KR20080084530A - Air conditioner - Google Patents

Abstract

A high speed air conditioner is provided to pass the air through a heat exchanger quickly with excellent heat exchange efficiency by streamlining heat exchange pipes. A high speed air conditioner comprises an air conditioning case, a heat exchanger(200), and blower. The air conditioning case has an outlet, an outdoor air inlet, and an indoor air inlet. The outlet is installed at one side of the case and discharges the cool air indoors. The outdoor air is sucked through the outdoor air inlet. The indoor air inlet is installed adjacent to the outdoor air inlet and takes in the indoor air again. The heat exchanger is installed in the air conditioning case. The blower is located adjacent to the outlet of the air conditioning case, sends the air to the blower through the outdoor air inlet and the indoor air inlet, and then discharges the air through the outlet. The heat exchanger includes a plurality of heat exchange fins(230) and heat exchange pipes(240). The heat exchange fins are arranged at regular intervals, made of thin plates, and provided with corrosion resistant layer and a hydrophilic layer. The heat exchange pipes penetrate the heat exchange fins in zigzag and have an elliptic external surface whose axis is in a line with a flow direction of the air passing the heat exchanger. High temperature heat exchange fluid or low temperature heat exchange fluid flows through the heat exchange fins.

Description

High Speed Air Conditioner {AIR CONDITIONER}

The present invention relates to an air conditioner, and more particularly, to increase the heat exchange efficiency while increasing the air flow rate of the air passing through the heat exchanger, and to reduce the size of the heat exchanger, even if the air flow rate is increased. The present invention relates to an ultra-high speed air conditioner that prevents condensate from entering the room by allowing the condensate to flow along the surface of the heat exchanger without being scattered and to reduce the leakage of condensate and the odor generated by the condensate.

In general, an air conditioner is installed in a room as a part of an air conditioning system for cooling a room, such as a building, and is configured to discharge cold air into a room, as shown in FIG. A discharge port 11 for discharging cold air is formed, and an outdoor air inlet 12 is formed on the other side to allow outdoor air to flow out of the room, and the indoor air re-inlet 13 which re-introduces indoor air adjacent to the outdoor air inlet 12 is formed. Air conditioner case 10, heat exchanger 20 installed inside the air conditioner case 10, and filter 30 installed in front of the heat exchanger 20 to filter foreign matter in the air. And a filter 30 and a heat exchanger 20 which are installed adjacent to the discharge port 11 in the air conditioning case 10 and sequentially pressurize the air through the outside air inlet 12 or the indoor air re-inlet 13. After passing through to discharge to the discharge port (11) It consists of the blower 40 which comprises the air conditioner.

In the outside air inlet 12 and the indoor air re-inlet 13, dampers 12a and 13a are provided, in which an opening amount is changed by a driving motor (not shown) to adjust the amount of air introduced therein.

As illustrated in FIGS. 2 and 3, the heat exchanger 20 includes a cold water inlet 21 through which cold water is introduced and cold water introduced through the cold water inlet flows through the inside of the heat exchanger 20. Cold water outlet 22 through which cold water heat-exchanged with air passing through 20 is discharged is formed.

Here, the cold water flowing into the heat exchanger 20 is cooled in a state in which cooling is possible while passing the supplied water through a refrigerator provided separately.

However, the conventional air conditioner configured as described above has the following problems.

First, the structure of the heat exchanger 20 of the prior art, as shown in Figure 3, a plurality of heat exchange fins 23 made of a thin plate, and through the heat exchange fins 23 in a constant arrangement form, one side and the other side The heat exchanger tube 24 is connected to the cold water inlet 21 and the cold water outlet 22 so as to be in communication with each other, and the cold heat of cold water that is formed on the heat exchanger fin 23 and passes through the heat exchanger tube 24 is heat exchanged. It consists of a plurality of slits 25 protruding so as to exchange more heat with air in the process of being transferred to the fin 23, since the heat exchange tube 24 is made of a garden section with a constant radius, heat exchange in such a structure Increasing the passage wind speed through the air 20 to approximately 6 (m / s), as shown in the test results shown in Figure 9 (a), the blowing resistance due to the air flow increases to increase the pressure rapidly Notice that the pressure loss increases It was.

As described above, the reason why the pressure is increased is that, as shown in Fig. 7 (a), it represents the flow of air generated turbulent flow on the downstream side of the heat exchange tube (24).

As a result of testing the heat transfer coefficient indicating the heat exchange performance as the pressure loss increases, as shown in FIG. 8, the passage wind speed of the air passing through the heat exchanger 20 is increased to 6.0 (m / s). As a result, it was found that the heat transfer coefficient did not exceed approximately 70.

As described above, as a result of testing the wind speed passing through the heat exchanger 20 to 6.0 (m / s) or more, the heat exchange efficiency is increased by increasing the width (W) of the heat exchanger without improving the heat exchange efficiency. ) Although the overall size was increased, it was found that there was a closed end where the noise increased as the wind speed increased, and the closed end where the heat exchanger 20 was enlarged.

Second, in the heat exchanger 20 of the prior art, the condensed water is generated while heat exchanged with the air passing through the cold water flowing into the heat exchanger tube 24, and the condensed water of the air conditioning case 10 in which the heat exchanger 20 is installed. Although discharged to the outside through the condensate discharge pipe (not shown) formed on the lower side, some are scattered as the wind speed of the air forcedly blown by the blower 40 is introduced into the room through the discharge port 11, or into the room Some of the condensed water that has not been introduced remains on the bottom surface of the air conditioning case 10 corresponding to the outlet side of the heat exchanger 20 to cause odors, odors, and the like.

Then, it remains inside the bottom surface and the side of the air conditioning case 10 corresponding to the outlet side of the heat exchanger 20 and is not drained through the normal condensate discharge pipe (not shown) through the gap of the deduction case 10. There was also a leaking lung.

The present invention has been made to solve the above problems, it is possible to reduce the overall size of the heat exchanger while improving the heat exchange efficiency even if the air flow rate of the air passing through the heat exchanger is increased, and the air flow rate of air It is an object of the present invention to provide an ultra-high speed air conditioner that prevents condensate from entering the room by reducing the condensate flows down the surface of the heat exchanger without being scattered even if it is increased. .

The present invention for achieving the above object, the discharge port for discharging the cold air into the room is formed on one side and the outside air inlet is formed to enter the outside air outside the room on the other side is adjacent to the outside air inlet to re-introduce the air in the room An air conditioning case having an indoor air inlet; A heat exchanger installed inside the air conditioning case; In the air conditioner is installed adjacent to the discharge port in the air conditioning case and comprises a blower for pumping the air through the outside air inlet or indoor air re-inlet through the heat exchanger and discharged to the discharge port, the heat exchanger, a predetermined interval Arranged with a, made of a thin plate, a corrosion-resistant layer for preventing corrosion sequentially on the surface, a plurality of heat exchange fins formed with a hydrophilic layer; The heat exchanger is installed in a zigzag arrangement through the heat exchange fins, and a high temperature heat exchange medium or a low temperature heat exchange medium flows, and has an elliptical shape on an outer surface thereof, and has a long axis coinciding with the flow direction of air passing through the heat exchanger. Characterized in that made.

As described above, according to the present invention, it is possible to reduce the overall size of the heat exchanger while improving the heat exchange efficiency even though the air flow rate of the air passing through the heat exchanger is increased, and condensed water is not scattered even if the air flow rate is increased. It can be flowed along the surface of the heat exchanger to prevent condensate from entering the room, and leakage of the condensate and odor generated by the condensate can be reduced.

Figure 4 is a view showing the internal configuration of the air conditioner according to the present invention, Figure 5 is an external perspective view of the heat exchange of the air conditioner applied to Figure 4, Figure 6 is a heat exchanger shown in Figure 5 to the heat exchange fin 7 is a cross-sectional view illustrating a state in which a heat exchanger tube is inserted, and FIG. 7 is a view illustrating a comparison of the air flow through the heat exchanger of the present invention and the prior art, and FIG. 9 is a graph illustrating the test of the heat exchange efficiency according to the present invention, and FIG. 9 is a graph illustrating the pressure relationship according to the air flow wind speed according to the present invention and the prior art, and FIG. 10 is a heat exchange fin of the heat exchanger according to the present invention. It is sectional drawing which shows the condensate scattering prevention means formed in the.

The present invention, the discharge port 111 for discharging the cold air into the room is formed on one side and the outside air inlet 112 is formed on the other side to enter the outside air outside the room is adjacent to the outside air inlet 112 is introduced again to the indoor air An air conditioning case (100) having an indoor air inlet (113) formed therein; A heat exchanger 200 installed inside the air conditioning case 100; A filter 300 installed in front of the heat exchanger 200 to filter foreign substances in the air; It is installed adjacent to the discharge port 111 in the air conditioning case 100 and pressurizes the air through the outside air inlet 112 or the indoor air re-inlet 113 to sequentially pass through the filter 300 and the heat exchanger 200. In the air conditioner including a blower 400 to be discharged to the discharge port 111, by changing and improving the heat exchanger 200 to a new type, even if the number of air blowing stages is increased, the heat exchange efficiency While improving the overall size can be miniaturized, and even if the number of blowing stages increases, the condensate is not scattered but flows along the surface of the heat exchanger to prevent condensate from entering the room.

Here, the air inlet 112 and the indoor air re-inlet 113 is provided with a damper (121) (131) for varying the opening degree of opening by a drive motor (not shown) to adjust the amount of air introduced into the bar. In addition, the dampers 121 and 131 may be manipulated to allow air to be selectively introduced into both the outside air inlet 112 and the indoor air inlet 113.

The heat exchanger 200 according to the present invention includes a heat exchange fin 230 and a heat exchange tube 240.

The heat exchange fins 230 are formed in a thin plate shape, and are arranged at regular intervals, for example, from several to several tens. The material of the heat exchange fin 230 is any one of aluminum and aluminum alloy, copper, copper alloy.

Here, the slit portion 25 is formed on the heat exchange fin 230 so as to be in direct contact with the air blown by the blower 400 to be heat exchanged so that a part of the heat exchange fin 230 protrudes.

The corrosion resistant layer 310 and the hydrophilic layer 320 are sequentially formed on the surface of the heat exchange fin 230 to prevent corrosion.

As a material of the corrosion resistant layer 310, chromate is preferably used, and the corrosion resistant layer 310 serves to prevent corrosion of the heat exchange fin 230 and formation of white powder.

Silica is preferably used as the material of the hydrophilic layer 320. The hydrophilic layer 320 prevents condensation between heat exchange fins 230 due to condensed water and reduces air ventilation resistance. The phenomenon can be expected and the heat exchange efficiency between the heat exchange medium flowing into the heat exchange tube 240 and the air passing through the heat exchanger 200 can be increased.

That is, the hydrophilic layer 320 serves to allow the flow of condensed water to smoothly flow along the heat exchange fins 230 from the top to the bottom of the heat exchanger 200. By smoothly discharging the condensate, microorganisms such as molds and bacteria in the condensate can also be quickly discharged to remove odors such as odors.

In addition, as the hydrophilic layer 320 according to the present invention is formed, condensate is not scattered in the air traveling direction of the heat exchanger 200 even when the air flow rate is increased, and the upper portion of the heat exchanger 200 moves downward. Flow down and drain through condensate drainage, not shown. That is, in the present invention, since the condensed water does not remain on the surface of the heat exchange fin 230 constituting the heat exchanger 200 and is quickly discharged, the heat exchange medium and the heat exchanger 200 that flow into the heat exchange tube 240 are separated. The heat exchange efficiency with the air passing through can be increased.

Meanwhile, as illustrated in FIG. 6, the heat exchange tube 240 is installed in a zigzag arrangement through the heat exchange fin 230. Cold water, which is a low temperature heat exchange medium, flows into the heat exchange tube 240. do.

Here, in FIG. 5, the heat exchange tube 240 is not arranged in a zigzag shape on the heat exchange fin 230 unlike FIG. 6.

The outer surface of the heat exchange tube 240 is made of an elliptical cross-sectional shape, it is made of a heat exchange tube 240 having a long axis corresponding to the flow direction of the air passing through the heat exchanger 200.

By configuring the outer surface shape of the heat exchange tube 240 as an elliptical cross-sectional shape as described above, in the structure of the present invention to increase the passage wind speed of the air passing through the heat exchanger 200 to 6.0 m / s, Figure 9 ( As shown in the test results shown in b), it was found that the blowing resistance caused by the air flow was reduced, so that the pressure was reduced, so that the pressure loss was not large.

As described above, the reason why the pressure loss is reduced is that as shown in FIG. 7 (b), the air flow pattern flows while contacting the entire outer surface without turbulence on the downstream side of the heat exchange tube 240. Because.

 As a result of testing the heat transfer coefficient indicating the heat exchange performance in the configuration of the present invention, as shown in Figure 8, even if the passage wind speed of the air passing through the heat exchanger 200 to 6.0m / s to increase the heat transfer coefficient Is 120, it can be seen that the heat exchange efficiency is increased than the conventional.

Here, the cold water flowing into the heat exchanger 200 is cooled in a state in which cooling is possible while passing the supplied water separately from a freezer to generate cooling air heat exchanged by heat exchange with air.

That is, as can be seen in Figure 7 (a) of the conventional structure, in the heat exchanger tube of the circular cross-section due to the problem that the air flow is in contact with only half of the heat exchanger tube, the dead zone that the vortex occurs in the other half, In the end, increasing the passing wind speed of the heat exchanger does not increase the heat exchange efficiency.

Accordingly, the present invention increases heat exchange efficiency between cold water, which is a heat exchange medium flowing into the heat exchange tube 240, and air passing through the heat exchanger 200, as compared with the related art.

In addition, as a result of testing the heat exchange efficiency according to the air flow wind speed according to the present invention and the prior art, as shown in Figure 8, even if the conventional wind speed is increased to 6m / s, there was a limit to the increase in the heat transfer coefficient, According to the present invention, even if the wind speed is increased to 6 m / s, the increase in the heat transfer coefficient is remarkably improved compared with the conventional art.

Therefore, the present invention can be expected to reduce the size in the heat exchanger width (W) direction while reducing the pressure loss to increase the heat exchange efficiency even if the air flow rate of air is increased, thereby reducing the overall size of the air conditioner can do.

In addition, the present invention allows the condensed water to flow along the surface of the heat exchanger without being scattered by the hydrophilic layer 320 even when the air velocity of air increases, so that the condensed water does not flow into the room. All can be discharged to the discharge pipe.

Therefore, the condensed water does not occur in the interior of the air conditioning case 100 corresponding to the outlet side of the heat exchanger 200 or is discharged to the room in severe cases, and the occurrence of odor such as odor due to condensed water is remarkable. It can be reduced.

On the other hand, the filter 300 of the configuration of the present invention is to be installed in the front of the heat exchanger 200, as viewed in the direction of the air inlet flows through the air inlet, it is the passage speed and pressure loss of commonly used air It is good to adopt and use a high performance filter which does not impair.

1 is a view showing the internal configuration of an air conditioner according to the prior art.

2 is an external perspective view of a heat exchanger constituting an air conditioner applied to FIG. 1.

3 is a cross-sectional view illustrating a state in which a heat exchanger tube is inserted into a heat exchanger fin shown in FIG. 2.

4 is a view showing the internal configuration of an air conditioner according to the present invention.

5 is an external perspective view of a heat exchanger of the air conditioner applied to FIG. 4.

6 is a cross-sectional view illustrating a state in which a heat exchanger tube is inserted into a heat exchanger fin shown in FIG. 5.

FIG. 7 shows a comparison of air flow through a heat exchanger of the present invention and prior art. FIG.

Figure 8 is a graph showing the heat exchange efficiency of the heat exchanger according to the present invention and the prior art by testing the heat exchange efficiency.

9 is a graph showing a test of the pressure relationship according to the air flow wind speed of the heat exchanger of the present invention and the prior art.

10 is a cross-sectional view showing the condensate splashing prevention means formed on the heat exchange fin of the heat exchanger according to the present invention.

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

100: air conditioning case

111: discharge port

112: outside air inlet

113: indoor air re-inlet

200: heat exchanger

230: heat exchange fins

240: heat exchanger tube

310: corrosion resistant layer

320: hydrophilic layer

300: filter

400: blower

Claims (5)

A discharge port 111 for discharging cold air into the room is formed at one side, and an outside air inlet 112 is formed at the outside to enter the outside air. An air conditioning case 100 having an inlet 113 formed therein; A heat exchanger 200 installed inside the air conditioning case 100; It is installed adjacent to the discharge port 111 in the air conditioning case 100 and pressurizes the air through the outside air inlet 112 or the indoor air re-inlet 113 to pass through the heat exchanger 200 to the discharge port 111. In the air conditioner comprising a blower 400 to be discharged, The heat exchanger 200, Arranged at regular intervals, made of a thin plate, a plurality of heat exchange fins 230, the corrosion-resistant layer 310 and the hydrophilic layer 320 is formed on the surface sequentially to prevent corrosion; A zigzag arrangement is installed through the heat exchange fins 230, and a high temperature heat exchange medium or a low temperature heat exchange medium flows, and an outer surface is formed in an elliptical shape, and coincides with a flow direction of air passing through the heat exchanger 200. Ultra-high speed air conditioner, characterized in that consisting of a heat exchanger tube 240 having a long axis. The method of claim 1, Ultra-high speed air conditioner, characterized in that the material of the corrosion-resistant layer (310). The method according to claim 1 or 2, Ultra-high speed air conditioner, characterized in that the material of the hydrophilic layer 320 is silica (silica). The method of claim 1, The heat exchange fin 230 is made of aluminum, aluminum alloy, copper, copper alloy for ultra-high speed, characterized in that any one of the copper alloy. The method of claim 1, Ultra-high speed air conditioner, characterized in that the maximum wind speed of the air passing through the heat exchanger 200 is 6 m / s.

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