KR20100046820A - A duck and a heat exchanging system for air conditioner having the same - Google Patents

Abstract

PURPOSE: An indoor purpose heat exchange system of an exhaust duct and an air-conditioner having the same are provided to increase the efficiency of the heat exchange system by preventing the air inhaled for the heat exchange and output air from being mixed. CONSTITUTION: An indoor purpose heat exchange system of an exhaust duct comprises a case(10), a heat exchange unit(20), an air circulation unit(30), a compressor(60), a switching unit, controller, and an exhaust duct. The case comprises an air inlet and an air outlet. The heat exchange unit is installed on an air movement path between the air outlet and the air inlet. The compressor is arranged between the air inlet and air circulation unit. The switching unit automatically opens and closes the window corresponding to the air inlet and air outlet when the case is installed in the building inside.

Description

A heat exchanging system for air conditioner having the same}

The present invention relates to an indoor heat exchange system, and more particularly, an exhaust duct that can be installed inside a building and guides air discharged to the outside by circulating external air, and an indoor heat exchanger having heat exchanger having the same. It is about the system.

An air conditioner including both an air conditioner or a heater may be classified into an integrated type and a separate type depending on whether the indoor unit and the outdoor unit are coupled.

For example, in the case of an air conditioner, a separate type is an indoor unit that is installed indoors to cool the room, and is connected to the indoor unit and a refrigerant pipe, and is installed outdoors to contact the air, and uses external air to condense heat exchange with the refrigerant gas in a condenser (heat exchange unit). After the condensed refrigerant may be divided into an outdoor unit for supplying the refrigerant through the refrigerant pipe to the evaporator of the indoor unit.

1 is a schematic diagram illustrating a conventional outdoor unit. Referring to FIG. 1, a conventional outdoor unit is installed outdoors, and an air inlet 1a is formed at the rear of the case 1, and an air outlet 1b is formed at the front thereof. The condenser 2 is installed inside the case 1, and the blower fan 3 is installed in front of the condenser 2.

According to the said structure, since the blowing fan 3 and the condenser 2 are arrange | positioned back and forth in the horizontal direction mutually, there exists a limit in reducing front-back width (thickness).

In addition, the conventional outdoor unit having the above-described configuration introduces external air through the air inlet port 1a of the rear side, and heat exchanged air is discharged through the air outlet port 1b of the front side, so that it is practically impossible to install indoors. do.

On the other hand, in recent years, regulations on the installation of facilities outside each building have been strengthened, and therefore, it is difficult to install an outdoor unit of an air conditioner outside the building. Therefore, the development of an indoor heat exchanger that can be installed indoors and occupy a small space is urgently needed.

In addition, the conventional outdoor unit as described above is designed to be installed on the outside of the building, but in recent years, it is practically impossible to install the outdoor unit on the outer wall in a building such as a building, an officetel, or a studio, so that the indoor outdoor unit can be installed indoors. Development is urgent.

The present invention has been made in view of the above, and provides an exhaust heat duct for guiding the heat exchanged air inside the building to be discharged to the outside and an air conditioner for an indoor air conditioner having the same and installed inside the building. The purpose is.

An exhaust duct for an indoor heat exchange system of an air conditioner of the present invention for achieving the above object comprises a case having an air inlet and an air outlet; A heat exchange unit installed on the air movement path between the air inlet and the air outlet in the case; An air circulation unit installed between the heat exchange unit and the air discharge port to force air circulation; A compressor installed inside the case so as to be disposed between the air inlet and the air circulation unit; Opening and closing unit for automatically opening and closing the window corresponding to the air inlet and air outlet when the case is installed in the building; A control unit controlling driving of the air circulation unit and the opening / closing unit; And an exhaust duct installed to be interlocked with the window to guide the heat exchanged air from the discharge port through the sliding window and formed of a flexible material.

The apparatus may further include an opening / closing sensor for detecting an open / closed state of the window, and the controller may control driving and stopping of the pusher and the air circulation unit based on the information detected by the opening / closing sensor. Do.

In addition, the exhaust duct is formed of a flexible material, one end is connected to the window frame and the other end is connected to the lower end of the window; It is connected to each of both sides of the upper surface, the lower end is connected to the lower portion of the window frame; preferably comprises a.

In addition, the exhaust duct is formed of a flexible material, both ends of the duct body is open; A coupling part provided at one end of the duct body and coupled to a discharge port of the case; A first connection member connected to the upper end of the other end of the duct body and connected to the window; And a second connection member connected to the lower end of the other end of the duct body and connected to the window frame.

According to the exhaust duct for the indoor heat exchange system of the air conditioner of the present invention, installed in conjunction with the sliding window of the building, the heat exchanged exhaust air discharged from the heat exchange system installed inside the building so as not to mix with the suction air You can guide. Therefore, there is an advantage that can be installed without damaging the existing windows or building walls.

In particular, by guiding the air heat exchanged by the exhaust duct to the end of the sliding window, it is possible to increase the efficiency of the heat exchange system by preventing the intake air and the discharge air to be mixed for heat exchange.

In addition, since the exhaust duct is formed of a flexible material that can be deformed, the window can be closed while the air conditioner is not in operation.

In addition, by installing a crossflow fan inside the case it can be effectively forced circulation by drawing air from the outside of the building in the installed state.

In addition, by having the configuration to automatically open and close the window in conjunction with the operation and stop operation of the heat exchanger, it is possible to use more easily and efficiently.

Hereinafter, an indoor exhaust duct of an air conditioner and a heat exchange system having the same will be described in detail with reference to the accompanying drawings.

2 to 5, an indoor heat exchange system of an air conditioner according to an embodiment of the present invention includes a case 10 having an air inlet 11 and an air outlet 12 on the same surface (front surface 10a). And a heat exchange unit 20 installed on the air movement path between the air inlet 11 and the air outlet 12 in the case 10, the heat exchange unit 20, and the air outlet 12. It is provided with an air circulation unit 30 installed between, the opening and closing unit 210 for automatically opening and closing the window 110, the control unit 220 for controlling the driving of the opening and closing unit 210 and the exhaust duct 230 is provided. do.

The case 10 is formed in a substantially quadrangular box shape, and the front surface 10a is installed to face the window 110 of the building 100, that is, toward the outside as shown in FIG. 3. Here, the window 110 will be described taking the case of a sliding window as an example. In the case of the sliding window 110, the upper end is typically rotatably connected to the window frame 120, a handle (not shown) is provided at the lower end may have a structure that can be opened by pushing out of the building 100. .

An air inlet 11 for introducing air from the outside for heat exchange to the same surface of the case 10, that is, the front surface 10a, and hot air heat-exchanged with the heat exchange unit 20 inside the case 10. An air discharge port 12 for discharging to the outside is formed. Here, preferably, the air outlet 12 is formed at the center portion of the front surface 10a of the case 10, and the air inlet 11 has a pair of the case 10 symmetrically with each other with the air outlet 12 interposed therebetween. It is formed on both sides of the front surface 10a.

In addition, the case 10 may be formed of a metal material, and a color panel 15 (see FIG. 4) may be attached to the rear surface 10b, that is, the rear surface 10b facing toward the interior.

The heat exchange unit 20 is preferably provided with a pair, it is disposed between the air inlet 11 and the air circulation unit 30, respectively. The heat exchange unit 20 is a configuration including a plurality of heat exchange fins and heat exchange pipes (not shown), and has a configuration widely used in the outdoor unit of the air conditioner, and the detailed configuration is omitted since the configuration does not limit the present invention. do.

In addition, the heat exchange unit 20 is disposed up and down inside the case 10, it is disposed to be inclined at a predetermined angle, it is possible to increase the contact area with air as much as possible, the outside air introduced into the air inlet (11) It is possible to increase the efficiency of heat exchange while passing through.

The air circulation unit 30 is for forcibly circulating the air outside the building 100 to the inside of the case 10 installed in the room to be heat exchanged and then discharged to the outside again. The air circulation unit 30 includes a crossflow fan 31 installed inside the case 10 and an internal duct guiding air discharged by the crossflow fan 31 to the air discharge port 12. 33 is provided.

The crossflow fan 31 is preferably a pair of up and down side by side, providing an air suction force through the suction portion 31a of both ends facing the heat exchange unit 20, the fan blades 31b on the outer peripheral surface It has a structure to discharge the air sucked through.

Accordingly, the air suction force is provided in the axial direction at the suction portions 31a at both ends of the crossflow fan 31, and the earth output is provided in the circumferential direction. The cloth flow fan 31 is driven and stopped by the control signal of the controller 220. That is, the controller 220 controls the crossflow fan 31 to be driven when a switching on signal is generated by the switching unit 200 in the room, and when the switching off signal is generated by the switching unit 200, the crossflow fan 31. ) Is stopped.

The inner duct 33 is installed to surround the outer circumferential side of the fan 31, and is installed to guide the heat exchanged air introduced through the suction part 31a to the air discharge port 12. Therefore, the air heat-treated in the case 10 can be discharged only to the air outlet 12 by the inner duct 33.

In addition, the sound absorbing material 17 is preferably installed inside the case 10 to block noise generated when the crossflow fan 31 and the like are driven. The sound absorbing material 17 may include a sponge, urethane, or the like.

In addition, as shown in FIG. 4, since the window 110 of the building 100 is a sliding window, the discharge air of the air discharge port 12 is not mixed with the external suction air introduced into the air inlet 11. In order to do this, the exhaust duct 230 is preferably installed further. The exhaust duct 230 has an upper surface 231 and both side surfaces 232 provided on both sides of the upper surface 231, respectively.

Coupling portions 233 and 234 are provided at each of the front and rear sides of the upper surface 231. As shown in FIG. 4, the coupling part 233 is coupled to the upper side of the window frame 120, and the opposite coupling part 234 is coupled to the lower end 111 of the window 110. The coupling parts 233 and 234 may be coupled by an adhesive or may be coupled by separate fastening members.

In addition, coupling portions 235 are also formed at corner portions of both side surfaces 232. The coupling part 235 is coupled to the lower portion of the window frame 120.

The exhaust duct 230 having the above configuration is installed in the window frame 120 and the window frame 110 so as to correspond to the outlet 12. When the window 110 is closed, the exhaust duct 230 is deformed flexibly to the interior side together with the window 110. It is preferable that the flexible material be collected, for example, from a material such as cloth or synthetic fiber.

Accordingly, the discharged air is guided to the upper portion of the sliding window 110 by the exhaust duct 230 and discharged by the exhaust duct 230, so that the outside air flows through both side portions A of the inner side of the sliding window 110. It does not mix with.

In the state where the exhaust duct 230 is previously installed in the window frame 120 and the window 110 as described above, the case 10 may be installed indoors, so that the installation is easy.

In addition, when the air conditioner is not used, the window 110 may be closed. In this case, since the exhaust duct 230 is a flexible material, the window 110 may be closed while being deformed without removing the exhaust duct 230. Operation is possible.

In addition, preferably, the compressor 50 may be installed in the case 10. Since the compressor 50 is disposed at a position corresponding to the air inlet 11, the compressor 50 can be effectively cooled by the air introduced therein.

According to the above configuration, by forming both the air inlet 11 and the air discharge port 12 on the same front surface (10a) of the case 10, it is opened without removing the sliding window 110 in the interior of the building 100 It is possible to install so as to communicate with the outside of the building 100 in the state, thereby circulating the outside air to the case 100 of the interior. The case 100 may be installed to be placed on a separate support member 50 installed on the wall as shown in FIG. 4 so as to correspond to the window height. The support member 50 may be installed on the inner wall surface by a screw or the like. In addition, when the building 100 has a central heating system, it is natural that the case 100 may be placed on the heating discharge unit (not shown) provided by the window.

In addition, the sliding window 110 is automatically opened by the opening and closing unit 210 can be closed. An example of the opening and closing unit 210 may be a cylinder unit having a piston part 211 and a cylinder part 212. One end of the piston portion 211 is rotatably connected to the sliding window 110, the cylinder portion 212 may be rotatably connected to the case 10, or may be separately rotatable to the building 100. have. The driving of the opening and closing unit 210 is controlled by the controller 220.

Therefore, like the crossflow fan 31, the opening / closing unit 210 is driven to open the window 110 by the control signal of the control unit 220 when the switching on signal is generated from the switching unit 200. . When the switching-off signal is generated by the switching unit 200, the control unit 220 drives the opening / closing unit 210 to drive the sliding window 110 to be closed, thereby interlocking with the air conditioner, the sliding window 110. It can be opened and closed automatically.

In addition, as shown in Figure 4, the heat exchange system according to an embodiment of the present invention, it is preferable to further include a detection sensor 230 for detecting whether the sliding window 110 is opened or closed. The detection sensor 230 may be installed in the window frame or the case 10, and may be a touch sensor or a touch switch that generates a detection signal when the sliding window 110 contacts the sliding window 110 in a position where the sliding window 110 is closed. The detection information about whether the sliding window 110 is opened or closed by the detection sensor 230 is transmitted to the controller 220.

The controller 220 applies driving and stop signals of the compressor 60 and the crossflow fan 31 based on the information detected by the detection sensor 230. That is, when the switching on signal is applied from the switching unit 200, the control unit 220 first drives the opening and closing unit 210 to open the sliding window 110. When the sliding window 110 is opened, the sensor 230 detects the opening of the sliding window 110 and applies the detection signal to the controller 220. Then, the control unit 220 applies the drive signal of the compressor 60 and the crossflow fan 31 after confirming the open detection signal of the sliding window 110. Therefore, when the sliding window 110 is not opened due to a failure of the opening / closing unit 210, the heat exchange system is not driven, thereby ensuring safety.

In addition, when a switching off signal is applied from the switching unit 200, the controller 220 first stops driving the compressor 60, the crossflow fan 31, and the like, and then controls the opening / closing unit 210. The sliding window 110 is to be closed. As such, the sliding window 110 is automatically opened and closed, and driving control is performed with a time signal and a time difference of the heat exchange system, thereby ensuring convenient safety and using the heat exchange system.

6 to 8, in the case of a heat exchange system according to another exemplary embodiment of the present invention, the heat exchange system is formed of a flexible material and is installed at the outlet 12 of the case 10 to interlock with the window 110. It is characterized by having an exhaust duct 240 that is expanded and folded.

The body 241 of the exhaust duct 240 has a structure in which both ends are open as predetermined lengths, and one end thereof is positioned to correspond to the discharge port 12 and is coupled to the front surface of the case 10. The coupling part 242 may be provided at one end of the body 141 of the 240.

The coupling part 242 may be coupled by an adhesive or the like, or may be coupled by a screw or the like.

In addition, a first connection member 243 and a second connection member 244 are provided at the outlet side of the body 241. The first connection member 243 is a connection string connecting the outlet side of the body 241 and the window 110, and the second connection member 244 is the bottom of the outlet side and the window frame 120 of the body 241. It is a connecting string for connecting the lower part. According to the above configuration, when the window 110 is opened while the exhaust duct 240 is connected to each of the window 110 and the window frame 120 using the first and second connection members 243 and 244, the window 110 is illustrated. As shown, the exhaust duct 240 is unfolded so that the hot air heat exchanged through the exhaust duct 240 can be discharged through the window 110.

When the window 110 is closed, since the exhaust duct 240 is formed of a flexible material, the window 110 can be closed without removing the exhaust duct 240.

1 is a view showing a heat exchange system of a conventional air conditioner.

Figure 2 is a perspective view showing an indoor heat exchange system of the air conditioner according to the embodiment of the present invention.

3 is a cross-sectional view showing a state in which the heat exchange system shown in FIG. 2 is installed indoors.

4 is a cross-sectional view showing the heat exchange system shown in FIG.

5 to 8 is a view showing an indoor heat exchange system of the air conditioner according to another embodiment of the present invention

<Description of Symbols for Main Parts of Drawings>

10. Case 11. Air inlet

12. Air outlet 20. Heat exchange unit

30. Air circulation unit 31, 32. Crossflow fan

33..Inside duct 40..Outside duct

50. Support member 51, 53. First and second guide members

60. Compressor 70. Suction duct

100..Building 110..Window

200. Switching unit 210. Opening and closing unit

220. Control part 230. Detection sensor

Claims (4)

A case having an air inlet and an air outlet; A heat exchange unit installed on the air movement path between the air inlet and the air outlet in the case; An air circulation unit installed between the heat exchange unit and the air discharge port to force air circulation; A compressor installed inside the case so as to be disposed between the air inlet and the air circulation unit; Opening and closing unit for automatically opening and closing the window corresponding to the air inlet and air outlet when the case is installed in the building; A control unit controlling driving of the air circulation unit and the opening / closing unit; And an exhaust duct installed to be interlocked with the window so as to guide the heat exchanged air from the discharge port through the sliding window, and formed of a flexible material. The method of claim 1, Further comprising an opening and closing detection sensor for detecting the opening and closing state of the window, The control unit is a heat exchange system of the air conditioner, characterized in that for controlling the driving and stop of the pusher and the air circulation unit based on the information detected by the open and close detection sensor. The method of claim 1, wherein the exhaust duct, Is formed of a flexible material, one end is connected to the window frame and the other end is connected to the bottom of the window; And a side portion connected to each of both sides of the upper surface and having a lower end connected to a lower portion of the window frame. The method of claim 1, wherein the exhaust duct, A duct body formed of a flexible material and having both ends open; A coupling part provided at one end of the duct body and coupled to a discharge port of the case; A first connection member connected to the upper end of the other end of the duct body and connected to the window; And And a second connection member connected to the lower end of the other end of the duct body and connected to the window frame.

Images