KR20000075822A - Evaporator coil support for a room air conditioner - Google Patents

Abstract

According to the present invention, there is provided an apparatus for mounting an evaporator coil in an indoor part of an air conditioner. The air conditioner includes an interior with a housing equipped with an evaporator coil with a top and vertically extending tube sheet. The evaporator is supported by a horizontally extending support surface formed at the front end of the housing that supports the lower end of the tube sheet. The first and second vertically extending evaporator support structures are disposed at each end of the horizontally extending support surface. Each of the first and second support structures is adapted to receive one of the tube sheets therein as the evaporator is displaced in engagement therewith and towards engagement with the horizontally extending support surface. The scroll structure for guiding the flow of air through the interior is provided with a vertically extending evaporator support channel that axially aligns with the vertically evaporator support structure in the housing. This scroll structure is adapted to engage the upper end of the tube sheet following engagement with the evaporator and the vertically extending evaporator support structure of the tube sheet.

Description

Evaporator coil support for room air conditioner {EVAPORATOR COIL SUPPORT FOR A ROOM AIR CONDITIONER}

Indoors of room air conditioners or split system air conditioners are typically housings with built-in structures which direct the evaporator coil, the indoor fan, the electrical control unit and the room air to the evaporator coil and redirect the regulated air back to the space to be cooled. It includes. Room air conditioner designers constantly strive to reduce the size and cost of products while increasing the capacity and efficiency of the air conditioner unit. The smaller the number of components and the fewer fasteners required to combine these components, the lower the material and labor costs, the greater the cost savings.

Thus, the mounting portion of the evaporator coil, which is carried without fasteners and supported by molded plastic components forming part of the air conditioner housing and by other supports as supplied by the components for guiding the flow of air, is provided in the jade of the room air conditioner. It is considered desirable to be provided on the interior.

The present invention relates generally to air conditioning systems, and more particularly to an arrangement for mounting an evaporator coil in a room air conditioner.

Those skilled in the art may better understand the present invention by referring to the accompanying drawings and the objects and advantages of the present invention will become apparent.

1 is a perspective view of a room air conditioner embodying features of the present invention.

FIG. 2 is a perspective view of the air conditioner of FIG. 1 with the top cover, front grille portion, and other selected components removed. FIG.

3 is a top view of the air conditioner of FIG. 1 with the upper housing and other components removed.

FIG. 3A is an enlarged view of the left front part of FIG.

3B is an enlarged view of the right front part of FIG.

4 is a partially exploded perspective view of the air conditioner of FIG. 1 with some components removed.

FIG. 5 is a plan view of the bottom housing and base pan of the air conditioner of FIG. 1 with many components removed. FIG.

6 is a partial perspective view of the air conditioner of FIG.

7 is a cross-sectional view taken along the line 7-7 of FIG.

According to the present invention, there is provided an apparatus for mounting an evaporator coil in an indoor part of an air conditioner. The air conditioner includes an interior with a housing equipped with an evaporator coil with a top and vertically extending tube sheet. The evaporator is supported by a horizontally extending support surface formed at the front end of the housing that supports the lower end of the tube sheet. The first and second vertically extending evaporator support structures are disposed at each end of the horizontally extending support surface. Each of the first and second support structures is adapted to receive one of the tube sheets therein as the evaporator is displaced downwardly in engagement with it and towards engagement with the horizontally extending support surface. The scroll structure for guiding the flow of air through the interior is provided with a vertically extending evaporator support channel that axially aligns with the vertically evaporator support structure in the housing. This scroll structure is adapted to engage the upper end of the tube sheet following engagement with the evaporator and the vertically extending evaporator support structure of the tube sheet.

Referring first to FIG. 1, the air conditioner 2 generally includes an indoor portion 4 and an outdoor portion 6. This air conditioning unit 2 comprises a generally rectangular housing 12 having a lower housing section 14, an upper housing section 16, and an indoor grill section 18. The lower housing section 14 is mounted in a metal support pan 20 and the entire room air conditioner is located on a rectangular opening or window sill of the exterior wall of the room where cooling is required with the indoor grill section 18 facing the room as conventionally. Will be.

The housing sections 12, 14 and the grill 18 are preferably made of molded plastic material. As best shown in Figs. 2 to 6, the whole air conditioning unit 2 is supported on a base fan 8 which is integrally molded with the lower housing 14 and forms the bottom thereof. A vertically extending partition wall 13 separating the indoor part 4 and the outdoor part 6 extends upwardly from the base pan and is integrally formed with each of the left and right side walls 10 and 11.

2 shows the unit 2 with the upper housing section 16 and the indoor grill section 18 removed. In addition, as conventionally, the unit includes an indoor refrigerant to air heat exchanger 22 (hereinafter “evaporator coil”) and an internal fan or evaporator fan 24. Air from the space to be controlled by this system is sucked through the inlet louvers 26 formed in the indoor grill section 18 by the action of the evaporator fan 24 and guided through the evaporator coil 22 where the air is cooled. do. The cooled air is then returned to the space to be cooled by the scroll assembly 28 which in turn guides the air through the indoor adjustable air discharge assembly 30 forming part of the grill 18.

In a fully assembled unit, the evaporator fan 24 is positioned in the scroll to cause the air flow described above. This scroll has been removed from some of the drawings to show in detail the evaporator coil support of the present invention.

With continued reference to FIG. 2, the unit also includes an outdoor refrigerant to air heat exchanger or coil 32 (hereinafter “condenser coil”), a condenser fan 34, and a compressor 36 as conventionally. In operation, circulating air enters the housing 12 through a plurality of louvered air inlets 38 located in the top and sides of the housing sections 14, 16. Air entering the inlet 38 is then sucked through the outdoor fan 34 and guided through the condenser coil 32 before exiting through the discharge opening 40 in the rear portion of the housing 12. As best seen in FIG. 2, both the evaporator fan 24 and the condenser fan 34 are both ends of a single drive shaft of a common drive motor 42 mounted within the outdoor portion 6 of the housing 12. Is driven from.

Referring now to Figures 3, 3A and 3B, a plan view of the evaporator coil 22 supported at the front end 44 of the base pan 8 of the lower housing section 14 is shown. The evaporator coil 22 includes a left tube sheet 46 and a right tube sheet 48. As conventional, two rows of heat exchanger tubes 50 interconnected by hairpin turn ends 52 extend between the tube sheets to define a continuous flow path for the refrigerant passing therethrough. A plurality of vertically extending heat exchange fins 54 are supported by the tubes and generally extend perpendicularly parallel to the tube thin plates 46, 48.

The support of the evaporator coil 22 will now be described with reference to FIGS. 4, 5 and 6 show the unit with the evaporator coil 22 and many other components removed to illustrate this support structure.

As shown in the figure, each of the tube thin plates 46 and 48 has a long U-shaped cross section with short legs 56 and 58 extending to the left, respectively. In particular, with reference to FIG. 3A and first with reference to the support for the left tube sheet 46, the vertically extending support channel 60 is integrally formed with the interior of the left wall 10 of the base pan and lower housing section 14. This channel 60 comprises a first section 64 formed integrally with the wall 10 and extending generally parallel to the evaporator coil 22. The second section 66 extends vertically forward of the first section 64 and the shorter third section 68 extends to the right, generally parallel to the evaporator coil 22. A short wall section 70 spaced from the third wall section 68 by a distance approximately equal to the thickness of the rear leg 58 of the tube sheet 48 extends from the right side of the lower end of the second section 66 and have. Thus, the rear leg 58 of the tube sheet 48 engages with the rear facing surface 72 of the third channel section 68 and is to be received in a defined space between the surface and the short wall section 70. have.

3B, the rear leg 58 of the right tube sheet 48 has a vertically extending channel 76 having a cross section substantially the same as that of the channel 60 described in detail for the support of the left tube sheet 46. It is adapted to engage the rear facing surface 74, which is defined for this purpose. The channel 76 on the right side is molded into the base pan of the lower housing section 14. As in the case of the left tube thin plate, the rear leg 58 of the right tube thin plate is adapted to engage the rear surface 72 of the channel 60. However, unlike the left tube thin plate, the support of the right tube thin plate is generally cross-shaped, which is adapted not only to the right facing wall 80 of the right tube thin plate 48 but also to the rear facing surface of the rear leg 58. It is provided in both lateral and front and rear positions by the vertically extending section 78.

Further positioning of the evaporator coil 22 is provided by the combination of the front leg 56 of the left tube sheet 46 and the right facing wall 86 molded into the front of the lower housing section 14. . In a similar manner, the left facing wall formed into the front portion of the lower housing section 14 is adapted to engage the right facing wall 88 of the right tube sheet 48.

As best shown in FIG. 2, the lower ends of the tube sheets 46, 48 of the evaporator coil 22 are formed at the front end of the base pan 8 of the lower housing section 14. Supported by). This condensate drain pan 92 is defined by a lower horizontal surface 94 and a vertically extending peripheral wall section 96 that serve to support the lower end of the tube sheet. This peripheral wall 96 includes short outwardly extending sections 98, 100 on its left and right sides and a long section 102 interconnecting the short sections 98, 100. It will be appreciated that the above described tube sheet support walls 86, 88 are formed in the long wall section 102.

As best shown in FIGS. 4 and 5, the horizontal surface 94 of the condensate drain pan 92 has a number of both at its left and right ends just below the lower ends of the left and right tube sheets 46 and 48. A small upright support pad 104 of is provided. When the evaporator coil is installed as described above, the lower ends of the tube thin plates 46 and 48 engage with the pad 104. As a result, the lower end of the tube heat exchanger and thus the heat exchange fin 54 of the coil is supported to be spaced apart from the horizontal surface 94.

Referring now to FIGS. 4, 6 and 7, the air guide scroll 28 includes upper and lower sections 106 and 108, respectively. Both scroll sections are made of foamed plastic material. From the above description with respect to indoor fan 24 and scroll 28, it will be appreciated that fan 24 is intended to be housed within scroll 24. Thus, referring to Figure 4, the lower scroll section 108 is shown installed in an air conditioning unit prior to installing the evaporator fan 24 therein. 4, the scroll extends downwards behind the evaporator support channels 60, 76 and has a main body having a front wall 112 with an opening 114 serving as an inlet to the evaporator fan 24. It will be appreciated that it includes a section 110. A pair of vertically extending evaporator support channels 116 are located on both sides of the front wall 112. Each of the channels 116 is axially aligned with one of the horizontally extending support structures described above in detail for each of the left and right tube sheets 46, 48. As best shown in FIG. 7, the channel 116 houses therein the rear leg 58 and a portion of the flat leg of each tube sheet.

In addition, an evaporator support ledge 118 extending across the front portion of the lower section 108 overlying the evaporator support channel 116 and the inlet opening 114 is formed integrally with the lower section 108 of the scroll 28. . As best shown in FIG. 6, the support ledge 118 engages with each upper end of the tube sheet 46, 48 and overlies the entire upper portion of the evaporator coil.

Thus, it should be understood that the evaporator coil is mounted within the interior of the housing by simply sliding the left and right tube sheets 46 and 48 in engagement with their respective vertically extending support structures described above. The thus mounted evaporator is coupled with the support channel 116 and the support ledge 118 by the lower section 108 of the scroll 28 described above to provide additional lateral and vertical support, respectively. This attachment is performed without the need for fasteners.

Claims (2)

In an air conditioner having an indoor unit with a housing, An evaporator coil with vertically extending tube sheets at the top and both ends, A horizontally extending evaporator support surface formed at the front end of the housing to support the lower end of the tube sheet; One is disposed at each end of the horizontally extending support surface, each adapted to receive one of the tube sheets therein as the evaporator is displaced in engagement therewith and towards the engagement with the horizontally extending support surface. First and second vertically extending evaporator support structures, Guiding air flow within the interior and having a vertically extending evaporator support channel formed therein axially aligned with the vertically extending evaporator support structure, followed by engagement of the evaporator and tube sheet with the vertically extending evaporator support structure. Scroll structure adapted to engage the upper end of the tube sheet An air conditioner comprising a. 2. The scroll structure of claim 1, wherein the scroll structure further comprises a horizontally extending evaporator holding structure extending between the vertically extending support channel and its front, wherein the channel has a vertically extending evaporator support channel of the scroll completely with the tube sheet. And an air conditioner coupled with an upper portion of the evaporator when in the engaged state.