KR20020009841A - Shroud structure for airconditioner - Google Patents

Abstract

PURPOSE: Shroud structure of an integrally assembled air conditioner is provided to prevent condensate water from draining by mounting a cutoff wall between a fan and a condenser, and to improve heat exchange efficiency of the condenser by enlarging the area of heat exchange between air and the condenser. CONSTITUTION: A shroud system of an integrally assembled air conditioner is composed of a shroud(2) guiding air from a fan(7) to a condenser(6), and a cutoff wall(22) installed between the fan and the condenser to shut off condensate water and pass air to the condenser. Condensate water is collected in a base pan with colliding into the cutoff wall and a guide surface, and air from the fan is streamed to the condenser with moving along the guide surface. An air through hole is formed in the cutoff wall, and the guide surface is inclined and integrally formed in the upper end of the air through hole. The performance of the condenser is improved with preventing condensate water from being discharged. Condensate water is prevented from being discharged with installing the cutoff wall between the fan and the condenser, and air is moved into the condenser along the guide surface. Heat exchange efficiency is improved with enlarging the area of heat exchange between air and the condenser.

Description

Shroud structure for air conditioner

The present invention relates to an integrated air conditioner, and more particularly, to a shroud structure of an integrated air conditioner that can improve the heat exchange efficiency of the condenser by changing the structure of the shroud of the integrated air conditioner.

1 shows the internal configuration of an integrated air conditioner, generally called a window type. As shown in the figure, an evaporator 1 is installed on the indoor side of the air conditioner. Inside the evaporator 1, a blower 3 for sucking air exchanged with the evaporator 1 is installed. The blower 3 is provided inside the air guide 4. The air guide 4 forms a flow path of cold air formed by the blower 3. On the right side of the blower 3, a discharge part 5 is formed which is sucked by the blower 3 and heat-exchanges through the evaporator 1 to discharge the air having a relatively low temperature back into the room.

And the condenser 6 is installed in the outdoor side of an air conditioner. In addition, a fan 7 for sucking outdoor air and delivering it to the condenser 6 is installed inside the condenser 6. A motor 8 for driving the fan 7 and the blower 3 is installed between the blower 3 and the fan 7. In addition, the ring-shaped fan ringer 13 is installed so that the circumferential end of the fan 7 is connected. In addition, a compressor 9 for compressing the refrigerant in the refrigeration cycle is installed next to the motor 8 on the outdoor side. In order to distinguish the indoor side where the evaporator 1 and the blower 3 are installed and the outdoor side where the condenser 6, the motor 8, the compressor 6, etc. are installed, the barrier 10 is provided with an air conditioner. Installed across.

An air conditioner having such a configuration can perform cooling and heating. In the case of cooling, a refrigeration cycle comprising components such as an evaporator 1, a compressor 9, a condenser 6, and a capillary tube (not shown) As it proceeds, the blower 3 and the fan 7 are rotated by the motor 8 and operated. That is, the air in the room sucked in the direction of arrow A of FIG. 1 while the blower 3 is operated is heat exchanged in the evaporator 1 to a relatively low temperature, and is guided to the discharge port 5 by the blower 3. As indicated by arrow B, it is discharged back into the room.

Then, the air sucked into the air conditioner as indicated by the arrow D by the drive of the fan 7 is heat-exchanged while passing through the condenser 6 and discharged to the outside as indicated by the arrow E again.

2 shows a shroud structure of an integrated air conditioner. According to this, the fan 7 is installed between the shroud 11 and the condenser 6, and the shroud 11 having the fan 7 installed therein condenses the air sucked in the direction of arrow D. (6) to the side. And the air heat-exchanged with the condenser 6 is discharged in the direction of the arrow E. In general, the condensed water generated during heat exchange in the evaporator 1 and the condenser 6 flows to the base pan 12 to be collected.

However, the following problems are pointed out in such a conventional integrated air conditioner.

Looking at the structure of the condenser 6 is a bent portion 14 is formed so that the left portion is refracted on the basis of Figure 2, the side portion 15 of the shroud 11 is the bent portion of the condenser 6 ( 14). In general, the condensed water collected in the base pan 12 is scattered by the fan ringer 13 to cool the condenser 6, in which the side portion 15 is formed to prevent condensate from splashing out of the product. .

The disadvantage is that the heat efficiency of the condenser 6 is reduced due to such a structure. In detail, the air introduced from the fan 7 and the condenser 6 exchange heat, and the shroud in part A of FIG. The side portion 15 of the (11) surrounds the bent portion 14 of the condenser 6, so that the air sucked in the fan (7) is not discharged to the outside after heat exchange with the condenser (6). As a result, the hot air heat exchanged in the portion A of FIG. 2 is stagnant, and heat exchange does not occur smoothly.

Such a phenomenon does not have a great influence when the integrated air conditioner is used for a short time, but provides a cause of deterioration of the performance of the integrated air conditioner when used for a long time.

Accordingly, an object of the present invention is to solve the conventional problems as described above to improve the structure of the shroud surrounding the condenser to provide a shroud structure of the integrated air conditioner that can efficiently perform heat exchange of the condenser. It is.

1 is a perspective view showing the configuration of a general integrated air conditioner.

Figure 2 is a plan view showing the structure of the shroud and the condenser of the conventional integrated air conditioner.

3 is a plan view showing a preferred embodiment of the shroud structure of the integrated air conditioner according to the present invention.

4 is a perspective view showing the structure of part B of FIG.

5 is a perspective view showing a modified structure of the portion B of FIG.

Explanation of symbols on the main parts of the drawings

20: shroud 22: barrier

24, 28: air passage 26, 30: guide surface

The shroud structure of the integrated air conditioner according to the present invention for achieving the above object comprises a shroud for guiding the air introduced from the fan to the condenser side; It is installed between the centrifugal direction of the fan and the condenser, and includes a blocking wall for blocking condensate and passing air to the condenser side.

The blocking wall is provided with a plurality of air passing holes on one surface thereof, and one side of the air ventilation holes is provided with a guide surface for guiding air to the condenser side.

The condensate scattered by the fan ringer by this configuration hits the blocking wall and the guide surface and accumulates in the base pan, and the air moves along the guide surface and flows into the condenser to exchange heat with the condenser, thereby increasing the efficiency of the condenser. .

A preferred embodiment of the shroud structure of the integrated air conditioner according to the present invention as described above will be described in detail with reference to the accompanying drawings. The same as the prior art will be described using the same reference numerals.

3 is a plan view of the outdoor side of the integrated air conditioner according to the present invention. As shown in FIG. 2, the shroud 20 surrounding the condenser 6 is shortened in the portion A of FIG. 2 to fix the condenser 6. In addition, in FIG. 3, a blocking wall 22 may be installed between the centrifugal direction of the fan 7 and the condenser 6 to prevent the condensate 6 from being discharged out of the product.

4 is a perspective view of a blocking wall 22 according to the present invention. As shown in the drawing, the blocking wall 22 has a rectangular plate shape, and a plurality of rectangular air passing holes 24 are formed on the surface of the blocking wall 22, and the air passing holes are based on a flow direction of air. The guide surface 26 is integrally formed in the upper end of the 24 inclined downward.

The function of the shroud 20 structure of the integrated air conditioner according to the present invention configured as described above will be described.

In general, the air conditioner heat exchange occurs in the evaporator (1) and the condenser (6), the condensate generated in the process is moved along the flow path (not shown) is collected in the base fan 12. The condensed water accumulated in the base pan 12 is scattered by the fan ringer 13 while the fan 7 is operated to hit the blocking wall 22 together with the air. An air through hole 24 is formed in the blocking wall 22, and the guide surface 26 is integrally formed to be inclined downward on the upper end of the air through hole 24. When the fan 7 is operated, a part of the condensate hits the blocking wall 22 and is collected in the base fan 12, and a part of the condensate falls into the base fan 12 while hitting the guide surface 26. That is, the condensed water scattered by the fan ringer 13 is collected in the base fan 12 while hitting the blocking wall 22 and the guide surface 26. Therefore, it is possible to prevent the discharge of condensate out of the product.

However, the air sucked by the fan 7 passes through the air passage hole 24 formed in the blocking wall 22 and flows into the condenser 6 to be heat-exchanged with the condenser 6 and then discharged to the outside. .

The air through hole 24 formed in the barrier wall 22 may be molded in various forms. In FIG. 5, the structure of the modified air through hole 28 is illustrated. As shown in the drawing, a rectangular air passing hole 28 is vertically formed on one surface of the blocking wall 22 provided between the centrifugal direction of the fan 7 and the condenser 6, and the air passing hole ( The guide surface 30 is molded integrally with the right end of 28). The guide surface 30 is formed to be inclined leftward in a direction in which air flows based on the right side of the air passage hole 28.

Even when the condensed water is prevented from being discharged out of the product even in the above structure, heat exchange can also occur on one side of the condenser 6 which has not been heat exchanged in the past.

In the present invention as described above, the blocking wall 22 is installed between the centrifugal direction of the fan 7 and the condenser 6 to prevent condensate from being discharged to the outside because it does not pass through the blocking wall 22, and only air is provided. It is a basic technical idea that heat exchange occurs in the condenser 6 by flowing into the condenser 6 along the guide surface 30.

Within the scope of the basic technical idea of the present invention, of course, many other modifications are possible to those skilled in the art.

The shroud structure of the integrated air conditioner according to the present invention as described in detail above is provided with a blocking wall between the centrifugal direction of the fan and the condenser to increase the heat exchange area between the air and the condenser while preventing condensate from being discharged out of the product. The effect of increasing the heat exchange efficiency of can be obtained.

Claims (2)

A shroud for guiding the air introduced from the fan to the condenser side; The shroud structure of the integrated air conditioner is installed between the centrifugal direction of the fan and the condenser, the condensate is blocked and the air passes through the condenser side. The method of claim 1, The barrier wall is provided with a plurality of air through holes on one side, the shroud structure of the integrated air conditioner, characterized in that the one side of the air vent is provided with a guide surface for guiding air to the condenser side.