This disclosure is directed, in general, to heating ventilating and cooling (HVAC) systems, and more specifically, to support systems and methods for HVAC systems, and more specifically still, but without limitation, to support units and related methods.
In packaged, roof top, and other heating ventilating and cooling (HVAC) systems supporting the structure is very important in the field and during transportation. Often a portion of the system is supported on planar member and a structure is assembled to go under one or more components that involves significant amounts of box steel and fasteners. Some of the components, like a compressor on certain units, weigh more than 120 pounds. The box steel arrangements to assist with support take considerable material and labor.
According to an illustrative embodiment, a support unit for supporting a portion of a heating, ventilation, and air conditioning system includes a base rail frame having a top surface and having two parallel lateral sides, a first longitudinal side parallel to a second longitudinal side. The parallel lateral sides and first longitudinal side and second longitudinal side together form a closed end frame having an interior portion. The support unit further includes at least a first pocket formed on the first longitudinal side of the base rail frame having a first upward angled rail face directed toward the interior portion and at least a second pocket formed on the second longitudinal side of the base rail frame having a second upward angled rail face directed toward the interior portion. The second pocket is formed directly across the interior portion from the first pocket.
The support unit further includes a first compressor beam having a first end and a second end, a top surface, a first longitudinal side, and a second longitudinal side and further including a first downward angled face formed on the first end of the first compressor beam and configured to substantially mate with the first upward angled rail face of the first pocket. The first compressor beam also includes a second downward angled face formed on the second end of the first compressor beam and configured to substantially mate with the second upward angled rail face of the second pocket. In an assembled position, the top surface of the first compressor beam is substantially flush with the top surface of the base rail frame. The support unit also includes a base pan disposed over the top surface of the base rail frame.
According to another illustrative embodiment, a heating, ventilating, and cooling (HVAC) system includes a compressor; a condenser fluidly coupled to the condenser for receiving a refrigerant therefrom; an expansion device fluidly coupled to the condenser for receiving a refrigerant therefrom; and an evaporator fluidly coupled to the expansion device for receiving a refrigerant therefrom. The system also includes a base rail frame having a top surface and having two parallel lateral sides, a first longitudinal side parallel to a second longitudinal side. The parallel lateral sides and first longitudinal side and second longitudinal side together form a closed end frame having an interior portion.
The system further includes at least a first pocket formed on the first longitudinal side of the base rail frame having a first upward angled rail face directed toward the interior portion and at least a second pocket formed on the second longitudinal side of the base rail frame having a second upward angled rail face directed toward the interior portion. The second pocket is typically formed across the interior portion from the first pocket. The system has at least a first compressor beam having a first end and a second end, a top surface, a first longitudinal side, and a second longitudinal side. A first downward angled face is formed on the first end of the first compressor beam and configured to substantially mate with the first upward angled rail face of the first pocket. A second downward angled face is formed second end of the first compressor beam and configured to substantially mate with the second upward angled rail face of the second pocket.
In an assembled position, the top surface of the first compressor beam may be substantially flush with the top surface of the base rail frame. The system also includes a base pan formed to substantially cover the interior portion of the base rail frame and, in an assembled position, supported in part along a peripheral edge by the base rail frame and a plurality of first fasteners that in the assembled position extend through the base pan and are coupled to the first compressor beam. The compressor is disposed on the base pan and is at least partially supported by the first compressor beam.
According to still another illustrative non-limiting embodiment, a method of manufacturing a support unit for supporting a portion of a heating, ventilation, and air conditioning system includes forming a base rail frame having a top surface and having two parallel lateral sides, a first longitudinal side parallel to a second longitudinal side. The parallel lateral sides and first longitudinal side and second longitudinal side together form a closed end frame having an interior portion. The method further includes forming at least a first pocket on the first longitudinal side of the base rail frame having a first upward angled rail face directed toward the interior portion; forming at least a second pocket on the second longitudinal side of the base rail frame having a second upward angled rail face directed toward the interior portion. The second pocket is formed across the interior portion from the first pocket. The method also involves providing a first compressor beam having a first end and a second end, a top surface, a first longitudinal side, and a second longitudinal side.
The method also involves forming a first downward angled face on the first end of the first compressor beam that is configured to substantially mate with the first upward angled rail face of the first pocket; forming a second downward angled face on the second end of the first compressor beam that is configured to substantially mate with the second upward angled rail face of the second pocket; and disposing the first compressor beam on to the base rail frame such that the first pocket engages the first downward angled face of the first end of the first compressor beam and such that the second pocket engages the second downward angled face of the second end of the first compressor beam.
Other embodiments are included below and contemplated herein.
Illustrative embodiments of the present invention are described in detail below with reference to the attached drawing figures, which are incorporated by reference herein and wherein:
Heating, ventilation, and cooling (HVAC) systems come in many shapes and sizes. All the various HVAC systems must be supported in transport and when in an installed position in the field. Moreover, during transportation, the support structure must be able to handle enhanced loading, e.g., 3 Gs, as well as lateral accelerations. The methods and systems described herein for supporting aspects of HVAC systems may be included with a wide range of HVAC systems and provide such support. Referring to the drawings, and initially to
The portion of the HVAC system 100 shown in
The compressors 102, 104, and 106 are shown on the base pan 108 and in an interior portion 124 of the base rail frame 122. While three compressors are shown, one skilled in the art will understand that one or two or another number of compressors might be used. The compressors 102, 104, and 106 are associated with a condenser 126 on an outboard portion 128 of the base pan 108. A top member 130 is formed with apertures 132 and 134 covered by grills 136 and 138 respectively. Condenser fans 140 and 142 are associated with the apertures 132 and 134. A sheet metal enclosure member (not explicitly shown) would typically extend from edge 144 to edge 146 but has been removed so that the interior portion 124 is visible.
The compressors 102, 104, and 106 and the condenser 126 form part of a refrigeration or cooling unit. In this regard, referring primarily to
Referring now primarily to
The support unit 123 includes a first compressor beam 147 and a second compressor beam 149. The second compressor beam 149 is only shown in
As shown clearly in
The base pan 108 may be coupled to the first compressor beam 147 by a plurality of fasteners 158 shown clearly in
Referring now primarily to
In an analogous fashion (and therefore not shown in detail), at least a second pocket 170 is formed on the second longitudinal side 139 of the base rail frame 122. Again, the second pocket 170 is formed with a first upward angled rail face directed toward the interior portion 124. The second pocket 170 is formed across (angled or directly across) the interior portion 124 from the first pocket 166. It will be appreciated that a longitudinal length of the first compressor beam 147 is sized so that the first downward angled face 162 of the compressor beam 147 mates with the first pocket 166 and the second downward angled face 164 mates with the second pocket 170. Moreover, the longitudinal length of the first compressor beam 147 may be sized and configured so that the top surface 152 is substantially flush with the top surface 130 of the base rail frame 122 when in the assembled position. In some embodiments, the longitudinal length of the first compressor beam 147 may be sized to form an interference fit with the pockets 166 and 170.
The first downward angled face 162 formed at the first end 148 of the first compressor beam 147 is configured to substantially mate with the first upward angled rail face 168 of the first pocket 166. An angle (θ) of the first downward angled face 162 relative to horizontal (orthogonal to gravitational field) may be selected to be identical with or substantially the same as the angle (α) of the first upward angled rail face 168 on the first longitudinal side 137 of the base rail frame 122. In this previous sentence, “substantially same” means within two degrees. The angle θ may vary between 5 and 95 degrees, but often is selected to be 45 degrees. The second downward angled face 164 on the second end 150 of the first compressor beam 147 is formed in analogous fashion to that of the first downward angled face 162.
It should be noted that the compressor beams, e.g., compressor beam 147, may thus be installed in the support unit 123 without requiring any fasteners. The weight of the load supported by the compressor beam 147 further drives the angled faces 162, 164 into or towards the mating angled rail faces, e.g., 168, of the first and second pockets 166, 170. That is, in the assembled position and loaded state, no fasteners are required to hold the first downward angled face 162 formed at the first end 148 of the first compressor beam 147 to the first upward angled rail face 168 of the first pocket 166 and to hold the second downward angled face 164 formed second end 150 of the first compressor beam 144 to the second upward angled rail face of the second pocket 170. Among other things, this may make for faster assembly, fewer parts, and greater stability than previously known systems. Still, in some embodiments, a fastener could be added.
It should also be understood that while only two pockets 166, 170 are shown and described, numerous additional pockets may be formed on the longitudinal sides 137, 139. For example, without limitation, a third pocket and a fourth pocket may be included. Likewise, as previously referenced, while on only compressor beam 147 is described, numerous compressor beams might be included. In one illustrative non-limiting embodiment, the support unit 123 includes at least a third pocket formed on the first longitudinal side 137 having a first upward angled rail face (analogous to first upward angled rail face 168) directed toward the interior portion 124 and spaced from the first pocket 166 formed on the first longitudinal side; at least a fourth pocket formed on the second longitudinal side 139 having a second upward angled rail face directed toward the interior portion 124, wherein the second pocket is formed across the interior portion 124 from the third pocket; a second compressor beam having a first end and a second end, a top surface, a first longitudinal side, and a second longitudinal side; a first downward angled face formed on the first end of the second compressor beam and configured to mate with the first upward angled rail face of the third pocket; a second downward angled face formed second end of the second compressor beam and configured to mate with the second upward angled rail face of the fourth pocket; and wherein, in an assembled position, the top surface of the second compressor beam is substantially flush with the top surface of the base rail frame.
As previously noted, the base pan 108 may be coupled to one or more compressor beams, e.g., compressor beam 147. The base pan 108 may include raised pads 109 formed on a top surface of the base pan 108. The raised pads 109 provide support for parts, such as the coil. The coil and any other parts sit on these raised pads 109 to keep them elevated and so water will run of the pan and not collect on the parts. The base pan 108 is formed to substantially cover the interior portion 124 of the base rail frame 122 and, in an assembled position, be supported at least in part along a peripheral edge 172 (
Referring primarily to
Referring now primarily to
As shown in
Referring to the Figures, an illustrative, non-limiting embodiment of a method of manufacturing a support unit for supporting a portion of a heating, ventilation, and air cooling system is presented. The method includes forming a base rail frame having a top surface and having two parallel lateral sides, and a first longitudinal side parallel to a second longitudinal side. The parallel lateral sides and first longitudinal side and second longitudinal side together form a closed end frame having an interior portion. The method further includes forming at least a first pocket on the first longitudinal side of the base rail frame having a first upward angled rail face directed toward the interior portion; forming at least a second pocket on the second longitudinal side of the base rail frame having a second upward angled rail face directed toward the interior portion. The second pocket is formed across (angled or directly across) the interior portion from the first pocket. To form a pocket, the rail frame is formed and then secondary tooling may be used to press form the pockets.
The methods also involve providing a first compressor beam having a first end and a second end, a top surface, a first longitudinal side, and a second longitudinal side. The method further comprises forming a first downward angled face on the first end of the first compressor beam that is configured to substantially mate with the first upward angled rail face of the first pocket; forming a second downward angled face on the second end of the first compressor beam that is configured to substantially mate with the second upward angled rail face of the second pocket; and disposing the first compressor beam on to the base rail frame such that the first pocket engages the first upward angled face of the first end of the first compressor beam and such that the second pocket engages the second downward angled face of the second end of the first compressor beam.
In one illustrative embodiment, the method of manufacturing of the previous paragraph further includes disposing a base pan onto the base rail frame covering the interior portion and wherein the base rail frame is substantially flush with the top of the first compressor beam; and fastening the base pan to the first compressor beam with a plurality of fasteners.
In one illustrative embodiment, a support unit goes under a portion of an HVAC system to support one or more aspects of such a system. The supported equipment rests on a frame having a top cover, or base pan. The nature of the top cover suggests that a support beam, or crossbeam, is necessary to go under top cover. In one illustrative embodiment, the crossbeam is made with angled faces formed on each of longitudinal end of the crossbeam. Then there are matching or substantially matching angled sections formed at pockets on two opposite sides of the frame. To put the crossbeam in position, it is placed so that the two angled faces of the crossbeam go into the pockets against the two angled faces in the pockets. Once there, the weight of the beam forces the two faces together and even more so once it is loaded. The crossbeam is flush with the top edge or top perimeter or lip of the frame. The cover, or base pan, may be placed over the crossbeam and the rail frame. Equipment to be supported may be applied on the base pan and fasteners extended from that equipment through the base pan or cover and into the crossbeam. It should be understood that the support unit may include any number of crossbeams; that is, one or a plurality of crossbeams as required for the equipment. Each item of equipment supported may be coupled to one crossbeam or multiple crossbeams. This arrangement adds internal support and stiffening of the base pan. It should be noted that the arrangement is self positioning when assembled and stabilizes once loaded.
By providing a surface-to-surface contact at the ends of the crossbeam, or compressor beam, the structure allows for flexure and supports the weight of the equipment. The crossbeams help to support and damp any flexure or vibrations from system operations or shipping impacts. In one alternative embodiment, a dampener member may be disposed between the downward angled face on each end of the crossbeam and the matching upward angled rail face in a corresponding pocket. The dampening member may be an elastomeric material, such as a centimeter thick rubber member or natural rubber such as EPDM, NBR, or Silicon. The dampening member could also be a thermoplastic elastomer such as TPE's, or any ductile plastic such as an impact grade ABS plastic. The dampening member may be secured to either of the matching angled faces before installation with glue or other means. The dampening member would help to absorb energy to dampen vibrations.
While the examples herein are given with respect to a compressor and the term “compressor beam” is used, it should be understood that other package units might be supported in the same way and are within the scope of this disclosure.
In the detailed description herein of the preferred embodiments, reference is made to the accompanying drawings that form a part hereof, and in which is shown, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, and it is understood that other embodiments may be utilized and that logical structural, mechanical, electrical, and chemical changes may be made without departing from the spirit or scope of the invention. To avoid detail not necessary to enable those skilled in the art to practice the invention, the description may omit certain information known to those skilled in the art. The detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is defined only by the claims. Unless otherwise indicated, as used throughout this document, “or” does not require mutual exclusivity.
Although the present invention and its advantages have been disclosed in the context of certain illustrative, non-limiting embodiments, it should be understood that various changes, substitutions, permutations, and alterations can be made without departing from the scope of the invention as defined by the claims. It will be appreciated that any feature that is described in a connection to any one embodiment may also be applicable to any other embodiment.
Number | Name | Date | Kind |
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6095482 | LaGrotta | Aug 2000 | A |
8225581 | Strickland | Jul 2012 | B2 |
10180266 | Joseph | Jan 2019 | B2 |
20140048678 | Chen | Feb 2014 | A1 |
Number | Date | Country | |
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20190195515 A1 | Jun 2019 | US |