KR100934559B1 - Fan Coils for Air Conditioner Evaporator Units and Air Conditioning Systems - Google Patents

Abstract

An evaporator unit having a blower chamber in the lower portion and an evaporator chamber in the upper portion includes a pair of inner member each having a structure for receiving and holding one end of the evaporator coil. Each of the inner members includes a planar lamp which jointly receives a plane of a flange extending outward from the tube sheet of the evaporator coil. The condensate drain pan partially forms the downstream portion of the evaporator chamber together with the evaporator coil. Each of the closing elements of the one phase is positioned in engagement with the side of one of the evaporator coil, the condensate drain pan and the inner member to close each of the sides of the downstream portion of the evaporator chamber.

Evaporator unit, blower, evaporator, lamp, inner part, flange

Description

Fan coil for air conditioner evaporator unit and air conditioning system {AIR CONDITIONER EVAPORATOR UNIT AND FAN COIL FOR AIR CONDITIONING SYSTRM}

The present invention relates generally to an evaporator unit for an air conditioning system, and more particularly to a closed structure for an evaporator chamber.

In many air conditioning, heating and ventilation systems, the conditioned air is discharged into the interior space through an air distribution or conditioning unit. For example, one general type of air conditioning system, often referred to as a split system, includes separate indoor and outdoor units. The outdoor unit includes a compressor, a heat exchanger and a fan. The indoor unit includes a heat exchanger and a fan and is referred to as an evaporator unit. In operation, the indoor fan draws air through its inlet into the evaporator unit and forces the air out of the evaporator unit via the heat exchanger and through the internal outlet opening.

The outdoor fan draws outdoor air into the outdoor unit, circulates it throughout the outdoor heat exchanger and returns it to the atmosphere. At the same time, the compressor allows the refrigeration fluid to circulate through and between the indoor and outdoor heat exchangers. In an indoor heat exchanger, the refrigerant absorbs heat from the air passing over the heat exchanger to cool the air. At the same time, in an outdoor heat exchanger, the air passing over the heat exchanger absorbs heat from the refrigerant passing through the heat exchanger.

This split type air conditioner unit is usually manufactured to have a wide range of cooling capacity. In the manufacture of such evaporator units, in particular, the larger the evaporator unit, the more cumbersome and cumbersome the manufacture and assembly of the various components. Typically, the larger the evaporator unit, the more components are needed and the more fasteners are needed for the assembly of all components. It is considered very desirable to minimize the number of components and fasteners needed in the manufacturing and assembly process.

An evaporator unit for an air conditioning system includes a housing having a rear panel and a front panel forming an air inlet opening and an air outlet opening. The housing forms an air flow path extending through the evaporator unit from the inlet opening to the blower chamber, to the evaporator chamber and to the outlet opening. The evaporator coil is supported in the housing and in the air passage, and the evaporator fan allows air to flow along the air passage and through the evaporator coil to be matched. Overall support for the evaporator coil is provided by a pair of side members attached to the rear panel and having a cavity on the inner side for receiving one end of the evaporator coil. The side panel has a planar surface to be joined by the rear and top edges of the evaporator, and a single fastener secures each side member to the evaporator coil. The downstream part of the evaporator air chamber is formed in part by the evaporator coil and by the condensate drain pan. The pair of closing elements are respectively located in engagement with the evaporator coil, the condensate drain pan and one of the inner members to close the respective sides of the downstream portion of the evaporator chamber. The closing elements are made of styrofoam material and serve to close the ends of the evaporator chamber to prevent penetration of air flow.

1 is a perspective view of an installed evaporator in accordance with one embodiment of the present invention.

2 is an exploded view of FIG.

3 is a partial perspective view of the inner portion of the left inner side member.

4 is a partial perspective view of a coil provided in the left inner side member.

5 is a cross-sectional view taken along the line 5-5 of FIG.

6 is a partial perspective view of an inner portion of the right inner side member.

Figure 7 is a perspective view of the evaporator unit of the present invention with any components removed for clarity.

8 is a cross-sectional view taken along the line 8-8 of FIG.

9 is a cross-sectional view taken along line 9-9 of FIG. 7.

10 and 11 are perspective views of a closing element according to one embodiment of the present invention.

12 is a partial perspective view of a closure element as installed in accordance with one embodiment of the present invention.

Figure 13 is a partial perspective view of the closing element facing the condensate drain pan as installed.

Referring now to FIG. 1, the evaporator unit 11 is shown with the rear side 12 in contact with the side wall in one of the possible installation positions. Although the same evaporator unit is configured such that its rear side 12 is installed alternatively to the ceiling of the room, it is described herein in a situation where it is installed in a vertical arrangement as shown. The evaporator unit has a front side 13, a left end 14, a right end 15, a top 16 and a bottom 17.

In operation, the evaporator unit comprises a blower that draws air from the room via the inlet opening 18, after which the air passes through the heat exchanger coil and then is discharged from the evaporator unit via the outlet opening 19. .

2, the evaporator unit is shown in exploded view to include all the various components prior to assembly. The order and manner of assembly are now described.

The rear panel 21 forms part of the housing of the first structural component and the evaporator unit. The upper closure assembly 22 is secured to the rear panel 21 by first joining the upper edge across the upper edge of the rear panel 21 and then fastening the two components together by fasteners 23. The left and right inner side members 24, 26 are attached to the rear panel 21 by fasteners. The fan assembly 27 is then secured to the lower portion of the rear panel 21 by fasteners 28.

In the assembly process, the next step is to install the evaporator coil 29 into the housing by placing its ends in the respective left and right inner member 24, 26. The evaporator coil 29 is then fixed in its installation position by a single screw at each of its ends passing through the inner member and at the end of the evaporator coil 29 into the tube sheet. The evaporator coil 29 is disposed in the evaporator chamber which is formed in part by the rear panel 21 and the left and right inner side members 24, 26. However, it is still necessary to close the end of the evaporator chamber to prevent the flow of air through. This is realized by the left and right closing elements 31, 32 which are held in place simply by being located in place without fasteners and also in combination with a drain pan 33 which forms an evaporator chamber. The drain pan 33 is fixed in place by fasteners at each end to secure the left and right inner member 24, 26 to the drain pan 33. The drain hose 34 is attached to the drain element of the drain pan 33. Then, the front panel 36 is positioned above the drain pan 33 and fixed in place by fasteners so that both the left and right inner member 24, 26 and the fan deck portion of the rear panel 21 are also in place. Attached.

Referring to the sides of the unit, the control box 37 is installed by snapping into the left inner side member 24, and the stepping motor 38 is also fixed to the left inner side member 24.

The blower chamber, which is formed in part by the lower part of the rear panel 21 and by the fan assembly 27, has an air intake opening therein. The suction opening is partially closed by the grille in which the plurality of filter elements 41 are located.

The next step is to connect the stepping motor 38 to the horizontal louver mechanism on the upper closure assembly 22, the horizontal louvers 42 closing the upper and the left and right inner members 24 and 26 at their ends and at the middle thereof. It is fixed to the assembly (22). The left and right end caps 43 and 44 are secured to the left and right inner side members 24 and 26 respectively to complete the assembly process.

Referring now to the structure for supporting the evaporator coils in the evaporator unit, in FIGS. 3 and 6, the respective portions of the left and right inner member 24, 26 each configured to receive and hold one end of the evaporator coil 29 Is shown. The left and right inner side members 24, 26 are fixed to the rear panel 21 at their respective rear edges 46, 47, and the closing assembly 22 is also attached to the rear panel 21.

Referring to FIG. 3, the internal structure of the left inner member 24 is shown to include a rear edge 46 and a ramp surface 48 that forms an angle of inclination at the bottom of the rounded base structure 49. Base structure 49 includes a substantially horizontal plane 51 at the rear with a small notch 52. Horizontal plane 51 and notch 52 are designed to receive an end flange of evaporator coil 29 as described below.

Near the upper end of the ramp face 48 is provided a substantially vertical wall 53, and above the upper end of the ramp face 48 is a retaining structure 54 having a plane 56. The ramp surface 48, the base structure 49, the vertical wall 53 and the plane 56 cooperate to form a boundary of the cavity for receiving one end of the evaporator coil 29 therein.

The manner in which the evaporator coil is installed in the cavity 57 is shown in FIGS. 4 and 5. The evaporator coil flange 58 usually extends outwardly from the end as shown in FIG. 4 and at the lower end 59 sliding over the horizontal plane 51 to be engaged with the notch 52 as shown in FIG. It rests on the lamp surface 48 by this. The upper end of the coil is then captured by the vertical wall 53 and the plane 56. The notch 52 is not intended to be a means for securing the evaporator coil 29 in its installed position, but rather is a means for holding it in position until it can be finally fixed by a fastener. In this way, the assembly is very helpful when temporarily holding the evaporator coil 29 in place until the evaporator coil 29 can be properly secured.

On the other side of the evaporator unit, the right inner side member 26 comprises a similar structure for holding the other end of the evaporator coil 29 by its associated flange. That is, the ramp surface 61, the horizontal surface 62, the vertical wall 63, the retaining structure 64 and the plane 66 that collectively form a cavity for accommodating the right end of the evaporator coil 29 therein are Is provided. The basic difference from the Figure 3 embodiment is that notches 52 are not provided, but such a structure can be provided if desired.

Referring now to FIG. 7, there is shown an evaporator unit with an evaporator coil 29 in an installation position but without a drain pan 33 and a front panel 36 to be installed. The evaporator coil 29 is fixed in place by a pair of fasteners, each of which passes through each of the inner members and into the tube sheet of the evaporator coil. A fastener for the right inner side member 26 is shown at 67. When the evaporator coil 29 is fixed in its installation position, the evaporator coil 29, together with the left and right inner side members 24 and 26 and the rear panel 21, respectively, is a rigid and stable backbone of the evaporator unit. It is important to note that

After the air has passed through the evaporator coil 29 to be cooled, downstream of the evaporator chamber formed by the evaporator coil 29 on the rear side, the condensate drain pan 33 on the front side and the closing assembly 22 on the upper side. Enter the part. The ends of the downstream part of the evaporator chamber are closed by the left and right inner side members 24, 26 together with their left and right closing elements 31, 32, respectively. The closing elements 31, 32 are formed of a lightweight styrofoam material that seals the ends of the upper part of the evaporator chamber and prevents the discharge of air that is adapted to flow only outside the outlet opening associated with the closing assembly 22. As shown in Figs. 7-9, the closing element is triangular in shape and one side is installed on the downstream side of the evaporator coil 29 and the upper side is disposed on the closing assembly 22 and the front side is condensate. It is coupled with the inner side (not shown) of the drain pan 33.

Referring now to FIG. 10, the left closure element 31 is shown as a triangular shaped element with three sides 71, 72, 73. As described below, the first side 71 is configured to seat against the surface of the evaporator coil 29, the third side 72 is configured to seat relative to the closing assembly 22, and the second side 73 ) Is configured to engage with the inner side of the condensate drain pan 33. The outer portion 74 of the closing element 31 is configured to engage the inner portion of the left inner portion member 24.

The right closure element 32 also has three sides 76, 77, 78 associated with the evaporator coil 29, the closure assembly 22 and the condensate drain pan 33, respectively. The outer side 79 of the closing element 32 is associated with the right inner side member 26.

The closing elements 31 and 32 are preferably made of a lightweight rigid material, such as styrofoam. The closing elements 31 and 32 simply need to be in place and no fasteners are required and are held by the surrounding element.

Referring now to FIGS. 12 and 13, the right closure element 32 is shown installed against the evaporator coil 29 and the right inner side member 26 to close the end of the downstream portion of the evaporator chamber. In FIG. 12, the right closing element 32 is shown before installing the condensate drain pan 33, and in FIG. 13 is shown as being associated with the condensate drain pan 33 when positioned in its final position. It is.

Claims (8)

An air conditioner of the type having an evaporator coil for the passage through which the refrigerant passes and the passage for the air and at least one blower that draws air into the air inlet opening in the air conditioner evaporator unit, over the coil and out of the air outlet opening. Evaporator unit, An evaporator coil having a rectangular cross section and having two ends, A housing having an evaporator coil and at least one blower and having a rear panel partially forming a blower chamber and partially forming an evaporator chamber, A pair of inner members attached to the rear panel for partially closing respective sides of the housing and in combination with respective ends of the evaporator coil to receive respective ends of the evaporator coil, A condensate drain pan forming an acute angle with the evaporator coil end and partially forming a downstream portion of the evaporator chamber together with the evaporator coil end; An air conditioner comprising a pair of closing elements for closing respective sides of the downstream portion of the evaporator chamber by respectively engaging the evaporator coil, the condensate drain pan and the inner member of one of the pair of inner members. Evaporator unit. 2. The method of claim 1, wherein each of the pair of closing elements is a triangular shaped element having three sides, the first of the three sides engaging the evaporator coil and the second side of the pair of closing elements with the condensate drain pan. Combining air conditioner evaporator unit. 3. An air conditioner evaporator unit as set forth in claim 2 including a closure assembly defining a discharge opening through which conditioned air is discharged, said closure assembly also engaging a third side of said closure element. The air conditioner evaporator unit as set forth in claim 1, wherein said closing element is made of styrofoam material. A fan coil for an air conditioning system of the type having a blower and an evaporator coil mounted in a housing partially formed by a rear panel forming a evaporator chamber, A long evaporator coil having a rectangular cross-sectional shape and having two ends and an upper edge, A pair attached to a rear panel, each having a first plane coupled with an end of the coil to receive an end of the coil and a second plane coupled with an upper edge of the coil to receive an upper edge of the coil The inner members of, A condensate drain pan forming an acute angle with the evaporator coil end and partially forming a downstream portion of the evaporator chamber together with the evaporator coil end; A fan for an air conditioning system including a pair of closing elements for closing respective sides of the downstream portion of the evaporator chamber by respectively engaging with the evaporator coil, the condensate drain pan and an inner member of one of the inner members. coil. 6. The method of claim 5, wherein each of the pair of closing elements is a triangular shaped element having three sides, the first of the three sides engaging the evaporator coil and the second side being the condensate drain pan. Fan coils for mating air conditioning systems. 7. The fan coil of claim 6, further comprising a closing assembly defining a discharge opening through which the conditioned air is discharged, the closure assembly coupled with a third side of the closing element. 6. The fan coil of claim 5 wherein the closure element is made of styrofoam material.

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