KR102538755B1 - Air conditioning system - Google Patents

Abstract

An air conditioning system according to an embodiment of the present invention includes a first heat exchanger including a coil coated with a desiccant and exchanging heat before supplying indoor air or exchanging heat before exhausting outdoor air; When heat is exchanged before, heat is exchanged before outdoor air is exhausted, and when heat is exchanged before the first heat exchanger exhausts outdoor air, heat is exchanged before indoor air is supplied, and a second heat exchanger including a coil coated with a desiccant; A refrigerant movement passage for moving the refrigerant between the second heat exchanger, an expansion valve installed in the refrigerant movement passage, a compressor installed in the refrigerant movement passage for compressing the refrigerant, and switching suction and discharge paths of the compressor It includes quadrilaterals.

Description

Air conditioning system {AIR CONDITIONING SYSTEM}

The present invention relates to an air conditioning system for performing cooling and heating in an indoor space.

Due to the climate characteristics of the Republic of Korea, the temperature and humidity are low in winter, while the temperature and humidity are gradually increasing in summer, and the daily temperature range and annual temperature range are gradually increasing.

Most of modern people's activities are performed indoors, and cooling or heating is performed for more than half of the year to maintain a comfortable indoor temperature. In addition, due to the increasingly shorter spring and autumn, the period during which cooling or heating is required is also increasing.

Accordingly, energy consumption due to an increase in cooling and heating time is also increasing, and a plan to save energy during cooling or heating is required.

In addition, air conditioners generally used in residential and non-residential buildings perform cooling and heating by switching between condensers and evaporators. However, in the heating operation mode, the defrosting operation must be operated once in the middle to defrost the frosted evaporator to maintain heating efficiency. Since this defrosting operation is usually maintained for about 10 minutes, there is a problem in that during that time, heating is stopped and cold air is supplied to the room.

An embodiment of the present invention provides an air conditioning system capable of continuously heating without interruption and improving energy use efficiency.

According to an embodiment of the present invention, an air conditioning system includes a first heat exchanger that exchanges heat before supplying indoor air or exchanging heat before exhausting outdoor air and includes a coil coated with a desiccant; When heat is exchanged before supplying air, heat is exchanged before outdoor air is exhausted, and when the first heat exchanger exchanges heat before outdoor air is exhausted, heat is exchanged before supplying indoor air, and second heat exchanger including a coil coated with a desiccant A refrigerant flow path for moving the refrigerant between the first heat exchanger and the second heat exchanger, an expansion valve installed in the refrigerant flow path, a compressor installed in the refrigerant flow path to compress the refrigerant, and the compressor It includes a four-way valve that converts the intake and discharge paths. In the winter season, the air conditioning system moves the refrigerant discharged from the compressor in the direction of the first heat exchanger so that the first heat exchanger operates as a condenser and the second heat exchanger operates as an evaporator, and the indoor air A first heating cycle in which the temperature is raised through the first heat exchanger, then air is supplied to the room, and outdoor air is exhausted to the outside after passing through the second heat exchanger;

Moves toward the second heat exchanger to operate the second heat exchanger as a condenser and operate the first heat exchanger as an evaporator. It operates in a continuous heating operation mode in which the second heating cycle of exhausting to the outside after being exhausted is alternately and repeatedly operated.

The first heating cycle and the second heating cycle in the continuous heating operation mode are alternately repeated according to a predetermined cycle or alternately according to the freezing state of the first heat exchanger or the second heat exchanger operating as an evaporator. can be repeated with

When operating in the first heating cycle, the condensed water generated in the coil of the second heat exchanger operating as an evaporator absorbs moisture into the desiccant of the second heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant during the second heating cycle. The condensed water that has been absorbed by the desiccant of the machine and then evaporates and evaporates with the condensation heat of the first heat exchanger lowers the refrigerant condensation temperature and is supplied to the room to humidify the room. When operating in the second heating cycle, the condensed water generated in the coil of the first heat exchanger operating as an evaporator absorbs moisture into the desiccant of the first heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant during the first heating cycle. The condensed water that has been absorbed by the desiccant of the heat exchanger and then frozen is vaporized and evaporated by the condensation heat of the second heat exchanger to lower the condensation temperature of the refrigerant and is supplied to the room to humidify the room.

In the air conditioning system, in summer, the four sides move the refrigerant discharged from the compressor in the direction of the first heat exchanger to operate the first heat exchanger as a condenser and operate the second heat exchanger as an evaporator to supply indoor air to the first heat exchanger. 2 A first cooling cycle in which air is supplied indoors after cooling through a heat exchanger, and outdoor air is exhausted to the outdoors after passing through the first heat exchanger, and the four sides move the refrigerant discharged from the compressor toward the second heat exchanger The second heat exchanger is operated as a condenser and the first heat exchanger is operated as an evaporator, the indoor air is cooled through the first heat exchanger, supplied to the room, and the outdoor air is exhausted to the outdoors after passing through the second heat exchanger. It may operate in a continuous cooling operation mode in which the cooling cycle is alternately and repeatedly operated.

The first cooling cycle and the second cooling cycle in the continuous cooling operation mode are alternately repeated according to a predetermined cycle, or the desiccant coated on the coil of the first heat exchanger and the coil of the second heat exchanger It may be repeated alternately depending on the moisture absorption state of the desiccant.

When operating in the first cooling cycle, the condensed water generated in the coil of the second heat exchanger, which operates as an evaporator, absorbs moisture into the desiccant of the second heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant in the first heat exchanger during the second cooling cycle. The condensed water absorbed by the desiccant of the machine evaporates with the condensation heat of the first heat exchanger and hot outdoor air heat, lowering the condensation temperature of the refrigerant and discharging it to the outdoors. In addition, when operating in the second cooling cycle, the condensed water generated in the coil of the first heat exchanger operating as an evaporator increases the evaporation temperature of the refrigerant while being absorbed by the desiccant of the first heat exchanger, and increases the evaporation temperature of the refrigerant during the first cooling cycle. The condensed water absorbed by the desiccant of the heat exchanger evaporates with the condensation heat of the second heat exchanger and hot outdoor air heat, thereby lowering the condensation temperature of the refrigerant and discharging it to the outdoors.

The air conditioning system includes a first condensate collecting fan for collecting the condensate water generated in the first heat exchanger, a second condensate collecting fan for collecting the condensate water generated in the second heat exchanger, and the first condensate collecting fan. A drain pipe for discharging the condensed water collected in the second condensate collection fan, a first drain valve installed in the drain pipe for discharging the condensate collected in the first condensate collection fan, and a drain pipe installed in the drain pipe for discharging the condensate water collected in the first condensate collection fan. A second drain valve for discharging the condensed water collected in the collecting fan may be further included.

In addition, the air conditioning system includes a first condensate collecting fan for collecting the condensate that has fallen from the first heat exchanger, a second condensate collecting fan for collecting the condensate that has fallen from the second heat exchanger, and the first heat exchanger. A first condensate injection unit for injecting condensate, a first condensate supply line for supplying the condensate collected in the first condensate collection fan to the first condensate injection unit, and the condensate collected in the first condensate collection fan, 2 a second condensate supply line supplied to the condensate spraying unit, a third condensate supply line supplying the condensate collected in the second condensate collecting fan to the first condensate spraying unit, and the condensed water collected in the second condensate collecting fan A fourth condensed water supply line supplied to the second condensed water injection unit may be further included.

The air conditioning system is a first condensate for supplying the condensate collected in the first condensate collecting fan to the first condensate spraying part or the second condensing water spraying part through the first condensate supply line or the second condensate supply line. A pump, and a second condensate pump for supplying the condensate collected in the second condensate collection fan to the first condensate spray part or the second condensate spray part through the third condensate supply line or the fourth condensate supply line; , a first control valve installed on the first condensate supply line, a second control valve installed on the second condensate supply line, a third control valve installed on the third condensate supply line, and the fourth condensate water It may further include a fourth control valve installed on the supply line.

One or more first condensate spraying parts are provided to spray condensate in the form of mist toward one surface of the first heat exchanger that contacts indoor air or outdoor air, and one or more second condensate spraying parts are provided to indoor air or outdoor air. One or more may be provided to spray condensed water in the form of mist toward one side of the second heat exchanger in contact with air.

When operating in the first heating cycle of the continuous heating operation mode, the condensate collected in the first condensate collection fan is supplied to the first condensate injection unit through the first condensate supply line, and is supplied to the second condensate collection fan. The remaining condensed water is supplied to the first condensate spraying unit through the third condensed water supply line, and the first condensed water spraying unit injects condensed water into the first heat exchanger operating as a condenser in the first heating cycle, During the second heating cycle, the condensate that is absorbed by the desiccant of the first heat exchanger and then frozen is melted by the condensation heat of the first heat exchanger and the condensate sprayed from the first condensate injection unit, or vaporized and evaporated together with the condensate, The indoor air may be supplied to the room together with the indoor air passing through the heat exchanger to humidify the indoor air.

In addition, when operating in the second heating cycle of the continuous heating operation mode, the condensate collected in the second condensate collection fan is supplied to the second condensate injection unit through the fourth condensate supply line, and the first condensate collection fan The condensate remaining in the fan is supplied to the second condensate injection unit through the second condensate supply line, and the second condensate injection unit injects condensate into the second heat exchanger operating as a condenser in the second heating cycle, The condensate that has been absorbed by the desiccant of the second heat exchanger during the first heating cycle and then frozen is melted by the condensation heat of the second heat exchanger and the condensate sprayed from the second condensate injection unit, or vaporized and evaporated together with the condensate. The indoor air may be supplied to the room together with the indoor air passing through the second heat exchanger to humidify the indoor air.

In the first heating cycle, condensate that is not evaporated after being sprayed from the first condensate injection unit is collected in the first condensate collection fan and then supplied to the first condensate injection unit again through the first condensate supply line, In the second heating cycle, condensate that is not evaporated after being sprayed from the second condensate injection unit may be collected in the second condensate collection fan and then supplied to the second condensate injection unit again through the fourth condensate supply line.

When operating in the first cooling cycle of the continuous cooling operation mode, the condensate collected in the first condensate collection fan is supplied to the first condensate spraying part through the first condensate supply line, and is supplied to the second condensate collection fan. The collected condensate is supplied to the first condensate spraying unit through the third condensate supply line, and some or all of the condensed water sprayed from the first condensate spraying unit absorbs moisture into the desiccant coated on the coil of the first heat exchanger. In the first heat exchanger operating as a condenser, the refrigerant may be evaporated by the condensation heat of the refrigerant and the thermal energy of the outdoor air, and discharged to the outdoors together with the outdoor air passing through the first heat exchanger.

In addition, when operated in the second cooling cycle of the continuous cooling operation mode, the condensate collected in the second condensate collection fan is supplied to the second condensate spraying part through the fourth condensate supply line, and the first condensate collection fan The condensate collected in the fan is supplied to the first condensate spraying part through the second condensate supply line, and some or all of the condensed water sprayed from the second condensate spraying part is a desiccant coated on the coil of the second heat exchanger. In the second heat exchanger that operates as a condenser, the refrigerant is evaporated by the condensation heat of the refrigerant and the thermal energy of the outdoor air, and discharged to the outdoors together with the outdoor air passing through the second heat exchanger.

In the first cooling cycle, the condensate that has not been evaporated after being sprayed from the first condensate spray part is collected in the first condensate collection fan and then supplied to the first condensate spray part again through the first condensate supply line. In the second cooling cycle, condensate that is not evaporated after being sprayed from the second condensate spray unit may be collected in the second condensate collection fan and then supplied to the second condensate spray unit again through the fourth condensate supply line.

According to an embodiment of the present invention, the air conditioning system can continuously heat without interruption and can effectively improve energy use efficiency.

1 is a configuration diagram showing a first cooling cycle of continuous cooling operation of an air conditioning system according to a first embodiment of the present invention.
2 is a configuration diagram showing a second cooling cycle of continuous cooling operation of the air conditioning system according to the first embodiment of the present invention.
3 is a configuration diagram showing a first heating cycle of continuous heating operation of the air conditioning system according to the first embodiment of the present invention.
4 is a configuration diagram showing a second cooling cycle of continuous heating operation of the air conditioning system according to the first embodiment of the present invention.
5 is a configuration diagram showing a first cooling cycle of continuous cooling operation of an air conditioning system according to a second embodiment of the present invention.
6 is a configuration diagram showing a second cooling cycle of continuous cooling operation of the air conditioning system according to the second embodiment of the present invention.
7 is a configuration diagram showing a first heating cycle of continuous heating operation of an air conditioning system according to a second embodiment of the present invention.
8 is a configuration diagram showing a second cooling cycle of continuous heating operation of an air conditioning system according to a second embodiment of the present invention.
9 is a configuration diagram showing an air conditioning system according to a third 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 skilled in the art can easily carry out the present invention. This invention may be embodied in many different forms and is not limited to the embodiments set forth herein.

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

It is advised that the drawings are schematic and not drawn to scale. Relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and not limiting. And like structures, elements or parts appearing in two or more drawings, like reference numerals are used to indicate like features.

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

In addition, all technical terms and scientific terms used in this specification have meanings commonly understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined. All terms used herein are selected for the purpose of more clearly describing the present invention and are not selected to limit the scope of rights according to the present invention.

In addition, expressions such as 'comprising', 'including', 'having', etc. used in this specification imply the possibility of including other embodiments, unless otherwise stated in the phrase or sentence in which the expression is included. It should be understood in open-ended terms.

In addition, singular expressions described in this specification may include plural meanings unless otherwise stated, and this applies to singular expressions described in the claims as well.

In addition, expressions such as 'first' and 'second' used in this specification are used to distinguish a plurality of components from each other, and do not limit the order or importance of the components.

Hereinafter, the air conditioning system 101 according to the first embodiment of the present invention will be described with reference to FIGS. 1 to 4 .

1 to 4, the air conditioning system 101 according to the first embodiment of the present invention includes a first heat exchanger 210, a second heat exchanger 220, a refrigerant flow passage 260, an expansion valve 270 , compressor 280 , and quadrilateral 240 .

In addition, the air conditioning system 101 according to the first embodiment of the present invention further includes a first condensate collection fan 510, a second condensate collection fan 520, a drain pipe 690, and drain valves 791 and 792. can include

The first heat exchanger 210 may perform heat exchange before supplying indoor air or heat exchange before exhausting outdoor air. That is, the first heat exchanger 210 may be a condenser or an evaporator according to the direction in which the refrigerant moves along the refrigerant flow path 260 to be described later.

The second heat exchanger 220 exchanges heat before exhausting outdoor air when the first heat exchanger 210 exchanges heat before supplying indoor air, and exchanges heat before exhausting outdoor air when the first heat exchanger 210 exchanges heat before exhausting outdoor air. Heat can be exchanged before supplying air. That is, the second heat exchanger 220 operates as an evaporator when the first heat exchanger 210 operates as a condenser according to the moving direction of the refrigerant moving along the refrigerant flow path 620 to be described later, and the first heat exchanger 210 ) can operate as a condenser if it operates as an evaporator.

As such, in the first embodiment of the present invention, one of the first heat exchanger 210 and the second heat exchanger 220 becomes an evaporator and the other becomes a condenser, and their roles may be repeatedly switched.

Meanwhile, although not shown, the first heat exchanger 210 and the second heat exchanger 220 may be connected to the air movement passage, respectively. In addition, according to the operation of the direction changing device for changing the direction of the air moving along the air movement passage, the indoor air (RA) passes through the first heat exchanger 210 and then supplies the indoor air (SA) again to the outdoor air ( OA) is exhausted (EA) to the outdoors again after passing through the second heat exchanger 220, or indoor air (RA) is supplied to the room again after passing through the second heat exchanger 220 (SA) and outdoor air (OA) ) After passing through the first heat exchanger 210, it may be exhausted (EA) to the outdoors again.

In addition, according to the first embodiment of the present invention, the first heat exchanger 210 and the second heat exchanger 220 include coils 210 and 220 coated with desiccants 215 and 225, respectively. . That is, the first heat exchanger 220 includes the first coil 211 and the first desiccant 215 coated on the first coil 211, and the second heat exchanger 220 includes the second coil 221 and a second desiccant 225 coated on the second coil 221 .

In addition, the first desiccant 215 and the second desiccant 225 absorb moisture from the condensed water generated in the first heat exchanger 210 and the second heat exchanger 220, respectively, so that the first heat exchanger 210 or the second heat exchanger The refrigerant evaporation temperature of (220) is increased.

The refrigerant movement passage 260 may move the refrigerant between the first heat exchanger 210 and the second heat exchanger 220 .

The expansion valve 270 may be installed on the refrigerant flow path 260 . For example, the expansion valve 270 may be installed on the refrigerant flow path 260 between the first heat exchanger 210 and the second heat exchanger 220 . The expansion valve 270 is a device that reduces the high-temperature and high-pressure liquid refrigerant condensed and liquefied in the condenser to a pressure capable of causing evaporation by a throttling action, and is also called an expansion valve. In addition, the expansion valve 270 regulates and supplies an appropriate amount of refrigerant capable of absorbing sufficient heat in the evaporator.

The compressor 270 may be installed in the refrigerant flow path 260 to compress the refrigerant. In addition, the compressor 270 may provide power for moving the refrigerant along the refrigerant movement passage 260 .

The four sides 240 may switch between suction and discharge paths of the compressor 270 . The four-way valve 240 is a valve used to switch between cooling and heating in the heat pump method, and is a valve used to change the moving direction of the refrigerant discharged from the compressor 270 . That is, according to the operation of the four sides 240, the refrigerant discharged from the compressor 280 first moves to the first heat exchanger 210, passes through the expansion valve 270 and the second heat exchanger 220, and then returns to the compressor 280. ) or the refrigerant discharged from the compressor 280 may first move to the second heat exchanger 220, pass through the expansion valve 270 and the first heat exchanger 210, and then return to the compressor 280.

The first condensate collecting fan 510 may collect the condensed water generated and dropped from the first heat exchanger 210 .

The second condensate collecting fan 520 may collect the condensate generated and dropped from the second heat exchanger 220 .

The drain pipe 690 is connected to the first condensate collecting fan 510 and the second condensate collecting fan 520, and the condensate collected and stored in the first condensate collecting fan 510 and the second condensate collecting fan 520 is discharged to the outside. can be ejected.

The drain valves 791 and 792 are installed in the drain pipe 690 to open and close the drain pipe 790 . Specifically, the drain valve includes a first drain valve 791 for discharging the condensate collected in the first condensate collecting fan 510 and a second drain for discharging the condensed water collected in the second condensate collecting fan 520. valve 792. Accordingly, when condensate is stored in one or more of the first condensate collecting fan 510 and the second condensate collecting fan 520, one or more of the first drain valve 790 and the second drain valve is opened and the drain pipe is opened. Condensate can be discharged to the outside through

As described above, the air conditioning system 101 according to the first embodiment of the present invention may operate in one selected from among a continuous cooling operation mode and a continuous heating operation mode.

First, in the summer season, the air conditioning system 101 may operate in a continuous cooling operation mode. In the continuous cooling operation mode, the first cooling cycle and the second cooling cycle may be alternately and repeatedly operated.

Specifically, as shown in FIG. 1 , in the first cooling cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the first heat exchanger 210 so that the first heat exchanger 210 is operated as a condenser and the second heat exchanger 220 is operated as an evaporator, and after cooling the indoor air (RA) through the second heat exchanger 220, supplying (SA) indoor air and supplying outdoor air (OA) to the first After passing through the heat exchanger 210, it is exhausted (EA) to the outdoors.

2, in the second cooling cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the second heat exchanger 220 to turn the second heat exchanger 220 into a condenser. and operates the first heat exchanger 210 as an evaporator, cools the indoor air (RA) through the first heat exchanger 210, supplies air (SA) to the room, and supplies outdoor air (OA) to the second heat exchanger After passing through 220, it can be exhausted to the outdoors (EA).

The first cooling cycle and the second cooling cycle in the continuous cooling operation mode are alternately repeated according to a predetermined cycle or the first desiccant 215 coated on the first coil 211 of the first heat exchanger 210 and This may be alternately repeated according to the moisture absorption state of the second desiccant 225 coated on the second coil 221 of the second heat exchanger 220 . Here, the predetermined cycle may be set in various ways according to the amount of condensed water generated in the first coil 211 and the second coil 221 and the moisture absorption capacities of the first desiccant 215 and the second desiccant 225.

In this way, when the air conditioning system 101 is operated in the first cooling cycle during cooling operation in summer, the condensate generated in the second heat exchanger 220 operating as an evaporator is the second desiccant coated on the second coil 221. As moisture is absorbed by 225, the evaporation temperature of the refrigerant is increased. Meanwhile, the condensed water generated during the refrigerant evaporation period of the first heat exchanger 210 during the second cooling cycle and absorbed by the first desiccant 215 is the first heat exchanger 210 generated during the refrigerant condensation period of the first cooling cycle. While evaporating with condensation heat and outdoor hot air heat, the refrigerant condensation temperature is lowered and discharged to the outdoors.

For example, when all the condensed water absorbed by the first desiccant 215 of the first heat exchanger 210 operating as a condenser in the first cooling cycle evaporates, the second cooling cycle is switched.

In addition, when the air conditioning system 101 operates in the second cooling cycle, the condensed water generated in the first heat exchanger 210 operating as an evaporator is absorbed by the first desiccant 215 coated on the first coil 211. As a result, the evaporation temperature of the refrigerant increases. On the other hand, the condensate generated during the refrigerant evaporation period of the second heat exchanger 220 during the first cooling cycle and absorbed by the second desiccant 225 is the condensation heat of the second heat exchanger generated during the refrigerant condensation period of the second cooling cycle. As it evaporates with outdoor hot air heat, it lowers the refrigerant condensation temperature and is discharged to the outdoors.

In addition, the condensate generated in excess of the moisture absorption capacity of the first desiccant 215 and the second desiccant 225 falls from the first heat exchanger 210 and the second heat exchanger 220, and the first condensate collecting fan 510 ) and the second condensate collection fan 520. Since the first cooling cycle and the second cooling cycle are alternately operated, the condensate absorbed by the first desiccant 215 and the second desiccant 225 is periodically evaporated. Condensate collected in the first condensate collection fan 510 and the second condensate collection fan 520 can be minimized. Accordingly, the amount of condensed water that the air conditioning system 101 must discharge to the outside can be minimized.

As described above, according to the first embodiment of the present invention, the second heat exchanger 210 operating as an evaporator or the second heat exchanger 220 operating as a condenser using the condensed water generated in any one of the second heat exchanger 220. By efficiently lowering the condensation temperature of the other one of the heat exchanger 220 or the first heat exchanger 210, it is possible to remove moisture from the indoor air and at the same time save energy required for cooling. In particular, since latent energy can be recovered by nearly 100% in an indirect manner using condensation heat, energy can be greatly reduced.

Also, in the winter season, the air conditioning system 101 may operate in a continuous heating operation mode. In the continuous heating operation mode, the first heating cycle and the second heating cycle may be alternately and repeatedly operated.

Specifically, as shown in FIG. 3 , in the first heating cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the first heat exchanger 210 to cool the first heat exchanger 210. Operates as a condenser, operates the second heat exchanger 220 as an evaporator, raises the temperature of the indoor air (RA) through the first heat exchanger 210, supplies the indoor air (SA), and transfers the outdoor air (OA) to the second heat exchanger After passing through the group 220, it is exhausted (EA) to the outdoors.

4, in the second heating cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the second heat exchanger 220 to turn the second heat exchanger 220 into a condenser. and operates the first heat exchanger 210 as an evaporator, raises the temperature of the indoor air (RA) through the second heat exchanger 220, supplies air (SA) to the room, and supplies outdoor air (OA) to the first heat exchanger After passing through 210, it is exhausted (EA) to the outdoors.

In addition, the first heating cycle and the second heating cycle in the continuous heating mode are alternately repeated according to a predetermined cycle or alternated according to the freezing state of the first heat exchanger 210 or the second heat exchanger 220 operating as an evaporator. It can be repeated callously. Here, the predetermined cycle may be set in various ways according to the external air temperature or the evaporation efficiency of the first heat exchanger 210 and the second heat exchanger 220 .

In this way, when the air conditioning system 101 is operated in the first heating cycle during heating operation in winter, the condensate generated in the second heat exchanger 220 operating as an evaporator is the second desiccant coated on the second coil 221. As moisture is absorbed by 225, the evaporation temperature of the refrigerant is increased. At this time, the condensed water absorbed by the second desiccant 225 due to the low external temperature may be frozen. On the other hand, condensate that is generated during the refrigerant evaporation period of the first heat exchanger 210 during the second heating cycle and is absorbed by the first desiccant 215 and then frozen is evaporated by condensation heat generated during the refrigerant condensation period of the first heating cycle. while lowering the condensation temperature of the refrigerant and supplied to the room.

For example, when the second heat exchanger 220 operating as an evaporator in the first heating cycle is dripped and the evaporation efficiency decreases, the second heating cycle is switched.

In addition, when the air conditioning system 101 is operated in the second heating cycle during heating operation in winter, the condensate generated in the first heat exchanger 210 operating as an evaporator is the first desiccant coated on the first coil 211 ( 215) increases the refrigerant evaporation temperature. At this time, the condensed water absorbed by the first desiccant 215 due to the low external temperature may be frozen. On the other hand, condensate that is generated during the refrigerant evaporation period of the second heat exchanger 220 during the first heating cycle and is absorbed by the second desiccant 225 and then frozen is evaporated by condensation heat generated during the refrigerant condensation period of the second heating cycle. while lowering the condensation temperature of the refrigerant and supplied to the room.

In addition, when the condensed water generated while melting the dripping phase of the first heat exchanger 210 or the second heat exchanger 220 exceeds the moisture absorption capacity of the first desiccant 215 or the second desiccant 225, the first heat exchanger ( 210) or from the second heat exchanger 220 and is collected in the first condensate collection fan 510 or the second condensate collection fan 520, since the first heating cycle and the second heating cycle are operated alternately, the first Condensate collected in the condensate collecting fan 510 or the second condensate collecting fan 520 can be minimized.

As described above, according to the first embodiment of the present invention, the air conditioning system 101 operates a continuous heating operation mode in which the first heating cycle and the second heating cycle are alternately operated, so that a separate defrosting operation is not required. heating can be achieved.

With this configuration, the air conditioning system 101 according to the first embodiment of the present invention enables continuous cooling and heating without interruption and can effectively improve energy use efficiency.

Specifically, the cooling efficiency may be maximized by maximally utilizing the latent heat of the condensate in the cooling operation mode.

In addition, in the conventional heat pump method, a separate defrosting operation was required to defrost the evaporator during heating, and during this defrosting operation, heating was not possible and rather cold air was introduced into the room, but the air conditioning according to the first embodiment of the present invention The system 101 may implement continuous heating without a separate defrosting operation through a continuous heating operation mode in which the first heating cycle and the second heating cycle are alternately operated.

In addition, by vaporizing the frost generated in the evaporator in another heating cycle, it is possible to obtain a non-water supply humidifying effect that does not require separate water supply at the same time as heating.

Hereinafter, an air conditioning system 102 according to a second embodiment of the present invention will be described with reference to FIGS. 5 to 8 .

5 to 8, the air conditioning system 102 according to the second embodiment of the present invention includes a first heat exchanger 210, a second heat exchanger 220, a refrigerant flow path 260, an expansion valve 270 , compressor 280 , and quadrilateral 240 .

In addition, the air conditioning system 102 according to the second embodiment of the present invention includes a first condensate collecting fan 510, a second condensate collecting fan 520, a first condensate spraying unit 410, a second condensate spraying unit ( 420), the first condensate supply line 610, the second condensate supply line 620, the third condensate supply line 630, the third condensate supply line 640, the first condensate pump 810, the second condensate water A pump 820, a first control valve 710, a second control valve 720, a third control valve 730, and a fourth control valve 740 may be further included.

The first heat exchanger 210 may perform heat exchange before supplying indoor air or heat exchange before exhausting outdoor air. That is, the first heat exchanger 210 may be a condenser or an evaporator according to the direction in which the refrigerant moves along the refrigerant flow path 260 to be described later.

The second heat exchanger 220 exchanges heat before exhausting outdoor air when the first heat exchanger 210 exchanges heat before supplying indoor air, and exchanges heat before exhausting outdoor air when the first heat exchanger 210 exchanges heat before exhausting outdoor air. Heat can be exchanged before supplying air. That is, the second heat exchanger 220 operates as an evaporator when the first heat exchanger 210 operates as a condenser according to the moving direction of the refrigerant moving along the refrigerant flow path 620 to be described later, and the first heat exchanger 210 ) can operate as a condenser if it operates as an evaporator.

As such, in the second embodiment of the present invention, one of the first heat exchanger 210 and the second heat exchanger 220 becomes an evaporator and the other becomes a condenser, and their roles may be repeatedly switched.

Meanwhile, although not shown, the first heat exchanger 210 and the second heat exchanger 220 may be connected to the air movement passage, respectively. In addition, according to the operation of the direction changing device for changing the direction of the air moving along the air movement passage, the indoor air (RA) passes through the first heat exchanger 210 and then supplies the indoor air (SA) again to the outdoor air ( OA) is exhausted (EA) to the outdoors again after passing through the second heat exchanger 220, or indoor air (RA) is supplied to the room again after passing through the second heat exchanger 220 (SA) and outdoor air (OA) ) After passing through the first heat exchanger 210, it may be exhausted (EA) to the outdoors again.

Further, according to the second embodiment of the present invention, the first heat exchanger 210 and the second heat exchanger 220 include coils 210 and 220 coated with desiccants 215 and 225, respectively. . That is, the first heat exchanger 220 includes the first coil 211 and the first desiccant 215 coated on the first coil 211, and the second heat exchanger 220 includes the second coil 221 and a second desiccant 225 coated on the second coil 221 .

In addition, the first desiccant 215 and the second desiccant 225 absorb moisture from the condensed water generated in the first heat exchanger 210 and the second heat exchanger 220, respectively, so that the first heat exchanger 210 or the second heat exchanger The refrigerant evaporation temperature of (220) is increased.

The refrigerant movement passage 260 may move the refrigerant between the first heat exchanger 210 and the second heat exchanger 220 .

The expansion valve 270 may be installed on the refrigerant flow path 260 . For example, the expansion valve 270 may be installed on the refrigerant flow path 260 between the first heat exchanger 210 and the second heat exchanger 220 . The expansion valve 270 is a device that reduces the high-temperature and high-pressure liquid refrigerant condensed and liquefied in the condenser to a pressure capable of causing evaporation by a throttling action, and is also called an expansion valve. In addition, the expansion valve 270 regulates and supplies an appropriate amount of refrigerant capable of absorbing sufficient heat in the evaporator.

The compressor 270 may be installed in the refrigerant movement passage 260 to compress the refrigerant. In addition, the compressor 270 may provide power for moving the refrigerant along the refrigerant movement passage 260 .

The four sides 240 may switch between suction and discharge paths of the compressor 270 . The four-way valve 240 is a valve used to switch between cooling and heating in the heat pump method, and is a valve used to change the moving direction of the refrigerant discharged from the compressor 270 . That is, according to the operation of the four sides 240, the refrigerant discharged from the compressor 280 first moves to the first heat exchanger 210, passes through the expansion valve 270 and the second heat exchanger 220, and then returns to the compressor 280. ) or the refrigerant discharged from the compressor 280 may first move to the second heat exchanger 220, pass through the expansion valve 270 and the first heat exchanger 210, and then return to the compressor 280.

The first condensate collecting fan 510 may collect the condensate that has fallen from the first heat exchanger 210 .

The second condensate collecting fan 520 may collect condensate that has fallen from the second heat exchanger 220 .

The first condensate injection unit 410 may inject condensate into the first heat exchanger 210 .

The second condensate injection unit 420 may inject condensate into the second heat exchanger 220 .

The first condensate supply line 610 may supply the condensate collected in the first condensate collection fan 510 to the first condensate injection unit 410 . For example, the first condensate supply line 610 may connect the first condensate collection fan 510 and the first condensate injection unit 410 .

The second condensate supply line 620 may supply the condensate collected in the first condensate collection fan 510 to the second condensate injection unit 420 . For example, the second condensate supply line 620 may be branched from the first condensate supply line 610 and connected to the second condensate injection unit 420 .

The third condensate supply line 630 may supply the condensate collected in the second condensate collection fan 520 to the first condensate injection unit 410 . For example, the third condensate supply line 630 may connect the second condensate collection fan 520 and the first condensate injection unit 410 .

The fourth condensate supply line 640 may supply the condensate collected in the second condensate collection fan 520 to the second condensate injection unit 420 . Specifically, the fourth condensate supply line 640 may be branched from the third condensate supply line 630 and connected to the second condensate injection unit 420 .

The first condensate pump 810 transfers the condensate collected in the first condensate collection fan 510 to the first condensate injection unit 410 or the first condensate supply line 610 or the second condensate supply line 620 2 It can be supplied to the condensate injection unit 420. For example, the first condensate pump 810 may be installed on the first condensate supply line 610 between the branch point and the first condensate collection fan 510 with the second condensate supply line 620 . That is, the first condensate pump 810 provides pressure so that the condensate collected in the first condensate collecting fan 510 moves to the first condensate injection unit 410 or the second condensate injection unit 420 and is sprayed. can do.

The second condensate pump 820 transfers the condensate collected in the second condensate collecting fan 520 to the first condensate spraying unit 410 or the third condensate supply line 630 or the fourth condensate supply line 640. 2 It can be supplied to the condensate injection unit 420. For example, the second condensate pump 820 may be installed on the third condensate supply line 630 between the branch point and the second condensate collection fan 520 with the fourth condensate supply line 640 . That is, the second condensate pump 820 provides pressure so that the condensate collected in the second condensate collecting fan 520 moves to the second condensate spray part 410 or the second condensate spray part 420 so that it can be sprayed. can do.

The first control valve 710 may be installed on the first condensate supply line 610 . For example, the first control valve 710 may be installed on the first condensate supply line 610 between the branch point and the first condensate injection unit 410 with the second condensate supply line 620 . The first control valve 710 may control whether or not to supply the collected condensate to the first condensate collection fan 510 through the first condensate injection unit 410 .

The second control valve 720 may be installed on the second condensate supply line 620 . The second control valve 720 may control whether the condensed water collected in the first condensate collection fan 510 is supplied to the second condensate injection unit 420 .

The third control valve 730 may be installed on the third condensate supply line 630 . For example, the third control valve 730 may be installed on the third condensate supply line 630 between the branch point and the first condensate injection unit 410 with the fourth condensate supply line 640 . The third control valve 730 may control whether the condensed water collected in the second condensate collecting fan 520 is supplied to the first condensate injection unit 410 .

The fourth control valve 740 may be installed on the fourth condensed water supply line 640 . The fourth control valve 740 may control whether or not to supply the collected condensate to the second condensate collection fan 510 through the second condensate injection unit 420 .

As described above, the air conditioning system 102 according to the second embodiment of the present invention may operate in one selected from among a continuous cooling operation mode and a continuous heating operation mode.

First, in the summer season, the air conditioning system 102 may operate in a continuous cooling operation mode. In the continuous cooling operation mode, the first cooling cycle and the second cooling cycle may be alternately and repeatedly operated.

Specifically, as shown in FIG. 5 , in the first cooling cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the first heat exchanger 210 so that the first heat exchanger 210 is operated as a condenser and the second heat exchanger 220 is operated as an evaporator, and after cooling the indoor air (RA) through the second heat exchanger 220, supplying (SA) indoor air and supplying outdoor air (OA) to the first After passing through the heat exchanger 210, it is exhausted (EA) to the outdoors.

In addition, when the air conditioning system 102 operates in the first cooling cycle of the continuous cooling operation mode, condensate generated in the second heat exchanger 220 operating as an evaporator and collected in the second condensate collection fan 520 is converted into third condensate water. It can be supplied to the first condensate injection unit 410 through the supply line 630. And some or all of the condensed water sprayed from the first condensate spraying unit 410 is absorbed by the first desiccant 215 coated on the first coil 211 of the first heat exchanger 210, and the first desiccant 215 ) The condensate exceeding the moisture absorption capacity falls and is collected in the first condensate collection fan 510. The condensed water absorbed by the first desiccant 215 increases the evaporation temperature of the refrigerant in the first heat exchanger 210 . That is, the condensed water absorbed by the first desiccant 215 evaporates with the condensation heat generated during the refrigerant condensation period of the first heating cycle and hot outdoor air heat, lowering the refrigerant condensation temperature and discharging it to the outdoors.

As such, when the condensed water evaporates in the first desiccant 215 of the first heat exchanger 210, the temperature of the first heat exchanger 210 operating as a condenser is greatly lowered, and cooling efficiency can be effectively improved.

In addition, after being sprayed from the first condensate injection unit 410, the condensate collected in the first condensate collection fan 510 by being dropped without being absorbed by the first desiccant 215 again through the first condensate supply line 610. It is supplied to the first condensate injection unit 410, and may be injected again from the first condensate injection unit 410 to the first heat exchanger 210. The condensed water sprayed from the first condensed water injection unit 410 supplements the condensed water evaporated from the first desiccant 215 .

To this end, in the first cooling cycle of the continuous cooling operation mode, the first condensate pump 810 and the second condensate pump 820 are operated. Also, the first control valve 710 and the third control valve 730 are opened, and the second control valve 720 and the fourth control valve 740 are closed. Thus, the condensate water collected in the first condensate collecting fan 510 discharged by the first condensate pump 810 is not directed to the second condensate spray unit 420 but is directed to the first condensate spray unit 410, and the second The condensate water collected in the second condensate collection fan 520 discharged by the condensate pump 820 is also directed to the first condensate spray unit 410 without being directed to the second condensate spray unit 420 . That is, all the condensate collected in the first condensate collection fan 510 and the second condensate collection fan 520 is directed toward the first heat exchanger 210 and absorbed into the first desiccant 215 of the first heat exchanger 210. It can be.

In addition, since condensed water is generated in the second heat exchanger 220 operating as an evaporator, moisture in the air supplied to the room (SA) via the second heat exchanger 220 is removed while the second heat exchanger 220 generates It can be used to lower the temperature of the first heat exchanger 210, which operates as a condenser, without wasting condensed water.

6, in the second cooling cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the second heat exchanger 220 to turn the second heat exchanger 220 into a condenser. and operates the first heat exchanger 210 as an evaporator, cools the indoor air (RA) through the first heat exchanger 210, supplies air (SA) to the room, and supplies outdoor air (OA) to the second heat exchanger After passing through 220, it is exhausted (EA) to the outdoors.

In addition, when the air conditioning system 102 operates in the second cooling cycle of the continuous cooling operation mode, condensate generated in the first heat exchanger 210 operating as an evaporator and collected in the first condensate collection fan 510 is converted into second condensate water. It can be supplied to the second condensate injection unit 420 through the supply line 620. In addition, some or all of the condensed water sprayed from the second condensate injection unit 420 is absorbed by the second desiccant 225 coated on the second coil 221 of the second heat exchanger 220, and the second desiccant 225 ) The condensed water exceeding the moisture absorption capacity falls and is collected in the second condensate collecting fan 520. The condensed water absorbed by the second desiccant 225 increases the evaporation temperature of the refrigerant in the second heat exchanger 220 . That is, the condensed water absorbed by the second desiccant 225 evaporates with condensation heat generated during the refrigerant condensation period of the first heating cycle and outdoor hot air heat to lower the refrigerant condensation temperature and is discharged outdoors.

As such, when the condensed water evaporates in the second desiccant 215 of the second heat exchanger 220, the temperature of the second heat exchanger 220 operating as a condenser is greatly lowered, and cooling efficiency can be effectively improved.

In addition, after being sprayed from the second condensate injection unit 420, the condensate collected in the second condensate collection fan 520 by being dropped without being absorbed by the first desiccant 225 is again passed through the fourth condensate supply line 640. It is supplied to the second condensate injection unit 420, and may be injected back to the first heat exchanger 220 from the second condensate injection unit 420. The condensed water sprayed from the second condensed water injection unit 420 supplements the condensed water evaporated from the second desiccant 225 .

To this end, in the second cooling cycle of the continuous cooling operation mode, the first condensate pump 810 and the second condensate pump 820 are operated. Also, the first control valve 710 and the third control valve 730 are closed and the second control valve 720 and the fourth control valve 740 are open. Thus, the condensate water collected in the first condensate collection fan 510 discharged by the first condensate pump 810 does not go to the first condensate spray part 410 and is directed to the second condensate spray part 420, and the second condensate water spray part 420 The condensate water collected in the second condensate collection fan 520 discharged by the condensate pump 820 is also directed to the second condensate spray unit 420 without being directed to the first condensate spray unit 410 . That is, all the condensate collected in the first condensate collection fan 510 and the second condensate collection fan 520 is directed toward the second heat exchanger 220 and absorbed into the second desiccant 225 of the second heat exchanger 220. It can be.

In addition, since condensed water is generated in the first heat exchanger 210 operating as an evaporator, moisture in the air supplied to the room (SA) via the first heat exchanger 210 is removed while the first heat exchanger 210 generates It can be used to lower the temperature of the second heat exchanger 220, which mostly operates as a condenser, without wasting condensed water.

In addition, the first cooling cycle and the second cooling cycle in the continuous cooling operation mode are alternately repeated according to a predetermined cycle or the first desiccant 215 coated on the first coil 211 of the first heat exchanger 210 And the moisture absorption state of the second desiccant 225 coated on the second coil 221 of the second heat exchanger 220 or the level of condensate stored in the first condensate collection fan 510 and the second condensate collection fan 520 can be repeated alternately. Here, the predetermined cycle may be set in various ways according to the amount of condensed water generated in the first coil 211 and the second coil 221 and the moisture absorption capacities of the first desiccant 215 and the second desiccant 225. For example, when the moisture absorption capacities of the first desiccant 215 and the second desiccant 225 are large, the cycle may be set to be very long.

As described above, the first heat exchanger 210 operating as an evaporator or the second heat exchanger 220 operating as a condenser using the condensed water generated in the second heat exchanger 220 or the first heat exchanger 210 By effectively lowering the condensation temperature of the air conditioner, it is possible to remove moisture from the indoor air and at the same time reduce the energy required for cooling. In particular, since latent energy can be recovered by nearly 100% in an indirect manner using condensation heat, energy can be greatly reduced.

In addition, in the second embodiment of the present invention, the condensed water can be circulated and utilized without being wasted by discharging it.

Also, in winter, the air conditioning system 102 may operate in a continuous heating operation mode. In the continuous heating operation mode, the first heating cycle and the second heating cycle may be alternately and repeatedly operated.

Specifically, as shown in FIG. 7 , in the first heating cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the first heat exchanger 210 to cool the first heat exchanger 210. Operates as a condenser, operates the second heat exchanger 220 as an evaporator, raises the temperature of the indoor air (RA) through the first heat exchanger 210, supplies the indoor air (SA), and transfers the outdoor air (OA) to the second heat exchanger After passing through the group 220, it is exhausted (EA) to the outdoors.

In addition, when the air conditioning system 102 operates in the first heating cycle of the continuous heating operation mode, the condensate collected in the first condensate collection fan 510 passes through the first condensate supply line 610 to the first condensate injection unit 410. ), and the condensate remaining in the second condensate collecting fan 520 may be supplied to the first condensate injection unit 410 through the third condensate supply line 630.

The first condensate injection unit 410 injects condensed water to the first heat exchanger 210 operating as a condenser in the first heating cycle, and is generated during the refrigerant evaporation period of the first heat exchanger 210 during the second heating cycle. The condensate that is absorbed by the first desiccant 215 and then frozen is melted by the condensation heat generated in the first heat exchanger 210 and the condensate water sprayed from the first condensate injection unit 410 during the refrigerant condensation period of the first heating cycle. The refrigerant condensation temperature of the first heat exchanger 210 is lowered while being vaporized or evaporated together with the condensed water, and supplied to the room together with the indoor air passing through the first heat exchanger 210 to humidify the indoor air.

In addition, the condensed water generated in the second heat exchanger 220 operating as an evaporator is absorbed by the second desiccant 225 coated on the second coil 221 to increase the evaporation temperature of the refrigerant. At this time, the condensed water absorbed by the second desiccant 225 due to the low external temperature may be frozen. As such, when the second heat exchanger 220 is dripped and the evaporation efficiency decreases, the second heating cycle may be switched.

In addition, in the first heating cycle of the continuous heating operation mode, the first condensate pump 810 and the second condensate pump 820 are operated. Also, the first control valve 710 and the third control valve 730 are opened, and the second control valve 720 and the fourth control valve 740 are closed. Thus, the condensate water collected in the first condensate collecting fan 510 discharged by the first condensate pump 810 is not directed to the second condensate spray unit 420 but is directed to the first condensate spray unit 410, and the second The condensate water collected in the second condensate collection fan 520 discharged by the condensate pump 820 is also directed to the first condensate spray unit 410 without being directed to the second condensate spray unit 420 . That is, all the condensate collected in the first condensate collecting fan 510 and the second condensed water collecting fan 520 is directed to the first heat exchanger 210 .

8, in the second heating cycle, the four sides 240 move the refrigerant discharged from the compressor 280 in the direction of the second heat exchanger 220 to turn the second heat exchanger 220 into a condenser. and operates the first heat exchanger 210 as an evaporator, raises the temperature of the indoor air (RA) through the second heat exchanger 220, supplies air (SA) to the room, and supplies outdoor air (OA) to the first heat exchanger After passing through 210, it is exhausted (EA) to the outdoors.

In addition, when the air conditioning system 102 operates in the second heating cycle of the continuous heating operation mode, the condensate collected in the second condensate collection fan 520 passes through the fourth condensate supply line 640 to the second condensate injection unit 420. ), and the condensate remaining in the first condensate collecting fan 510 may be supplied to the second condensate injection unit 420 through the second condensate supply line 620.

The second condensed water injection unit 420 injects condensed water into the second heat exchanger 220 operating as a condenser in the second heating cycle, and is generated during the refrigerant evaporation period of the second heat exchanger 220 during the first heating cycle. The condensate that is absorbed by the second desiccant 225 and then frozen is melted by the condensation heat generated in the second heat exchanger 220 and the condensate water sprayed from the second condensate injection unit 420 during the refrigerant condensation period of the second heating cycle. The refrigerant condensation temperature of the second heat exchanger 220 is lowered while being vaporized or evaporated together with the condensed water, and supplied to the room together with the indoor air passing through the second heat exchanger 220 to humidify the indoor air.

In addition, the condensed water generated in the first heat exchanger 210 operating as an evaporator is absorbed by the first desiccant 215 coated on the first coil 211 to increase the evaporation temperature of the refrigerant. At this time, the condensed water absorbed by the first desiccant 215 due to the low external temperature may be frozen. In this way, when the evaporation efficiency decreases while the first heat exchanger 210 is dripped, it may be changed to the first heating cycle.

In addition, in the second heating cycle of the continuous heating operation mode, the first condensate pump 810 and the second condensate pump 820 are operated. Also, the first control valve 710 and the third control valve 730 are closed and the second control valve 720 and the fourth control valve 740 are open. Thus, the condensate water collected in the first condensate collection fan 510 discharged by the first condensate pump 810 is not directed to the first condensate spray unit 410 but is directed to the second condensate spray unit 420, and the second The condensate water collected in the second condensate collection fan 520 discharged by the condensate pump 820 is also directed to the second condensate spray unit 420 without being directed to the first condensate spray unit 410 . That is, all the condensate collected in the first condensate collecting fan 510 and the second condensed water collecting fan 520 is directed to the second heat exchanger 220 .

In addition, the first heating cycle and the second heating cycle in the continuous heating mode are alternately repeated according to a predetermined cycle or according to the freezing state of the first heat exchanger 210 or the second heat exchanger 220 operating as an evaporator. Can be repeated alternately. Here, the predetermined cycle may be set in various ways according to the external air temperature or the evaporation efficiency of the first heat exchanger 210 and the second heat exchanger 220 . For example, when the second heat exchanger 220 operating as an evaporator in the first heating cycle is dripped and the evaporation efficiency decreases, the second cooling cycle is switched.

With this configuration, the air conditioning system 102 according to the second embodiment of the present invention enables continuous cooling and heating without interruption and can effectively improve energy use efficiency.

Specifically, the cooling efficiency may be maximized by maximally utilizing the latent heat of the condensate in the cooling operation mode.

In addition, in the conventional heat pump method, a separate defrosting operation was required to defrost the evaporator during heating, and during this defrosting operation, heating was not possible and rather cold air was introduced into the room, but the air conditioning according to the second embodiment of the present invention The system 102 may implement continuous heating without a separate defrosting operation through a continuous heating operation mode in which the first heating cycle and the second heating cycle are alternately operated.

In addition, by vaporizing the frost generated in the evaporator in another heating cycle, it is possible to obtain a non-water supply humidifying effect that does not require separate water supply at the same time as heating.

In addition, condensed water that has not been vaporized can be vaporized in the condenser while being repeatedly recycled without being wasted. That is, the condensed water can be repeatedly recycled until it is vaporized.

Hereinafter, an air conditioning system 103 according to a third embodiment of the present invention will be described with reference to FIG. 9 .

As shown in FIG. 9 , in the air conditioning system 102 according to the third embodiment of the present invention, the first condensate injection units 411 and 412 direct the condensate in the form of mist toward one side of the first heat exchanger 210 . One or more are provided to spray, and one or more second condensate injection units 421 and 422 may be provided to spray condensate in the form of mist toward one side of the second heat exchanger 220 . Here, one surface of the first heat exchanger 210 and the second heat exchanger 220 refers to one surface in contact with indoor air (RA) or outdoor air (OA), respectively.

In addition, when a plurality of first condensate spraying parts 411 and 412 and second condensing water spraying parts 421 and 422 are provided, the condensed water is evenly sprayed on one surface of the first heat exchanger 210 and the second heat exchanger 220. can be placed to do so.

Meanwhile, the operating principle of the air conditioning system 103 according to the third embodiment of the present invention is the same as that of the second embodiment. That is, the third embodiment is the same as the second embodiment except for the installation positions and spray shapes of the first condensate spraying units 411 and 412 and the second condensing water spraying units 421 and 422 .

9 exemplarily shows a case where the air conditioning system 103 operates in the second heating cycle of the continuous heating mode, but the air conditioning system 103 according to the third embodiment of the present invention also performs the first cooling in the continuous cooling mode. The cycle and the second cooling cycle may alternately and repeatedly operate, and in the continuous heating mode, the first heating cycle and the second heating cycle may alternately and repeatedly operate.

With this configuration, the air conditioning system 103 according to the third embodiment of the present invention also enables continuous cooling and heating without interruption and can effectively improve energy use efficiency.

In particular, since the condensed water does not collect on the upper part of the first heat exchanger 210 and the second heat exchanger 220, it is possible to suppress the propagation of bacteria and implement a more hygienic air conditioning system 103.

In addition, since the one or more first condensate spraying parts 411 and 412 and the second condensing water spraying parts 421 and 422 spray and spread condensate in the form of mist, the first heat exchanger 210 and the second heat exchanger 220 and The contact surface of the sprayed condensed water is increased so that the evaporation effect can be further improved.

Although the embodiments of the present invention have been described 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, the embodiments described above should be understood as illustrative in all respects and not limiting, and the scope of the present invention is indicated by the following detailed description of the claims, the meaning and scope of the claims, and All changes or modified forms derived from the equivalent concept should be construed as being included in the scope of the present invention.

101, 102, 103: air conditioning system
210: first heat exchanger
211: first coil
215: first desiccant
220: second heat exchanger
221: second coil
225: second desiccant
240: quadrilateral
260: refrigerant flow path
270: expansion valve
280: compressor
410, 411, 412: first condensate injection unit
420, 421, 422: second condensate injection unit
510: first condensate collection fan
520: second condensate collection fan
610: first condensate supply line
620: second condensate supply line
630: third condensate supply line
640: fourth condensate supply line
690: drain pipe
710: first control valve
720: second control valve
730: third control valve
740: fourth control valve
791: first drain valve
792: second drain valve
810: first condensate pump
820: second condensate pump

Claims (14)

a first heat exchanger that exchanges heat before supplying indoor air or exchanging heat before exhausting outdoor air, and includes a coil coated with a desiccant;
When the first heat exchanger exchanges heat before supplying indoor air, it exchanges heat before exhausting outdoor air, and when the first heat exchanger exchanges heat before exhausting outdoor air, it exchanges heat before supplying indoor air, and a desiccant is coated. A second heat exchanger including a coil;
a refrigerant flow passage for moving refrigerant between the first heat exchanger and the second heat exchanger;
an expansion valve installed in the refrigerant flow passage;
a compressor installed in the refrigerant flow path to compress the refrigerant;
a four-way valve that converts a suction and discharge path of the compressor;
a first condensate collecting fan for collecting the condensed water that has fallen from the first heat exchanger;
a second condensate collecting fan for collecting the condensed water that has fallen from the second heat exchanger;
a first condensate injection unit for injecting condensate into the first heat exchanger;
a second condensate injection unit for injecting condensate into the second heat exchanger;
A first condensate supply line for supplying the condensate collected in the first condensate collecting fan to the first condensate injection unit;
a second condensate supply line supplying the condensate collected in the first condensate collecting fan to the second condensate spraying unit;
a third condensate supply line supplying the condensate collected in the second condensate collecting fan to the first condensate spraying unit;
a fourth condensate supply line supplying the condensate collected in the second condensate collecting fan to the second condensate spraying unit;
A first condensate pump for supplying the condensate collected in the first condensate collecting fan to the first condensate injection unit or the second condensate injection unit through the first condensate supply line or the second condensate supply line;
A second condensate pump for supplying the condensate collected in the second condensate collecting fan to the first condensate spraying unit or the second condensing water spraying unit through the third condensate supply line or the fourth condensate supply line;
a first control valve installed on the first condensed water supply line;
a second control valve installed on the second condensate supply line;
a third control valve installed on the third condensate supply line; and
A fourth control valve installed on the fourth condensate supply line
Air conditioning system comprising a. According to claim 1,
In the winter season, the air conditioning system
The four sides move the refrigerant discharged from the compressor in the direction of the first heat exchanger to operate the first heat exchanger as a condenser and operate the second heat exchanger as an evaporator to raise the temperature of indoor air through the first heat exchanger, and then to a first heating cycle in which air is supplied to the air and outdoor air is exhausted to the outdoors after passing through the second heat exchanger;
The four sides move the refrigerant discharged from the compressor in the direction of the second heat exchanger to operate the second heat exchanger as a condenser and operate the first heat exchanger as an evaporator to raise the temperature of indoor air through the second heat exchanger, and then to A second heating cycle in which air is supplied to the air and outdoor air is exhausted to the outdoors after passing through the first heat exchanger
An air conditioning system that operates in a continuous heating operation mode in which the According to claim 2,
The first heating cycle and the second heating cycle in the continuous heating operation mode are alternately repeated according to a predetermined cycle or alternately according to the freezing state of the first heat exchanger or the second heat exchanger operating as an evaporator. repeated air conditioning system. According to claim 2,
When operating in the first heating cycle, the condensed water generated in the coil of the second heat exchanger operating as an evaporator absorbs moisture into the desiccant of the second heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant during the second heating cycle. After being absorbed by the desiccant of the machine, the frozen condensate evaporates with the condensation heat of the first heat exchanger to lower the refrigerant condensation temperature and is supplied to the room to humidify the room,
When operating in the second heating cycle, condensed water generated in the coil of the first heat exchanger operating as an evaporator absorbs moisture into the desiccant of the first heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant during the first heating cycle. The air conditioning system of claim 1 , wherein the frozen condensate after being absorbed by the desiccant of the machine vaporizes and evaporates with the condensation heat of the second heat exchanger to lower the refrigerant condensation temperature and is supplied to the room to humidify the room. According to claim 1,
The air conditioning system in the summer season,
The four sides move the refrigerant discharged from the compressor in the direction of the first heat exchanger to operate the first heat exchanger as a condenser and operate the second heat exchanger as an evaporator to cool indoor air through the second heat exchanger. a first cooling cycle in which air is supplied to the air and outdoor air is exhausted to the outdoors after passing through the first heat exchanger;
The four sides move the refrigerant discharged from the compressor in the direction of the second heat exchanger to operate the second heat exchanger as a condenser and operate the first heat exchanger as an evaporator to cool indoor air through the first heat exchanger. A second cooling cycle in which air is supplied to the air and outdoor air is exhausted to the outdoors after passing through the second heat exchanger.
An air conditioning system that operates in a continuous cooling operation mode that alternately and repeatedly operates. According to claim 5,
The first cooling cycle and the second cooling cycle in the continuous cooling operation mode are alternately repeated according to a predetermined cycle, or the desiccant coated on the coil of the first heat exchanger and the coil of the second heat exchanger An air conditioning system that is alternately repeated according to the moisture absorption state of the desiccant. According to claim 5,
When operating in the first cooling cycle, the condensed water generated in the coil of the second heat exchanger, which operates as an evaporator, absorbs moisture into the desiccant of the second heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant in the first heat exchanger during the second cooling cycle. The condensed water absorbed by the desiccant of the group is evaporated with the condensation heat of the first heat exchanger and the heat of outdoor hot air, lowering the condensation temperature of the refrigerant and discharged to the outdoors,
When operating in the second cooling cycle, condensed water generated in the coil of the first heat exchanger operating as an evaporator absorbs moisture into the desiccant of the first heat exchanger to increase the evaporation temperature of the refrigerant, and increases the evaporation temperature of the refrigerant during the first cooling cycle. The condensed water absorbed by the desiccant of the air conditioner is evaporated with the condensation heat of the second heat exchanger and the heat of outdoor hot air to lower the condensation temperature of the refrigerant and discharged to the outdoors. According to claim 1,
a drain pipe discharging the condensate collected in the first condensate collection fan and the second condensate collection fan;
a first drain valve installed in the drain pipe to discharge the condensate collected in the first condensate collection fan; and
A second drain valve installed in the drain pipe to discharge the condensate collected in the second condensate collection fan
Air conditioning system further comprising a. delete According to claim 1,
At least one first condensate injection unit is provided to spray condensate in the form of mist toward one surface of the first heat exchanger that is in contact with indoor air or outdoor air,
The air conditioning system, wherein one or more second condensate injection units are provided to spray condensate in the form of mist toward one surface of the second heat exchanger that contacts indoor air or outdoor air. a first heat exchanger that exchanges heat before supplying indoor air or exchanging heat before exhausting outdoor air, and includes a coil coated with a desiccant;
When the first heat exchanger exchanges heat before supplying indoor air, it exchanges heat before exhausting outdoor air, and when the first heat exchanger exchanges heat before exhausting outdoor air, it exchanges heat before supplying indoor air, and a desiccant is coated. A second heat exchanger including a coil;
a refrigerant flow passage for moving refrigerant between the first heat exchanger and the second heat exchanger;
an expansion valve installed in the refrigerant flow path;
a compressor installed in the refrigerant flow path to compress the refrigerant;
a four-way valve that converts a suction and discharge path of the compressor;
a first condensate collecting fan for collecting the condensed water that has fallen from the first heat exchanger;
a second condensate collecting fan for collecting the condensed water that has fallen from the second heat exchanger;
a first condensate injection unit for injecting condensate into the first heat exchanger;
a second condensate injection unit for injecting condensate into the second heat exchanger;
A first condensate supply line for supplying the condensate collected in the first condensate collecting fan to the first condensate injection unit;
a second condensate supply line supplying the condensate collected in the first condensate collecting fan to the second condensate spraying unit;
a third condensate supply line supplying the condensate collected in the second condensate collecting fan to the first condensate spraying unit; and
a fourth condensate supply line supplying the condensate collected in the second condensate collecting fan to the second condensate spraying unit;
Including,
In winter, the four sides move the refrigerant discharged from the compressor in the direction of the first heat exchanger to operate the first heat exchanger as a condenser and operate the second heat exchanger as an evaporator, raising indoor air through the first heat exchanger. A first heating cycle in which air is supplied indoors and outdoor air is exhausted to the outdoors after passing through a second heat exchanger, and the four sides move the refrigerant discharged from the compressor toward the second heat exchanger so that the second heat exchanger is a condenser and operating the first heat exchanger as an evaporator, increasing the temperature of indoor air through the second heat exchanger, supplying air to the room and exhausting outdoor air to the outdoors after passing through the first heat exchanger. It operates in a continuous heating operation mode that operates repeatedly,
When operating in the first heating cycle of the continuous heating operation mode,
The condensate collected in the first condensate collection fan is supplied to the first condensate injection unit through the first condensate supply line, and the condensate remaining in the second condensate collection fan is supplied to the first condensate supply line through the third condensate supply line. 1 Condensate is supplied to the injection part,
The first condensate injection unit injects condensate into the first heat exchanger operating as a condenser in the first heating cycle,
During the second heating cycle, the condensate that has been absorbed by the desiccant of the first heat exchanger and then frozen is melted by the condensation heat of the first heat exchanger and the condensate sprayed from the first condensate injection unit, or vaporized and evaporated together with the condensate. supplied to the room together with the indoor air passing through the first heat exchanger to humidify the indoor air;
When operating in the second heating cycle of the continuous heating operation mode,
The condensate collected in the second condensate collection fan is supplied to the second condensate spraying unit through the fourth condensate supply line, and the condensate remaining in the first condensate collection fan is supplied to the second condensate supply line through the second condensate supply line. 2 Condensate is supplied to the injection part,
The second condensate injection unit injects condensate into the second heat exchanger operating as a condenser in the second heating cycle,
The condensate that has been absorbed by the desiccant of the second heat exchanger during the first heating cycle and then frozen is melted by the condensation heat of the second heat exchanger and the condensate sprayed from the second condensate injection unit, or vaporized and evaporated together with the condensate. An air conditioning system that humidifies the indoor air by supplying indoor air together with the indoor air passing through the second heat exchanger. According to claim 11,
In the first heating cycle, the condensate that is not evaporated after being sprayed from the first condensate injection unit is collected in the first condensate collection fan and then supplied to the first condensate injection unit again through the first condensate supply line,
In the second heating cycle, the condensate that is not evaporated after being sprayed from the second condensate sprayer is collected in the second condensate collection fan and then supplied to the second condensate sprayer again through the fourth condensate supply line. . a first heat exchanger that exchanges heat before supplying indoor air or exchanging heat before exhausting outdoor air, and includes a coil coated with a desiccant;
When the first heat exchanger exchanges heat before supplying indoor air, it exchanges heat before exhausting outdoor air, and when the first heat exchanger exchanges heat before exhausting outdoor air, it exchanges heat before supplying indoor air, and a desiccant is coated. A second heat exchanger including a coil;
a refrigerant flow passage for moving refrigerant between the first heat exchanger and the second heat exchanger;
an expansion valve installed in the refrigerant flow passage;
a compressor installed in the refrigerant flow path to compress the refrigerant;
a four-way valve that converts a suction and discharge path of the compressor;
a first condensate collecting fan for collecting the condensed water that has fallen from the first heat exchanger;
a second condensate collecting fan for collecting the condensed water that has fallen from the second heat exchanger;
a first condensate injection unit for injecting condensate into the first heat exchanger;
a second condensate injection unit for injecting condensate into the second heat exchanger;
A first condensate supply line for supplying the condensate collected in the first condensate collecting fan to the first condensate injection unit;
a second condensate supply line supplying the condensate collected in the first condensate collecting fan to the second condensate spraying unit;
a third condensate supply line supplying the condensate collected in the second condensate collecting fan to the first condensate spraying unit; and
a fourth condensate supply line supplying the condensate collected in the second condensate collecting fan to the second condensate spraying unit;
Including,
In summer, the four sides move the refrigerant discharged from the compressor in the direction of the first heat exchanger to operate the first heat exchanger as a condenser and operate the second heat exchanger as an evaporator to cool indoor air through the second heat exchanger. A first cooling cycle in which air is supplied indoors and outdoor air is exhausted to the outdoors after passing through the first heat exchanger, and the four sides move the refrigerant discharged from the compressor in the direction of the second heat exchanger so that the second heat exchanger A second cooling cycle alternately operates as a condenser, operates the first heat exchanger as an evaporator, cools indoor air through the first heat exchanger, supplies air to the room, and exhausts outdoor air to the outdoors after passing through the second heat exchanger. It operates in a continuous cooling operation mode that repeatedly operates as
When operating in the first cooling cycle of the continuous cooling operation mode,
The condensate collected in the first condensate collection fan is supplied to the first condensate injection unit through the first condensate supply line, and the condensate collected in the second condensate collection fan is supplied to the first condensate supply line through the third condensate supply line. 1 Condensate is supplied to the injection part,
Some or all of the condensed water sprayed from the first condensate injection unit is absorbed by the desiccant coated on the coil of the first heat exchanger and evaporated by the condensation heat of the refrigerant and the thermal energy of outdoor air in the first heat exchanger operating as a condenser. and is discharged to the outdoors together with outdoor air passing through the first heat exchanger,
When operating in the second cooling cycle of the continuous cooling operation mode,
The condensate collected in the second condensate collecting fan is supplied to the second condensate spraying unit through the fourth condensate supply line, and the condensate collected in the first condensate collection fan is supplied to the second condensate supply line through the second condensate supply line. 1 Condensate is supplied to the injection part,
Some or all of the condensed water sprayed from the second condensate injection part is absorbed by the desiccant coated on the coil of the second heat exchanger and evaporated by the condensation heat of the refrigerant and the thermal energy of outdoor air in the second heat exchanger operating as a condenser. and is discharged to the outdoors together with the outdoor air passing through the second heat exchanger. According to claim 13,
In the first cooling cycle, the condensate that is not evaporated after being sprayed from the first condensate spray part is collected in the first condensate collection fan and then supplied to the first condensate spray part again through the first condensate supply line,
In the second cooling cycle, the condensate that has not been evaporated after being sprayed from the second condensate spray part is collected in the second condensate collection fan and then supplied to the second condensate spray part again through the fourth condensate supply line. .

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