KR102246320B1 - Air conditioning system - Google Patents

Abstract

According to an embodiment of the present invention, an air conditioning system comprises: a first passage of which an outside air suction port is installed at one end and an air supply port is installed at the other end, and in which a first heat exchanger is installed between the outside air suction port and the air supply port; a second passage of which an exhaust port is installed at one end and an inside air suction port is installed at the other end, and in which a second heat exchanger for exchanging a refrigerant with the first heat exchanger is installed between the exhaust port and the inside air suction port; a third passage connected to one side of the first passage and the second passage; a fourth passage connected to the other side of the first passage and the second passage; and a plurality of direction change dampers for selectively opening and closing one of the first passage, the second passage, the third passage, and the fourth passage.

Description

Air conditioning system {AIR CONDITIONING SYSTEM}

The present invention relates to an air conditioning system for controlling an indoor environment.

In general, an air conditioning system performs cooling, heating, and ventilation of the room. In this air conditioning system, when cooling indoors, the refrigerant is discharged from the compressor and then introduced into the evaporator through the condenser and the expansion valve, and absorbs heat from the air introduced into the room while passing through the evaporator. When air, which has been deprived of heat from the evaporator, flows into the room, the room is cooled. Conversely, during indoor heating, the refrigerant is discharged from the compressor and then flows into the condenser, and transfers heat to the air entering the room while passing through the condenser. Accordingly, when the air that has absorbed heat from the condenser flows into the room, the room is heated. In addition, when heating the room, the cooling water circulation circuit acts as a heat pump with respect to the refrigerant circulation circuit.

Conventionally, in order to perform all the cooling and heating with one air conditioner, a heat pump for cooling and heating by changing the functions of the evaporator and the condenser in reverse by operating the refrigerant flow in the refrigeration cycle according to the season in a stationary cycle has been used. In addition, ventilation to recover the heat energy of the indoor air discarded outdoors by installing a total heat exchanger between the air exhausted to the outside and the air supplied to the room while discharging the indoor air to the outside for indoor ventilation and supplying fresh outdoor air to the room. The use of units to purify indoor air is also gradually increasing.

However, in the conventional air conditioning system as described above, the heat pump and the ventilation unit used for cooling, heating, and ventilation are separately installed as separate systems, and the outdoor unit and the air conditioner are also separated to each other indoors and outdoors. Since it is installed, there is a problem that it takes up a lot of installation space. In addition, a water pipe for humidification and a drain for discharging condensation water generated during dehumidification are separately required.

An embodiment of the present invention provides an air conditioning system capable of efficiently performing cooling, dehumidification, heating, humidification, defrosting, and ventilation with one air conditioner by variously converting airflow.

According to an embodiment of the present invention, the air conditioning system includes a first passage in which an outside air intake is installed at one end and an air supply port is installed at the other end, a first heat exchanger is installed between the outside air inlet and the air supply port, and an exhaust port is installed at one end. And a second passage in which an internal air intake port is installed at the other end and a second heat exchanger for exchanging the first heat exchanger and refrigerant is installed between the exhaust port and the internal air inlet, and between the outside air intake port and the first heat exchanger, and between the air supply port A third passage connected to one side of the first passage between the first heat exchangers and connected to one side of the second passage between the inner air intake port and the second heat exchanger, and between the exhaust port and the second heat exchanger , Between the outside air intake port and the first heat exchanger, and between the air supply port and the first heat exchanger, respectively, connected to the other side of the first passage, and between the inner air intake port and the second heat exchanger, and between the exhaust port and the second heat exchanger. A fourth passage connected to the other side of the second passage between the heat exchanger, and one of the first passage and the second passage, and one of the third passage and the fourth passage, among a plurality of bypass openings respectively communicating And a plurality of direction change dampers selectively opening and closing one of the first passage and the second passage.

The air conditioning system may further include an air supply fan disposed relatively adjacent to the air supply port of the first passage, and an exhaust fan disposed relatively adjacent to the exhaust port of the second passage.

The third passage has a first bypass opening formed on one surface of the first passage between the outside air intake port and the first heat exchanger, and a first bypass opening formed on one surface of the first passage between the air supply port and the first heat exchanger. A third bypass opening formed on one surface of the second passage between the air inlet and the second heat exchanger, each connected to the first passage through a second bypass opening, and the exhaust port and the second heat exchanger Between them, each of the second passages may be connected to the second passage through a fourth bypass opening formed on one surface of the second passage.

The fourth passage has a fifth bypass opening formed on the other surface of the first passage between the outside air intake port and the first heat exchanger, and a fifth bypass opening formed on the other surface of the first passage between the air supply port and the first heat exchanger. A seventh bypass opening connected to the first passage through a sixth bypass opening and formed on the other surface of the second passage between the inner air intake port and the second heat exchanger, and between the exhaust port and the second heat exchanger In may be connected to the second passage through an eighth bypass opening formed on the other surface of the second passage.

The plurality of direction change dampers may include a first damper selectively closing one of the first passage and the first bypass opening between the outside air inlet and the first heat exchanger, and between the air supply port and the first heat exchanger. And a second damper selectively closing one of the first passage and the second bypass opening of the inner air inlet and one of the second passage and the third bypass opening between the air intake and the second heat exchanger. A third damper closing, a fourth damper selectively closing one of the second passage and the fourth bypass opening between the exhaust port and the second heat exchanger, and the external air intake port and the first heat exchanger. A fifth damper selectively closing one of the first passage and the fifth bypass opening, and a first passage selectively closing one of the first passage and the sixth bypass opening between the air supply port and the first heat exchanger 6 a damper, a seventh damper selectively closing one of the second passage between the inner air intake and the second heat exchanger and the seventh bypass opening, and the first between the exhaust port and the second heat exchanger. It may further include an eighth damper selectively closing one of the two passages and the eighth bypass opening.

The air conditioning system further includes a refrigerant movement passage for moving a refrigerant between the first heat exchanger and the second heat exchanger, an expansion valve installed in the refrigerant movement passage, and a compressor installed in the refrigerant movement passage to compress the refrigerant. Can include.

The first heat exchanger may operate as an evaporator, and the second heat exchanger may operate as a condenser.

It may further include a control device for controlling the operation of the plurality of direction change dampers. In addition, the control device may control the operation of the plurality of direction change dampers by dividing according to a mode selected from among a plurality of modes including a summer cooling and dehumidifying mode, a winter heating and humidifying mode, and a winter heating and defrosting mode.

In the summer cooling and dehumidification mode, the control device operates so that the first damper blocks the first passage and opens the first bypass opening, and the third damper blocks the second passage and the third bypass The fourth damper is operated to open the opening, the fourth damper is operated to close the fourth bypass opening and open the second passage, and the eighth damper close the eighth bypass opening and open the second passage. So that the outside air sucked through the outside air intake port is operated to be discharged to the exhaust port through the second heat exchanger through the third passage, and the seventh damper blocks the second passage and opens the seventh bypass opening. And the fifth damper is operated to block the first passage and open the fifth bypass opening, the sixth damper is operated to close the sixth bypass opening and open the first passage, the A second damper is operated to close the second bypass opening and open the first passage to induce the indoor air sucked through the inner air intake port to be discharged to the supply port through the fourth passage through the first heat exchanger. I can.

In the winter heating and humidification mode, the control device operates so that the first damper blocks the first bypass opening and opens the first passage, and the fifth damper blocks the fifth bypass opening and the first Operated to open a passage, the sixth damper is operated to block the first passage and open the sixth bypass opening, and the eighth damper may block the second passage and open the eighth bypass opening. By operating and inducing the outside air sucked into the outside air intake port to be discharged to the exhaust port through the fourth passage after passing through the first heat exchanger, the seventh damper blocks the seventh bypass opening and opens the second passage And the third damper is operated to close the third bypass opening and open the second passage, and the fourth damper is operated to close the second passage and open the fourth bypass opening, The second damper is operated to block the first passage and open the second bypass opening so that the indoor air sucked through the inside air intake port passes through the second heat exchanger and then is discharged to the supply port through the third passage. You can induce it.

In the winter heating defrost mode, the control device operates so that the first damper blocks the first passage and opens the first bypass opening, and the third damper blocks the second passage and the third bypass The fourth damper is operated to open the opening, the fourth damper is operated to close the fourth bypass opening and open the second passage, and the eighth damper close the eighth bypass opening and open the second passage. So that the outside air sucked through the outside air intake port is operated to be discharged to the exhaust port through the second heat exchanger through the third passage, and the seventh damper blocks the second passage and opens the seventh bypass opening. And the fifth damper is operated to block the first passage and open the fifth bypass opening, the sixth damper is operated to close the sixth bypass opening and open the first passage, the A second damper is operated to close the second bypass opening and open the first passage, so that the indoor air sucked through the inner air intake port is discharged to the supply port through the first heat exchanger through the fourth passage. can do.

When the plurality of direction change dampers close the first passage and the second passage, a blocking frame for supporting the plurality of direction change dampers and filling a gap between the plurality of direction change dampers may be further included.

The air conditioning system includes a first ventilation port passing through a region of the blocking frame installed in the first passage between the outdoor air intake port and the first heat exchanger and a first ventilation device for opening and closing the first ventilation port, and the betting unit A second ventilation port passing through a region of the blocking frame installed in the second passage between the suction port and the second heat exchanger and a second ventilation device opening and closing the second ventilation port may be further included.

A control device for controlling operations of the plurality of direction change dampers, the first ventilation device, and the second ventilation device may be further included. And the control device is divided according to a mode selected from a plurality of modes including a summer cooling dehumidification ventilation mode and winter heating defrost ventilation mode operation of the plurality of direction switching dampers, the first ventilation device, and the second ventilation device. Can be controlled.

In the summer cooling and dehumidifying ventilation mode, the control device operates so that the first damper blocks the first passage and opens the first bypass opening, and the third damper blocks the second passage and the third bypass Operated to open the path opening, the fourth damper is operated to close the fourth bypass opening and open the second passage, and the eighth damper closes the eighth bypass opening and opens the second passage So that the outside air sucked into the outside air intake port is discharged to the exhaust port through the second heat exchanger through the third passage, and the seventh damper blocks the second passage and opens the seventh bypass opening. And the fifth damper is operated to close the first passage and open the fifth bypass opening, and the sixth damper is operated to close the sixth bypass opening and open the first passage, The second damper is operated to close the second bypass opening and open the first passage so that the indoor air sucked through the inner air intake port is discharged to the air supply port through the fourth passage through the first heat exchanger. And, it is possible to operate the first ventilation device and the third ventilation device.

In the winter heating defrost ventilation mode, the control device operates so that the first damper blocks the first passage and opens the first bypass opening, and the third damper blocks the second passage and the third bypass Operated to open the path opening, the fourth damper is operated to close the fourth bypass opening and open the second passage, and the eighth damper closes the eighth bypass opening and opens the second passage So that the outside air sucked into the outside air intake port is discharged to the exhaust port through the second heat exchanger through the third passage, and the seventh damper blocks the second passage and opens the seventh bypass opening. And the fifth damper is operated to close the first passage and open the fifth bypass opening, and the sixth damper is operated to close the sixth bypass opening and open the first passage, The second damper is operated to close the second bypass opening and open the first passage so that the indoor air sucked through the inner air intake port is discharged to the air supply port through the fourth passage through the first heat exchanger. And, it is possible to operate the first ventilation device and the third ventilation device.

Water generated from the first heat exchanger may be supplied to the second heat exchanger, and water supplied to the second heat exchanger may be evaporated into steam through condensation heat of the second heat exchanger.

In addition, the steam generated by the second heat exchanger may be supplied indoors in winter and discharged outdoors in summer.

In addition, the first heat exchanger and the second heat exchanger are arranged side by side to the left and right, and may further include a water pump for supplying water generated in the first heat exchanger to the second heat exchanger.

In addition, the second heat exchanger may be positioned below the first heat exchanger, and water generated in the first heat exchanger may freely fall toward the second heat exchanger.

According to an embodiment of the present invention, the air conditioning system may convert airflow in various ways to efficiently perform cooling, dehumidification, heating, humidification, defrosting, and ventilation with one air conditioner.

1 is a perspective view of an air conditioning system according to a first embodiment of the present invention.
2 to 7 are perspective views and system circuit diagrams showing the internal configuration of the air conditioning system of FIG. 1 for each operating state.
8 to 10 are perspective views and system circuit diagrams showing an internal configuration of an air conditioning system according to operating states according to a second embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. The present invention may be implemented in various different forms and is not limited to the embodiments described herein.

In addition, in various embodiments, components having the same configuration are typically described in the first embodiment by using the same reference numerals, and in other second embodiments, only configurations different from the first embodiment will be described. It should be.

It should be noted that the drawings are schematic and are not drawn to scale. Relative dimensions and ratios of parts in the drawings are exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are merely exemplary and not limiting. In addition, the same reference numerals are used to indicate similar features to the same structure, element, or part appearing in two or more drawings.

Examples of the present invention specifically represent an ideal embodiment of the present invention. As a result, various variations of the illustration are expected. Accordingly, the embodiment is not limited to a specific shape of the illustrated area, and includes, for example, a modification of the shape by manufacturing.

Hereinafter, an air conditioning system 101 according to a first embodiment of the present invention will be described with reference to FIGS. 1 to 7. For example, the air conditioning system 101 may be used to perform air conditioning for a plurality of zones.

1 and 2, the air conditioning system 101 according to the first embodiment of the present invention includes a first passage 310, a second passage 320, a third passage 330, and a fourth passage. A passage 340, a first heat exchanger 410, a second heat exchanger 420, and a plurality of direction change dampers 700 may be included.

In addition, the air conditioning system 101 according to the first embodiment of the present invention includes an air supply fan 210, an exhaust fan 220, a refrigerant flow path 460, an expansion valve 440, a compressor 450, and a control device ( (Not shown), a blocking frame 800, a first ventilation device 810, a second ventilation device 830, a storage tank 480, and a water pump 470 may be further included.

In the first passage 310, an outside air intake 311 is installed at one end, an air supply port 319 is installed at the other end, and a first heat exchanger 410 is installed between the outside air intake 311 and the air supply port 319 do.

In the second passage 320, an exhaust port 329 is installed at one end, an air intake port 321 is installed at the other end, and a second heat exchanger 420 is installed between the exhaust port 329 and the air intake port 321.

In the first embodiment of the present invention, the first heat exchanger 410 may operate as an evaporator, and the second heat exchanger 420 may operate as a condenser. In addition, the first heat exchanger 410 and the second heat exchanger 420 may exchange refrigerant through the refrigerant flow passage 460. That is, the refrigerant circulates between the first heat exchanger 410 and the second heat exchanger 420 through the refrigerant flow passage 460.

In addition, the expansion valve 440 and the compressor 450 are installed in the refrigerant flow path 460 to form a refrigeration cycle and heat pump.

In addition, in the first embodiment of the present invention, the first heat exchanger 410 and the second heat exchanger 420 are arranged side by side, and the water pump 470 is Is supplied to the second heat exchanger 420. At this time, the water generated in the first heat exchanger 410 may be directly supplied to the second heat exchanger 420 by the water pump 470, but first, it is stored in a separate storage tank 480 and then the storage tank 480 ) May be supplied to the second heat exchanger 420 using a water pump 470.

In this way, water generated from the first heat exchanger 410 is supplied to the second heat exchanger 420, and the water supplied to the second heat exchanger 420 is supplied to water vapor through the heat of condensation of the second heat exchanger 420. To evaporate. In addition, the steam generated by the heat of condensation in the second heat exchanger 420 is supplied indoors in winter and discharged outdoors in summer. Accordingly, not only can the efficiency of the refrigeration cycle in the air conditioning system 101 be greatly improved, but also the humidification performance can be improved when the air conditioning system 101 is operated in a winter heating humidification mode, which will be described later.

The air supply fan 210 is disposed relatively adjacent to the air supply port 319 of the first passage 310 to supply air into the room through the air supply port 319.

The exhaust fan 220 is disposed relatively adjacent to the exhaust port 329 of the second passage 320 and discharges air to the outside through the exhaust port 329.

The third passage 330 is coupled to one side of the first passage 310 and the second passage 320. And the third passage 330 is connected to one side of the first passage 310 between the outside air intake 311 and the first heat exchanger 410 and between the air supply port 319 and the first heat exchanger 410, respectively. , It is connected to one side of the second passage 320 between the internal air inlet 321 and the second heat exchanger 420 and between the exhaust port 329 and the second heat exchanger 420.

Specifically, the third passage 330 includes a first bypass opening 510 formed on one surface of the first passage 310 between the outside air inlet 311 and the first heat exchanger 410, and a supply port 319 The first passage 310 is connected to the first passage 310 through a second bypass opening 520 formed on one surface of the first passage 310 between the and the first heat exchanger 410. In addition, the third passage 330 has a third bypass opening 530 formed on one surface of the second passage 320 between the internal air inlet 321 and the second heat exchanger 420, and the exhaust port 329 and the third passage. 2 Between the heat exchangers 420, they are respectively connected to the second passages 320 through fourth bypass openings 540 formed on one surface of the second passages 320.

Accordingly, the air introduced into the outside air inlet 311 of the first passage 310 can move to the second passage 320 through the third passage 330, and a second heat exchanger installed in the second passage 320 It will be able to pass through 420. Similarly, the air introduced into the inner air intake port 321 of the second passage 320 may move to the first passage 310 through the third passage 330, and the first heat exchanger installed in the first passage 310 It will be able to pass through 410.

The fourth passage 340 is coupled to the other side of the first passage 310 and the second passage 320. That is, the first passage 310 and the second passage 320 are disposed between the fourth passage 340 and the third passage 330. And the fourth passage 340 is connected to the other side of the first passage 310 between the outside air intake 311 and the first heat exchanger 410 and between the air supply port 319 and the first heat exchanger 410, respectively. , It is connected to the other side of the second passage 320 between the internal air intake port 321 and the second heat exchanger 420 and between the exhaust port 329 and the second heat exchanger 420.

Specifically, the fourth passage 340 includes a fifth bypass opening 550 formed on the other surface of the first passage 310 between the outside air inlet 311 and the first heat exchanger 410, and a supply port 319. The first passage 310 is connected to the first passage 310 through a sixth bypass opening 560 formed on the other surface of the first passage 310 between the and the first heat exchanger 410. In addition, the fourth passage 340 includes a seventh bypass opening 570 formed on the other surface of the second passage 320 between the air intake port 321 and the second heat exchanger 420, and the exhaust port 329 and the fourth passage 340. 2 It is connected to the second passage 320 through an eighth bypass opening 580 formed on the other surface of the second passage 320 between the heat exchangers 420.

Accordingly, the air introduced into the outside air inlet 311 of the first passage 310 can move to the second passage 320 through the fourth passage 340, and a second heat exchanger installed in the second passage 320 It will be able to pass through 420. Similarly, the air introduced into the inner air intake port 321 of the second passage 320 may move to the first passage 310 through the fourth passage 340, and a first heat exchanger installed in the first passage 310 It will be able to pass through 410.

The plurality of direction change dampers 700 may include a plurality of bypass openings for communicating one of the first passage 310 and the second passage 320 and one of the third passage 330 and the fourth passage 340, respectively. 500) and one of the first passage 310 and the second passage 320 may be selectively opened and closed.

That is, the plurality of direction change dampers 700 are a single blade method in which the single blade rotates about the rotation axis, and the plurality of bypass openings 500 or the first passage 310 and the second passage 320 ) Can optionally be completely sealed.

In addition, the plurality of direction change dampers 700 may include at least one of a heat insulating member and a heat reflecting member. That is, when the plurality of direction change dampers 700 selectively seal one of the plurality of bypass openings 500 or the first passage 310 and the second passage 320, the heat transfer to the sealed place is minimized. can do. In this case, the plurality of direction change dampers 700 itself may be formed of a heat insulating member or a heat reflecting member, and may be configured in a form in which an insulating member or a heat reflecting member is attached or coated on the damper body.

Specifically, the plurality of direction change dampers 700 include a first damper 710, a second damper 720, a third damper 730, a fourth damper 740, a fifth damper 750, and a sixth damper. 760, a seventh damper 770, and an eighth damper 780.

The first damper 710 may selectively close one of the first passage 310 and the first bypass opening 510 between the outside air inlet 311 and the first heat exchanger 410. However, the first damper 710 may close the first bypass opening 510 alone, but to close the first passage 310 between the outside air intake 311 and the first heat exchanger 410, which will be described later. It must operate together with the fifth damper 750. That is, the first damper 710 and the fifth damper 750 close the first passage 310 by half.

The second damper 720 may selectively close one of the first passage 310 and the second bypass opening 520 between the supply port 319 and the first heat exchanger 410. However, the second damper 720 may close the second bypass opening 520 alone, but to close the first passage 310 between the supply port 319 and the first heat exchanger 410, which will be described later. It must operate together with the sixth damper 760. That is, the second damper 720 and the sixth damper 760 close the first passage 310 by half.

The third damper 730 may selectively close one of the second passage 320 and the third bypass opening 530 between the air inlet 321 and the second heat exchanger 420. However, the third damper 730 may close the third bypass opening 530 alone, but to close the second passage 320 between the air intake port 321 and the second heat exchanger 420, which will be described later. It must operate together with the seventh damper 770. That is, the third damper 730 and the seventh damper 770 close the second passage 320 by half.

The fourth damper 740 may selectively close one of the second passage 320 and the fourth bypass opening 540 between the exhaust port 329 and the second heat exchanger 420. However, the fourth damper 740 may close the fourth bypass opening 540 alone, but to close the second passage 320 between the exhaust port 329 and the second heat exchanger 420, 8 Must operate together with the damper 780. That is, the fourth damper 740 and the eighth damper 780 close the second passage 320 by half.

The fifth damper 750 may selectively close one of the first passage 310 and the fifth bypass opening 550 between the outside air inlet 311 and the first heat exchanger 410. However, the fifth damper 750 may close the fifth bypass opening 550 alone, but in order to close the first passage 310 between the outside air intake 311 and the first heat exchanger 410, the above-described It must operate together with the first damper 710.

The sixth damper 760 may selectively close one of the first passage 310 and the sixth bypass opening 560 between the supply port 319 and the first heat exchanger 310. However, the sixth damper 760 may close the sixth bypass opening 560 alone, but to close the first passage 310 between the supply port 319 and the first heat exchanger 410, the above-described It must operate together with the second damper 720.

The seventh damper 770 may selectively close one of the second passage 320 and the seventh bypass opening 770 between the air inlet 321 and the second heat exchanger 420. However, the seventh damper 770 may close the seventh bypass opening 570 alone, but in order to close the second passage 320 between the air intake port 321 and the second heat exchanger 420, the above-described It must operate together with the third damper 730.

The eighth damper 780 may selectively close one of the second passage 320 and the eighth bypass opening 580 between the exhaust port 329 and the second heat exchanger 420. However, the eighth damper 780 may close the eighth bypass opening 580 alone, but in order to close the second passage 320 between the exhaust port 329 and the second heat exchanger 420 4 Must operate together with the damper 740.

The blocking frame 800 supports the plurality of direction change dampers 700 when the plurality of direction change dampers 700 close the first passage 310 and the second passage 320 while supporting the plurality of direction change dampers 700. ) To fill the gap.

As described above, the first damper 710 and the fifth damper 750 close the first passage 310 between the outside air intake 311 and the first heat exchanger 410 by half, and the second damper 720 ) And the sixth damper 760 close the first passage 310 between the supply port 319 and the first heat exchanger 410 by half, and the third damper 730 and the seventh damper 770 The second passage 320 between the air intake port 321 and the second heat exchanger 420 is closed by half, and the fourth damper 740 and the eighth damper 780 are formed with the exhaust port 329 and the second heat exchanger ( When the second passage 320 between the 420 is closed by half, the gap between the first damper 710 and the fifth damper 750, the gap between the second damper 720 and the sixth damper 760, and the third Each of the dampers is supported while filling the gap between the damper 730 and the seventh damper 770 and the gap between the fourth damper 740 and the eighth damper 780.

In addition, a first ventilation port and a second ventilation port may be formed in the blocking frame 800. In addition, a first ventilation device 810 and a second ventilation device 830 may be installed at the first ventilation port and the second ventilation port, respectively.

The first ventilation port in which the first ventilation device 810 is installed is formed to pass through a region of the blocking frame 800 installed in the first passage 310 between the outside air inlet 311 and the first heat exchanger 410.

The second ventilation port in which the second ventilation device 830 is installed is formed to pass through a region of the blocking frame 800 installed in the second passage 320 between the air intake port 321 and the second heat exchanger 420.

The first ventilation device 810 may open and close the first ventilation port to adjust the flow rate of air passing through the first ventilation port.

The second ventilation device 830 may open and close the second ventilation port to adjust the flow rate of air passing through the second ventilation port.

In addition, the first ventilation device 810 and the second ventilation device 830 may be ventilation dampers. In addition, the first ventilation device 810 and the second ventilation device 830 may include an air volume detection unit, and measure the air volume of air passing through the first and second ventilation openings, respectively, through the air volume detection unit, and based on this Accordingly, the first ventilation device 810 and the second ventilation device 830 may adjust the amount of air that passes through the first ventilation port and the second ventilation port, respectively.

The control device (not shown) may control operations of the plurality of direction change dampers 700, the first ventilation device 810, and the second ventilation device 820. In addition, the control device may also control the operation of the air supply fan 210 and the exhaust fan 220.

In the first embodiment of the present invention, the control device is divided according to a mode selected from among a plurality of modes including a summer cooling and dehumidifying mode, a winter heating and humidifying mode, and a winter heating and defrosting mode, and the operation of the plurality of direction change dampers 700 Can be controlled.

In addition, the plurality of modes may further include a cooling dehumidifying ventilation mode in summer and a heating defrosting ventilation mode in winter. In this case, the control device may control operations of the first ventilation device 810 and the second ventilation device 830 as well as the plurality of direction change dampers 700 by dividing according to the selected mode.

Hereinafter, the operating principle of the air conditioning system 101 according to the first embodiment of the present invention will be described in detail with reference to FIGS. 2 to 7. In FIGS. 3, 5, and 7, OA represents outside air intake, EA represents exhaust, RA represents internal air intake, and S represents supply air.

Among the plurality of modes, the summer cooling and dehumidifying mode may be selected to supply cold air to the indoor room in the summer and to lower the indoor humidity.

2 and 3, in the summer cooling and dehumidifying mode, the control device operates so that the first damper 710 blocks the first passage 310 and opens the first bypass opening 510, and 3 The damper 730 is operated to block the second passage 320 and open the third bypass opening 530, and the fourth damper 740 blocks the fourth bypass opening 540 and the second passage 320 ) To open, and the eighth damper 780 is operated to close the eighth bypass opening 580 and open the second passage 320 to be sucked into the outside air inlet 311 of the first passage 310. The outside air is guided to be discharged to the exhaust port 329 through the second heat exchanger 420 after moving to the second passage 320 through the third passage 330.

As described above, according to the first embodiment of the present invention, the outside air sucked through the outside air inlet 311 does not flow into the room, and the temperature of the second heat exchanger 420 is reduced while passing through the second heat exchanger 420. Lowered. In addition, water generated in the first heat exchanger 410 and supplied to the second heat exchanger 420 is evaporated into steam by the heat of the second heat exchanger 420, and the steam is evaporated into steam through the exhaust port 329 together with outside air. It is discharged to the outside.

In the first embodiment of the present invention, since the first heat exchanger 410 and the second heat exchanger 420 constitute a refrigeration cycle in the cooling and dehumidifying mode in the summer, the temperature of the second heat exchanger 420 is lowered by outside air. In addition, since it is possible to lower the temperature of the second heat exchanger 420 by the latent heat of evaporation when the water generated in the first heat exchanger 410 and supplied to the second heat exchanger 420 evaporates, Efficiency can be greatly improved.

In addition, the control device operates so that the seventh damper 770 blocks the second passage 320 and opens the seventh bypass opening 570, and the fifth damper 750 blocks the first passage 310 5 Operated to open the bypass opening 550, the sixth damper 760 is operated to close the sixth bypass opening 760 and open the first passage 310, and the second damper 720 is 2 By closing the bypass opening 720 and operating to open the first passage 310, indoor air sucked through the air intake port 321 of the second passage 320 is transferred to the first passage ( After moving to 310), passing through the first heat exchanger 410, it is induced to be discharged to the air supply port 319 of the first passage 310.

As described above, according to the first embodiment of the present invention, indoor air sucked through the internal air inlet 321 is cooled while passing through the first heat exchanger 410 to supply cold air to the room.

In addition, since the indoor air passes through the first heat exchanger 410 and the moisture contained in the indoor air is condensed, the moisture of the air supplied back into the room through the first heat exchanger 410 and through the supply port 319 It can be reduced to obtain a dehumidification effect.

In addition, as described above, the efficiency of the refrigeration cycle constituted by the first heat exchanger 410 and the second heat exchanger 420 is improved, so that the cooling efficiency can be greatly improved.

In addition, in the first embodiment of the present invention, outside air is not introduced into the room and the indoor air is cooled while circulating, so that the cooling efficiency can be further improved.

Among the plurality of modes, a winter heating and humidification mode may be selected to supply warm air to the interior during winter and increase indoor humidity.

4 and 5, in the winter heating and humidification mode, the control device operates so that the first damper 710 closes the first bypass opening 510 and opens the first passage 310, and The 5 damper 750 is operated to close the fifth bypass opening 550 and open the first passage 310, and the sixth damper 760 blocks the first passage 310 and the sixth bypass opening 560 ) To open, and the eighth damper 780 is operated to close the second passage 320 and open the eighth bypass opening 580, thereby being sucked into the outside air inlet 311 of the first passage 310. After the outside air passes through the first heat exchanger 410, it is induced to be discharged to the exhaust port 329 of the second passage 320 through the fourth passage 340.

As described above, according to the first embodiment of the present invention, the outside air sucked through the outside air inlet 311 does not flow into the room, and the temperature of the first heat exchanger 410 is increased while passing through the first heat exchanger 410. Lowered. In addition, water is generated when cold air outside the winter season comes into contact with the first heat exchanger 410, and the water thus generated is supplied to the second heat exchanger 420 or stored in the storage tank 480, followed by a second heat exchange. It may be supplied to the machine 420.

In addition, the control device operates so that the seventh damper 770 blocks the seventh bypass opening 570 and opens the second passage 320, and the third damper 730 opens the third bypass opening 530. It is operated to block and open the second passage 320, the fourth damper 740 is operated to close the second passage 320 and open the fourth bypass opening 540, and the second damper 720 is The first passage 310 is blocked and the second bypass opening 520 is opened so that the indoor air sucked through the inside air intake 321 of the second passage 320 passes through the second heat exchanger 420 and then the third It is induced to be discharged to the air supply port 319 of the first passage 310 through the passage 330.

In the first embodiment of the present invention, since the first heat exchanger 410 and the second heat exchanger 420 constitute heat pumps in the winter equipment heating and humidification mode, the indoor air sucked through the internal air inlet 321 is second As it passes through the heat exchanger 420, it becomes hot and warm air is supplied to the room.

In addition, water generated by the water generated in the first heat exchanger 410 is evaporated in the second heat exchanger 420 and the generated water vapor passes through the second heat exchanger 420 and is supplied back to the room through the supply port 319. It increases the humidity of the room, so that a humidification effect can be obtained.

In addition, the efficiency of the heat pump constituted by the first heat exchanger 410 and the second heat exchanger 420 is improved, so that heating efficiency can be greatly improved.

In addition, in the first embodiment of the present invention, since outside air is not introduced into the room and is heated while circulating indoor air, heating efficiency can be further improved.

Among the plurality of modes, the winter heating defrost mode may be selected when defrost is to be performed on the first heat exchanger 410 in winter.

6 and 7, in the winter heating defrost mode, the control device operates so that the first damper 710 blocks the first passage 310 and opens the first bypass opening 510, and 3 The damper 730 is operated to block the second passage 320 and open the third bypass opening 530, and the fourth damper 740 blocks the fourth bypass opening 540 and the second passage 320 ) To open, and the eighth damper 780 is operated to close the eighth bypass opening 580 and open the second passage 320 to be sucked into the outside air inlet 311 of the first passage 310. The outside air is guided to be discharged to the exhaust port 329 of the second passage 320 through the second heat exchanger 420 after moving to the second passage 320 through the third passage 330.

In addition, the control device operates so that the seventh damper 770 blocks the second passage 320 and opens the seventh bypass opening 570, and the fifth damper 750 blocks the first passage 310 5 Operated to open the bypass opening 550, the sixth damper 760 is operated to close the sixth bypass opening 560 and open the first passage 310, and the second damper 720 is 2 By closing the bypass opening 520 and operating the first passage 310 to open, the indoor air sucked through the air intake port 321 of the second passage 320 is transferred to the first passage ( After moving to 310), it is controlled to induce discharge to the air supply port 319 of the first passage 310 through the first heat exchanger 410.

In this way, in the winter heating defrost mode, hot air in the room passes through the first heat exchanger 410 to remove frost generated in the first heat exchanger 410.

In addition, as the frost of the first heat exchanger 410 is removed, the humidity of the air supplied back to the room through the air supply port 319 of the first passage 310 through the first heat exchanger 410 is increased. The humidification effect can also be obtained.

Among the plurality of modes, the summer cooling and dehumidifying ventilation mode may be selected when cold air is supplied to the room in the summer season, and ventilation is also performed while lowering indoor humidity.

The summer cooling and dehumidifying ventilation mode operates in the same manner as the summer cooling and dehumidifying mode described above, but only the operation of the first ventilation device 810 and the third ventilation device 830 is added.

In the summer cooling and dehumidification mode, outside air is not introduced into the room and the indoor air is circulated to cool it, so no ventilation is performed. Accordingly, when the indoor air quality is deteriorated or ventilation is required according to the wish of the occupant, the first ventilation device 810 installed in the first passage 310 between the outdoor air intake 311 and the first heat exchanger 410, and the internal air By operating the third ventilation device 830 installed in the second passage 320 between the inlet 321 and the second heat exchanger 420, the indoor air introduced into the internal air inlet 321 is transferred to the outside through the exhaust port 329. It is discharged to, and the outside air introduced through the outside air intake port 311 can be supplied to the room through the air supply port 319.

At this time, the air volume of the air ventilated through the first ventilation device 810 and the third ventilation device 830 is relatively less than the volume of air discharged through the air supply port 319 after being sucked into the air intake port 321 . For example, after being sucked through the air intake port 321, the air may be ventilated with an air volume less than 10% of the maximum air volume of air discharged through the air supply port 319.

Among the plurality of modes, the winter heating defrost ventilation mode may be selected when defrosting is performed on the first heat exchanger 410 in winter and ventilation is also performed.

The winter heating defrost ventilation mode operates in the same manner as the winter heating defrost mode, but only the operation of the first ventilation device 810 and the third ventilation device 830 is added.

In the winter heating defrost mode, outside air is not introduced into the room and indoor air is circulated while heating, so ventilation is not performed at all. Accordingly, when the indoor air quality is deteriorated or ventilation is required according to the wish of the occupant, the first ventilation device 810 installed in the first passage 310 between the outdoor air intake 311 and the first heat exchanger 410, and the internal air By operating the third ventilation device 830 installed in the second passage 320 between the inlet 321 and the second heat exchanger 420, the indoor air introduced into the internal air inlet 321 is transferred to the outside through the exhaust port 329. It is discharged to, and the outside air introduced through the outside air intake port 311 can be supplied to the room through the air supply port 319.

At this time, the air volume of the air ventilated through the first ventilation device 810 and the third ventilation device 830 is relatively less than the volume of air discharged through the air supply port 319 after being sucked into the air intake port 321 . For example, after being sucked through the air intake port 321, the air may be ventilated with an air volume less than 10% of the maximum air volume of air discharged through the air supply port 319.

With this configuration, the air conditioning system 101 according to the first embodiment of the present invention converts airflow into a plurality of specific flow paths to efficiently cool, dehumidify, heat, humidify, defrost, and ventilate with one air conditioner. You can do it.

Specifically, according to the first embodiment of the present invention, unlike a method of implementing cooling and heating by cross-operating an evaporation coil and a condensation coil on all four sides of an existing heat pump, a plurality of direction change dampers 700 are used to Without it, it is possible to provide a heat pump type integrated air conditioning system capable of efficiently performing cooling, dehumidification, heating, humidification, defrost, and ventilation with one air conditioner.

Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 8 to 10.

8 to 10, in the air conditioning system 102 according to the second embodiment of the present invention, the second heat exchanger 420 is located below the first heat exchanger 410, and the first Water generated in the heat exchanger 410 freely falls toward the second heat exchanger 420.

Therefore, since it is not necessary to separately install the water pump 470 for supplying water, not only the installation space can be reduced, but also energy consumption required to operate the water pump 470 can be reduced.

That is, according to the second embodiment of the present invention, the operating efficiency of the air conditioning system 101 can be further improved.

8 shows a summer cooling dehumidifying mode or a summer cooling dehumidifying ventilation mode in the second embodiment of the present invention, except that the second heat exchanger 420 is disposed under the first heat exchanger 410 Same as the example.

9 shows a winter heating and humidification mode in the second embodiment of the present invention, and is the same as the first embodiment except that the second heat exchanger 420 is disposed under the first heat exchanger 410.

10 shows a winter heating defrost mode or a winter heating defrost ventilation mode in the second embodiment of the present invention, except that the second heat exchanger 420 is disposed under the first heat exchanger 410 Same as the example.

With this configuration, the air conditioning system 102 according to the second embodiment of the present invention converts airflow into a plurality of specific flow paths to efficiently cool, dehumidify, heat, humidify, defrost, and ventilate with one air conditioner. You can do it.

Specifically, according to the second embodiment of the present invention, unlike a method of implementing cooling and heating by cross-operating evaporation coils and condensing coils on all four sides of a conventional heat pump, a plurality of direction change dampers 700 are used to Without it, it is possible to provide a heat pump type integrated air conditioning system capable of efficiently performing cooling, dehumidification, heating, humidification, defrost, and ventilation with one air conditioner.

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. will be.

Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects, and the scope of the present invention is indicated by the claims to be described later, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

101, 102: air conditioning system
210: air supply fan
220: exhaust fan
310: first passage
311: outside air intake
319: air supply
320: second passage
321: bet inlet
329: exhaust port
330: third passage
340: fourth passage
410: first heat exchanger
420: second heat exchanger
440: expansion valve
450: compressor
460: refrigerant flow path
470: water pump
480: storage tank
500: multiple bypass openings
510: first bypass opening
520: second bypass opening
530: third bypass opening
540: fourth bypass opening
550: fifth bypass opening
560: sixth bypass opening
570: seventh bypass opening
580: eighth bypass opening
700: multiple direction change dampers
710: first damper
720: second damper
730: third damper
740: fourth damper
750: fifth damper
760: sixth damper
770: seventh damper
780: eighth damper
800: blocking frame
810: first ventilation device
830: second ventilation device

Claims (18)

A first passage having an outside air intake port installed at one end, a supply port at the other end, and a first heat exchanger installed between the outside air intake port and the air supply port;
A second passage having an exhaust port installed at one end, an air intake port at the other end, and a second heat exchanger configured to exchange the first heat exchanger and the refrigerant between the exhaust port and the air intake port;
It is connected to one side of the first passage between the outside air intake port and the first heat exchanger, and between the air supply port and the first heat exchanger, and between the inner air intake port and the second heat exchanger, and between the exhaust port and the second heat exchanger. A third passage connected to one side of the second passage between heat exchangers;
It is connected to the other side of the first passage between the outside air intake port and the first heat exchanger, and between the air supply port and the first heat exchanger, and between the inner air intake port and the second heat exchanger, and between the exhaust port and the second heat exchanger. A fourth passage connected to the other side of the second passage between heat exchangers; And
Selectively opening and closing one of the first passage and the second passage and one of the plurality of bypass openings respectively communicating one of the third passage and the fourth passage and one of the first passage and the second passage Multiple direction change dampers
Air conditioning system comprising a. The method of claim 1,
An air supply fan disposed relatively adjacent to the air supply in the first passage;
An exhaust fan disposed relatively adjacent to the exhaust port of the second passage
Air conditioning system, characterized in that it further comprises. The method of claim 1,
The third passage,
A first bypass opening formed on one surface of the first passage between the outside air intake port and the first heat exchanger, and a second bypass opening formed on one surface of the first passage between the air supply port and the first heat exchanger Each connected to the first passage through,
A third bypass opening formed on one surface of the second passage between the air intake port and the second heat exchanger, and a fourth bypass opening formed on one surface of the second passage between the exhaust port and the second heat exchanger. Each is connected to the second passage through,
The fourth passage,
A fifth bypass opening formed on the other surface of the first passage between the outside air intake port and the first heat exchanger, and a sixth bypass opening formed on the other surface of the first passage between the air supply port and the first heat exchanger Is connected to the first passage through,
A seventh bypass opening formed on the other surface of the second passage between the air intake port and the second heat exchanger, and an eighth bypass opening formed on the other surface of the second passage between the exhaust port and the second heat exchanger. Air conditioning system, characterized in that connected to the second passage through. The method of claim 3,
The plurality of direction change dampers,
A first damper selectively closing one of the first passage and the first bypass opening between the outside air inlet and the first heat exchanger;
A second damper selectively closing one of the first passage and the second bypass opening between the air supply port and the first heat exchanger;
A third damper selectively closing one of the second passage and the third bypass opening between the inner air inlet and the second heat exchanger;
A fourth damper selectively closing one of the second passage and the fourth bypass opening between the exhaust port and the second heat exchanger;
A fifth damper selectively closing one of the first passage and the fifth bypass opening between the outside air inlet and the first heat exchanger;
A sixth damper selectively closing one of the first passage and the sixth bypass opening between the air supply port and the first heat exchanger;
A seventh damper selectively closing one of the second passage and the seventh bypass opening between the inner air inlet and the second heat exchanger; And
An eighth damper selectively closing one of the second passage and the eighth bypass opening between the exhaust port and the second heat exchanger
Air conditioning system, characterized in that it further comprises. The method of claim 4,
The air conditioning system,
A refrigerant flow path for moving a refrigerant between the first heat exchanger and the second heat exchanger;
An expansion valve installed in the refrigerant flow path; And
Compressor installed in the refrigerant flow path to compress the refrigerant
Air conditioning system, characterized in that it further comprises. The method of claim 5,
The first heat exchanger operates as an evaporator,
The second heat exchanger is an air conditioning system, characterized in that operating as a condenser. The method of claim 6,
Further comprising a control device for controlling the operation of the plurality of direction change dampers,
The control device is an air conditioning system, characterized in that the control unit controls the operation of the plurality of direction change dampers by dividing according to a mode selected from among a plurality of modes including a summer cooling dehumidification mode, a winter heating and humidifying mode, and a winter heating and defrosting mode. . The method of claim 7,
In the summer cooling and dehumidifying mode, the control device,
The first damper is operated to block the first passage and open the first bypass opening, the third damper is operated to close the second passage and open the third bypass opening, and the fourth damper Is operated to close the fourth bypass opening and open the second passage, and the eighth damper is operated to close the eighth bypass opening and open the second passage. Inducing to be discharged to the exhaust port through the second heat exchanger through a third passage,
The seventh damper is operated to block the second passage and open the seventh bypass opening, the fifth damper is operated to close the first passage and open the fifth bypass opening, and the sixth damper Is operated to close the sixth bypass opening and open the first passage, and the second damper is operated to close the second bypass opening and open the first passage, so that the indoor air sucked through the inner air intake port is Air conditioning system, characterized in that inducing to be discharged to the supply port through the first heat exchanger through the fourth passage. The method of claim 7,
In the winter heating humidification mode, the control device,
The first damper is operated to close the first bypass opening and open the first passage, the fifth damper is operated to close the fifth bypass opening and open the first passage, and the sixth damper Is operated to block the first passage and open the sixth bypass opening, and the eighth damper is operated to close the second passage and open the eighth bypass opening, After passing through the first heat exchanger, it is induced to be discharged to the exhaust port through the fourth passage,
The seventh damper is operated to close the seventh bypass opening and open the second passage, the third damper is operated to close the third bypass opening and open the second passage, and the fourth damper Is operated to block the second passage and open the fourth bypass opening, and the second damper is operated to close the first passage and open the second bypass opening, so that the indoor air sucked through the inside air intake port is After passing through the second heat exchanger, the air conditioning system is guided to be discharged to the supply port through the third passage. The method of claim 7,
In the winter heating defrost mode, the control device,
The first damper is operated to block the first passage and open the first bypass opening, the third damper is operated to close the second passage and open the third bypass opening, and the fourth damper Is operated to close the fourth bypass opening and open the second passage, and the eighth damper is operated to close the eighth bypass opening and open the second passage. Inducing to be discharged to the exhaust port through the second heat exchanger through a third passage,
The seventh damper is operated to block the second passage and open the seventh bypass opening, the fifth damper is operated to close the first passage and open the fifth bypass opening, and the sixth damper Is operated to close the sixth bypass opening and open the first passage, and the second damper is operated to close the second bypass opening and open the first passage. Air conditioning system, characterized in that inducing to be discharged to the air supply port through the first heat exchanger through the fourth passage. The method of claim 6,
When the plurality of direction change dampers close the first passage and the second passage, further comprising a blocking frame for supporting the plurality of direction change dampers while filling a gap between the plurality of direction change dampers,
The air conditioning system,
A first ventilation device for opening and closing the first ventilation port and a first ventilation port passing through a region of the blocking frame installed in the first passage between the outside air intake port and the first heat exchanger; And
A second ventilation device for opening and closing the second ventilation port and the second ventilation port passing through a region of the blocking frame installed in the second passage between the air intake port and the second heat exchanger
Air conditioning system, characterized in that it further comprises. The method of claim 11,
Further comprising a control device for controlling the operation of the plurality of direction change dampers, the first ventilation device, and the second ventilation device,
The control device divides the operation of the plurality of direction change dampers, the first ventilation device, and the second ventilation device according to a mode selected from among a plurality of modes including a summer cooling dehumidification ventilation mode and a winter heating dehumidification ventilation mode. Air conditioning system, characterized in that to control. The method of claim 12,
In the summer cooling dehumidifying ventilation mode, the control device,
The first damper is operated to block the first passage and open the first bypass opening, the third damper is operated to close the second passage and open the third bypass opening, and the fourth damper Is operated to close the fourth bypass opening and open the second passage, and the eighth damper is operated to close the eighth bypass opening and open the second passage. Inducing to be discharged to the exhaust port through the second heat exchanger through a third passage,
The seventh damper is operated to block the second passage and open the seventh bypass opening, the fifth damper is operated to close the first passage and open the fifth bypass opening, and the sixth damper Is operated to close the sixth bypass opening and open the first passage, and the second damper is operated to close the second bypass opening and open the first passage, so that the indoor air sucked through the inner air intake port is Induces discharge to the supply port through the first heat exchanger through the fourth passage,
An air conditioning system, characterized in that the first ventilation device and the second ventilation device are operated. The method of claim 12,
In the winter heating defrost ventilation mode, the control device,
The first damper is operated to block the first passage and open the first bypass opening, the third damper is operated to close the second passage and open the third bypass opening, and the fourth damper Is operated to close the fourth bypass opening and open the second passage, and the eighth damper is operated to close the eighth bypass opening and open the second passage. Inducing to be discharged to the exhaust port through the second heat exchanger through a third passage,
The seventh damper is operated to block the second passage and open the seventh bypass opening, the fifth damper is operated to close the first passage and open the fifth bypass opening, and the sixth damper Is operated to close the sixth bypass opening and open the first passage, and the second damper is operated to close the second bypass opening and open the first passage, so that the indoor air sucked through the inner air intake port is Induces discharge to the supply port through the first heat exchanger through the fourth passage,
An air conditioning system, characterized in that the first ventilation device and the second ventilation device are operated. The method according to any one of claims 1 to 14,
Supplying water generated in the first heat exchanger to the second heat exchanger,
An air conditioning system, characterized in that the water supplied to the second heat exchanger is evaporated into steam through the heat of condensation of the second heat exchanger. The method of claim 15,
The water vapor generated by the second heat exchanger is supplied indoors in winter and discharged outdoors in summer. The method of claim 15,
The first heat exchanger and the second heat exchanger are arranged side by side to the left and right,
And a water pump for supplying water generated in the first heat exchanger to the second heat exchanger. The method of claim 15,
The second heat exchanger is located below the first heat exchanger,
The water generated in the first heat exchanger freely falls toward the second heat exchanger.

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