system for indoor heating, a cooling system for indoor cooling, and an air conditioning device for adjusting the temperature, intensity, and direction of air entering the room.

In the general air conditioning system, when cooling the room, the refrigerant is discharged from the compressor and then flows through the condenser and expansion valve to the evaporator, and absorbs heat from the air entering the room via the evaporator. When the air deprived of heat from the evaporator enters the room, cooling is performed inside the room. Conversely, when heating indoors, the refrigerant is discharged from the compressor and then flows into the condenser, and transfers heat to the air flowing into the room via the condenser. Accordingly, when air absorbing heat from the condenser flows into the room, heating is performed inside the room. In addition, when heating indoors, the cooling water circulation circuit acts as a heat pump for the refrigerant circulation circuit.

On the other hand, Japanese Patent Publication No. 2005-114294 is a type of air conditioning system, in the refrigerant circuit of a vapor compression type refrigeration cycle, two adsorption heat in addition to two air heat exchangers (outdoor heat exchanger and indoor heat exchanger) in which refrigerant and air exchange heat. An air conditioning system is described in which an exchanger (a heat exchanger carrying an adsorbent on the fin surface of an air heat exchanger) is constructed, two indoor heat exchangers and two adsorption heat exchangers are arranged in an indoor unit, and an outdoor heat exchanger is arranged in an outdoor unit.

This conventional air conditioning system is a desiccant method in which moisture in the air is adsorbed by an adsorbent in an adsorption heat exchanger serving as an evaporator, and moisture is released from an adsorbent in an adsorption heat exchanger serving as a condenser. By supplying air into the room, the latent heat load in the room can be treated. On the other hand, in the other two indoor heat exchangers, air is cooled or heated. Therefore, by supplying cooled air or heated air from the indoor heat exchanger to the room, it was possible to handle the indoor sensible heat load.

Here, in the conventional air conditioning system, a ventilation operation is also possible in which air introduced from the outside is supplied to the room through one adsorption heat exchanger, and air introduced from the room is discharged to the outside through the other adsorption heat exchanger. However, in such a conventional air conditioning system, it is necessary to arrange four heat exchangers in the refrigerant circuit, respectively, and there is a problem in that the device configuration is complicated.

1 is a perspective view showing a conventional air conditioning system.

Accordingly, the air conditioning system disclosed in Korean Patent Publication No. 10-2008-0007407 has a first adsorption heat exchanger 51 in which an adsorbent is supported on the surface of the heat exchanger of the refrigerant circuit 50 to solve the above-described problem, as shown in FIG. And a second refrigerant heat exchanger (52), wherein the refrigerant circuit (50) is a first refrigerant heat exchanger (51), the first adsorption heat exchanger (51) is an evaporator, and the second adsorption heat exchanger (52) is a condenser. Dehumidification operation mode is performed by switching the second refrigerant flow state in which the adsorption heat exchanger (52) is an evaporator and the first adsorption heat exchanger (51) is a condenser, switching the refrigerant distribution state and the air distribution state every predetermined time. And a humidifying operation mode, a cooling operation mode and a heating operation mode, which are performed by fixing the refrigerant distribution state and the air distribution state without switching, and by circulating air through the air passage 60 while the refrigerant circuit 50 is stopped. The ventilation operation mode was made feasible.

That is, the conventional air conditioning system of the related art switches the air passage 60 in the state where the air from the outdoor to the indoor and the air from the indoor to the outdoor flow through either of the first and second adsorption heat exchangers 51 and 52. By configuring as much as possible, the device configuration is simply arranged to solve the problem of a conventional complex device.

Figure 2 is a block diagram schematically showing the air conditioning system of Figure 1, Figure 2 (a) and Figure 2 (b) is a block diagram having the same principle and air conditioning method, the refrigerant line is added to Figure 2 (b) Is marked with.

As shown in Figure 2, looking at the above-mentioned conventional air conditioning system in detail, a plurality of dampers (41, 43, 45, 47) are communicated with one side of the first adsorption heat exchanger (51) to open or close the air of the outdoors and the room. Then, a plurality of dampers (42, 44, 46, 48) communicate with one side of the second adsorption heat exchanger (52) to open or close the air inside and outside. Accordingly, the indoor intake air (RA) introduced through the internal air intake port (24) is exhausted (EA) to the outside through the exhaust port (21) repeatedly through the first and second adsorption heat exchangers (51, 52), and also external suction Air (OA) is introduced through the outside air intake 23 and is repeatedly supplied to the room through the first and second adsorption heat exchangers (51, 52) through the air intake (22) (SA).

That is, as shown in Fig. 2 (a), the air from the outdoors to the room passes through the first adsorption heat exchanger (51), and the air from the room to the outdoors passes through the first adsorption heat exchanger (52) and , 2 (b), the air from the outside to the room through the second adsorption heat exchanger (52), the air from the interior to the outside is formed a second air circulation state through the first adsorption heat exchanger (51) In this case, the first and second air circulation states could be repeatedly switched and performed.

On the other hand, the first and second adsorption heat exchangers (51, 52) are provided with an adsorbent in the heat exchanger, and the adsorbent adsorbs moisture when the heat exchanger acts as an evaporator, and evaporates the adsorbed moisture when acting as a condenser, thereby providing air conditioning using latent heat. You can do

However, the above-described conventional air conditioning system has a problem in that the heat efficiency is considerably lowered because the air is directed through the outdoor/outdoor system in which all of the indoor air is directed to the outdoors and all of the outdoor air is directed to the room. In addition, in the conventional air conditioning system, only cooling dehumidification by the adsorbent attached to the heat exchanger is performed during dehumidification, dehumidification by ventilation is not considered at all, and humidification by ventilation is not considered as well, so humidification by ventilation is not considered. The humidifier of the situation was provided separately on one side of the case.

Therefore, it is required to develop an air conditioning system that has a variety of functions while maximizing thermal efficiency while maintaining a simple configuration, and is currently actively researching such an air conditioning system.

Japanese Patent Publication No. 2005-114294 Korean Patent Publication No. 10-2008-0007407

Therefore, the object of the present invention invented in view of these issues is that a certain amount of air sucked from the air intake port goes out through the exhaust port by the control of the damper, and the amount of air sucked from the external air intake port is controlled by the damper. By having a partial ventilation function to supply air to the room through a mechanism, unlike the conventional air conditioning system that performs an external/external air ventilation system, recirculation or partial ventilation system air conditioning is possible, and the latent heat of moisture attached to the adsorbent of the adsorption heat exchanger is actively It is to provide an air conditioning system that can maximize the thermal efficiency of the air conditioning system, as it can bring the humidification effect in the winter and the dehumidification effect in the summer.

In order to achieve the above object, the present invention is an indoor air intake air intake; An outdoor air intake device through which outdoor air is sucked; A first adsorption heat exchanger heat-exchanged with the air sucked in from the intake air intake or the outside air intake, and provided with a first adsorption member; A second adsorption heat exchanger heat-exchanged with the air sucked in from the intake air intake or the outside air intake, and provided with a second adsorption member; The first adsorption heat exchanger or the second adsorption heat exchanger includes an air supply heat exchanged air is supplied to the room and an exhaust port through which the air heat exchanged in the first adsorption heat exchanger or the second adsorption heat exchanger is exhausted to the outside, the bet Partial ventilation, in which a certain amount of air sucked from the intake port may be exhausted to the outside through the exhaust port by the control of the damper, and a certain amount of air sucked from the external air intake port may be supplied to the room through the supply port by the control of the damper. An air conditioning system having a function is provided.

In addition, the first adsorption heat exchanger is provided around the first heat exchange member and the first heat exchange member where heat exchange takes place, adsorbs moisture in the air when the first heat exchange member acts as an evaporator, and the first heat exchange When the member acts as a condenser, the first adsorption member has a function of discharging the adsorbed moisture into the air, and the second adsorption heat exchanger includes a second heat exchange member in which heat exchange takes place, and surroundings of the second heat exchange member. It is provided, and includes a second adsorption member having a function of adsorbing moisture in the air when the second heat exchange member acts as an evaporator, and releasing the adsorbed water into the air when the second heat exchange member acts as a condenser. Can.

In addition, on both sides of the first adsorption heat exchanger, a first bypass damper that opens and closes an air passage to and from the air intake, and a second bypass damper that opens and closes an air passage to and from the exhaust port are provided, and the second adsorption heat exchanger is provided. On both sides of the, a third bypass damper for opening and closing the air flow path with the outside air intake port and a fourth bypass damper for opening and closing the air flow path with the air supply port may be provided.

In addition, on both sides of the first bypass damper, a first diverter damper for opening and closing the air intake port and a first passage, and a second diverter damper for opening and closing the first adsorption heat exchanger and the second passage are provided in parallel. , On both sides of the second bypass damper, a fourth diver damper for opening and closing the exhaust port and the first passage, and a third diver damper for opening and closing the first adsorption heat exchanger and the second passage are provided in parallel. In addition, on both sides of the third bypass damper, an eight-divert damper that opens and closes the external air intake and the second passage, and a seven-divert damper that opens and closes the second adsorption heat exchanger and the first passage Is provided, and on both sides of the fourth bypass damper, the fifth diverter damper for opening and closing the air supply and the second passage, and the sixth diverter damper for opening and closing the second adsorption heat exchanger and the first passage Is provided in parallel, and the first diverter damper, the fourth diverter damper, the sixth diverter damper and the seventh diverter damper open and close the air flow path of the first passage, and the second diverter damper , The third diverter damper, the fifth diverter damper, and the eighth diverter damper may open and close the air path of the second passage.

In addition, the partial ventilation function, the first bypass damper, and the third bypass damper is partially opened, and the air sucked into the intake suction port is discharged by a predetermined amount from the first bypass damper, and the escaped air It can be implemented by refilling the third bypass damper by a predetermined amount of.

In addition, the air sucked into the air intake is passed through the first diverter damper, the first passage, and the seventh diverter damper and heat-exchanged with the hot air in the second adsorption heat exchanger that acts as a condenser, and then through the fourth bypass damper. After air is supplied from the air supply to the room and the air sucked into the air intake is passed through an eighth diverter damper, a second passage, and a second diverter damper, and heat-exchanged with cold air in the first adsorption heat exchanger that acts as an evaporator. , A first heating mode that is exhausted to the exhaust port through the second bypass damper, and the third diverter damper, the fourth diverter damper, the fifth diverter damper, and the sixth diverter damper are closed, and suctioned through the air intake port After the air passes through the first bypass damper and heat exchanges with the hot air in the first adsorption heat exchanger, which acts as a condenser, it is passed through the air supply through a third diverter damper, a second passage, and a fifth diverter damper. After being supplied to the room, the air sucked into the outside air intake is passed through a third bypass damper, and then exchanged with cold air in the first adsorption heat exchanger serving as an evaporator, the sixth diver damper, the first passage, and the fourth. The second exhaust damper, the fourth bypass damper, the first diver damper, the second diver damper, the seven diver damper, and the eight diver damper are closed through the diverter damper. It may include a heating mode.

In addition, the first heating mode and the second heating mode are repeatedly switched to continuously recover latent heat of the first and second adsorption heat exchangers at regular intervals.

In addition, the air sucked through the air intake is passed through a first diverter damper, a first passage, and a seventh diverter damper and heat exchanged with cold air in a second adsorption heat exchanger that acts as an evaporator, and then through a fourth bypass damper. After being supplied to the room from the supply air, the air sucked into the external air intake is passed through an eighth diverter damper, a second passage, and a second divert damper, and then heat-exchanged with hot air in the first adsorption heat exchanger serving as a condenser. , A first cooling mode that is exhausted to the exhaust port through the second bypass damper, and the third diverter damper, the fourth diverter damper, the fifth diverter damper, and the sixth diverter damper are closed, and suctioned through the air intake port After the air passes through the first bypass damper and heat exchanges with the cold wind in the first adsorption heat exchanger, which acts as an evaporator, the air is supplied through an air supply through a third diverter damper, a second passage, and a fifth diverter damper. After being supplied to the room, the air sucked through the outside air intake is passed through a third bypass damper, and then heat-exchanged with hot air in the first adsorption heat exchanger serving as a condenser, the sixth diver damper, the first passage, and the fourth. The second exhaust damper is exhausted through the diverter damper, the second bypass damper, the fourth bypass damper, the first diverter damper, the second diverter damper, the seventh diverter damper, and the eighth diverter damper is closed. It may include a cooling mode.

In addition, the first cooling mode and the second cooling mode are repeatedly switched to repeatedly recover latent heat of the first and second adsorption heat exchangers at regular intervals.

In addition, the indoor air sucked from the air intake is exhausted to the outside through the exhaust port via the first bypass damper, the first adsorption heat exchanger and the second bypass damper, and the outdoor air sucked through the external air intake is third The air may be supplied to the room through the air supply through the pass damper, the second adsorption heat exchanger, and the fourth bypass damper.

In addition, the indoor air sucked from the air intake port is exhausted to the outside through the exhaust port via the first diverter damper, the first passage, and the fourth diverter damper, and the outdoor air sucked through the external air intake port is the eighth diver Via a damper, a second passage, and a fifth diver damper, it may be supplied to the room through an air supply.

In addition, the indoor air sucked from the air intake port is exhausted to the outside through the exhaust port after passing through the first adsorption heat exchanger, and the outdoor air sucked through the external air intake port is passed through the second adsorption heat exchanger to the room through the air supply port. The first mode, which is supplied with air, and the indoor air sucked in from the inner air intake port are passed through a second adsorption heat exchanger, and then exhausted to the outside through an exhaust port, and the outdoor air sucked through the external air intake port is passed through a first adsorption heat exchanger. Thereafter, a second mode is supplied to the room through the air supply mechanism, and the first mode and the second mode may be repeatedly switched during a predetermined switching period.

According to the air conditioning system of the present invention described above, unlike a conventional air conditioning system that performs a ventilation system, it is possible to perform recirculation or partial ventilation, and by actively utilizing the latent heat of moisture attached to the adsorbent of the adsorption heat exchanger It has the effect of maximizing the thermal efficiency of the air conditioning system, and at the same time, it can bring humidification effect in winter and dehumidification in summer.

In addition, the adsorption member is used in the heat exchanger, and the principle of desiccant and heat pump is used. Through various damper technologies, the maximum amount of moisture contained in the outdoor suction air or outdoor suction air is recovered and supplied to the room or discharged to the outside. At the same time, it has the effect of maintaining the optimum humidity in the room.

In addition, in the winter heating mode, the desiccant heat pump method blocks the outdoor discharge of indoor air, and at the same time, the maximum humidification efficiency can be realized by introducing outdoor moisture into the room. Also, the latent heat of moisture by the adsorption member is used. It has the effect of maximizing the heating and cooling efficiency. In addition, in the summer cooling mode, the desiccant heat pump method blocks the inflow of outdoor moisture, and at the same time, the maximum dehumidification efficiency can be achieved by discharging the indoor moisture to the outside, thereby maximizing cooling and heating efficiency. .

Accordingly, since partial ventilation is possible, ventilation capable of recovering heat is also possible in the heating mode and the cooling mode, thereby improving energy recovery efficiency. In addition, since the indoor air is reheated/recooled instead of heating/cooling outdoor air, there is an effect of reducing the heating/cooling power load.

In addition, the air conditioning system of the present invention has an effect that can be very usefully applied due to the partial ventilation function even when it is difficult to open and close the window due to a poor ambient environment such as fine dust, odor, urban environment, and noise.

In addition, it is possible to control the amount of carbon dioxide even with the partial ventilation mode, and therefore, there is no need to provide a separate ventilation facility because a separate ventilation operation is not required during the recirculation air conditioning operation. In addition, there is an effect capable of automatically humidifying and dehumidifying operation without having to install a separate humidifier or dehumidifier in the air conditioning system, and can significantly reduce the initial investment cost compared to the air conditioning system and the air conditioning system, and at the same time, significantly increase the efficiency. It has an effect.

1 is a perspective view showing a conventional air conditioning system.
FIG. 2 is a block diagram schematically showing the air conditioning system of FIG. 1, and FIGS. 2A and 2B are block diagrams having the same principle and air conditioning method.
3 is a block diagram showing an air conditioning system according to the present invention.
4 and 5 is a block diagram showing a humidifying and heating mode of the winter season according to the first embodiment of the air conditioning system of the present invention.
6 and 7 is a block diagram showing a summer dehumidification cooling mode according to a second embodiment of the air conditioning system of the present invention.
8 is a block diagram showing a rapid ventilation mode according to a third embodiment of the air conditioning system of the present invention.
9 is a block diagram showing a ventilation mode of a switch according to a fourth embodiment of the air conditioning system of the present invention.
10 is a configuration block diagram showing a ventilation mode according to a fifth embodiment of the air conditioning system of the present invention.
11 is a perspective view showing a case to which the air conditioning system of the present invention is applied.
12 is a perspective view illustrating a state in which the embodiment of FIG. 6 is applied to the air conditioning case shown in FIG. 11.
13 is a perspective view illustrating a state in which the embodiment of FIG. 7 is applied to the air conditioning case illustrated in FIG. 11.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention can be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This embodiment is provided to more fully describe the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same members may be indicated by the same reference numerals. In addition, detailed descriptions of well-known functions and configurations that are judged to unnecessarily obscure the subject matter of the present invention are omitted.

First, the air conditioning system according to the present invention, for example, all the components to be described later are built in one air conditioning case 100 to form the air conditioning system of the present invention (see FIG. 11 ). In addition, the air conditioning system according to the present invention, unlike the air conditioning system that performs an outdoor/outdoor ventilation method in which all indoor air is discharged to the outdoors, and all outdoor air is supplied to the room, the indoor air is discharged only indoors after heat exchange. The air is characterized in that it is possible to additionally recirculate air-conditioning that discharges only to the outdoors after heat exchange, and in addition to partial recirculation, where a certain amount of outdoor air can be supplied indoors. In addition, the air conditioning system according to the present invention can actively utilize the latent heat of moisture attached to the adsorbent of the adsorption heat exchanger, and at the same time bring the humidifying effect in the winter and the dehumidifying effect in the summer, thereby maximizing the thermal efficiency (COP) of the air conditioning system. There are features.

3 is a block diagram showing an air conditioning system according to the present invention.

As shown in FIG. 3, the air conditioning system includes, for example, the first adsorption heat exchanger 110 and the second adsorption heat exchanger 120 built in the air conditioning case 100 (see FIG. 11 ), and indoor air formed outside the air conditioning case 100. The intake air intake 161, the air supply port 162, the air is discharged into the room, the outdoor air intake port 163, the air is discharged to the outdoors, the exhaust port 164, the air conditioning case 100 of The first and second passages 101 and 105 formed therein and the air conditioner 100 include a plurality of dampers that open and close air passages. In particular, in the present invention, the damper is formed of a total of 12 by 4 bypass dampers and 8 diverter dampers, and is characterized by implementing various air conditioning modes to be described later.

The first adsorption heat exchanger 110 includes a pin-shaped first heat exchange member 111 and a first adsorption member 112 attached to the periphery of the first heat exchange member 111. In this case, the first adsorption member 112 adsorbs moisture in the air when the first heat exchange member 111 acts as an evaporator, and the first heat exchanges the adsorbed water when the first heat exchange member 111 acts as a condenser. Discharge into the air passing through the member 111 is possible.

Similarly, the second adsorption heat exchanger 120 includes a pin-shaped second heat exchange member 121 and a second adsorption member 122 attached to the periphery of the second heat exchange member 121. In this case, the second adsorption member 122 absorbs moisture in the air when the second heat exchange member 121 acts as an evaporator, and the second heat exchanges the adsorbed water when the second heat exchange member 121 acts as a condenser. It allows release into the air passing through the member (121). The present invention can maximize the thermal efficiency (COP) by implementing the air-conditioning method of continuously recovering latent heat by the first and second adsorption heat exchangers (110, 120).

The first and second adsorption members 112 and 122 attached to the surfaces of the fins of the first and second heat exchange members 111 and 121 contact zeolite and silica gel to absorb or release moisture by contacting air passing between the fins. , Activated carbon, an organic polymer material having a hydrophilic functional group, a material or a structure capable of adsorbing moisture in the air and releasing moisture into the air can be used.

For example, the first and second adsorption members 112 and 122 may be formed of a crystalline zirconium-based MIP-200 hybrid material (Metal-Organic Framework, MOF) synthesized from coordination polymers of metal ions and organic acid ligands. The MIP-200 hybrid material has a large surface area and pore volume adsorption amount of 3 to 15 times or more compared to the zeolite used in the past, and can achieve a 30% adsorption rate for the chemisorbent. As the technology for the adsorption member has recently been developed, the utilization of the air conditioning system according to the present invention has been further increased, and active technology development is in progress.

Therefore, the air conditioning system according to the present invention uses the adsorption member of the above-mentioned material, uses the heat pump principle of the latent heat recovery operation method, and uses outdoor suction air (RA) or outdoor suction air through various damper technologies according to the present invention. Since the moisture contained in (OA) is recovered as much as possible and supplied to the room or discharged to the outside, it is effective to maintain the optimum humidity in the room at the same time as heating and cooling.

The first adsorption heat exchanger (110) has a first bypass damper (131) that opens and closes the air flow path with the air intake port (161) and a second bypass damper (132) that opens and closes the air flow path with the exhaust port (164). Is provided, the second adsorption heat exchanger 120 has a third bypass damper 133 to open and close the air flow path with the outside air intake 163 on one side, a fourth bypass damper to open and close the air flow path with the air supply 162 134 is provided. That is, a total of four bypass dampers are provided.

On both sides of the first bypass damper 131, a first diverter damper 141 that opens and closes the inner air intake 161 and the first passage 101, a first adsorption heat exchanger 110 and a second passage 105 ) A second diver damper 142 for opening and closing is provided in parallel. In addition, on both sides of the second bypass damper 132, a fourth diver damper 144 for opening and closing the exhaust port 164 and the first passage 101, the first adsorption heat exchanger 110 and the second passage 105 ) A third diver damper 143 for opening and closing is provided in parallel.

On the other hand, the meaning of being provided in parallel here means that it is physically installed on opposite sides or on one side of the upper and lower sides. In the configuration block diagram of a simple air conditioning system, it can be seen that it is provided in parallel along the flow path of air.

Likewise, on both sides of the third bypass damper 133, the eighth diverter damper 148 that opens and closes the external air intake 163 and the second passage 105, the second adsorption heat exchanger 120 and the first passage ( 101) is provided with a seventh diverter damper 147 to open and close in parallel. In addition, on both sides of the fourth bypass damper 134, a fifth diver damper 145 that opens and closes the air supply 162 and the second passage 105, the second adsorption heat exchanger 120 and the first passage ( 101) a sixth diverter damper 146 for opening and closing is provided in parallel. That is, a total of eight diverter dampers are provided.

In this case, the first diverter damper 141, the fourth diverter damper 144, the sixth diverter damper 146, and the seventh diverter damper 147 open and close the air passage to the first passage 101, , The second diverter damper 142, the third diverter damper 143, the fifth diverter damper 145, and the eighth diverter damper 148 open and close the air passage to the second passage 105.

That is, the present invention is different from the conventional air conditioning system, compared to FIG. 2 (b), four diver dampers having different functions, that is, the second diver damper 142, the third diver damper 143, The sixth diverter damper 146 and the seventh diverter damper 147 are further provided, and in the air conditioning case 100, first and second passages 101 and 105 communicating with them are further formed.

The refrigerant circuit 200 of the present invention is a closed circuit in which a compressor 230, a four-way valve 210, a first adsorption heat exchanger 110, an expansion valve 220, and a second adsorption heat exchanger 120 are disposed. The refrigerant circuit 200 forms a refrigerant cycle by circulating the charged refrigerant. In addition, the compressor 230 may be a variable-capacity type capable of variably controlling the operation capacity by controlling the operation frequency by controlling the inverter.

In this case, an expansion valve 220 is disposed between the first adsorption heat exchanger 110 and the second adsorption heat exchanger 120, and the compressor 230 is connected to the four-way valve 210 to adjust the four-way valve 210 Depending on the first and second adsorption heat exchanger (110, 120) may act as an evaporator or condenser. That is, as illustrated in FIG. 3, when the four-way valve 210 of the refrigerant circuit 200 is set in the A direction, the second adsorption heat exchanger 120 serves as a condenser, and the first adsorption heat exchanger 110 serves as an evaporator. On the contrary, when the four-way valve 210 of the refrigerant circuit 200 is set in the B direction, the first adsorption heat exchanger 110 serves as a condenser, and the second adsorption heat exchanger 120 serves as an evaporator.

By the above-described configuration, the air conditioning system according to the present invention is capable of recirculating or partially ventilating air conditioning in addition to the conventional all-outdoor ventilation method. In detail, the air conditioning process of recirculation or partial outdoor ventilation will be described with reference to FIGS. 4 to 10. On the other hand, the above-mentioned recirculation method means an air conditioning method in which indoor air is discharged only to indoors and outdoor air only to outdoor, and the partial outdoor ventilation method refers to an air conditioning method in which a certain amount of indoor air is discharged outdoors in addition to the recirculation method.

4 and 5 is a block diagram showing a humidifying and heating mode of the winter season according to the first embodiment of the air conditioning system of the present invention.

In the winter humidification and heating mode of this embodiment, the first heating mode of FIG. 4 and the second heating mode of FIG. 5 are repeatedly performed. In the first heating mode of FIG. 4, the four-way valve 210 is switched to the A direction. The second adsorption heat exchanger 120 serves as a condenser, and the first adsorption heat exchanger 110 serves as an evaporator. In addition, in the second heating mode of FIG. 5, the four-way valve 210 is switched in the B direction, so that the first adsorption heat exchanger 110 serves as a condenser, and the second adsorption heat exchanger 120 serves as an evaporator.

In the humidification heating mode according to the present embodiment, for example, the switching period of the four-way valve 210 can be set to 3 minutes, wherein the first heating mode of FIG. 4 and the second heating mode of FIG. 5 are every 3 minutes. Each time, the moisture of the first and second adsorption members 112 and 122 is adsorbed or released at a sufficient time interval. Accordingly, there is an effect capable of automatically humidifying and dehumidifying operation without having to install a separate humidifier or dehumidifier in the air conditioning system. Accordingly, the air conditioning system according to the present invention can achieve high-efficiency cooling and air conditioning of the highest level of cooling efficiency (COP).

However, the present invention does not limit the switching period of the four-way valve 210 to 3 minutes and can be changed to a suitable period or variably controlled according to the performance of the adsorption member attached to the heat exchange member. As an example, the present invention is provided with a separate humidity sensor capable of checking the humidity of the air SA that is supplied to the room through the air supply 162 for a predetermined time, based on the sensing value of the humidity sensor. The switching period of 210) may be set to be variable, or the switching period of the four-way valve 210 may be controlled to 3 minutes or more in consideration of the sizes or adsorption amounts of the first and second adsorption members 112 and 122.

First, as shown in FIG. 4, the indoor intake air RA sucked into the air intake 161 in the first heating mode has a certain amount of moisture and is shown as 100. Such a value of 100 is a value representing the current indoor air (RA) moisture content as the first 100, and through the air conditioning case 100, the air supply air is supplied back to the room through the air supply 162 in a state including a water amount having a value of 130. Can be. For example, if the indoor intake air (RA) contains 50% humidity, it can be supplied to the room with 65% humidity by the air conditioning system.

In this case, the air sucked into the inner air intake 161 passes through the first diverter damper 141, the first passage 101, and the seventh diverter damper 147, and the second adsorption heat exchanger 120 serves as a condenser. After being heat-exchanged with hot air, the air is supplied from the air supply port 162 to the room through the fourth bypass damper 134. In this process, the moisture adsorbed on the second adsorption member 122 of the second adsorption heat exchanger 120 is evaporated by heat and supplied with an amount of water of 30 as shown in the air passing through it.

Similarly, the outdoor intake air (OA) sucked into the outside air intake port 163 has a water content of 100, and is exhausted through the exhaust port 164 including a water content having a value of 70 via an air conditioning system. For example, if the outdoor intake air (OA) contains a relative humidity of 50%, it can be exhausted outdoors with a humidity of 35% via an air conditioning system.

In this case, the air sucked into the outside air intake 163 passes through the eighth diverter damper 148, the second passage 105, and the second divert damper 142, and the first adsorption heat exchanger serving as an evaporator ( After heat exchange with cold wind at 110), it is exhausted to the exhaust port 164 through the second bypass damper 132. During this process, moisture generated in the first adsorption heat exchanger 110 is adsorbed to the first adsorption member 112. On the other hand, even in the winter season, it is possible to adsorb a sufficient amount of moisture from the outside air in accordance with the recent technological development of the adsorption member.

In the first heating mode, the third diver damper 143, the fourth diver damper 144, the fifth diver damper 145, and the six diver diver damper 146 are closed.

In this case, if the indoor air is closed for a certain period of time or more, ventilation may be necessary according to an increase in the amount of carbon dioxide in the room. Therefore, for indoor ventilation as a feature of the air conditioning system of the present invention, in the first heating mode of FIG. 4, the first bypass damper 131 and the third bypass damper 133 may be partially opened, in detail. The air sucked into the air intake 161 is discharged by a predetermined amount from the first bypass damper 131, and refilled by a predetermined amount from the third bypass damper 133, thereby enabling partial ventilation. . As shown in this process, the difference in the humidity change amount of the air SA supplied to the final air supply 162 by making a certain amount of water loss and replenishment, such as -10, 10, becomes insignificant.

After the first heating mode is performed for a period of time, the first adsorption member 112 is filled with moisture, and the second adsorption member 122 is removed, so it is necessary to switch to the second heating mode. That is, when a certain switching period elapses in the first heating mode, the valve is switched in the four-way valve 210, and through this, the air conditioning system of FIG. 5 is automatically switched to the second heating mode.

In the second heating mode as shown in FIG. 5, the indoor intake air (RA) sucked through the air intake 161 has a water content of 100, and includes an air supply system 162 including a water content having a value of 130 through the air conditioning system. It is supplied to the room through the furnace again to perform humidification.

In this case, the air sucked through the inner air intake 161 passes through the first bypass damper 131 and heat exchanges with the hot wind in the first adsorption heat exchanger 110 serving as a condenser, and then the third diver damper 143 ), the second passage 105, the fifth diver damper 145 through the air supply 162 is supplied to the room. In this process, the moisture adsorbed on the first adsorption member 112 of the first adsorption heat exchanger 110 is evaporated by heat and supplied to the air passing through it.

Similarly, the outdoor intake air (OA) sucked into the outside air intake port 163 has a water content of 100, and is exhausted through the exhaust port 164 including a water content having a value of 70 via an air conditioning system. In this case, the air sucked into the external air intake 163 passes through a third bypass damper 133, and then is exchanged with cold wind in the first adsorption heat exchanger 110 serving as an evaporator, and the sixth diverter damper ( 146), the first passage 101, the fourth diver is damper 144 through the exhaust port (164). In this process, moisture generated in the second adsorption heat exchanger 120 is adsorbed to the second adsorption member 122.

In the second heating mode, partial ventilation is not performed in consideration of thermal efficiency. That is, in the second heating mode, the second bypass damper 132 and the fourth bypass damper 134 need to be partially opened for partial ventilation, and the air RA sucked through the air intake 161 is already Since the heat is exchanged with the hot air in the first adsorption heat exchanger (110), heat may escape when a certain portion of the second bypass damper (132) and the fourth bypass damper (134) is opened, so that the thermal efficiency may drop rapidly. have. That is, in the second heating mode, the second bypass damper 132, the fourth bypass damper 134, the first diver damper 141, the second diver damper 142, and the seven diver damper 147 ), the eighth diver damper 148 is closed.

After the second heating mode is performed for a certain period of time, the second adsorption member 122 is filled with moisture, and the first adsorption member 112 is removed, so when the predetermined switching period has elapsed, the first heating mode is passed. Switch back.

Accordingly, the air conditioning system according to the present invention can implement maximum humidification efficiency by blocking outdoor discharge of indoor air and simultaneously introducing outdoor moisture into the room using a desiccant heat pump method according to the first embodiment. In addition, there is an effect that can maximize the cooling and heating efficiency (COP) by using the latent heat of moisture by the adsorption member.

6 and 7 is a block diagram showing a summer dehumidification cooling mode according to a second embodiment of the air conditioning system of the present invention.

In the summer dehumidification cooling mode of the second embodiment, the first cooling mode of FIG. 6 and the second cooling mode of FIG. 7 are repeatedly performed with a predetermined switching period. In the first cooling mode of FIG. 6, the four-way valve 210 Is switched to the B direction, the first adsorption heat exchanger 110 serves as a condenser, and the second adsorption heat exchanger 120 serves as an evaporator. 7, in the second cooling mode, the four-way valve 210 is switched to the A direction, so that the second adsorption heat exchanger 120 serves as a condenser, and the first adsorption heat exchanger 110 serves as an evaporator.

In this summer dehumidification cooling mode, as in the winter humidification heating mode of the first embodiment, the switching period of the four-way valve 210 can be set, and the first and second adsorption members 112 and 122 absorb or release moisture. . In this case, as described above, the switching period of the four-way valve 210 may be variably controlled to a specific period in consideration of the sizes of the first and second adsorption members 112 and 122 or the moisture adsorption amount.

First, as shown in FIG. 6, in the first cooling mode, the indoor intake air RA sucked through the air intake 161 has a water content of 100, and includes a water content having a value of 70 through the air conditioning system of the present invention. It is again supplied to the room through the mechanism 162. For example, if the indoor intake air (RA) contains 80% humidity, it can be dehumidified with an humidity of 56% via the air conditioning system to be supplied to the room.

In this case, the air sucked into the inner air intake 161 passes through the first diverter damper 141, the first passage 101, and the seventh diverter damper 147, and the second adsorption heat exchanger 120 serves as an evaporator. After being heat-exchanged with cold wind, the air is supplied from the air supply port 162 to the room through the fourth bypass damper 134. In this process, the second adsorption member 122 of the second adsorption heat exchanger 120 absorbs and deposits moisture from the air passing through the second adsorption heat exchanger 120 to perform dehumidification. Similarly, the outdoor intake air (OA) sucked into the outside air intake port 163 has a water content of 100, and is exhausted through the exhaust port 164 including a water content having a value of 130 via an air conditioning system.

In this case, the air sucked into the outside air intake 163 passes through the eighth diverter damper 148, the second passage 105, and the second divert damper 142, and the first adsorption heat exchanger serving as a condenser ( After heat exchange with the hot wind at 110), it is exhausted to the exhaust port 164 through the second bypass damper 132. In this process, the air adsorbed on the first adsorption heat exchanger 110 is evaporated by heat and exhausted to the outside.

On the other hand, if the indoor air is closed for a certain period of time or more, ventilation may be necessary according to an increase in the amount of carbon dioxide in the room. Therefore, for indoor ventilation characterized by the air conditioning system of the present invention, in the first cooling mode of FIG. 6, the first bypass damper 131 and the third bypass damper 133 may be partially opened, in detail. The air sucked into the air intake 161 is discharged by a predetermined amount from the first bypass damper 131, and is refilled by a predetermined amount by the third bypass damper 133, thereby enabling partial ventilation.

Meanwhile, in the first cooling mode, the third diver damper 143, the fourth diver damper 144, the fifth diver damper 145, and the six diver diver damper 146 are closed.

After the first cooling mode is performed for a period of time, moisture is removed from the first adsorption member 112 and the second adsorption member 122 is filled with moisture, so it is necessary to switch to the second cooling mode. That is, when a certain switching period elapses in the first heating mode, the valve is switched in the four-way valve 210, and through this, the air conditioning system of FIG. 7 is automatically switched to the second cooling mode repeatedly.

As shown in FIG. 7, in the second cooling mode, the indoor intake air (RA) sucked through the air intake 161 has a moisture content of 100, and is dehumidified via an air conditioning system, including a moisture supply having a numerical value of 70. 162) and it is again supplied to the room.

In this case, the air sucked into the inner air intake 161 passes through the first bypass damper 131, and after being exchanged with cold wind in the first adsorption heat exchanger 110 serving as an evaporator, the third diver damper 143 ), the second passage 105, the fifth diver damper 145 through the air supply 162 is supplied to the room. In this process, the moisture of the indoor air is adsorbed on the first adsorption member 112 of the first adsorption heat exchanger 110 to dehumidify the air passing through it.

Similarly, the outdoor intake air (OA) sucked into the outside air intake port 163 has a water content of 100, and is exhausted through the exhaust port 164 including a water content having a value of 130 via an air conditioning system. In this case, the air sucked into the outside air intake 163 passes through a third bypass damper 133, and is then exchanged with hot air in the first adsorption heat exchanger 110 serving as a condenser, and the sixth divert damper ( 146), the first passage 101, the fourth diver is damper 144 through the exhaust port (164). In this process, the moisture adsorbed on the second adsorption heat exchanger 120 is evaporated by heat.

In the second cooling mode, partial ventilation is not performed in consideration of thermal efficiency. That is, in the second cooling mode, the second bypass damper 132, the fourth bypass damper 134, the first diver damper 141, the second diver damper 142, and the seven diver damper 147 ), the eighth diver damper 148 is closed.

After the second cooling mode is performed for a certain period of time, the first adsorption member 112 is filled with water, and the second adsorption member 122 is water-removed. Switch back.

Accordingly, the air conditioning system according to the present invention can implement maximum dehumidification efficiency by blocking the inflow of outdoor moisture by the desiccant heat pump method according to the second embodiment and simultaneously discharging indoor moisture to the outside. (COP) has the effect of achieving maximization.

In addition, in the above-described first and second embodiments, partial ventilation is possible, so that heat recovery is possible even in the heating mode and the cooling mode, and thus there is an effect of increasing energy recovery efficiency. In addition, since the indoor air is reheated/recooled instead of heating/cooling outdoor air, there is an effect of reducing the heating/cooling power load. In addition, the partial ventilation mode can be used to control the amount of carbon dioxide, so there is no need to provide a separate ventilation facility, because a separate ventilation operation is not required during the recirculation air conditioning operation. In addition, even if it is difficult to open and close the window due to poor ambient environment such as fine dust, odor, urban environment, and noise, the air conditioning system of the present invention has an effect that can be very usefully applied due to the partial ventilation function.

8 is a block diagram showing a rapid ventilation mode according to a third embodiment of the air conditioning system of the present invention.

In the third embodiment, it can be applied when a rapid ventilation of the air conditioning system is required, so that the compressor 230 is turned off so that the circulation of the refrigerant circuit 200 does not occur.

In this case, the indoor air (RA) sucked from the air intake port 161 passes through the exhaust port 164 via the first bypass damper 131, the first adsorption heat exchanger 110, and the second bypass damper 132. It is exhausted outdoors. In addition, the outdoor air sucked through the outside air intake 163 is passed through the third bypass damper 133, the second adsorption heat exchanger 120 and the fourth bypass damper 134 to go indoors through the air supply 162. It is aired. Accordingly, when rapid ventilation is required, the number of rotations of the fans attached to the intake air intake 161, the air supply 162, and the air exhaust 164 may be increased to quickly ventilate.

In addition, in this embodiment, when it is necessary to quickly remove moisture in the first and second adsorption members 112 and 122 of the first and second adsorption heat exchangers 110 and 120 for removing odors other than ventilation, the first, 2 It can be applied in special cases where air must pass through the adsorption heat exchangers (110, 120).

9 is a block diagram showing a ventilation mode of a switch according to a fourth embodiment of the air conditioning system of the present invention.

In this embodiment, in the third embodiment of FIG. 8, rapid ventilation is possible by bypassing the first and second adsorption heat exchangers 110 and 120. In addition, the compressor 230 is turned off so that the circulation of the refrigerant circuit 200 does not occur, and the indoor air RA sucked from the air intake 161 is a first diverter damper 141, a first passage 101, a first 4 It is exhausted to the outside through the exhaust port 164 via the diver damper 144. That is, the first adsorption heat exchanger 110 is bypassed and exhausted to the outside through the exhaust port 164.

In addition, the outdoor air sucked through the external air intake vent 163 passes through the eighth diverter damper 148, the second passage 105, and the fifth divert damper 145, and the second adsorption heat exchanger 120 is turned on. After passing, it is supplied to the room through the supply mechanism 162. Accordingly, when rapid ventilation is required to bypass the first and second adsorption heat exchangers (110, 120), the number of fans attached to the air intake 161, the air intake 162, and the exhaust 164 is increased to quickly ventilate. It becomes possible.

10 is a configuration block diagram showing a ventilation mode according to a fifth embodiment of the air conditioning system of the present invention.

In the fifth embodiment, it can be applied to a space provided with a heating facility such as ondol during the winter season, and can be used to perform the desiccant type ventilation according to the present invention while heating by the heating facility during the winter season.

In detail, in the present embodiment, the configurations shown in FIGS. 8 and 10 are used together, and the indoor hot air (RA) of the room passes through the first adsorption heat exchanger 110 as shown in FIG. 8, and then the exhaust port 164 After being exhausted to the outside through a certain period of time, as shown in FIG. 10, the indoor air (RA) in the room passes through the second adsorption heat exchanger 120, and then is exhausted to the outside through the exhaust port 164.

In addition, cold air outside the winter season (OA) is supplied through the second adsorption heat exchanger 120 as shown in FIG. 8 and then supplied indoors through the air supply 162, and after a certain circulation period elapses, the first adsorption heat exchanger as shown in FIG. After passing through 110, air is supplied into the room through the air supply 162.

Accordingly, when the hot air in the room is exhausted to the outside in a desiccant manner as in the first embodiment, the temperature of the first and second adsorption heat exchangers (110, 120) is increased while moisture is adsorbed, and cold air outside is indoors. When entering the furnace, the temperature and humidity for the cold outdoor air are raised to a certain level by the first and second adsorption heat exchangers 110 and 120, which are increased in temperature and moisture, to be supplied indoors.

11 is a perspective view showing a case to which the air conditioning system of the present invention is applied, and FIG. 12 is a perspective view showing a state in which the embodiment of FIG. 6 is applied to the air conditioning case 100 shown in FIG. 11, and FIG. 7 is a perspective view showing a state applied to the air conditioning case 100 shown in FIG.

11 to 13 may be formed of one air-conditioning case 100 of the air-conditioning system according to the present invention. In addition, an air intake port 161 and an air supply port 162 are formed on one side of the air conditioning case 100, and an external air intake port 163 and an exhaust port 164 are formed on the other side. This allows installation across the wall. In addition, the first passage 101 is formed on the lower side of the air conditioning case 100 in the drawing direction, and the second passage 105 is formed on the upper side. Between each configuration, a partition wall and a plurality of dampers are disposed to control the flow of air. In addition, since the flow of air shown in FIGS. 11 and 12 has been described above, description thereof will be omitted.

Air conditioning system according to the present invention can be provided that all the components can be provided in one air-conditioning case 100, it is possible to realize that each of the components of the air conditioning system and its functions can be implemented, it can also bring the effect accordingly. have.

According to the air conditioning system according to the present invention, there is no need for water piping and refrigerant piping work indoors for air conditioning, and can be configured as an indoor unit, outdoor air, and ventilation equipment integrated (Unitary A/C), and universal air conditioning (Universal IEQ) Controller), regardless of the surrounding environment of the building, the location of the building, and the presence/absence of opening/closing conditions, the indoor temperature, humidity, and air quality can be controlled to automatically maintain the optimal condition at all times so that the occupants do not feel any discomfort. It works. In addition, the initial investment cost is cheaper than any conventional air conditioning equipment, the efficiency is high, the maintenance cost is low, and the management is very simple and easy, so that the user can enjoy it without burden.

In addition, buildings with poor ventilation or building direction, various business buildings, high-rise apartments, multi-commercial buildings, various multi-use buildings, small buildings (detached houses, commercial buildings), non-window/no-open/closed windows, various production plants, storage It has an effect that can be applied to various surrounding environments such as warehouses, various underground structures, extreme area buildings, mobile buildings (applied as a roof top unit type), automobiles, railroad cars, and transportation equipment such as ships.

In addition, the air conditioning system according to the present invention does not need to have a separate humidifying device or a dehumidifying device, and can reduce the volume significantly compared to a desiccant air conditioning device using a conventional rotor, and at the same time has an effect of significantly increasing efficiency.

The embodiments of the air conditioning system of the present invention described above are only exemplary, and those skilled in the art to which the present invention belongs can appreciate that various modifications and other equivalent embodiments are possible. There will be. Therefore, it will be understood that the present invention is not limited to the forms mentioned in the above detailed description. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, it should be understood that the present invention includes all modifications, equivalents, and substitutes within the spirit and scope of the invention as defined by the appended claims.

100: air-conditioning case 101: first passage
105: second passage 110: first adsorption heat exchanger
111: first heat exchange member 112: first suction member
120: second adsorption heat exchanger 121: second heat exchange member
122: second adsorption member 131 ~ 134: first ~ fourth bypass damper
141 ~ 148: 1st ~ 8th divert dampers
161: bet inlet 162: air supply
163: outside air intake 164: exhaust port
200: refrigerant circuit 210: four-way valve
220: expansion valve 230: compressor

Claims (12)

An indoor air intake 161 through which indoor air is sucked;
An outdoor air intake 163 through which outdoor air is sucked;
A first adsorption heat exchanger (110) heat-exchanged with the air sucked from the air intake port (161) or the air intake port (163), and provided with a first adsorption member (112);
A second adsorption heat exchanger (120) which is heat-exchanged with the air sucked in from the air intake port (161) or the air intake port (163) and is provided with a second adsorption member (122);
The air supply heat exchanged from the first adsorption heat exchanger (110) or the second adsorption heat exchanger (120) is supplied to the room, and
The first adsorption heat exchanger 110 or the second adsorption heat exchanger 120 includes an exhaust port 164 through which the heat exchanged air is exhausted to the outdoors,
The air sucked from the air intake port 161 is supplied to the room through the air supply port 162 by the control of the damper, and the air sucked from the air air supply port 163 is connected to the air exhaust port 164 by the control of the damper. An air conditioning system having a recirculation function that is exhausted through the outside. The method according to claim 1,
The first adsorption heat exchanger 110,
A first heat exchange member 111 where heat exchange takes place,
It is provided around the first heat exchange member 111 to adsorb moisture in the air when the first heat exchange member 111 serves as an evaporator, and adsorbs when the first heat exchange member 111 serves as a condenser. It includes a first adsorption member 112 having a function of discharging the moisture into the air,
The second adsorption heat exchanger 120,
A second heat exchange member 121 where heat exchange takes place,
It is provided around the second heat exchange member 121, adsorbs moisture in the air when the second heat exchange member 121 serves as an evaporator, and adsorbs when the second heat exchange member 121 serves as a condenser. An air conditioning system including a second adsorption member (122) having a function of discharging the moisture into the air. The method according to claim 2,
On both sides of the first adsorption heat exchanger (110),
A first bypass damper 131 for opening and closing the air flow path with the air intake port 161,
A second bypass damper 132 for opening and closing the air passage with the exhaust port 164 is provided,
On both sides of the second adsorption heat exchanger (120),
A third bypass damper 133 that opens and closes an air passage with the external air intake 163;
An air conditioning system equipped with a fourth bypass damper 134 that opens and closes an air passage with the air supply 162. The method according to claim 3,
On both sides of the first bypass damper 131,
A first diver damper 141 for opening and closing the air intake 161 and the first passage 101,
A second diverter damper 142 for opening and closing the first adsorption heat exchanger 110 and the second passage 105 is provided in parallel,
On both sides of the second bypass damper 132,
A fourth diver damper 144 that opens and closes the exhaust port 164 and the first passage 101,
A third diver damper 143 for opening and closing the first adsorption heat exchanger 110 and the second passage 105 is provided in parallel,
On both sides of the third bypass damper 133,
An eighth diver damper 148 that opens and closes the external air intake 163 and the second passage 105,
The second adsorption heat exchanger 120 and the seventh diverter damper 147 for opening and closing the first passage 101 is provided in parallel,
On both sides of the fourth bypass damper 134,
A fifth diver damper 145 that opens and closes the air supply 162 and the second passage 105,
The second adsorption heat exchanger 120 and the sixth diverter damper 146 for opening and closing the first passage 101 are provided in parallel,
The first diverter damper 141, the fourth diverter damper 144, the sixth diverter damper 146, and the seventh diverter damper 147 open and close the air passage to the first passage 101. and,
The second diver damper 142, the third diver damper 143, the fifth diver damper 145, and the eight diver damper 148 open and close the air passage to the second passage 105. Air conditioning system. The method according to claim 4,
A certain amount of air sucked from the air intake port 161 goes out through the exhaust port 164 by the control of a damper, and the amount of air sucked from the external air intake port 163 is controlled by the damper. Has a partial ventilation function that is supplied to the room through (162),
The partial ventilation function,
The first bypass damper 131 and the third bypass damper 133 are partially opened, and the air sucked into the bet suction port 161 is discharged by a predetermined amount from the first bypass damper 131. An air conditioning system that is implemented by being refilled in the third bypass damper 133 by a predetermined amount of the air that exits and exits. The method according to claim 4,
The air sucked into the inner air intake 161 passes through the first diverter damper 141, the first passage 101, and the seventh diverter damper 147, and the second adsorption heat exchanger 120 serves as a condenser. After heat-exchanging with hot wind, the air supplied from the air supply port 162 to the room through the fourth bypass damper 134, and the air sucked into the external air supply port 163 is the eighth diver damper 148, the second After passing through the passage 105 and the second diver damper 142 and heat-exchanging with cold wind in the first adsorption heat exchanger 110 serving as an evaporator, the exhaust port 164 through the second bypass damper 132 The first heating mode is exhausted, and the third diver damper 143, the fourth diver damper 144, the fifth diver damper 145, and the six diver damper 146 are closed.
The air sucked into the inner air intake 161 passes through a first bypass damper 131 and heat exchanges with hot wind in the first adsorption heat exchanger 110 serving as a condenser, and then the third diver damper 143 , Air that is supplied into the room through the air supply port 162 via the second passage 105 and the fifth diver damper 145 and the air sucked into the external air intake port 163 is the third bypass damper 133 After passing through, the first adsorption heat exchanger 110 serving as an evaporator exchanges heat with cold wind, and exhausts through a sixth diverter damper 146, a first passage 101, and a fourth divert damper 144. Exhausted to (164), the second bypass damper 132, the fourth bypass damper 134, the first diver damper 141, the second diver damper 142, the seventh diver damper 147 ), The eighth diver damper 148 is an air conditioning system including a closed second heating mode. The method according to claim 6,
The air conditioning system in which the first heating mode and the second heating mode are repeatedly switched during a predetermined switching period. The method according to claim 4,
The air sucked into the inner air intake 161 passes through the first diverter damper 141, the first passage 101, and the seventh diverter damper 147, and the second adsorption heat exchanger 120 serves as an evaporator. After heat exchange with cold wind, the air supplied from the air supply port 162 to the room through the fourth bypass damper 134, and the air sucked into the external air intake port 163 is the eighth diver damper 148, the second After passing through the passage 105 and the second diver damper 142 and heat-exchanging with the hot wind in the first adsorption heat exchanger 110 serving as a condenser, the exhaust port 164 through the second bypass damper 132 And a first cooling mode in which the third diver damper 143, the fourth diver damper 144, the fifth diver damper 145, and the six diver damper 146 are closed,
The air sucked into the inner air intake 161 passes through a first bypass damper 131 and heat exchanges with cold wind in the first adsorption heat exchanger 110 serving as an evaporator, and then the third diver damper 143 , Air that is supplied into the room through the air supply port 162 via the second passage 105 and the fifth diver damper 145 and the air sucked into the external air intake port 163 is the third bypass damper 133 After passing through, the heat is exchanged with the hot air in the first adsorption heat exchanger 110 serving as a condenser, and the exhaust port is provided through the sixth diverter damper 146, the first passage 101, and the fourth divert damper 144. Exhaust to (164), the second bypass damper 132, the fourth bypass damper 134, the first diver damper 141, the second diver damper 142, the seventh diver damper 147 ), the eighth diver damper 148, the air conditioning system including a closed second cooling mode. The method according to claim 8,
The air conditioning system in which the first cooling mode and the second cooling mode are repeatedly switched during a predetermined switching period. The method according to claim 4,
The indoor air sucked from the air intake port 161 is exhausted to the outside through the exhaust port 164 via the first bypass damper 131, the first adsorption heat exchanger 110 and the second bypass damper 132. , The outdoor air sucked through the external air intake 163 is indoors through the air supply 162 via a third bypass damper 133, a second adsorption heat exchanger 120 and a fourth bypass damper 134. Air supply system that is supplied with air. The method according to claim 4,
The indoor air sucked from the air intake 161 is exhausted to the outside through the exhaust port 164 via the first diverter damper 141, the first passage 101, and the fourth diverter damper 144, The outdoor air sucked through the outside air intake 163 passes through an eighth diverter damper 148, a second passage 105, and a fifth divert damper 145, and goes indoors through an air supply 162. Air conditioning system supplied. The method according to claim 4,
The indoor air sucked from the air intake port 161 is exhausted to the outside through the exhaust port 164 after passing through the first adsorption heat exchanger 110, and the outdoor air sucked through the external air intake port 163 is the second adsorption heat A first mode that is supplied to the room through the air supply 162 after passing through the exchanger 120,
The indoor air sucked from the air intake port 161 passes through the second adsorption heat exchanger 120, and then is exhausted outdoor through the air exhaust port 164, and the outdoor air sucked through the air intake port 163 is first. After passing through the adsorption heat exchanger 110, and includes a second mode that is supplied to the room through the air supply 162,
The air conditioning system in which the first mode and the second mode are repeatedly switched during a predetermined switching period.

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