KR20100011144A - Ventilating system having heat pump - Google Patents

Abstract

The present invention provides a case having a plurality of passages for circulating indoor air and outdoor air, an electrothermal heat exchanger for exchanging indoor air and outdoor air installed inside the case, a heat pump system installed in the case to perform cooling and heating, It is connected to the case and consists of multi-pipes to allow outdoor air to flow selectively from the south and north of the building according to the summer and winter seasons.The multi-intake air inlet is installed on the south side and the north side, respectively. Alternatively, it provides a ventilation device having a heat pump that can maximize the energy utilization efficiency.

Description

Ventilation system with heat pump {VENTILATING SYSTEM HAVING HEAT PUMP}

The present invention relates to a ventilator provided with a heat pump which is installed in the ventilator for circulating indoor air and outdoor air to heat and cool the room to improve waste heat recovery performance and maximize heat energy efficiency.

1 is a block diagram of a ventilation apparatus having a total heat exchanger according to the prior art.

Ventilation apparatus according to the prior art is provided with an air supply duct 110 to guide the outdoor air to the interior of the case 100, the exhaust duct to cross the air supply duct 110 at a predetermined position and the indoor air is guided to the outdoor. 120 is provided. In addition, an electric heat exchanger 130 in which the outdoor air that is supplied at the point where the air supply duct 110 and the exhaust duct 120 intersect and the indoor air that is exhausted is heat-exchanged is installed.

An air inlet 112 is formed at one end of the air supply duct 110 and an air inlet 114 is formed at the other end to communicate with the room, and an exhaust air inlet communicated with the room at one end of the exhaust duct 120. An exhaust outlet 124 is formed at the other end and communicated with the outside at the other end.

At this time, the air supply duct 110 and the exhaust duct 120 are not interfering with each other while crossing each other in the inner space of the case 100 around the heat exchanger (130). An air supply fan 116 is provided on the air supply outlet 114 side of the air supply duct 110 to forcibly suck the outdoor air, and an exhaust fan 126 is provided on the exhaust outlet 124 side to forcibly discharge the indoor air to the outside. In addition, an air purification filter 140 is provided between the air supply inlet 112 and the heat exchanger 130 to remove various foreign matters contained in outdoor air.

The operation of the ventilation apparatus according to the prior art configured as described above will be described below.

First, when power is applied to the exhaust fan 126 when the indoor air is somewhat contaminated, the indoor air flows into the exhaust duct 120 through the exhaust inlet 122, and then passes through the heat exchanger and exhaust exhaust 124. It is discharged to the outdoors through.

At the same time, while supplying power to the air supply fan 116, the fresh outdoor air flows into the air supply duct 110 through the air supply inlet 112, and then passes through the heat exchanger 130, through the air supply outlet 114. It enters the room.

At this time, the indoor air and the outdoor air passing through the heat exchanger 130 are heat exchanged through the heat exchange membrane. In detail, this process, the heat exchange occurs in the heat exchanger 130 is sensible heat exchange occurs between the air supply and the outdoor air discharged, the hot air of the indoor air or outdoor air dew point temperature (dew point temp.) It becomes the latent heat exchange by the condensate produced | generated while being in the following states.

Since the ventilation device according to the related art, which is configured only for heat exchange between indoor air and outdoor air by an electric heat exchanger, the energy recovery rate is about 40% when cooling and about 60% when heating, resulting in a large amount of energy loss. There is a problem.

In addition, when a separate air-conditioning device is installed in the room, there is a problem that the cost is increased because the air-conditioning device and the ventilation device is installed separately.

An object of the present invention is to provide a ventilation device having a heat pump that can maximize the energy recovery efficiency by integrally equipped with a heat pump for cooling and cooling the room to the ventilation device for circulating the indoor air and outdoor air.

Another object of the present invention is to provide a ventilation device having a heat pump that can maximize the energy use efficiency by installing the multi-air intake inlet on the south side and the north side, respectively, different positions of the air intake in the winter and summer.

Another object of the present invention is to provide a ventilation device having a heat pump that can further improve energy efficiency by allowing only indoor air to be circulated after ventilation of indoor air.

Ventilation apparatus according to an embodiment of the present invention is a case having a plurality of passages for circulating the indoor air and outdoor air, an electric heat exchanger for heat-exchanging the indoor air and outdoor air installed inside the case, is installed inside the case It includes a heat pump system for performing air conditioning and heating, and a multi-pipe connected to the case to allow outdoor air to selectively flow in the south and north of the building according to the summer and winter.

The heat pump system includes a first heat exchanger installed in an air supply duct through which the outdoor air of the case passes and heat exchanged with the outdoor air, a second heat exchanger installed in an exhaust duct through which the indoor air of the case passes through, and heat exchanged with the indoor air, and a low temperature and low pressure. A compressor for compressing the gaseous refrigerant into a gaseous state of high temperature and high pressure gas, and a four-way valve for switching the flow of the refrigerant in accordance with the mode of cooling operation and heating operation.

The multi-pipe is connected to the air intake port for intake of outdoor air and installed in the north direction of the building, the south intake port connected to the air intake port and installed in the south direction of the building, and one of the north intake port and the south intake port. And a damper for selectively communicating between the air supply inlets.

The damper is characterized by comprising a valve plate for selectively opening any one of the north side suction port and the south side suction port, and a damper motor for operating the valve plate.

Ventilation apparatus according to a second embodiment of the present invention is a case having a plurality of passages for circulating the indoor air and outdoor air, an electrothermal heat exchanger installed in the case, a heat pump system installed in the case to perform cooling and heating; It is installed on one side of the case, and when the indoor ventilation is completed includes an indoor air circulation device for performing the cooling and heating by circulating only the indoor air.

The indoor air circulation system includes a connection pipe connected to communicate between an air intake port through which outdoor air is sucked and an exhaust outlet through which indoor air is discharged, a first damper installed at the air supply inlet to open and close the air supply inlet, and a connection to the connection pipe. And a second damper provided to open and close the connection pipe, and a third damper provided to the exhaust outlet to open and close the exhaust outlet.

Ventilation apparatus according to a third embodiment of the present invention includes a case having a plurality of passages for circulating the indoor air and outdoor air, an electrothermal exchanger installed inside the case, a heat pump system installed in the case to perform cooling and heating; Connected to the case, the multi-pipe allows the outdoor air to be selectively introduced from the north and south of the building according to the summer and winter, and the indoor air that is installed on one side of the case to perform cooling and heating when only indoor air is circulated. Circulator.

According to the above configuration, the ventilation device of the present invention has an advantage of maximizing energy recovery efficiency by integrally providing a heat pump for cooling and cooling the room in a ventilation device for circulating indoor air and outdoor air.

In addition, the north side suction port is installed in the north direction of the building, and the south side suction port is installed in the south direction of the building. There is an advantage that can maximize the energy exchange efficiency when cooling by maximizing the temperature difference.

In addition, the indoor air circulation device is provided when the ventilation of the indoor air is completed, there is an advantage to further improve the energy efficiency by allowing only the indoor air to be cooled and heated.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram of a ventilation device having a heat pump according to an embodiment of the present invention.

Ventilation device according to the present invention is the case 10, the heat exchanger 20 for heat-exchanging the indoor air and the outdoor air installed in the case 10, and the inside of the case 10 to perform indoor cooling and heating Installed on the north side and south side of the heat pump system 30 and the building in which the ventilator is installed, respectively, one of the north side intake port 42 and the south side intake port 44 is selected to allow outdoor air to flow in during the winter and summer seasons. The multi piping 40 is included.

Ventilation device of the present invention can be applied to the ceiling-mounted type installed on the ceiling, the wall-mounted type installed on the wall, the floor-mounted type installed on the floor.

Inside the case 10, an air supply duct 50 for guiding the outdoor air to the interior and an exhaust duct 60 for interposing the air supply duct 50 at a predetermined position and the indoor air to be guided to the outdoor are installed. The total heat exchanger 20 is installed at the point where the air supply duct 50 and the exhaust duct 60 cross each other.

One end of the air supply duct 50 is provided with an air supply inlet port 52 communicating with the outside to suck the outdoor air, and the other end is provided with an air supply outlet 54 communicating with the room to supply the outdoor air to the room. One end of the exhaust duct 60 is provided with an exhaust inlet 62 which communicates with the room and sucks the indoor air, and the other end has an exhaust outlet 64 that communicates with the outside and discharges the indoor air to the outside.

An air supply fan 56 for forcibly sucking outdoor air is installed at the air supply duct 50 of the air supply duct 50, and an exhaust fan 66 for forcibly discharging indoor air is installed at the exhaust outlet 64.

One side of the air supply suction port 52 and the heat exchanger 20 or the air supply duct 50 into which the outdoor air is sucked is provided with an air purification filter 70 for removing various foreign substances contained in the outdoor air. The air purification filter 70 may include a pre-filter 72 to remove foreign substances, an electrostatic filter 74 to remove dust and the like using static electricity, a deodorization filter 76 to remove odors, and the like. .

The heat exchanger (20) is provided so that the air supply passage through which the outdoor air passes and the exhaust passage through which the indoor air passes through each other intersect with each other to exchange heat between the outdoor air and the indoor air. Specifically, the heat exchange occurring in the total heat exchanger 20 is a sensible heat exchange between the outdoor air to be supplied and the indoor air to be exhausted, and the high temperature air in the indoor air or the outdoor air is below the dew point temp. And latent heat exchange by condensate produced.

3 is a block diagram of a heat pump system according to an embodiment of the present invention.

The heat pump system is installed in the air supply duct 50 to exchange heat with the outdoor air sucked through the air supply duct 50, and the indoor air discharged through the air exhaust duct installed in the exhaust duct 60. A second heat exchanger 82 which exchanges heat with air, a compressor 84 which compresses a refrigerant in a low-temperature low-pressure gas state into a refrigerant in a high-temperature high-pressure gas state, and switches the flow of the refrigerant in accordance with a cooling operation and a heating operation mode. Four-way valve 86 and expansion valve 88 and the like.

The first heat exchanger 80 may be installed on either side of both sides of the total heat exchanger 20 through which the outdoor air passes. That is, the outdoor air may be installed on one side of the total heat exchanger 20, which is a position after passing through the total heat exchanger 20, and the outdoor air of the total heat exchanger 20, which is a position before the outdoor air passes through the heat exchanger 20, may be installed. Can be installed on the other side. The first heat exchanger 80 may recover the heat energy of the outdoor air introduced into the room to the secondary, thereby maximizing the heat exchange efficiency.

The first heat exchanger 80 serves as an evaporator for evaporating the refrigerant in a low temperature low pressure liquid state into a gas state in a cooling operation mode, and condensers condensing the refrigerant in a high temperature high pressure gas state into a normal temperature high pressure liquid state in a heating operation mode. It acts as a heat exchanger with the outdoor air in response to the enthalpy change of the refrigerant.

The second heat exchanger 82 may be installed on either side of both sides of the total heat exchanger 20 through which the indoor air passes. That is, the indoor air may be installed on one side of the total heat exchanger which is a position before passing through the total heat exchanger 20, and may be installed on the other side of the total heat exchanger which is the position after the indoor air passes through the total heat exchanger. The second heat exchanger 82 may recover the heat energy of the indoor air discharged to the outside to the secondary, thereby maximizing the heat exchange efficiency. The second heat exchanger 82 serves as a condenser during the cooling operation and as an evaporator during the heating operation, thereby exchanging heat with the indoor air discharged to the outside.

The compressor 84 is installed inside the case 10 and serves to compress and discharge the refrigerant in a low temperature and low pressure gas state into a high temperature and high pressure gas state.

The four-way valve 86 is connected to the discharge port 84a and the suction port 84b of the compressor 84, and is connected to the first heat exchanger 80 and the second heat exchanger 82, respectively, in the cooling operation and the heating operation mode. The refrigerant flow path is changed so that the flow of the refrigerant changes.

The expansion valve 88 is connected between the first heat exchanger 80 and the second heat exchanger 82 to convert the room temperature high pressure liquid refrigerant flowing from one of the two heat exchangers 80 and 82 into a low temperature low pressure liquid state. It serves to decompress.

The multi-pipe 40 is connected to the air supply inlet 52 and installed on the north side wall of the building, the north side intake port 42 through which the outdoor air in the north direction is sucked, and connected to the air supply inlet port 52, and installed on the south wall side of the building. And a damper 46 for selectively communicating between the south suction port 44 through which the outdoor air in the south direction is sucked, and one of the north suction port 42 and the south suction port 44, and the air supply suction port 52.

North side suction port 42 is installed in the north direction of the building is in communication with the air supply intake port 52 during winter to maximize the temperature difference between the indoor and outdoor air to maximize the energy exchange efficiency when performing cooling.

The south inlet 44 is installed in the south direction of the building to communicate with the air supply inlet 52 during the summer to maximize the temperature difference between the indoor and outdoor air to maximize the energy exchange efficiency when performing heating. do.

The damper 46 is rotatably installed on the air supply passage 48 to selectively switch the air supply passage 48 and to operate the valve plate 46a according to an electric signal applied from a user. It is comprised by the damper motor 46b.

The operation of the ventilation device according to an embodiment of the present invention configured as described above will be described below.

First, when indoor air is contaminated to some extent, power is applied to the exhaust fan 66 and the air supply fan 56. Then, the indoor air flows into the exhaust duct 60 through the exhaust inlet 62, and then passes through the total heat exchanger 20 and is discharged to the outside through the exhaust outlet 64. At the same time, fresh outdoor air flows into the air supply duct 50 through the air supply inlet port 52, passes through the total heat exchanger 20, and enters the room through the air supply outlet 54.

At this time, the primary heat exchange is performed between the indoor air and the outdoor air passing through the total heat exchanger (20). Then, the second heat exchange between the indoor air and the outdoor air is performed by the first heat exchanger 80 and the second heat exchanger 82 provided on the side of the total heat exchanger 20. That is, the heat energy may be recovered first by the total heat exchanger 20, and the heat energy may be recovered secondarily by the first heat exchanger and the second heat exchanger to maximize energy recovery efficiency.

As such, when the ventilation device is driven, the heat pump system may be driven according to a user's selection.

In the heating operation, the refrigerant is discharged from the discharge port 84a of the compressor 84 and then flows into the four-way valve 86. The refrigerant introduced into the four-way valve 86 is transferred to the first heat exchanger 80, and the refrigerant transferred to the first heat exchanger 80 passes through the expansion valve 88 to the second heat exchanger 82. Inflow. In addition, the refrigerant discharged from the second heat exchanger 82 passes through the four-way valve 86 and flows into the compressor 84 through the inlet 84b of the compressor 84.

At this time, the first heat exchanger 80 is secondary heat exchanged with the outdoor air, the second heat exchanger 82 is heat exchanged with the indoor air to maximize the heat energy recovery rate.

In the heating operation, the damper motor 46b is driven according to the user's selection, and the valve plate 46a is operated by the damper motor 46b to operate between the north side suction port 42 and the air supply suction port 52. Communicate. Then, the temperature difference between the outdoor air and the indoor air in winter can be further increased, thereby improving the energy exchange efficiency.

In the cooling operation, the refrigerant is discharged from the discharge port 84a of the compressor 84 and transferred to the second heat exchanger 82 via the four-way valve 86, and the expansion valve 88 from the second heat exchanger 82. The first heat exchanger 80 is supplied to circulate the first heat exchanger 80, and is sucked into the inlet 84b of the compressor 84 via the four-way valve 86.

In this cooling operation, the damper motor 46b is driven by the user's choice so that the valve plate 46a communicates between the south suction port 44 and the air supply suction port 52. Then, it is possible to maximize the temperature difference between the outdoor air and the indoor air in the summer to improve the energy exchange efficiency.

4 is a configuration diagram of a circulation device according to a second embodiment of the present invention.

The circulation device according to the second embodiment includes a case 10, an electrothermal heat exchanger 20 for exchanging indoor air and outdoor air installed inside the case 10, and an inside of the case 10 to provide indoor cooling and heating. Heat pump system 30 to perform, and installed on one side of the case 10 includes the indoor air circulation device 200 to circulate only the indoor air to perform cooling and heating when the ventilation of the indoor air is completed.

Since the heat exchanger 20 and the heat pump system 30 are the same as the heat exchanger 20 and the heat pump system 30 described in the above embodiment, description thereof will be omitted.

The indoor air circulation system 200 includes a connection pipe 210 connected to communicate between the air supply inlet port 52 and the exhaust outlet port 64, and an air supply inlet port 52 that opens and closes the air supply inlet port 52. The first damper 220, the second damper 230 provided in the connecting pipe 210 to open and close the connecting pipe 210, and the third damper provided in the exhaust outlet 64 to open and close the exhaust outlet 64 It consists of 240.

The connection pipe 210 serves to suck the indoor air discharged through the exhaust outlet 64 through the air supply inlet 52 and supply the air back to the room.

The first damper 220, the second damper 230 and the third damper 240 are valve plates 220a, 230a and 240a for opening and closing the flow paths, respectively, and valve plates 220a, 230a and 240a according to a user's operation. And damper motors 220b, 230b, and 240b to operate.

As described above, referring to the action of the indoor air circulator, the second damper 230 installed in the connection pipe 210 is operated when the indoor air is contaminated to circulate the indoor air and the outdoor air. Close it.

The contaminated indoor air is then discharged to the outside through the exhaust outlet 64, and fresh outdoor air is sucked through the air supply inlet 52. At this time, while passing through the heat exchanger 20, indoor air and outdoor air are heat-exchanged, and the heat pump system 30 is driven to perform indoor cooling and heating.

In addition, when the indoor air is determined to be purified and only the indoor air is circulated to perform the heating and cooling to increase the thermal efficiency, the second damper 230 is operated to open the connection pipe 210 and the first and third dampers ( 220 and 240 are operated to block the air supply intake port 52 and the exhaust discharge port 64, respectively.

Then, the indoor air discharged to the exhaust discharge port 64 is sucked into the air supply suction port 52 through the connection pipe 210 and supplied to the room.

5 is a configuration diagram of a circulation device according to a third embodiment of the present invention.

The circulation device according to the third embodiment has a structure in which the multi-pipe 40 described in the above embodiment and the indoor air circulation device 200 described in the second embodiment are installed.

The operation of the circulator according to the third embodiment may be performed at the same time as the operation of the multi-pipe 40 described in the embodiment and the operation of the indoor air circulation device 200 described in the second embodiment will be omitted. .

Although described above with reference to preferred embodiments of the present invention, those skilled in the art or those skilled in the art without departing from the spirit and scope of the invention described in the claims to be described later Various modifications and variations can be made in the present invention without departing from the scope thereof.

1 is a block diagram of a ventilation apparatus according to the prior art.

2 is a block diagram of a ventilation device according to an embodiment of the present invention.

3 is a configuration diagram of a heat pump system applied to the present invention.

4 is a configuration diagram of a ventilation device according to a second embodiment of the present invention.

5 is a configuration diagram of a ventilation device according to a third embodiment of the present invention.

Claims (5)

A case having an air intake port through which outdoor air is sucked, an air supply outlet for supplying outdoor air to the room, an exhaust air intake port through which indoor air is sucked, and an exhaust port for discharging indoor air to the outside; A total heat exchanger for heat-exchanging the indoor air and the outdoor air installed in the case; A heat pump system installed inside the case to perform cooling and heating; North side inlet connected to the air supply inlet and installed in the north direction of the building, and south inlet connected to the air supply inlet and installed in the south direction of the building so that outdoor air is selectively introduced in the south and north of the building in summer and winter. And a multi-pipe having a damper for selectively communicating between any one of the north side suction port and the south side suction port and the air supply suction port. The method of claim 1, The heat pump system includes a first heat exchanger installed in an air supply duct through which the outdoor air of the case passes and heat exchanged with the outdoor air; A second heat exchanger installed in an exhaust duct through which the indoor air of the case passes and exchanging heat with the indoor air; A compressor for compressing a low temperature low pressure gaseous refrigerant into a high temperature high pressure gaseous refrigerant; And a four-way valve for switching the refrigerant flow in accordance with the cooling operation and the heating operation mode. The method of claim 1, The damper comprises a valve plate for selectively opening any one of the north side suction port and the south side suction port, and a damper motor for operating the valve plate. The method of claim 1, The damper communicates the air supply inlet port and the north side suction port in winter, and the air inlet and the south side suction port in summer. A case having an air intake port through which outdoor air is sucked, an air supply outlet for supplying outdoor air to the room, an exhaust air intake port through which indoor air is sucked, and an exhaust port for discharging indoor air to the outside; A total heat exchanger installed inside the case; A heat pump system installed inside the case to perform cooling and heating; North side inlet connected to the air supply inlet and installed in the north direction of the building, and south inlet connected to the air supply inlet and installed in the south direction of the building so that outdoor air is selectively introduced in the south and north of the building in summer and winter. And a multi pipe having a damper for selectively communicating between any one of the north side suction port and the south side suction port and the air supply suction port. A connection pipe installed at one side of the case and connected to communicate between an air intake port where outdoor air is inhaled and an exhaust outlet where indoor air is discharged so as to circulate only indoor air to perform cooling and heating when the indoor ventilation is completed, and the air supply intake port An indoor air circulation device having a first damper installed at the opening and closing air supply inlet, a second damper provided at the connecting pipe to open and close the connecting pipe, and a third damper provided at the exhaust opening and opening and closing the exhaust outlet. Ventilator included.

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