KR101337051B1 - Air conditioning system - Google Patents

Abstract

In the air conditioning system according to the present invention, a ventilation unit including an electric heat exchanger and an air cleaning unit and an air conditioner for supplying cold or warm air to the room are interconnected, and at least any one of the air cleaning unit and the air conditioner and the ventilation unit. The operating conditions of other devices are varied according to one operating condition, and the control unit of the ventilation unit, the air cleaning unit, and the air conditioner are connected by wire or wirelessly to check driving information of each device in real time and exchange information with each other. When a driving command of at least one device among the connected devices is input, any one of the driven devices becomes the main control unit, and the operating condition of the other device is changed by the main control unit. To be automatically variable.

Air Cleaners, Heat Exchangers, Splitters

Description

Air conditioning system

1 is an external perspective view of an air cleaning unit equipped with an air cleaning and ventilation function according to the spirit of the present invention.

2 is an exploded perspective view of the air cleaning unit.

3 is a vertical sectional view of the air cleaning unit.

4 is a perspective view showing a first embodiment of an installation case according to the spirit of the present invention.

5 is a perspective view showing a second embodiment of the installation case according to the spirit of the present invention.

Figure 6 is an exploded perspective view showing a state in which the air cleaning unit according to the spirit of the present invention is mounted on the interior wall.

Figure 7 is an exploded perspective view showing the flow of air in the air cleaning unit ventilation mode state according to the spirit of the present invention.

8 is a bottom perspective view showing the flow of air in a clean mode of the air cleaning unit according to the spirit of the present invention.

9 is an exploded perspective view showing a state in which the air cleaning unit according to the spirit of the present invention is connected to the duct member passing through the ceiling portion.

10 is a system showing a state connected to the air cleaning unit and the ventilation unit according to the spirit of the present invention.

11 is a schematic view showing the flow of air in the system.

12 is an exploded perspective view showing a duct member according to the spirit of the present invention.

13 is a first embodiment showing an air conditioning system in accordance with the teachings of the present invention.

14 is a second embodiment showing an air conditioning system in accordance with the teachings of the present invention.

15 is a third embodiment showing an air conditioning system in accordance with the teachings of the present invention.

16 is a fourth embodiment of an air conditioning system in accordance with the teachings of the present invention.

17 is a fifth embodiment of an air conditioning system in accordance with the teachings of the present invention.

<Description of the symbols for the main parts of the drawings>

10 air cleaning unit 11: front cover

12: cover guide 13: filter

14: discharge grill 15: pan

16: rear panel 17: installation case

18: installation bar 30: duct member

31: air supply duct 32: exhaust duct

40: heat exchanger 50: distributor

70: diffuser 80: air conditioner

The present invention relates to an air conditioning system and a control method thereof, and in more detail, to allow the air cleaning unit to operate in conjunction with another air conditioner such as a ventilation unit, and the like, and to automatically change the air volume of the other device according to the change in the air volume of one device. The present invention relates to an air conditioning system and a method of controlling the same, wherein the indoor air is kept in an optimal state.

In general, when a living organism breathes for a certain period of time in a space that is blocked from outdoor air, the amount of carbon dioxide increases in the room, which interferes with the living breathing. Therefore, indoor space should be ventilated frequently in a space where many people stay together, such as an office, or in a narrow space such as a vehicle. At this time, a commonly used ventilation system.

In detail, the ventilation system is generally a device that is installed on the indoor floor or fixedly mounted on the ceiling, such that outdoor air is introduced into the room and indoor air is discharged to the outside. Therefore, the installation of the ventilation system is required in a space where the circulation of indoor air is not smooth or a space where many people stay.

However, in the conventional general ventilation system, only a clean device for cleaning indoor air or a ventilation device for circulation of indoor air and outdoor air is installed. In other words, when the ventilation device is operated in winter when the temperature difference between the outdoor air and the indoor air is remarkable, there is a problem that the indoor temperature is lowered and the heating efficiency is significantly lowered.

In addition, there is a problem in that a separate air conditioner such as an air conditioner or a heater is additionally operated in order to increase or decrease the temperature of each indoor space partitioned while the ventilation device is operated.

In addition, conventionally, since the air discharged from one ventilation device is to be spread to a plurality of compartments, the ventilation efficiency is inferior to the volume.

In addition, when another air conditioner such as a ventilation device or an air conditioner is connected to the air cleaning unit, there may be a problem in that the air volume of the fan provided in each device cannot be collectively controlled.

The present invention has been proposed to solve the above problems, and in the air conditioning system to which a plurality of air conditioners including an air cleaning unit is connected, the air volume of the other device is appropriately changed according to the air volume of any one device, It is an object of the present invention to provide an air conditioning system and a control method to achieve the air conditioning efficiency of.

The air conditioning system according to the present invention for achieving the above object is a ventilation unit including an electric heat exchanger, an air cleaning unit and an air conditioner for supplying cold or warm air to the room are interconnected, and the air cleaning unit and The operating conditions of the other device are varied according to the operating conditions of at least one of the air conditioner and the ventilation unit, and the control unit of the ventilation unit, the air cleaning unit, and the air conditioner is connected by wire or wirelessly to drive information of each device. It is possible to check in real time and exchange information with each other, and when a driving command of at least one of the connected devices is input, any one control unit of the driven device becomes a main control unit, and the operating condition of any one device by the main control unit. As this change, the movement conditions of the other device are automatically changed. .

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By the above configuration, if the air volume of the air cleaning unit or another air conditioner connected thereto is changed, the air volume of the other air conditioner is automatically changed, thereby optimizing and maximizing the air conditioning efficiency.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It should be understood, however, that there is no intention to limit the scope of the present invention to the embodiment shown, and that other embodiments falling within the scope of the present invention may be easily devised by adding, Can be proposed.

1 is an external perspective view of an air cleaning unit having an air cleaning and ventilation function according to the spirit of the present invention, FIG. 2 is an exploded perspective view of the air cleaning unit, and FIG. 3 is a vertical cross-sectional view of the air cleaning unit.

1 to 3, the air cleaning unit 10 having the air cleaning and ventilation function according to the present invention includes a front cover 11 having an air inlet formed at a central portion thereof, and the front cover 11 is The cover guide 12 to be seated, the discharge guide 14 is mounted by the sliding method and the air discharge port is formed on the side, and laminated on the lower side of the discharge grill 14, suction Filter 13 to filter out foreign substances contained in the indoor air to be removed and the smell, the control box 19 is coupled to the lower edge of the discharge grill 14, the lower side of the cover guide 12 A control panel 21 detachably coupled to each other, and a shielding member 23 for selectively shielding a discharge port formed on the side surface of the discharge grill 14 are included. In detail, the control box 19 has a main PCB board for controlling the operation of the air cleaning unit 10. In addition, a display PCB substrate displaying an operating state of the air cleaning unit 10 is mounted on one side of the rear surface of the control panel 21. In addition, when the air cleaning unit 10 is mounted at an edge portion where the wall surface and the ceiling meet, the discharge port portion of the discharge grille 14 covered by the wall surface is shielded by the shielding member 23. Then, the air is discharged through the front and one side of the discharge port of the discharge grill 14.

In addition, the air cleaning unit 10 is provided on the upper side of the filter 13 and the fan 15 for sucking indoor air or outdoor air, and detachably coupled to the lower side of the discharge grill 14, the A shroud 145 for guiding the flow of indoor or outdoor air sucked by the fan 15, a fan motor 20 for driving the fan, and the fan motor 20 are mounted, and an exhaust duct is provided at one side thereof. And a rear panel 16 to which the air supply duct is connected.

In addition, the air cleaning unit 10 is coupled to the upper side of the rear panel 16 to the base panel 22 to reinforce the strength of the rear panel 16, and is coupled to one side of the rear panel 16 An installation case 17 for easily coupling the exhaust duct and the air supply duct and a detachable coupling to an upper side of the rear panel 16 to easily mount the rear panel 16 to a wall or a ceiling. An installation bar 18 is included.

Hereinafter, the operation of the air cleaner unit 10 mounted on the ceiling will be described.

First, when the air cleaning unit 10 is attached to the ceiling, the front cover 11 faces the bottom. When the air cleaning mode is selected in this state, the fan motor 20 driving the fan 15 is operated to rotate the fan 15. As the fan 15 rotates, indoor air flows through the indoor air intake port 111 provided in the front cover 11. Here, the fan 15 is preferably a centrifugal fan in which air is sucked in the axial direction and discharged in the radial direction. Then, the sucked indoor air is purified while passing through the filter 13, and is moved to the upper surface of the discharge grill 14 through the shroud 145. In addition, the air moved to the upper surface of the discharge grill 14 is guided by the air guide 144, and is discharged back to the room through the discharge grill 141 formed on the side of the discharge grill 14 .

On the other hand, when the user selects the ventilation mode, the indoor air is sucked through the exhaust grill 148 formed on the side of the discharge grill 14, and flows to the exhaust duct connected to the air cleaning unit 10. In addition, outdoor air is introduced through the air supply duct connected to the air cleaning unit 10, and the introduced outdoor air passes through the filter 13 and then discharges the discharge grill 141 formed in the discharge grill 14. Through the room.

4 is a perspective view showing a first embodiment of an installation case according to the spirit of the present invention.

Referring to FIG. 4, the installation case 17 according to the present embodiment is mounted when the intake duct and the exhaust duct connected to the air cleaning unit 10 are formed through the wall surface. In addition, the installation case 17 is seated on the bent surface of the rear panel 16.

In detail, both side upper surfaces of the installation case 17 are provided with an installation bar seating surface 171 for mounting the end of the installation bar 18. In addition, a wiring through hole 174 through which various electrical wires pass is formed at an edge of the installation case 17. In addition, an inlet port 173 and an exhaust port 172 are formed on a front surface of the installation case 17, and the inlet port 173 and the exhaust port 172 are inlet ports 163 of the rear panel 16 (see FIG. 8). And the exhaust port 162 (see Fig. 8) are in close contact. The guide ribs 161 (see FIG. 8) extending from the inlet port 163 and the exhaust port 162 of the rear panel 16 are outer peripheral surfaces of the inlet port 173 and the exhaust port 172 of the installation case 17. Is fitted on. Therefore, the air flowing in / out through the inlet 163 or the exhaust port 162 of the rear panel 16 is prevented from leaking to the outside by the guide rib 161.

5 is a perspective view showing a second embodiment of the installation case according to the spirit of the present invention.

5, the installation case 27 according to the present embodiment is characterized in that the intake duct and the exhaust duct is mounted when the ceiling is formed.

In detail, the installation case 27 includes an inlet port 273 and an exhaust port 272 formed at an upper side and a front side, and an installation bar recessed to a predetermined depth at both edges of the upper side to allow the installation bar 18 to be seated. A mounting surface 271 and an installation bar insertion hole 271a formed at a rear end of the installation bar mounting surface 271 may be included.

More specifically, the bent portion of the install bar 18 is inserted into the install bar insertion hole 271a. In addition, the intake port and the exhaust port formed on the front surface of the installation case 27 are coupled to the intake port 163 and the exhaust port 162 of the rear panel 16.

6 is an exploded perspective view showing a state in which the air cleaning unit according to the spirit of the present invention is mounted on the interior wall surface.

Referring to FIG. 6, when the duct member consisting of the air supply duct and the exhaust duct is connected to the interior wall surface, an installation case 17 in which the intake port and the exhaust port are formed in the front-rear direction is applied. That is, the inlet port 173 and the exhaust port 172 of the installation case 17 to which the installation bar 18 is coupled are attached to the indoor wall surface so as to be connected to the intake duct and the exhaust duct, respectively. In addition, the fastening member penetrating through the fastening hole 184 of the installation bar 18 is inserted into the ceiling so that the assembly of the installation case 17 and the installation bar 18 is fixedly mounted on the indoor wall and the ceiling. . Then, the air cleaning unit 10 is pushed in the direction of the arrow to be coupled to the installation case assembly. Then, the installation bar 18 is fastened to the installation bar mounting structure formed on the rear panel 16 of the air cleaning unit 10.

When the air cleaning unit 10 is connected to the duct member and the power is applied and the ventilation mode is selected according to the assembly sequence as described above, outdoor air is introduced into the air cleaning unit 10 through the air supply duct 31. . Then, the discharge grille 14 is discharged into the room through the discharge grille 141. In addition, the indoor air sucked through the exhaust grill 148 of the discharge grill 14 is discharged to the outside through the exhaust duct 32. When the air cleaning unit 10 is mounted to be spaced apart from the edge of the wall, outdoor air is discharged to the room through three surfaces of the discharge grille 14. Details thereof will be described later with reference to the accompanying drawings.

In addition, the installation case assembly consisting of the installation case 17 and the installation bar 18 can be fixed to the wall surface to be connected to the duct member during building construction. And, by varying the position of the outdoor air intake port and the indoor air discharge port provided in the air cleaning unit 10, it can be appropriately applied according to the position of the air supply duct and the exhaust duct connected to the room.

7 is an exploded perspective view illustrating the flow of air in the air cleaning unit according to the spirit of the present invention in the ventilation mode.

Referring to FIG. 7, as described above, an air supply duct 31 is connected to an inlet 173 of the installation case, and an exhaust duct 32 is connected to an exhaust port 172.

In detail, outdoor air introduced through the air supply duct 31 is introduced into the air cleaning unit 10 through the inlet 163 of the rear panel 16. At this time, in the state in which the indoor air intake port 111 of the front cover 11 is opened, ventilation and cleaning are performed at the same time. When the air intake port 111 is closed, only ventilation is performed. This is determined according to the case in which the front panel 112 is fixedly mounted or selectively coupled to open and close.

In more detail, the outdoor air introduced through the inlet 163 rises from the lower side to the upper side of the filter 13 stacked on the bottom surface of the discharge grille 14 to filter foreign matter. In addition, by the action of the fan 15 which sucks air in the axial direction and discharges it in the radial direction, the sucked outdoor air is spread in the horizontal direction. The air spreading in the horizontal direction is moved toward the discharge grill 141 by the air guide 144 formed in the discharge grill 14. Then, it passes through the discharge grill 141 and is finally discharged to the room.

Meanwhile, while the outdoor air is sucked through the air supply duct 31, the indoor air contaminated through the exhaust duct 32 is discharged to the outside.

8 is a bottom perspective view showing the flow of air in a clean mode of the air cleaning unit according to the spirit of the present invention.

Referring to FIG. 8, when the clean mode is selected, indoor air is sucked through the indoor intake port 111. In addition, the suctioned indoor air is purified while passing through the filter 13 and then discharged back to the room through the discharge grill 141 of the discharge grill 14.

On the other hand, when the clean mode is selected, the inlet 173 connected to the air supply duct 31 may be shielded.

In detail, since the clean mode is selected and the fan 15 is rotated, air is not sucked toward the exhaust grill 148, and thus it is not necessary to provide a separate blocking member on the exhaust port 172 side. However, since the intake port 173 communicates with the filter 13, there is a possibility that outdoor air is also sucked together when indoor air is sucked through the indoor intake port 111.

Thus, in order to completely block the inflow of external air through the inlet 173 connected to the air supply duct 31 in the clean mode and to perform only a pure clean function, the inlet 173 is selectively selected according to a specific mode. The opening and closing device to open and close may be provided.

On the other hand, when the flow of the air in more detail in the clean mode, first, the indoor air is sucked through the indoor intake port 111 by the drive of the fan 15. The sucked indoor air is filtered while passing through the filter 13, and passes through the orifice 143 to reach the fan 15. Then, the air reaching the fan 15 is dispersed in the horizontal direction, guided by the air guide 144 is discharged back to the room through the discharge grill 141.

9 is an exploded perspective view showing a state in which the air cleaning unit according to the spirit of the present invention is connected to the duct member passing through the ceiling portion.

9, in order to connect the air cleaning unit 10 to the duct member 30 passing through the ceiling, the installation case 27 for ceiling connection shown in FIG. 5 is mounted. In addition, the inlet port 273 formed at the upper side of the installation case 27 is connected to the connection pipe 71 branched to the bottom surface of the air supply duct 31. In addition, an exhaust port 273 of the installation case 27 is connected to an exhaust branch duct 321 branched to a bottom surface of the exhaust duct 32. Here, the intake and exhaust of the installation case 27 may be connected to the branch duct branched from the duct member 30, it is noted that the end of the air supply duct 31 and the exhaust duct 32 may be directly connected. In detail, when a plurality of air cleaning units are connected to the duct member 30, each branch duct is connected to the air cleaning unit. On the other hand, when one air cleaning unit is connected to the duct member 30, the end of the duct member 30 is directly connected to the air cleaning unit. Details thereof will be described later with reference to the accompanying drawings.

10 is a system diagram showing a state in which an air cleaning unit and a ventilation unit are connected according to the spirit of the present invention, and FIG. 11 is a schematic diagram showing the flow of air in the system.

10 and 11, the air cleaning unit 10 according to the present invention is connected to a ventilation unit such as the heat exchanger 40 by the duct member 30, thereby providing a heat exchange function together with a ventilation or clean function. This can be done at the same time.

In detail, one end of the intake duct 31 and the exhaust duct 32 is connected to the air cleaning unit 10, and the other end is connected to the heat exchanger (30). Here, the heat exchanger (30) allows the air introduced into the room and the air discharged to the outside to exchange with each other, thereby preventing the room temperature from dropping or increasing rapidly by the air introduced into the room. That is, when the indoor temperature is higher than the outdoor temperature, heat is transferred from the air discharged to the air to the air flowing into the room, thereby narrowing the temperature difference between the indoor temperature and the air flowing into the room, thereby rapidly changing the indoor temperature. You can stop it.

In addition, an air supply connecting pipe 33 may be connected to the other end of the intake duct 31, and an exhaust connecting pipe 34 may be connected to the other end of the exhaust duct 31. In addition, the air supply connection pipe 33 and the exhaust connection pipe 34 are connected to the heat exchanger 40.

On the other hand, the heat exchanger 40 is opposed to the exhaust inlet port 42 formed on one side of the outer circumferential surface, the air supply discharge port 43 formed to be spaced apart from the exhaust inlet port 42 by a predetermined distance, and the exhaust inlet port 42 An exhaust discharge port 44 formed at a position, an air supply suction port 45 formed at a position opposed to the air supply discharge port 43, and a heat exchange element 41 are included.

In addition, an exhaust fan 47 mounted inside the conduit connecting the exhaust inlet 42 and the exhaust outlet 44, and an air supply mounted inside the conduit connecting the air supply inlet 45 and the air supply outlet 43 The fan 46 is further included.

In detail, the exhaust inlet 42 is formed on the same side as the air supply outlet 43, and the exhaust outlet 44 is formed on the same side as the air supply inlet 45. The position of the exhaust inlet 42 and the air supply outlet 43 or the positions of the exhaust outlet 44 and the air supply inlet 45 may vary depending on the type of the total heat exchanger 40.

In more detail, the exhaust inlet 42 is connected to the exhaust connection pipe 34 so that indoor air discharged from the air cleaning unit 10 flows. In addition, the air supply outlet 43 is connected to the air supply connection pipe 33 so that outdoor air is supplied to the air cleaning unit 10.

In addition, when the exhaust fan 47 is operated, indoor air introduced into the heat exchanger 40 through the exhaust inlet 42 is discharged to the outside through the exhaust outlet 44. When the air supply fan 46 is operated, outdoor air sucked into the air supply inlet 45 is introduced into the air cleaning unit 10 through the air supply outlet 43 and discharged into the room. In addition, the indoor air introduced through the exhaust intake port 42 and the outdoor air sucked through the air supply intake port 45 exchange heat while passing through the electrothermal exchange element 41.

In addition, outdoor air introduced into the air cleaning unit 10 through the air supply discharge port 43 is purified while passing through the filter 13, and the discharge grill 141 of the discharge grill 14 is removed. It is discharged to the room through. In addition, the indoor air sucked through the exhaust grill 148 is introduced into the total heat exchanger 40 through the exhaust duct 32 and the exhaust suction port 42. Then, it is discharged to the outside through the exhaust discharge port 44.

In the air conditioning system having the above configuration, when the user selects the ventilation mode, the heat exchanger 40 and the air cleaning unit 10 are driven together.

In detail, when the ventilation mode is selected, the fan 15 mounted inside the air cleaning unit 10 and the air supply fan 46 and the exhaust fan 47 mounted inside the heat exchanger 40 are driven. . In addition, outdoor air sucked by the air supply fan 46 is introduced into the air cleaning unit 10 along the air supply duct 31. In addition, the outdoor air sucked by the driving of the fan 15 is purified while passing through the filter 13 and then discharged into the room through the discharge grill 141. In addition, indoor air is sucked through the exhaust grill 138 formed on one side of the air cleaning unit 10 by the driving of the exhaust fan 47. In addition, the sucked indoor air is introduced into the heat exchanger 40 through the exhaust duct 32. In the electrothermal heat exchanger 40, indoor air and outdoor air sucked in exchange with each other while passing through the electrothermal heat exchange element 41.

12 is an exploded perspective view showing a duct member according to the spirit of the present invention.

Referring to FIG. 12, the duct member 30 according to the present invention includes an air supply duct 31 through which outdoor air is sucked in, and an exhaust duct 32 through which indoor air is discharged.

In detail, the duct member 30 includes a straight straight tube 312 and 322 having a predetermined length, elbows 313 and 323 curved at a predetermined curvature, the straight pipes 312 and 322 and a straight tube 312 and 322. Or elbows 313 and 323, the same type of connector 301 and the straight pipes (312, 322) or elbows (313, 323) and the release connector (314, 324) connecting the heat exchanger (40). The duct member 30 is supported by the hanger 302 on the ceiling portion.

As shown, the elbows 313 and 323 are used when the heat exchanger 40 and the air cleaning unit 10 are not positioned in a straight line to change the direction of the duct member 30. And, one end of the release connector (313,323) forms the same shape as the cross-section of the straight pipe (312,322) or the elbow (313,323), the other end forms the same shape as the cross section of the intake and exhaust of the heat exchanger (40). .

In addition, the cross-sectional size of the elbow (313, 323) and the connector (301, 323) is formed to be slightly larger than the cross-section of the straight pipe (312, 322), so that the straight pipe (312, 322) and the elbow (313, 323) or the connector To be inserted into the interior of the (301,323) by a predetermined length. Therefore, the phenomenon that the air flowing along the inside of the duct member 30 leaks to the outside through the duct connecting portion is prevented.

13 is a first embodiment showing an air conditioning system according to the spirit of the present invention, FIG. 14 is a second embodiment showing an air conditioning system according to the spirit of the present invention, and FIG. 15 is an air according to the spirit of the present invention. A third embodiment showing a harmonic system.

Referring to FIG. 13, the air cleaning unit 10 according to the present invention is connected to the heat exchanger 40 by the duct member 30, and the heat exchanger 40 and the air cleaning unit 10 are the same indoor space or the like. Can be installed in other interior spaces. In other words, the total heat exchanger 40 is attached to the wall partitioning the indoor and outdoor, so that the outdoor air flows directly into the heat exchanger 40. When the indoor space in which the air cleaning unit 10 is installed is formed in the interior of the building, the heat exchanger 40 and the air cleaning unit 10 are connected to each other by using the duct member 30. And the linear pipe 312, the elbow 313, etc. which comprise the said duct member 30 are arrange | positioned suitably according to the installation position of the said air cleaning unit 10.

In addition, the air supply connecting pipe 33 is formed so that the end is divided in two directions as shown, one end is connected to the air supply duct 31 and the other end is connected to the diffuser 70. In addition, an end of the diffuser 70 may be located in another independent space in which the electrothermal exchanger 40 or the air cleaning unit 10 is not installed. Then, the connection pipe 71 is branched from one point of the diffuser 70, and the air conditioner 80 is connected to the connection pipe. In addition, the air conditioner 80 may be installed in an independent space similarly to the diffuser 70 so that each indoor space may be maintained independently of each other.

According to the above configuration, the outdoor air introduced through the heat exchanger 40 is discharged to the space where the air cleaning unit 10 is installed, and the indoor air is discharged to the outside through the exhaust duct 32. . In addition, in the clean mode, the indoor air is purged by the filter 13 while being introduced into the air cleaning unit 10 and then discharged back to the room. The outdoor air sucked through the heat exchanger 40 is immediately discharged in the space where the diffuser 70 is installed. Here, in the total heat exchanger 40, the outdoor air sucked out and the indoor air discharged are exchanged.

On the other hand, the connector 71 is to be connected to the indoor unit or outdoor unit of the air conditioner (80). In detail, when the connection pipe 71 is connected to the indoor unit of the air conditioner 80, the heat exchanger is primarily heat exchanged inside the heat exchanger 40 in the process of introducing outdoor air through the heat exchanger 40 to lower the outdoor temperature. In the state is introduced into the indoor unit of the air conditioner (80). And, although not shown in the drawings, when the connection pipe 71 is connected to the outdoor unit of the air conditioner 80, the efficiency of the outdoor heat exchanger is much better than the conventional outdoor unit.

In other words, the outdoor air introduced through the heat exchanger 40 maintains a lower temperature than the outdoor temperature because it heat exchanges with the indoor air discharged from the inside of the heat exchanger 40. The outdoor air flowing into the outdoor unit of the air conditioner 80 along the air supply connection pipe 33 and the connection pipe 71 exchanges heat with an outdoor heat exchanger installed in the outdoor unit.

Here, the conventional air conditioner outdoor unit is generally heat exchanged by direct contact with the outdoor air and the outdoor heat exchanger. However, as proposed in the present invention, since the outdoor air that is primarily heat exchanged through the heat exchanger 40 to maintain a state lower than the outdoor temperature is heat-exchanged with the outdoor heat exchanger, the heat exchange efficiency is further improved.

In addition, instead of the air conditioner 80, the connection pipe 71 may be equipped with a hot air heater or a combined air-conditioning and heating air conditioner. In detail, the warm air fan is also composed of an indoor unit and an outdoor unit, and the connection pipe 71 is connected to the indoor unit or the outdoor unit of the warm air fan, so that the outdoor air sucked is exchanged with the indoor heat exchanger or the outdoor heat exchanger. In more detail, when the connecting pipe 71 is connected to the outdoor unit of the warm air fan, the outdoor air sucked through the connecting pipe 71 exchanges heat with the indoor air discharged from the inside of the heat exchanger 40, thereby making the outdoor temperature. It will stay higher. Therefore, since the refrigerant flowing inside the outdoor heat exchanger absorbs more heat from the sucked outdoor air, the heat exchange efficiency is better than in the conventional case. In the embodiment presented below, it can be seen that a hot air heater or the like may be mounted at the position where the air conditioner 80 is mounted, as in the present embodiment, and a redundant description will be avoided in the following.

Referring to FIG. 14, the air conditioning system according to the present invention is characterized in that a plurality of air cleaning units 10 and a plurality of air conditioners 80 are mounted in one electrothermal exchanger 40.

In detail, the heat exchanger 40 is connected to the air cleaning unit 10 by a duct member 30, and the diffuser 70 is branched from one point of the air supply duct 31. In addition, a separate connecting pipe 71 may be branched again from one point of the diffuser 70 so that the end of the diffuser 70 and the end of the connecting pipe 71 may be located in a separate indoor space. In addition, the air cleaning unit 10 may be a combination of the ceiling connection type and the wall connection type according to the shape of the installation case 17.

In addition, an air supply branch duct 311 may be branched from another point of the air supply duct 31, and a plurality of air conditioners 80 or a warm air fan may be connected to the air supply branch duct 31. In addition, as described above, the air supply branch duct 311 may be connected to an outdoor unit or an indoor unit such as the air conditioner 80 or a hot air fan.

Referring to FIG. 15, in the air conditioning system according to the present invention, a diffuser 70 is connected to the total heat exchanger 40, a distributor 50 is installed at an end of the diffuser 70, and a plurality of air conditioners 80 and the like. It is characterized in that the connection.

In detail, an air supply connecting pipe 33 is mounted at the air supply outlet of the heat exchanger 40, and ends of the air supply connecting pipe 33 are divided in two directions so that the air supply duct 31 and the diffuser 70 are connected to each other. do. In addition, a distributor 50 is mounted at an end of the diffuser 70, and a plurality of distribution pipes 51 are branched from the distributor 50. In addition, an air conditioner such as an air conditioner 80 may be connected to the distribution pipe 51. As described above, the air conditioner 80 connected to the distribution pipe 51 may be mounted in an independent indoor space.

16 is a fourth embodiment of an air conditioning system in accordance with the teachings of the present invention.

Referring to FIG. 16, in the air conditioning system according to the present invention, a distributor 50 is directly connected to the total heat exchanger 40, and the air conditioner 80 and / or the air cleaning unit 10 and / or the distributor 50 are connected. Or it is characterized in that the diffuser 70 is connected.

In detail, the air supply outlet 43 and the distributor 50 of the heat exchanger 40 are connected by the air supply duct 31, and the air conditioner 80 is connected to the distribution pipe 51 branched from the distributor 50. The air cleaning unit 10 is connected. In addition, the diffuser 70 independently extends from one side of the distributor 50. In addition, a separate diffuser 70 may be connected to the air conditioner 80 so that all or part of the air discharged from the indoor unit of the air conditioner 80 may be discharged to the separate space through the diffuser 70.

In addition, the exhaust port of the air cleaning unit 10 is interconnected by the exhaust inlet 42 and the exhaust duct 32 of the total heat exchanger (40). Therefore, the indoor air sucked through the air cleaning unit 10 in the ventilation mode moves along the exhaust duct 32 and flows into the heat exchanger 40. Then, heat exchange with the outdoor air sucked in the heat exchanger 40 is discharged to the outside.

By the above configuration, the space in which the air cleaning unit 10 is installed, the space where the end of the diffuser 70 branched from the distributor 50 is located, and the space in which the air conditioner 80 is installed are independent of each other. The indoor environment is maintained.

17 is a fifth embodiment of an air conditioning system in accordance with the teachings of the present invention.

Referring to FIG. 17, in the air conditioning system according to the present invention, all of the cold air discharged through the indoor unit of the air conditioner 80 is directly connected by the air supply duct 31 and the heat exchanger 40 and the air conditioner 80. Or it is characterized in that part to be introduced into the distributor 50 through the air supply duct (31).

In detail, the cold air introduced into the distributor 50 is provided in a separate space through the air cleaning unit 10 connected to the distributor 50 by the diffuser 70 or the distribution pipe 51 connected to the distributor 50. Discharged. In addition, the air cleaning unit 10 is directly connected by the heat exchanger 40 and the exhaust duct 32, so that the indoor air sucked into the air cleaning unit 10 passes through the heat exchanger 40. Allow to be discharged outdoors. In addition, a separate diffuser 70 is branched from one point of the air supply duct 31 connecting the heat exchanger 40 and the air conditioner 80 to separate the outdoor air sucked through the heat exchanger 40. It can be discharged directly into the space of the.

As in the above-described embodiments, the air cleaning unit 10, the heat exchanger 40, the distributor 50, the diffuser 70, and the like are appropriately combined so that each indoor space meets the needs of the indoor occupants. It can be kept in the environment.

Hereinafter, in the air conditioning system having the above configuration, a method of allowing the fan air flow rate of the other device to be variably controlled according to the fan air flow rate of one device will be described.

First, the fan airflow control method of another apparatus will be described based on the fan airflow volume of the air conditioner 80.

In detail, the inside of the air conditioner 80 is equipped with a blowing fan for sucking the indoor air and discharged back to the room. The air volume of the air conditioner 80 is determined according to the rotational speed of the blower fan. That is, when it is necessary to lower the temperature of the indoor air due to the high room temperature, the amount of air passing through the heat exchanger is increased by increasing the rotation speed of the blower fan. At the same time, the driving force of the compressor is increased to lower the temperature of the refrigerant flowing inside the heat exchanger.

Here, since the air conditioner 80 is connected to the air supply duct of the heat exchanger 40, the air supply fan 46 inside the heat exchanger 40 rotates as the air volume of the air conditioner 80 changes. The speed should change together.

For example, when the air volume of the air conditioner 80 is increased, the air supply air volume of the air supply fan 46 of the heat exchanger 40 is varied together. Such a control of the fan air flow rate may be performed by the control unit of the air cleaning unit 10 or the air conditioner 80 or the heat exchanger 40. Preferably, the controller of the air cleaning unit 10 may control the driving states of the air conditioner 80 and the heat exchanger 40.

In detail, the control unit of the air conditioner 80 and the heat exchanger 40 is connected to the control unit of the air cleaning unit 10 in a wired or wireless manner, the information on the operating state of the air conditioner 80 or the heat exchanger (40). Is transmitted to the control unit of the air cleaning unit 10 in real time.

For example, when the user changes the air volume of the air conditioner 80 by using a remote control, the control signal is transmitted from the remote control to the control unit of the air conditioner 80, and the control unit of the air conditioner 80 according to the input command. Allow the fan air volume to vary. Then, the command input from the control unit of the air conditioner 80 to the control unit of the air cleaning unit 10 is retransmitted, so that the operation state of the other air conditioner connected to the air cleaning unit 10 is controlled by the control unit of the air cleaning unit 10. To be entered.

On the other hand, when a command for changing the air volume of the air conditioner 80 is input in the control unit of the air cleaning unit 10, it is determined whether there is a variable air volume command input to the control unit of the air cleaning unit 10, the heat transfer The proper rotational speed of the air supply fan of the exchanger 40 is calculated. Here, the proper rotational speed of the total heat exchanger 40 according to the fan speed of the air cleaning unit 10 and the air conditioner 80 is stored in a table form in a memory unit connected to the control unit of the air cleaning unit 10. The value allows the proper rotational speed of the fan to be automatically determined.

In detail, when a command to increase the fan air flow rate of the air conditioner 80 is input, if there is a change in the fan air flow rate of the air cleaning unit 10, the fan speed of the heat exchanger 40 considering the increase and decrease is determined.

For example, even if a command for reducing the air volume of the air conditioner 80 is input, if the fan air volume of the air cleaning unit 10 is increased, the fan air volume of the heat exchanger 40 will be controlled to increase.

Alternatively, the air supply fan speed of the heat exchanger 40 may be affected only by the air volume of the air conditioner 80 in the clean single operation mode state other than the ventilation clean interlock operation mode.

On the other hand, the air cleaning unit 10 does not operate, the air conditioner 80 is the main control unit for controlling the air volume of the fan in order to be applied to the idea of the present invention in the driving mode of driving only the air conditioner 80 and the heat exchanger (40) Or it should be a control unit of the total heat exchanger (40). As a method for flexibly responding to the fluctuation of the main control unit, the control unit of the heat exchanger 40 cleans the air, except in the case of clean single operation in the state where only the air cleaning unit 10 operates. It is possible to detect whether the unit 10 or the air conditioner 80 is on or off, and to transmit a signal for the device that is turned on to be the main control unit. Of course, in the clean single operation mode, the control unit of the air cleaning unit 10 will be the main control unit.

That is, when only the air cleaning unit 80 is operated alone and is operated only in the clean mode, the fan of the air conditioner 80 and the heat exchanger 40 is not driven. In this case, the main controller is not required. In addition, since the heat exchanger 40 should always be turned on in the operation state except the clean single operation mode as described above, it is determined whether the air cleaning unit 10 or the air conditioner 80 is turned on or off in the heat exchanger 40. Primarily detect it. In the operation mode in which the air cleaning unit 10 is turned on, the control unit of the air cleaning unit 10 is the main control unit. When only the air conditioner 80 is turned on, the control unit of the air conditioner 80 is the main control unit. Be sure to In addition, the above-described air flow rate table may be stored in the control unit of the air cleaning unit 10 and the air conditioner 80. Therefore, even if the control unit of any of the air conditioners 80 and the air cleaning unit 10 becomes the main control unit, the air volume control of the fan can be performed.

18 is a block diagram showing the configuration of an air conditioning system according to the spirit of the present invention.

Referring to FIG. 18, the air conditioner system according to the present invention includes an air conditioner including an air cleaning unit 10, a ventilation unit including an electric heat exchanger 40, an air conditioner 80, and the like, as described above. Included. In addition, these devices can input driving conditions through a wireless transceiver including a remote controller 60 or the like.

Of course, each of the devices 10, 40, 80 has a separate input button, that is, an operation unit, so that the user can directly input a driving command.

In detail, the cleaning unit 10 may include a first control unit 101 for controlling driving of the air cleaning unit 10, a signal transmitting and receiving unit 103 for receiving a command signal transmitted from the remote controller 60, and Means the memory 102 and the fan 15, the command signal transmitted from the signal transmitting and receiving unit 103 and information on the operating state transmitted from the air conditioner 80 and / or the heat exchanger 40, etc. are stored. The blower 106 and the drive unit 105 means a fan motor 20 for driving the blower 106. In addition, the signal transmitting and receiving unit 103 is provided with an antenna 104, the signal transmitted from the remote control 60 or the air conditioner 80 and the heat exchanger 40 is received. The received information is stored in the memory 102 connected to the first control unit 101. In addition, the memory 102 stores a wind volume table indicating a fan air volume change value of another apparatus according to the fan air volume change of at least one of the air cleaning unit 10 and the heat exchanger 40 and the air conditioner 80. do.

Here, the wireless communication between the air cleaning unit 10, the heat exchanger 40 and the air conditioner 80 is a short-range wireless communication method is used. That is, as an applicable short range wireless communication method, Infrared Data Association (IrDA), ZigBee, Bluetooth, Wireless LAN, Ultra WideBand (UWB), and RF-ID (Radio Frequency-IDentification) And recently emerging Wireless USB.

The electrothermal exchanger 40 also has a second control unit 401, a memory 402, an antenna 404, a signal transceiver 403, and a driver 405, similar to the air cleaning unit 10. ) And a blower 406.

In addition, the air conditioner 40 also has a third control unit 801, a memory 802, and an antenna 804, similar to the air cleaning unit 10 and the heat exchanger 40. And a driver 805 and a blower 806.

Here, the memory 402 of the heat exchanger 40 and the memory 802 of the air conditioner 80 also store various types of information in the same form as the memory 102 of the air cleaning unit 10. Each of the antennas 104, 404, and 804 transmits and receives various signals by the short range wireless communication method described above.

In addition, although not shown in the block diagram, the air cleaning unit 10, the heat exchanger 40, and the air conditioner 80 are each provided with a key input unit through which a user can directly input operating conditions, and determine an operation signal. An interface is provided. In detail, the interface is provided with an interface used for the operation of the air cleaning unit 10, an interface used for the operation of the heat exchanger 40, and an interface used for the operation of the air conditioner 80, respectively. The interfaces are selectively turned on / off so that a command input by a switch is transmitted to a control unit of a corresponding device.

 When the user inputs an operation command of at least one device through the remote controller 60 or the key input unit as described above, the command is transmitted to the control unit of the corresponding device through the user interface or the signal transceiver. The transmitted command is then temporarily stored in the memory of each device. The control unit of the corresponding apparatus transmits a driving command to each driving unit so that the blower unit is driven.

Meanwhile, a control unit of any one of the devices operated among the respective devices is set as the main control unit, and the operation state of each device according to the air volume change is controlled by the main control unit.

Hereinafter, the process of determining the main control unit in the air conditioning system according to the present invention will be described in detail.

First, a user inputs an operation command of an air conditioning system through the remote controller 60 or an input button (S100). In detail, the user can cause either or both of the air cleaning unit 10 or the air conditioner 80 to be operated.

Then, the controller of the device to which the operation command is input determines the operation of other devices to determine the main controller.

In detail, it is determined whether or not only the clean unit 10 is turned on in the controller of the powered-on device by inputting an operation command (S110). If it is determined that only the clean unit 10 is turned on, the control unit 101 of the clean unit 10 is set as the main control unit (S130). In addition, if only the clean unit 10 is not operated, it is determined whether only the air conditioner 80 is turned on (S120), and if only the air conditioner 80 is turned on, the control unit 801 of the air conditioner 80 becomes the main control unit ( S122). On the other hand, if it is determined that both the clean unit 10 and the air conditioner 80 is turned on, the control unit 101 of the clean unit 10 will be the main control unit (S121). Here, in determining which device is turned on or off by another device, since the devices can communicate with each other by a short range wireless communication method, it is determined whether the devices are turned on or off by transmitting and receiving a signal between the controllers. In addition, the controller of each device may detect whether another device is on or off, and have an algorithm for determining the main controller as one, so that the main controller may be automatically determined when one of the controllers is operated.

In addition, when a driving stop command of one of the devices is input while the air conditioning system is being driven, a program is built in which any one of the other devices being driven becomes the main control unit, and the main control unit changes according to the situation. Of course you can.

On the other hand, when at least the clean unit 10 is turned on, it is determined whether the ventilation and the clean interlocking operation mode or the clean single mode (S140). In addition, in the ventilation clean interlocking operation mode, the heat exchanger 40 is turned on (S150), and in the clean only operation mode while only the air cleaning unit 10 is turned on, the heat exchanger 40 is turned off. maintain.

In addition, only the air conditioner 80 is turned on, or even when the air conditioner 80 and the air cleaning unit 10 are turned on, the heat exchanger 40 is turned on (S150).

In addition, if the air volume command is input by the user after the above process is performed (S160), the fan speed of each device is determined according to the input air flow rate, and is driven by the set fan speed (S170). In operation S180, the main controller detects whether a power-off command is input by a user while the fan is driven at the set air flow rate (S180).

In detail, when the power-off command is input by the user, the driving of the device in which the power-off command is input is stopped (S190), and when the power-off command is not input, the fan continues to be driven at the set air volume. In addition, the main controller continuously detects whether a power off command has been input.

By the above algorithm, the main control unit is determined according to which device the driving command is set, and the main control unit controls the driving of each device.

FIG. 20 is a flowchart for explaining an algorithm made in the main controller when the air volume change command is input in the air conditioner system according to the spirit of the present invention.

Referring to FIG. 20, first, a power on command is input by a user (S200), and the air volume is input (S210).

In detail, when the air volume is input by the user (S210), the fan of the corresponding device is driven according to the input air volume (S220). In operation S230, the main controller detects whether a fan volume change command is input in a state in which the fan of the corresponding device is driven (S230).

On the other hand, if it is determined by the user that the air volume change command of the fan is input by the user, the main controller determines the fan speed of each device according to the changed air volume based on the air volume change table stored in the memory (S240).

In detail, the air volume table stored in the memory is data in which fan air volume values of other devices corresponding to the changed fan air volume are numerically stored when the fan air volume of one device is changed by the user.

For example, when the user inputs a command to change the air volume of the air conditioner 80 to be weaker than the previous air volume, the air volume of the air cleaning unit 10 is increased by the air volume table, and at the same time, the heat exchanger 40 The air supply fan air volume can be maintained as it is. Alternatively, the air flow rate of the air cleaning unit 10 may be maintained as it is and the air flow rate of the heat exchanger 40 may be reduced.

On the contrary, when the user inputs a command to increase the air volume of the air conditioner 80, the main controller increases the air volume of the air supply fan of the heat exchanger 40 based on the data of the air volume table, and the air cleaning unit 10. It is possible to maintain the air flow rate as it is, or to increase the air supply fan air flow rate of the heat exchanger 40 by only a little, and to relatively reduce the air flow rate of the air cleaning unit 10.

Alternatively, when a command for increasing the air volume of the air conditioner 80 is input, when it is determined that ventilation of the indoor air is required by the pollution degree sensor of the air cleaning unit 10, the main controller may be configured based on the air volume table. The fan air volume of the air cleaning unit 10 and the heat exchanger 40 may be increased at the same time.

This air volume table is applied to set the most appropriate fan air flow rate, that is, the fan speed, for each number of cases.

On the other hand, when the air volume change command is input, the fan speed is changed according to the air volume value of the air volume table (S250). Then, in the state in which the fan is driven according to the changed air volume, the main control unit continuously detects whether a wind volume change command is input in real time (S260). If the air volume change command is not input again, the fan is driven at the previous air volume (S261).

Here, the air volume change command of the fan may be made by a user input, but the fan air volume may be automatically changed according to a detection value detected by various sensors built in the air cleaning unit 10 or the air conditioner 80. have. That is, the sensed values detected by the sensors are transmitted to the control unit of each device, and if the control unit of each device determines that the air volume change is necessary, the signal is transmitted to the main control unit.

In detail, when the air volume change command is generated again by the user's command input or the detection sensor value, the main controller first determines whether a power off command of each device is input (S270). When the power off command is input, the driving of the system is stopped. On the other hand, when the power off command is not input, the process of calculating the changed air volume of the fan based on the air volume table (S240) is repeatedly performed.

According to the algorithm described above, when the fan of each device is initially driven according to the set air flow rate, and there is a change in the fan air flow rate of any one device by a user's input of a command or a change in sensor value, the main control unit changes the device. There is an advantage that the fan air volume of the other device can be automatically changed according to the fan air flow rate.

By the air conditioning system and control method thereof according to the present invention having the above configuration, if the air volume of the air cleaning unit or another air conditioner connected thereto is changed, the air volume of the other air conditioner is automatically changed, thereby improving air conditioning efficiency. This has the effect of optimizing and maximizing.

In addition, a plurality of air cleaning units or air conditioners are connected from one heat exchanger, and the purified air is discharged to the plurality of indoor spaces.

In addition, since the air cleaning unit can be interlocked with the total heat exchanger, the temperature difference between the outdoor air introduced into the room and the discharged indoor air is reduced, thereby reducing the cooling or heating loss of the room.

In addition, since the distributor is installed in the heat exchanger, a plurality of air conditioners or air cleaning units are connected to each other, so that purified air is smoothly supplied to each partitioned indoor space or cooling is maintained smoothly.

Claims (15)

A ventilation unit including an electric heat exchanger and an air cleaning unit and an air conditioner for supplying cold or warm air to the room are interrelated with each other and according to an operating condition of at least one of the air cleaning unit and the air conditioner and the ventilation unit. Operating conditions are variable, The control unit of the ventilation unit, the air cleaning unit and the air conditioner may be connected by wire or wirelessly to check driving information of each device in real time and exchange information with each other. When a driving command of at least one device among the connected devices is input, the control unit of any one of the driven devices becomes the main control unit, and the exercise condition of the other device is automatically changed as the driving condition of the one device is changed by the main control unit. Air conditioning system, characterized in that the variable. delete The method of claim 1, If a command to increase or decrease the fan air flow rate of the air conditioner is input, it is determined whether a command to increase or decrease the fan air flow rate of the ventilation unit and the air cleaning unit is input, and the command to increase or decrease the fan air flow rate of the ventilation unit and the air cleaning unit is input. The control unit of the air conditioner is determined as the main control unit, when no input is made, and the operating condition of the ventilation unit and the air cleaning unit is set by the determined main control unit. The method of claim 1, If a command to increase or decrease the fan air flow rate of the air cleaning unit is input, it is determined whether a command to increase or decrease the fan air flow rate of the ventilation unit and the air conditioner is input, and the command to increase or decrease the fan air flow rate of the ventilation unit and the air conditioner is input. If not input, the control unit of the air cleaning unit is determined as the main control unit, the air conditioner system characterized in that the operating conditions of the ventilation unit and the air conditioner is set by the determined main control unit. The method of claim 1, When the ventilation unit is operated, it is determined whether a command to increase or decrease the fan air flow rate of the air cleaning unit and the air conditioner is input, and if the command to increase or decrease the fan air flow rate of the air cleaning unit and the air conditioner is not input, And a control unit of the ventilation unit is determined as a main control unit, and the operation condition of the air cleaning unit and the air conditioner is set by the determined main control unit. delete delete delete delete delete The method of claim 1, The control unit of the air cleaning unit, the ventilation unit and the air conditioner is connected to a memory for storing various information, And said air volume table is stored in said memory so that the changed air volume of the remaining components according to the air volume change of any one of the air cleaning unit, the ventilation unit, and the air conditioner is determined. delete delete delete delete

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