KR101230683B1 - Air-conditioning system - Google Patents

Abstract

The present invention relates to an air conditioning system equipped with a ventilation and air purification function, which is easy to cool and supply power to a control box.

An air conditioning system according to the present invention includes: a cabinet having a plurality of outer surfaces, a service panel shielding the upper surface of the cabinet, a case provided with a front panel and a rear panel forming front and rear surfaces; An exhaust fan provided inside the case and forcing air flow in the indoor space; An exhaust motor provided at one side of the exhaust fan to provide rotational power to the exhaust fan; An air supply fan provided inside the case and forcing an outdoor air flow; An air supply motor provided at one side of the air supply fan to provide rotational power to the air supply fan; An exhaust damper provided at one side of the exhaust fan and configured to change a flow direction of air in order to discharge the air introduced from the inside into the room or to the outside; An exhaust damper motor provided at one side of the exhaust damper to force the operation of the exhaust damper; An air supply damper provided at one side of the air supply fan to allow external air to flow into the case or block the inflow of external air; An air supply damper motor provided at one side of the air supply damper to force the operation of the air supply damper; A control box which is provided with a plurality of electrical components and installed in a flow passage of air forcibly moved by the air supply fan or the exhaust fan; A filter assembly provided at one side of the air supply fan to filter foreign matter from the air; It is provided on one side of the air supply damper, has a configuration including a heater for heating the air introduced from the outside; Air introduced into the room through the air supply fan is characterized in that via the filter assembly.

According to this invention which has such a structure, there exists an advantage that the function of a product improves.

Air Conditioning, Ventilation, Purification, Damper, Heater, Control Box

Description

Air Conditioning System

The present invention relates to an air conditioning system. More particularly, the present invention relates to an air conditioning system having ventilation and air purification functions, and easy cooling and power supply of a control box.

Recently, due to problems such as energy saving measures and noise, human dwelling spaces are increasingly required to be airtight and insulated. However, the air in these closed spaces gradually changes to carbon dioxide and contaminates over time, thereby inhibiting the breathing of life.

Therefore, a place where many people stay in a narrow space, such as an office or a vehicle, should be frequently ventilated. In this case, a ventilation device using a total heat exchange method is usually used. This is for supplying the outside air while maintaining the indoor air temperature, and for exhausting the indoor air.

1 is a perspective view of an exterior of a conventional ventilation device. As shown in the figure, the ventilator 1 is formed by the case 10, the appearance of the rectangular parallelepiped. The case 10 forms the appearance of the entire product, and serves to protect a plurality of components installed therein from foreign objects.

On the rear left side of the case 10, an outside air suction port 11 through which outside air is sucked is installed to protrude rearward. In addition, the outside air suction opening 11 is installed to communicate with a suction hole mounting hole (not shown) drilled on the rear left side of the case 10.

An inner heat exchanger 20 is provided at an inner central portion of the case 10. The pre-heat exchanger (20) is made of a cross-flow plate-type structure to separate the supply and exhaust passage is configured to heat exchange without the air and indoor air mixed with each other.

The rear right side of the case 10 is provided with an indoor air discharge port (reference numeral 12 of FIG. 2) for guiding the indoor air to be discharged to the outside, and the indoor air discharge port 12 is in communication with the inside of the case 10. .

An outside air outlet 13 is provided at the front left side of the case 10. The outside air outlet 13 is installed in communication with the outlet mounting hole 14 perforated on the front left side of the case 10 to guide the outside air discharged through the case 10 to the outside of the ventilator 10. do.

Where the spaced to the right side from the outside air outlet 13 is provided with an indoor air inlet (15). The indoor air inlet 15 guides the indoor air to be introduced into the ventilator 1, and is coupled to communicate with the indoor inlet mounting hole 16 drilled on the front right side of the case 10.

An exhaust fan 30 is installed at the rear side of the total heat exchanger 20. The exhaust fan 30 is a configuration for forcibly blowing the air sucked through the indoor air inlet 15 to the indoor air outlet 12.

Outside the exhaust fan 30 is provided with an exhaust fan housing 32 for guiding the flow direction of the air forced by the exhaust fan 30.

In addition, an air supply fan 40 is installed in front of the heat exchanger 20. The air supply fan 40 allows the outside air to be supplied into the room through the outside air outlet 13. Therefore, the air supply fan housing 42 is provided on the outside of the air supply fan 40 to guide the flow direction of the air forcedly flowed by the air supply fan 40.

The fan motor 50 is provided inside the exhaust fan 30 and the air supply fan 40. The fan motor 50 generates rotational power by the input electricity and supplies the fan motor 50 to the exhaust fan 40 or the air supply fan 50.

The left and right sides of the case 10 is provided with a ceiling fixture (60). The ceiling fixture 60 is configured such that the ventilation device 1 is fixed to the ceiling.

However, the conventional ventilator configured as described above is not possible to switch the mode according to the user's selection, thereby reducing the ease of use. That is, the conventional ventilation device has only a function of simply ventilating by changing indoor air and outdoor air, and has a disadvantage in that it does not have a function of purifying indoor air.

An object of the present invention is to solve the problems of the prior art as described above, it is to provide an air conditioning system configured to pass through the filter assembly all the air flowing into the room to enable air purification as well as ventilation.

Another object of the present invention is to provide an air conditioning system having a heater such that air introduced from the outside has a temperature corresponding to the room temperature.

Another object of the present invention is to facilitate the cooling of the control box, and to simplify the connection of electric wires to supply power to each component.

Air conditioning system according to the present invention for achieving the above object,

A case including a cabinet forming a plurality of outer surfaces, a service panel shielding an upper surface of the cabinet, and a front panel and a rear panel forming front and rear exteriors; An exhaust fan provided inside the case and forcing air flow in the indoor space; An exhaust motor provided at one side of the exhaust fan to provide rotational power to the exhaust fan; An air supply fan provided inside the case and forcing an outdoor air flow; An air supply motor provided at one side of the air supply fan to provide rotational power to the air supply fan; An exhaust damper provided at one side of the exhaust fan to control a flow direction of air introduced from the room; An exhaust damper motor provided at one side of the exhaust damper to force the operation of the exhaust damper; An air supply damper provided at one side of the air supply fan to control a flow direction of air introduced from the outside; An air supply damper motor provided at one side of the air supply damper to force the operation of the air supply damper; A control box provided inside the plurality of front parts, the control box being installed in a flow passage of air forcibly moved by the air supply fan or the exhaust fan; A filter assembly provided at one side of the air supply fan to filter foreign matter from the air; It is provided on one side of the air supply damper, has a configuration including a heater for heating the air introduced from the outside; Air introduced into the room through the air supply fan is characterized in that via the filter assembly.

According to the air conditioning system of the present invention as described above, a number of dampers and filter assemblies are provided, there is an advantage that can utilize a variety of functions in one product. That is, by operating a plurality of dampers, it is possible to ventilate by discharging the indoor air and the outside air flows into the room, and also to allow the indoor air to return to the room again through the filter assembly. The function of purifying is also possible.

In addition, the outside air is introduced to allow ventilation to be made at the same time the indoor air is returned to the room again via the filter assembly. And the air flowing in from the outside is heated by a heater. Thus, according to the present invention, there is an advantage that can maintain the warm state of the room while the air purification and ventilation at the same time. That is, since the air introduced from the outside is heated by the heater, the problem that the room temperature is lowered due to the ventilation function is prevented.

In the present invention, the control box is installed in the flow passage of air, the bottom surface is formed with a plurality of heat radiation fins to increase the contact with the air. Therefore, there is an advantage in that the control box can be easily cooled to prevent malfunction due to high heat of each front part inside the control box.

In the present invention, a wire or a hole for passing through wires is formed in the barrier or the blocking wall so that the wires supplied from the control box to each component pass through the wires. Therefore, the requirement of the wire is reduced and there is an effect that the short circuit of the wire is prevented.

Hereinafter, a configuration of an air conditioning system according to the present invention will be described with reference to the accompanying drawings.
An air conditioning system according to the present invention includes: a cabinet having a plurality of outer surfaces, a service panel shielding an upper surface of the cabinet, a front panel and a rear panel having front and rear surfaces; An exhaust fan provided inside the case and forcing air flow in the indoor space; An exhaust motor provided at one side of the exhaust fan to provide rotational power to the exhaust fan; An air supply fan provided inside the case and forcing an outdoor air flow; An air supply motor provided at one side of the air supply fan to provide rotational power to the air supply fan; An exhaust damper provided at one side of the exhaust fan and configured to change a flow direction of air in order to discharge the air introduced from the room into the room or the outside; An exhaust damper motor provided at one side of the exhaust damper to force the operation of the exhaust damper; An air supply damper provided at one side of the air supply fan to allow external air to flow into the case or block the inflow of external air; An air supply damper motor provided at one side of the air supply damper to force the operation of the air supply damper; A control box which is provided with a plurality of electrical components and installed in a flow passage of air forcibly moved by the air supply fan or the exhaust fan; A filter assembly provided at one side of the air supply fan to filter foreign matter from the air; It is provided on one side of the air supply damper, has a configuration including a heater for heating the air introduced from the outside; Air introduced into the room through the air supply fan is characterized in that via the filter assembly.

3 to 5 show the assembled state of the air conditioning system according to the present invention in a perspective view, Figure 6 and Figure 7 shows an exploded perspective view showing the configuration of a preferred embodiment of the air conditioning system according to the present invention. That is, FIG. 3 is an external perspective view of the air conditioning system according to the present invention. FIG. 4 is a perspective view of the service panel removed from FIG. 3, and FIG. 5 is a filter assembly and a control box of FIG. 4. A perspective view of the state in which is removed is shown. 6 and 7 are exploded perspective views of the present invention as viewed from the front left and front right, respectively, and FIG. 8 is a rear perspective view of the control box constituting the embodiment of the present invention.

As shown in these figures, in the air conditioning system according to the present invention, the overall appearance is formed by the case 100 having a rectangular parallelepiped shape.

And, the ventilation device is inverted and installed in the ceiling of the building in the same state as in Figure 3, the upper surface of Figure 3 becomes the bottom surface when actually installed. Hereinafter, a description of the configuration of the ventilation device will be described based on the direction shown in the drawings.

The case 100 includes a cabinet 110 forming a plurality of outer surfaces, a service panel 120 shielding the upper surface of the cabinet 110, and a front panel 130 and a rear panel forming front and rear surfaces. 140 and the like. That is, the cabinet 110 has a '∪' shape as shown, and forms the outer surface and the left side and the right side appearance. And, the service panel 120 of the square plate is mounted on the upper surface of the cabinet 110.

The front panel and the rear panel of the cabinet 110, the front panel 130 and the rear panel 140 of the rectangular flat shape is mounted to form an appearance, respectively, the front panel 130 and the rear panel 140 is air Inlet and outlet are provided. That is, the front panel 130 has an external inlet 132 through which external air is introduced to protrude forward, and an external outlet 134 for guiding air to be discharged to the outside is provided on the right side of the external inlet 132. It is formed to protrude. In addition, an inner discharge port 142 for guiding air into the interior space is protruded to the rear near the left end of the rear panel 140, and air from the interior space flows in the vicinity of the right end of the rear panel 140. An inner inlet 144 that guides so as to protrude rearward.

Inside the case 100 is provided with a vertical barrier 200 for partitioning the inner space up and down. The upper and lower barriers 200 have a shape in which two rectangular plates are connected to each other, and partition the left rear half and right front half spaces of the case 100 up and down.

The upper and lower barriers 200 is formed of an air supply barrier 210 positioned above the air supply fan 230 to be described below, and an exhaust barrier 220 positioned above the exhaust fan 232 to be described below. The air supply barrier 210 and the exhaust barrier 220 are integrally formed.

On the other hand, the air supply barrier 210 and the exhaust barrier 220 is formed in a substantially square flat shape, the right rear edge of the exhaust barrier 220 has a shape in which a portion is cut. Therefore, the air introduced through the inlet 144 through the cut portion is able to flow.

An air supply hole 212 having a diameter of a predetermined size penetrates up and down in the air supply barrier 210, and an exhaust hole 222 having a size corresponding to the air supply hole 212 is vertically formed in the air exhaust barrier 220. Is formed through.

In addition, an air supply orifice 214 extending downward is formed at an edge of the air supply hole 212, and an air exhaust orifice 224 extended downward is formed at an edge of the exhaust hole 222. The air supply orifice 214 and the exhaust orifice 224 serve to guide the air to the center of the air supply fan 230 and the exhaust fan 232 to be described below.

An air supply fan 230 and an exhaust fan 232 are installed below the upper and lower barriers 200, respectively. In detail, an air supply fan 230 for forcing air to flow into the room is installed below the air supply barrier 210, and an air exhaust fan for forcing air to be discharged to the outside of the air exhaust barrier 220. 232) is installed.

The air supply fan 230 and the exhaust fan 232 are installed in a diagonal direction from the center of the inside of the case 100, as shown. That is, the air supply fan 230 is installed in the left rear half of the case 100, and the exhaust fan 232 is installed in the first half of the right side of the case 100.

The outside of the air supply fan 230 and the exhaust fan 232 is wrapped by the fan housing 240. The fan housing 240 guides the air flowing by the air supply fan 230 and the exhaust fan 232, and the air supply housing 242 and the exhaust fan 232 surrounding the outside of the air supply fan 230. Exhaust housing 244 surrounding the outside of the).

The air supply housing 242 and the exhaust housing 244 are integrally formed as shown. Then, the rear end of the air supply housing 242 and the front end of the exhaust housing 244 are opened to allow air to be discharged to the room or the outside.

A front side of the air supply housing 242 is provided with a square back plate of the air supply rear plate 250, the left side of the exhaust housing 244 is provided with a right side air supply plate 252 of the square plate. The air supply rear plate 250 and the air supply right side plate 252 serve as a barrier for partitioning the space inside the case 100 vertically and horizontally. That is, the air supply rear plate 250 partitions the left space inside and outside the case 100 back and forth, and the air supply right side plate 252 partitions the front half space inside the case 100 from side to side.

In addition, the vertical height of the air supply rear plate 250 has a size smaller than the vertical height of the air supply right side plate 252. Therefore, a predetermined gap is formed between the air supply rear plate 250 and the service panel 120, and through the gap, outside air introduced through the external inlet 132 passes through the air supply fan 230. Inflow.

On the other hand, the air supply rear plate 250 is formed through the heater hole 254 through which the electric wire for supplying power to the heater 280 to be described below. That is, the heater 280 to be described below is provided in front of the air supply rear plate 250, the electric wire for supplying power to the heater 280 passes through the heater hole 254.

The air supply frame 260 is provided at the rear half of the left half of the front panel 130. The air supply frame 260 is formed in a square flat plate shape, the rear end has a slight inclination, is coupled to the upper end of the air supply back plate 250.

In addition, an air supply damper sphere 262 penetrates up and down in the air supply frame 260, and the air supply damper sphere 262 is selectively shielded by the air supply damper 264. The air supply damper 264 is formed of a square flat plate having a shape corresponding to the air supply damper opening 262, and is configured to be rotatable about a rear end thereof.

An air supply damper motor 266 is installed on an upper surface of the rear end of the air supply frame 260. The air supply damper motor 266 is for forcing the rotational flow of the air supply damper 264, and the air supply damper motor 266 and the air supply damper 264 are connected by the air supply connecting unit 268. Therefore, when the air supply damper motor 266 is operated by the power supplied from the outside, the air supply damper motor 266 pushes or pulls the air supply connecting rod 268, so that the air supply damper 264 rotates. The air supply damper opening 262 is opened and closed.

The air supply guide 270 is further provided below the air supply frame 260. The air supply guide 270 guides the air introduced into the case 100 through the external inlet 132 to the air supply damper port 262. Accordingly, the latter half of the air supply guide 270 is formed of an inclined surface that gradually increases toward the rear end.

In addition, a heater 280 is provided below the air supply damper 264. That is, the heater 280 is installed at the rear side of the external inlet 132, and the heater 280 serves to heat the outside air introduced through the external inlet 132.

An air supply motor frame 300 and an exhaust motor frame 310 that support the air supply motor 302 and the exhaust motor 312 to be described below are installed above the upper and lower barriers 200. That is, the air supply motor frame 300 is installed to the left and right across the air supply hole 212, the exhaust motor frame 310 is installed to the left and right across the exhaust hole 222.

In addition, an air supply motor 302 and an exhaust motor 312 are mounted on the air supply motor frame 300 and the exhaust motor frame 310, respectively. The air supply motor 302 and the exhaust motor 312 are supplied with power applied from the outside, and serves to provide rotational power to the air supply fan 230 and the exhaust fan 232.

The filter assembly 320 is provided above the air supply barrier 210. The filter assembly 320 is for filtering foreign substances in the air introduced into the room through the inner discharge port 142, and preferably comprises a plurality of filters. That is, it is preferable that the plasma filter is formed of various filters such as ammonia deodorizing filter or hepa filter which deodorizes cigarette smoke and various odors.

The filter assembly 320 is fixed by the filter frame 322. The filter frame 322 is fastened to the case 100 or the central barrier 330 to be described below, and the filter assembly 320 is detachably seated inside the filter frame 322.

An upper center portion of the upper and lower barriers 200 is provided with a central barrier 330. The central barrier 330 is composed of a rectangular flat plate of a predetermined size, as shown in the figure, and serves to partition the upper and lower barrier 200 upper space to the front right and rear left.

The lower end of the central barrier 330 has a central hole 331 is formed through. The central hole 331 is a hole through which a wire for transmitting power supplied from the control box 370 to other components to be described below passes. That is, a central hole 331 is formed through the central barrier 330 so that an electric wire connected between the control box 370 and the air supply motor 302 to be described below passes.

An exhaust blocking wall 332 is formed at the right end of the central barrier 330. The exhaust blocking wall 332 serves to partition the upper and lower right spaces of the upper and lower barriers 200 forward and backward, and is preferably integrally formed with the central barrier 330.

A blocking hole 333 is formed through the lower left portion of the exhaust blocking wall 332. The blocking hole 333 is a hole through which a wire for transmitting power supplied from the control box 370 to other components, such as the central hole 331, passes through the other parts. That is, a blocking hole 333 is formed through the exhaust blocking wall 332 so that an electric wire connected between the control box 370 and the exhaust motor 312 to be described below passes.

An exhaust frame 340 is formed at a lower rear side of the exhaust blocking wall 332. The exhaust frame 340 supports the exhaust damper 344, which will be described below. A circulation port 342 is formed in the exhaust frame 340 to penetrate up and down. The circulation port 342 has a quadrangular shape, and serves as a passage through which the air introduced through the internal inlet 144 flows upward through the exhaust frame 340.

The circulation port 342 is selectively shielded by the exhaust damper 344. The exhaust damper 344 is formed of a rectangular flat plate corresponding to the shape of the circulation port 342, and is rotatably connected to the first half of the exhaust frame 340. Thus, the exhaust damper 344 is rotated about the tip end.

An exhaust guide 350 is provided below the exhaust frame 340. The exhaust guide 350 guides the air introduced through the internal inlet 144 upwards. Therefore, the exhaust guide 350 is formed to be inclined to gradually lower toward the rear as shown.

Meanwhile, an exhaust port 352 is formed through the exhaust guide 350. The exhaust port 352 is a passage through which the air introduced through the internal inlet 144 flows into the exhaust fan 232, and is selectively shielded by the exhaust damper 344.

An exhaust damper motor 360 is installed on an upper surface of the exhaust frame 340. The exhaust damper motor 360 forces the flow of the exhaust damper 344, and is connected to the exhaust damper 344 by an exhaust connector 362. Accordingly, the exhaust damper motor 360 generates power by the power applied from the outside, and the power is transmitted to the exhaust connecting rod 362 so that the exhaust damper 344 is the circulation port 342 or the exhaust port ( 352) to selectively shield.

In this way, the air supply damper 264 and the exhaust damper 344 are respectively installed in a diagonal direction from the center of the case 100. That is, the air supply damper 264 is installed in the first half of the inside of the case 100, the exhaust damper 344 is installed in the right rear half of the case 100.

The control box 370 is installed in the flow passage of air through which the air introduced through the inner inlet 144 passes. That is, the control box 370 is installed above the exhaust frame 340. The control box 370 is formed of a rectangular cylindrical box in which a plurality of electrical components are embedded, and the control of the air conditioning system is performed by the components embedded in the control box 370.

Looking in more detail, the control box 370 is installed in the flow passage of the air is forced to move by the air supply fan 230 or the exhaust fan 232. That is, the control box 370 is located in front of the inner inlet 144. Therefore, when the exhaust fan 232 is operated to discharge indoor air, indoor air is introduced through the internal inlet 144 and moved to the exhaust fan 232 to be in contact with the control box 370.

In addition, in the purification mode, the indoor air introduced through the internal inlet 144 is introduced back into the room through the internal outlet 142 by the suction force generated by the rotation of the air supply fan 230, and thus, the process The air introduced through the inner inlet 144 is in contact with the control box 370.

In addition, a plurality of heat dissipation fins 372 are formed on the bottom of the control box 370 to increase the contact area with air to promote the release of heat. Therefore, the plurality of heat dissipation fins 372 may serve to cool the control box 370 in contact with the air flowing through the inner inlet 144.

As shown in FIG. 4, the control box 370 has a size smaller than that of the exhaust frame 340. Thus, a predetermined gap is formed between the control box 370 and the filter assembly 320 (see FIG. 4), and the air introduced through the inner inlet 144 through the gap is introduced into the filter assembly 320. ) Can be introduced into.

The control box 370 is installed at one side (front) of the inner inlet 144 through which air flows to facilitate cooling. In addition, a plurality of holes through which electric wires pass are formed in the control box 370.

Specifically, the right side (left side in FIG. 8) of the control box 370 is formed through the power hole 374 for guiding the wires so that external power is applied, that is, the other side of the control box 370 On the left side (the right side in FIG. 8), a wire guide hole 376 for guiding the electric wire is provided through the control box 370 to supply power to other parts.

Therefore, the electric wire coming out through the electric wire guide hole 376 is supplied to the exhaust damper 344 or partially passes through the blocking hole 333 of the exhaust blocking wall 332. Then, the wire passing through the blocking hole 333 is connected to the exhaust motor 312 and the remaining part passes through the central hole 331 formed in the central barrier 330. The wires passing through the central hole 331 are connected to the air supply motor 302 to transfer the power supplied from the control box 370 to the air supply motor 302.

On the other hand, the rear of the control box 370 is provided with a box fixing means 380 to be fixed to the control box 370 is a predetermined distance away from the rear panel 140.

As shown in FIG. 9, the box fixing means 380 is attached to the rear surface of the control box 370 and a support fixed to the rear panel 140 by a screw. And a connection portion 386 connecting the attachment surface 382 and the support surface 384.

The attachment surface 382 is fixed to the control box 370 by welding or the like, but may be separated from the control box 370 to be used for the purpose of tightly fixing the control box 370.

In addition, a fastening hole 388 through which a screw is fastened is formed at a central portion of the support surface 384. Therefore, when a screw is passed through the rear panel 140 and fastened to the fastening hole 388 of the support surface 384, the rear surface of the control box 370 is fixed. The front end of the control box 370 is fastened to the exhaust blocking wall 332 by a screw.

Hereinafter, the operation of the air conditioning system as described above will be described.

The air conditioning system of the present invention as described above is installed upside down on the ceiling of the building as described above. Accordingly, the service panel 120 faces downward, and the external inlet 132 and the external outlet 134 of the front panel 130 communicate with the outside of the building. The inner inlet 144 and the inner outlet 142 of the rear panel 140 are installed to communicate with the indoor space.

10 to 12 illustrate a state in which air flows in the air conditioning system of the present invention having the configuration as described above. That is, FIG. 10 illustrates a ventilation mode state in which typical ventilation is performed according to the embodiment of the present invention, and FIG. 11 illustrates an air purification mode state in which air purification is performed according to the embodiment of the present invention. 12 shows a mixed mode in which ventilation and air purification occur simultaneously.

First, with reference to FIGS. 6, 7 and 10 look at the air flow when the embodiment of the present invention is operated in the ventilation mode.

First, look at the state that the outside air is introduced into the room (see '▶' arrow of Figure 10).

At this time, the air supply damper 264 flows by the air supply damper motor 266 to open the air supply damper opening 262. In addition, the air supply motor 302 is operated by a power source applied from the outside, and the air supply fan 230 rotates. In this case, the air around the air supply fan 230 is forced by the air supply fan 230.

Therefore, the outside air flowing through the external inlet 132 passes through the air supply damper port 262 to the upper side of the air supply frame 260, and then rearwards beyond the upper side of the air supply rear plate 250. Go to. Then, it passes through the filter assembly 320. As such, foreign matter in the air is filtered in the course of passing through the filter assembly 320.

Air passing through the filter assembly 320 is discharged to the rear through the inner discharge port 142 is supplied to the indoor space. By this process, the outside air is introduced into the indoor space.

When the outside air flows into the room as described above, the heater 280 may be operated according to the user's selection. That is, in the case of a cold winter, when the user operates the heater 280, the air introduced through the external inlet 132 is heated, so that relatively high-temperature air enters the room through the internal outlet 142. Inflow.

On the other hand, looking at the process of the indoor air is discharged to the outside (see the '▷' arrow of Figure 10), the exhaust damper motor 360 is operated by the power applied from the outside, the exhaust damper motor 360 The exhaust damper 344 shields the circulation port 342. Thus, the exhaust port 352 of the exhaust guide 350 is opened.

Then, the exhaust motor 312 is operated by the power applied from the outside to rotate the exhaust fan 232, the air flow occurs around the exhaust fan 232 by the rotation of the exhaust fan 232. .

Therefore, the air in the indoor space is introduced into the case 100 through the inner inlet 144, and then moves forward through the exhaust port 352, followed by the upper and lower barrier 200 and the cabinet 110. The upper and lower barriers 200 are moved upwards through the gap between the right sides of the upper side. In this process, the air introduced through the internal inlet 144 is in contact with the heat dissipation fin 372 of the bottom surface of the control box 370, thereby cooling the control box 370.

The air moved upward and downward of the upper and lower barriers 200 flows downward through the exhaust orifice 224, flows into the center of the exhaust fan 232, and is discharged radially and guided by the exhaust housing 244. do. Therefore, it is discharged to the outside (outdoor) through the external discharge port 134.

Next, a state in which air flows in a purification mode in which the indoor air is rotated to purify the indoor air without introducing external air will be described with reference to FIGS. 6, 7, and 11.

In the above purification mode, only the air supply fan 230 is operated and the exhaust fan 232 does not need to be operated. In addition, since the air supply damper 264 shields the air supply damper opening 262, external air inflow does not occur through the external inlet port 132.

In addition, since the exhaust damper 344 shields the exhaust port 352, the circulation port 342 is opened. Therefore, the indoor air introduced into the case 100 through the inner inlet 144 moves upward through the left gap of the control box 370 through the circulation port 342. In this process, the flow air cools the control box 370 while contacting the control box 370, in particular, a heat radiation fin (not shown) formed on the bottom surface of the control box 370.

Then, the suction force of the air supply fan 230 passes through the filter assembly 320 and moves downwards. In this process, foreign substances contained in the indoor air are removed. Therefore, the purified air is introduced into the center of the air supply fan 230 and then guided by the air supply housing 242 and discharged backward through the internal discharge port 142. Air discharged through the inner discharge port 142 as described above is introduced into the indoor space again.

By this process, the indoor air does not leak to the outside, but is purified and then flowed back into the room.

On the other hand, it is also possible to purify the air in the room as described above as well as to allow the outside air to enter the room, the air flow in this mixed mode is shown by the arrow in FIG.

In such a mixing mode, the purification of indoor air and the inflow of external air occur simultaneously, so that in addition to the air flow in the above-described purification mode (see FIG. 11) (see arrow 'in FIG. 12), An inflow (see '▷' arrow in Fig. 12) takes place.

More specifically, in the mixed mode, only the air supply fan 230 is operated and the exhaust fan 232 does not need to be operated.

In addition, since the exhaust damper 344 shields the exhaust port 352, the circulation port 342 is opened. Therefore, the indoor air introduced into the case 100 through the inner inlet 144 moves upward through the left gap of the control box 370 through the circulation port 342.

Then, the suction force of the air supply fan 230 passes through the filter assembly 320 and moves downwards. In this process, foreign substances contained in the indoor air are removed. Therefore, the purified air is introduced into the center of the air supply fan 230 and then guided by the air supply housing 242 and discharged backward through the internal discharge port 142. Air discharged through the inner discharge port 142 as described above is introduced into the indoor space again (see the air flow indicated by '▶' in Figure 12).

On the other hand, in the mixed mode is also introduced to the outside air, the air supply damper 264 flows to the air supply damper motor 266, the air supply damper opening 262 is opened. Then, the air supply motor 302 is operated by a power source applied from the outside, and the air supply fan 230 rotates. In this case, the air around the air supply fan 230 is forced by the air supply fan 230.

Therefore, the outside air flowing through the external inlet 132 passes through the air supply damper port 262 to the upper side of the air supply frame 260, and then rearwards beyond the upper side of the air supply rear plate 250. Go to.

Then, it passes through the filter assembly 320 together with the air introduced through the inlet 144. As such, foreign matter in the air is filtered in the course of passing through the filter assembly 320.

Air passing through the filter assembly 320 is discharged to the rear through the inner discharge port 142 is supplied to the indoor space. By this process, the outside air is introduced into the indoor space and ventilation is performed. In this case, as described above, the user may operate the heater 280 to increase the temperature of the air introduced from the outside.

The scope of the present invention is not limited to the above-described embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the scope of the present invention.

For example, in the above embodiment, the position of each hole through which the wire passes is described as an example, but the position of forming the hole may be changed as necessary.

1 is a perspective view showing the internal configuration of a ventilation apparatus according to the prior art.

Figure 2 is a state diagram showing the state of air flow inside the ventilation apparatus according to the prior art.

Figure 3 is an external perspective view of a preferred embodiment of an air conditioning system according to the present invention.

Figure 4 is a perspective view of the service panel peeled off in the embodiment of the present invention.

5 is a perspective view showing the inside of the embodiment of the present invention.

6 and 7 are exploded perspective view showing a detailed configuration of the embodiment of the present invention.

Figure 8 is a rear perspective view of the control box constituting the embodiment of the present invention.

9 is a perspective view of the box fixing means of the embodiment of the present invention.

10 is a use state diagram schematically showing the air flow when a typical ventilation mode is performed according to an embodiment of the present invention.

11 is a use state diagram schematically showing the air flow when the purification mode is performed according to an embodiment of the present invention.

12 is a use state diagram schematically showing the air flow when the mixed mode is performed according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100.Case 110.Cabinet

120. Service Panel 130. Front Panel

132. External inlet 134. External outlet

140. Rear panel 142. Inside outlet

144. Inlet 200. Upper and Lower Barriers

210. Supply Barrier 220. Exhaust Barrier

230. Supply fan 232. Exhaust fan

240. Fan housing 242. Supply housing

244. Exhaust housing 264. Air supply damper

280. Heater 302. Supply motor

312. Exhaust motor 342. Circulation port

344. Exhaust damper 352. Exhaust vent

370. Control Box 372. Heat Sink Fins

374. Power hole 376. Wire guide hole

380. Box fixing means

Claims (6)

A case including a cabinet forming a plurality of outer surfaces, a service panel shielding an upper surface of the cabinet, and a front panel and a rear panel forming front and rear exteriors; An exhaust fan provided inside the case and forcing air flow in the indoor space; An exhaust motor provided at one side of the exhaust fan to provide rotational power to the exhaust fan; An air supply fan provided inside the case and forcing an outdoor air flow; An air supply motor provided at one side of the air supply fan to provide rotational power to the air supply fan; An exhaust damper provided at one side of the exhaust fan and configured to change a flow direction of air in order to discharge the air introduced from the inside into the room or to the outside; An exhaust damper motor provided at one side of the exhaust damper to force the operation of the exhaust damper; An air supply damper provided at one side of the air supply fan to allow external air to flow into the case or block the inflow of external air; An air supply damper motor provided at one side of the air supply damper to force the operation of the air supply damper; A control box which is provided with a plurality of electrical components and installed in a flow passage of air forcibly moved by the air supply fan or the exhaust fan; A filter assembly provided at one side of the air supply fan to filter foreign matter from the air; It is provided on one side of the air supply damper, has a configuration including a heater for heating the air introduced from the outside; Air introduced into the room through the air supply fan, characterized in that via the filter assembly. According to claim 1, wherein the rear panel, the inner inlet for guiding the air in the indoor space is formed; The control box, the air conditioning system, characterized in that installed on one side of the inlet. The air conditioning system according to claim 2, wherein a plurality of heat dissipation fins are formed on one surface of the control box to increase the contact area with air to promote the release of heat. According to any one of claims 1 to 3, wherein one surface of the control box, a power hole for guiding the wire so that the external power is applied is formed; On the other side of the control box, the air conditioning system characterized in that the wire guide hole for guiding the wire so that power is supplied to the other parts. The method according to any one of claims 1 to 3, On one side of the heater, An air supply housing surrounding the outside of the air supply fan and an air supply rear plate provided in front of the air supply housing to partition the inner left space of the case back and forth; And a heater hole through which the electric wire for supplying power to the heater passes through the air supply rear plate. The method according to any one of claims 1 to 3, Inside the case, An upper and lower barriers for partitioning an inner space up and down, a central barrier provided at an upper center portion of the upper and lower barriers, and an exhaust barrier wall for partitioning back and forth the right and upper spaces of the upper and lower barriers, respectively; And a hole through which the electric wires passing power supplied from the control box to other components pass through the central barrier and the exhaust barrier wall.

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