Air conditioning device and method for adsorbing carbon dioxide

What is claimed is: 1 . An air conditioning device comprising: a main body provided with a first intake port through which indoor air is movable from an indoor area, a first discharge port through which supply air is movable to the indoor area, a second intake port through which outdoor air is movable from an outdoor area, and a second discharge port through which exhaust air is movable to the outdoor area; and wherein the main body includes: a carbon dioxide suction filter provided in a section where a first air passage connecting the first intake port and the first discharge port and a second air passage connecting the first intake port and the second discharge port are common; and a heater configured to heat the carbon dioxide suction filter to a predetermined temperature based on an operation state of which the air conditioning device discharge indoor air to the outdoor area and supply outdoor air to the indoor area. 2 . The air conditioning device of claim 1 , wherein a suction capacity of the carbon dioxide suction filter is 1.5 mmol/g to 2.5 mmol/g. 3 . The air conditioning device of claim 1 , further comprising: at least one of a first damper configured to open and close the first intake port, a second damper configured to open and close the first discharge port, a third damper configured to open and close the second intake port, and a fourth damper configured to open and close the second discharge port. 4 . The air conditioning device of claim 1 , wherein the heater is configured to heat the carbon dioxide suction filter to 65° C. to 70° C. 5 . The air conditioning device of claim 1 , wherein the carbon dioxide suction filter includes an adsorbent including a material in which carbon nanofibers, nanoparticles, and an amine group are combined at a predetermined component ratio, the carbon nanofibers include carbon nanotubes (CNTs) and/or graphene nanofibers (GNFs), the nanoparticles include at least one of silicon dioxide (SiO 2 ), aluminum oxide (Al 2 O 3 ), iron oxide (Fe 3 O 4 ), and titanium dioxide (TiO 2 ), and the amine group includes at least one or polyethylenimine (PEI), 3-aminopropyl triethoxysilane, tetraethylenepentamine, and diethylenetriamine. 6 . The air conditioning device of claim 5 , wherein a molecular weight of the amine group is 600 to 25,000. 7 . The air conditioning device of claim 5 , wherein the material of the adsorbent has a bead shape through a phase inversion method. 8 . The air conditioning device of claim 1 , wherein the carbon dioxide suction filter includes an adsorbent formed of a material in which an amine group is bonded to at least one synthetic resin-based adsorbent, and the material of the adsorbent has a capsule form through a phase inversion method. 9 . The air conditioning device of claim 1 , further comprising: the heater configured to heat the carbon dioxide suction filter to a predetermined temperature based on an operation state of the air conditioning device, and wherein the air condition device is configured so that: in a circulation operation state, a first air passage connecting the first intake port and the first discharge port is formed such that indoor air is moved from the indoor area through the first intake port, thereafter through the carbon dioxide suction filter, and thereafter through the first discharge port to the indoor area as supply air without the heater heating the carbon dioxide suction filter, and in a ventilation operation state: a second air passage connecting the first intake port and the second discharge port is formed such that indoor air is moved from the indoor area through the first intake port, thereafter through the carbon dioxide suction filter, and thereafter through the second discharge port to the outdoor area as exhaust air while the heater heats the carbon dioxide suction filter, and a third air passage connecting the second intake port to the first discharge port is formed such that outdoor air is moved from the outdoor area through the second intake port, and thereafter through the first discharge port to the indoor area as supply air. 10 . The air conditioning device of claim 1 , further comprising: a bypass damper through which bypass exhaust air is movable to the outdoor area, wherein the air condition device is configured so that: in a bypass ventilation operation state: a fourth air passage connecting the first intake port and the bypass damper is formed such that indoor air is moved from the indoor area through the first intake port, thereafter through the carbon dioxide suction filter, and thereafter through the bypass damper to the outdoor area as bypass exhaust air while the heater heats the carbon dioxide suction filter, and the third air passage connecting the second intake port to the first discharge port is formed such that outdoor air is moved from the outdoor area through the second intake port, and thereafter through the first discharge port to the indoor area as supply air. 11 . A method for driving an air conditioning device including a first intake port through which indoor air is movable from an indoor area, a first discharge port through which supply air is movable to the indoor area, a second intake port through which outdoor air is movable from an outdoor area, a second discharge port through which exhaust air if movable to the outdoor area, a carbon dioxide suction filter, and a heater configured to heat the carbon dioxide suction filter to a predetermined temperature based on an operation state of the air conditioning device, the method comprising: determining whether a current operation state is a circulation operation state or a ventilation operation state; and if the determined current operation state is the ventilation operation state to discharge indoor air to the outdoor area and supply outdoor air to the indoor area: heating the carbon dioxide suction filter to a predetermined temperature in response to determining that the operation state is the ventilation operation state for discharging the indoor air outdoors and supplying outdoor air indoors. 12 . The method of claim 11 , if the determined current operation state is the circulation operation state, forming a first air passage connecting the first intake port and the first discharge port such that indoor air is moved from the indoor area through the first intake port, thereafter through the carbon dioxide suction filter, and thereafter through the first discharge port to the indoor area as supply air, without operating the heater to heat the carbon dioxide suction filter, and if the determined current operation state is the ventilation operation state: forming a second air passage connecting the first intake port and the second discharge port such that indoor air is moved from the indoor area through the first intake port, thereafter through the carbon dioxide suction filter, and thereafter through the second discharge port to the outdoor area as exhaust air, while operating the heater to heat the carbon dioxide suction filter, and forming a third air passage connecting the second intake port to the first discharge port such that outdoor air is moved from the outdoor area through the second intake port, and thereafter through the first discharge port to the indoor area as supply air. 13 . The method of claim 11 , the air conditioning device including a bypass damper through which bypass exhaust air is movable to the outdoor area, the method further comprising: determining whether a current operation state is a bypass ventilation operation state; and if the determined current operation state is the