BRPI0709998A2 - evaporator wrap and assembly for a direct current air conditioning system - Google Patents

Abstract

<B> EVAPORATOR WRAP AND ASSEMBLY FOR A CONTINUOUS CURRENT AIR CONDITIONING SYSTEM <D> The present invention relates to an evaporator wrap for a variable capacity air conditioning system driven by direct current (DC), having an evaporator set and a condenser set. The system also includes an air intake opening for air inlet from a closed environment in the evaporator assembly and an air outlet opening for air exit from the evaporator assembly in the closed environment. The evaporator casing includes a seamless one-piece structure, positioned adjacent to the air inlet opening and the air outlet opening and defining an air passage between the air inlet opening and the air outlet opening.

Description

Report of the Invention Patent for "EVAPORATOR AND ASSEMBLY WRAPPING FOR A DC AIR CONDITIONING SYSTEM".

Governmental Rights

The present invention was made with the support of the Government under contract DE-FC26-04NT42106, granted by the US Department of E-Energy. The government may have certain rights in this invention.

Field

The present invention relates to direct current (DC) air conditioning systems, including an evaporator wrap for a DC air conditioning system.

Background

The statements in this section provide only basic information related to the present description and may not constitute prior art.

Direct current (CC) ambient temperature control systems (ETCSs), also referred to as air conditioning systems, are often used to control the temperature inside enclosed environments where alternating current (AC) ETCSs are not possible. possible, desirable or safe. For example, in environments enclosed by remotely located structures where AC power is not available or conveniently accessible, or where a backup air conditioning system is required in case AC power is interrupted, or where A DC air conditioning system is more desirable than an AC air conditioning system. Of a general nature, DC air conditioning systems have an adequate ability to efficiently control the temperature of environments enclosed by smaller structures or constructions. For example, DC air conditioning systems are very suitable for controlling temperature inside utility wraps, portable or mobile enclosures and electronic enclosures, and utility or equipment structures such as cellular electronic enclosures. wireless communication and battery-backed cabinets.

These smaller structures may be located in a wide variety of outdoor locations that have a myriad of stringent outdoor environmental conditions that affect the temperature of all structures. That is, structures can be exposed to a wide range of outside temperatures, for example, -30 ° C to 55 ° C, varying solar loads and various forms of precipitation that can affect the entire internal environmental temperature. In the case of equipment enclosures, temperature control requirements may be stringent to prevent damage to the often expensive and not terribly hard equipment interior. Thus, the use of DC air conditioning systems is often desirable to actively control the temperature in the enclosed environment of these smaller structures. And in many cases efficiency, consistency and reliability are critical needs of the DC air conditioning system.

Typically, DC air conditioning systems include a condenser assembly and an evaporator assembly. In operation, the evaporator assembly receives air from an enclosed environment and an air handler pushes air through a heater or e-vaporizer heat exchanger to condition the air (ie, heat or cool the air) before leaving the air. back in the enclosed environment. The evaporator assembly is typically mounted in a sheet metal box, the exterior of which is exposed to external environmental elements such as water, moisture, marine air, insects, dust, pollen and / or electromagnetic radiation. Isolation of the enclosed environment from these external environmental elements is important, as ingress of these elements may damage equipment inside the enclosed environment as well as the evaporator assembly.

As recognized by the inventors, however, mounting the e-vaporizer in a sheet metal box provides disadvantages. For example, sheet metal boxes are first formed by bending and bending sheet metal to form sides having edges, the edges are then sealed using a sealant such as room temperature vulcanization sealant (RTV). These seals are time consuming to apply, expensive and prone to failure. Over time the seals may tear or rupture, causing leaks, which may lead to the external environmental elements discussed above.

In addition, the sheet metal housing, due to its rectangular shape, can provide poor air flow through the evaporator assembly, thereby compromising its heating and / or cooling performance.

summary

According to one aspect of the present disclosure, an evaporator envelope for a variable current DC (DC) variable capacity air conditioning system having an evaporator assembly and a condenser assembly. The system further includes an air inlet vent for enclosed air inlet in the evaporator assembly and an air outlet vent for venting air from the evaporator assembly in the enclosed environment. The evaporator wrap includes a unique seamless structure positioned adjacent the air inlet opening and the air outlet opening and defining an air passageway between the air intake opening and the air outlet opening. air.

According to another aspect of the present disclosure, a direct current (DC) driven variable capacity air conditioning system having an evaporator assembly and a condenser assembly. The system further includes an air inlet opening for air inlet. an enclosed room in the evaporator assembly and an air outlet opening to vent air from the evaporator assembly in the enclosed environment. Additionally, the system includes a housing defining the inlet opening and the air outlet opening and an evaporator wrap. The evaporator wrap is secured in the housing and positioned adjacent the air inlet port and the air outlet port and defines an air passage between the air inlet port and the air outlet port. The evaporator shell further comprises a seamless, one-piece structure. According to another aspect of the present disclosure, a continuous current (DC) variable capacity air conditioning system having an evaporator assembly and a condenser assembly. It further includes an air inlet opening for air inlet in an enclosed evaporator assembly and an air outlet vent for venting air from the evaporator assembly in the enclosed environment. Additionally, the system includes a housing defining the inlet opening and the air outlet opening, an evaporator heat exchanger, an evaporator air mixer and an evaporator wrap. The evaporator wrap includes a positioned evaporator heat exchanger section adjacent the evaporator heat exchanger and an evaporator air mover section positioned adjacent the evaporator mover. The evaporator air mover section is configured to channel air from the air inlet opening to the evaporator heat exchanger section. The evaporator air handler section is configured to channel air substantially and evenly through the evaporator to the air outlet port.

graphics

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way.

Figure 1 is a block diagram of a direct current (DC) driven variable capacity air conditioning system (VCACS) including an evaporator wrap according to the various embodiments of the present disclosure connected to a structure. enclosed environment to be thermally conditioned by the variable capacity air conditioning system.

Figure 2 is an exploded perspective view of a portion of VCACS illustrating various components of VACS according to various embodiments of the present disclosure.

Figure 3 is a front view of an evaporator wrap according to various embodiments of the present disclosure. Figure 4 is a side view of the evaporator wrap of Figure 1 according to various embodiments of the present disclosure.

Figure 5 is a perspective view of the evaporator wrap of Figure 1 according to various embodiments of the present disclosure.

Fig. 6 is an exploded view of section A shown in Fig. 5 illustrating condensation collectors in detail according to various embodiments of the present disclosure.

Figure 7 is a side view of a portion of a direct current (DC) driven variable capacity air conditioning system in accordance with other embodiments of the present disclosure.

Detailed Description

Other areas of applicability of the present disclosure will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating various preferred embodiments, are intended for illustration purposes only and are not intended to limit the scope of the description. Additionally, the features, functions and advantages of the present disclosure may be independently obtained in various embodiments or may be combined in other embodiments.

Figure 1 illustrates a direct current (DC) driven variable capacity air conditioning system 10 having an evaporator shell 32 according to one or more embodiments described below. DC Variable Capacity Air Conditioning System (VCACS) 10 is connected to a wall of a frame 14 enclosing an environment 18 to be thermally conditioned by DC 10 VCACS. DC 10 O-VCACS can operate using any power supply suitable DC (not shown), such as one or more DC batteries or a converted AC supply. The frame 14 may be any construction, wrapper; enclosure, cabinet, portable or mobile enclosure or any other enclosure enclosing an environment desiring to be thermally controlled by the DC-controlled variable capacity air conditioning system 10. For example, structure 14 It may be an electronics cabinet and / or equipment such as a cellular wireless electronics cabinet or a battery support cabinet where it is important to keep the enclosure18 at a desired temperature to prevent damage to the components and / or closed systems. VCACS 10 is configured to provide heating and cooling to maintain a substantially constant temperature of frame 14 of frame 14. VCACS 10 and frame 14 may comprise a telecommunications station, for example, a wireless telecommunications station, wherein structure 14 is a cabinet of electronic components and telecommunications equipment, for example, an electronic components cabinet and wireless telecommunications equipment.

VCACS 10 generally includes a housing 12 enclosing a condenser assembly 34 and evaporator assembly 38 and a variable speed compressor 42 connected to condenser and evaporator assemblies 34 and 38 via refrigerant lines 46. The housing 12 defines an air intake opening 17 for enclosed air inlet 18 in evaporator assembly 38 (generally indicated by an arrow 16) and an air outlet port 19 for venting air from evaporator assembly 38 in enclosed environment 18 ( generally indicated by an arrow 20). Evaporator wrap 32, described in more detail below, defines an air passage between air inlet port 17 and air outlet port 19.

Referring to Figure 27 in various embodiments, the evaporator assembly 38 includes an evaporator heat exchanger 50, a heating mechanism 54, an evaporator air mover 58 and a circuit panel 62, all of which are mounted on the Evaporator wrap 32. Evaporator air mover 58 can be rotatably mounted to an evaportator air mover mounting plate 66, which can then be mounted to evaporator wrap 32. evaporator air 58 may be a radial fan, an axial fan or a turbine, a variable speed rearward bent impeller, or any suitable air mover for moving variable air capacities. In addition, the heating mechanism 130 may be any suitable heat producing mechanism such as an open conductor heater, radiator type heater, chemical reaction type heater or any other heating device.

The housing 12 may include a housing panel 70 and a housing cover 74. The housing panel 70, in various embodiments, is mounted via the evaporator air mover 58, the evaporator heat exchanger 50, the heating mechanism 54 and of the circuit board 62 and coupled to the evaporator wrap 32 and / or a housing cover 74. The housing panel 70 includes the inlet opening 17 and a plurality of meshed or finned openings which generally form the outlet opening of 19. In various embodiments, an evaporator air-moving cover 60 may be positioned through the housing panel 70, thus covering at least a portion of the air intake port 17.

In various embodiments, evaporator wrap 32 is formed or manufactured as a seamless, one-piece structure. For example, evaporator wrap 32 may be molded using thermoforming or injection molding, cast, stamped or compressed to form a one-piece structure with no bent edges or joining seams.

In addition, the evaporator wrap 32 may be made of any suitable material, such as any suitable plastic or composite polymer, any suitable reinforced epoxy or polyurethane resin, or any other material suitable for making a one-piece evaporator wrap seamless 32.

Referring now to Figures 3 - 5 and 7, the evaporator wrap 32 includes an evaporator air mover section 78 positioned adjacent the air inlet opening 17 and an evaporator heat detecting section 82 positioned adjacent the outlet opening. Evaporator air handler section 78 includes brackets 86 for supporting evaporator air handler 58, as well as brackets 90 for supporting circuit board 62 positioned below supports 86. The changer section Evaporator heat exchanger 82 includes brackets 94 to support an evaporator heat exchanger 50 and brackets 98 for supporting heating mechanism 54. Brackets 94 and 98 are positioned below brackets 86.

Evaporator air mover 58, circuit board 62, evaporator heat exchanger 50 and heating mechanism 54 may be secured to brackets 86, 90, 94 and 98 respectively via a plurality of fasteners 102, as best shown in Fig. 7, which are inserted into fastener openings 106. Fasteners 102 may be any suitable fastener type, including, without limitation, screws, nails, rivets or staples.

In various embodiments, the evapper air mover section 78 receives air from the air inlet port 17 and ducts air to the evaporator heat exchanger section 82. The evaporator heat exchanger section 82 then ducts The storage received from the evaporator air demolishing section 78 substantially and evenly, as best shown in Figures 4 and 7, through the evapador heat exchanger 50 and then through the air outlet opening 19.

Evaporator heat exchanger section 82 may include a curved surface 118 having a protrusion portion and a tapered portion 126. The protrusion portion 122 allows air from the evaporator wrap 32 to vent through an upper portion of the evaporator heat exchanger 50 while tapered portion 126 allows evaporator wrap 32 to vent air through the middle and bottom portions of evaporator heat exchanger 50. Substantially uniform air flow through evaporator heat exchanger 50 generally increases performance. of evaporator heat exchanger 50.

Although the curved surface 118 includes a protrusion portion 122 and a tapered portion 126, in various other embodiments, the curved surface 118 may include a single smooth curved contour, absent the protrusion portion 122 and / or the tapered portion 126, without spacing. the scope of this description.

The evaporator air handler section 78, in various embodiments, includes a curved portion 130 surrounding the evaporator air handler 58. When air enters the evaporator assembly 38 through the air intake port 17, the evaporator air handler 58 blows air radially outward from the center of the e-vaporizer air handler 58.

The air subsequently collects and is then channeled downwardly through the curved portion 130 of the evaporator air mover section 78 to the evaporator heat exchanger section 82. The curved portion 130 allows the air circulates from the air inlet port 17 downwards through the evaporator wrap 32 smoothly.

In various embodiments, circuit board 62 is supported on evaporator wrap 32 and is positioned in air passage 24 downstream of evaporator air mover 58. Circuit board 62 includes a plurality of components 134, as best seen in FIG. Figure 7. Air channeled downward through bent section 130 of evaporator air handler section 78 passes through circuit board 62 and its components 134 thereby cooling components 134.

Although circuit board 62 is positioned downstream of the evaporator air heater 58, it should be understood that circuit board 62 can be positioned anywhere in air passage 24 without departing from the scope of this disclosure.

Components 134 of circuit board 62 may be various electrical elements, including a DC power supply bus, processor and / or electronic storage device. In addition, components 134 may be used to control one or more elements of the VCACS DC. 10 including, for example, evaporator assembly 38 and / or condenser assembly 34.

Referring now to Figures 5 and 6, evaporator wrap 32, in various embodiments, may include condensation collectors 110 to collect and remove condensation produced by evaporator heat exchanger 50. Figure 6 is an exploded view of the section A, shown in figure 5, illustrating in detail the condensation manifolds 110. In various embodiments, condensation manifolds 110 are small cavities or depressions formed in the evaporator shell 32 to collect condensation produced by an evaporator assembly 38. Each condensation manifold includes an opening 114.

Condensation collected on collectors 110 simply trickles out of collectors 110 via openings 114. In addition, the remaining condensation on collectors 110 works to prevent external elements such as water, moisture, sea air, insects, dust, pollen, etc. to infiltrate into the evaporator assembly 38. More specifically, the remaining water within the collectors 110 before dripping out provides a barrier through which such external elements may not be able to penetrate.

Additionally, while Figures 5 and 6 illustrate two condensation collectors 110, it should be understood that there may be more or less than two condensation collectors 110, without departing from the scope of this disclosure. Additionally, although condensation collectors 110 each include opening 114, one or more of the condensation collectors may not include an opening 114 or may include more than one opening 114, without departing from the scope of this disclosure.

Although condensation collectors 110 are formed in evaporator wrap 32, it will be understood that condensation collectors 110 could be a separate portion positioned at the bottom of the evaporator wrap, without departing from the scope of this disclosure.

Evaporator assembly 38 may include an evaporator air deflector 138, which is mounted above the evaporator heat exchanger 50, as best shown in Figure 7. The evaporator air deflector deflects air circulating below the evaporator heat exchanger. evaporator air mover section58 away from evaporator heat exchanger 50. Air deflector 138 may be formed of any suitable metal or plastic. In various styles, the air deflector is integrally formed with the evaporator wrap 32.

In various embodiments, housing panel 70 includes a terminal block 142 for connecting a direct current power supply to one or more elements of VCACS 10, including, for example, evaporator assembly 38 and the assembly. condenser 34.

Claims (40)

1. Evaporator wrap for a direct current (DC) variable capacity air conditioning system has an evaporator assembly, a condenser assembly, an air inlet opening for entering a room enclosed environment evaporator and an air outlet opening for air outlet of the evaporator assembly in the enclosed environment, the evaporator wrap comprising: a seamless one-piece structure positioned adjacent the air inlet opening and defining an air passage between the air intake opening and the air outlet opening. Evaporator wrap according to claim 1, wherein the evaporator wrap includes mounts for supporting an evaporator heat exchanger. Evaporator wrap according to claim 1, wherein the evaporator wrap includes mounts for supporting an evaporator air impeller. Evaporator wrap according to claim 1, wherein the evaporator wrap includes assemblies for supporting a circuit panel. Evaporator wrap according to claim 4, wherein the assemblies are configured to support the air flow circuit board. Evaporator wrap according to claim 1, wherein the evaporator wrap includes mounts for an evaporator air impeller support positioned adjacent the air inlet opening, mounts for support of a positioned evaporator heat exchanger adjacent to the air outlet port and mounts to support a circuit panel positioned at the air outlet port and mounts to support a circuit panel positioned between the mounts that support the evaporator air impeller and the mounts that support the heat exchanger. evaporator. Evaporator wrap according to claim 1, wherein the evaporator wrap has an e-evaporator air impeller section positioned adjacent the air inlet opening and an evaporator heat exchanger section positioned adjacent the opening. the evaporator air impeller section configured to channel air from the air intake opening to the evaporator heat exchanger section and the evaporator heat exchanger section configured to channel substantial air and evenly to the air outlet opening. Evaporator wrap according to claim 7, wherein the evaporator heat exchanger section defines at least one curved surface for substantially and uniformly ducting air to the air outlet opening. Evaporator wrap according to claim 7, wherein the evaporator heat exchanger section defines a plurality of curved surfaces to channel air substantially and evenly to the air outlet opening. Evaporator wrap according to claim 1, wherein the evaporator wrap has at least one damping collector for collecting condensation produced by an evaporator. Evaporator wrap according to claim 10, wherein the at least one condensation manifold is a depression formed in the evaporator wrap. Evaporator wrap according to claim 10, wherein the at least one condensation manifold defines a condensation collector vent opening. Evaporator wrap according to claim 1, wherein the evaporator wrap comprises a plurality of condensation collectors. Evaporator wrap according to claim 1, wherein the one-piece seamless structure is a molded plastic part. 15. Direct current (DC) variable capacity air conditioning system having an evaporator assembly, a condenser assembly, an air inlet opening for entering an atmosphere enclosed in the evaporator assembly and an outlet opening for air outlet of the evaporator assembly in the enclosed environment, the system comprising: a housing defining the air inlet opening and the air outlet opening, an evaporator wrap attached to the housing and positioned adjacent the air inlet opening and to the air outlet opening and defining an air passageway between the air intake opening and the air outlet opening, the evaporator wrap comprising a one-piece seam structure. The system of claim 15 further comprising an evaporator heat exchanger, wherein the evaporator wrap includes mounts for supporting an evaporator heat exchanger. The system of claim 15 further comprising an evaporator air impeller, wherein the evaporator wrap includes assemblies for supporting the evaporator air impeller. The system of claim 15 further comprising a circuit board, wherein the evaporator casing is mounted to support the circuit board. Evaporator wrap as defined in claim 18, wherein the assemblies are configured to support the air flow circuit board. The system of claim 15, wherein the evaporator includes assemblies supporting a positioned evaporator air impeller adjacent the air inlet opening, assemblies supporting a adjacent positioned evaporator heat exchanger opening the air inlet and mounts to support the circuit board positioned between the mounts supporting the evaporator air impeller and the mounts supporting the evaporator. A system according to claim 15, wherein the evaporator wrap has an evaporator air impeller section positioned adjacent the air inlet opening and an evaporator decal heat exchanger section positioned adjacent the aperture. air outlet section, the evaporator air impeller section configured to channel air from the air inlet opening to the evaporator heat exchanger section and the evaporator heat exchanger section configured to channel the arsubstantial and evenly to the air outlet opening. The system of claim 21, wherein the evaporator heat exchanger section has at least one curved surface to channel air substantially and evenly to the air outlet opening. The system of claim 21, wherein the evaporator heat exchanger section has a plurality of substantially uniformly curved air conduit surfaces for the air outlet opening. The system of claim 23 further comprising an evaporator heat exchanger positioned adjacent the evaporator heat exchanger section and the air outlet opening such that the plurality of curved surfaces channel substantial air and evenly through the evaporator to the air outlet opening. The system of claim 24 further comprising an evaporator air impeller positioned adjacent the evaporator air impeller section and the air inlet opening. The system of claim 15, wherein the evaporator wrap has at least one condensation collector for collecting condensation produced by an evaporator heat exchanger. The system of claim 26 wherein at least one condensation collector is a depression formed in the evaporator shell. The system of claim 26, wherein at least one condensation collector defines an aperture for the condensation release of the collector. The system of claim 15, wherein the evaporator shell comprises a plurality of condensation manifolds. The system of claim 15, wherein the one-piece seamless structure is a molded plastic part. 31. DC-Variable Capacity Variable Capacity Air Conditioning System having an evaporator assembly, a condenser assembly, an air inlet opening for entering an atmosphere enclosed in the evaporator assembly and an outlet opening for air outlet of the evaporator assembly in the enclosed environment, the system comprising: a housing defining the air inlet opening and the air outlet opening; an evaporator heat exchanger; an evaporator air impeller; evaporator wrap having an evaporator decal heat exchanger section positioned adjacent to the evaporator heat exchanger and an evaporator air impeller section positioned adjacent to the evaporator air impeller; the evaporator air impeller section configured for cana- air from the air intake opening to the evaporator heat exchanger section and the evaporator heat exchanger section configured to channel substantial air and evenly through the evaporator to the air outlet opening. The system of claim 31, wherein the evaporator heat exchanger section has at least one substantially curved surface for ducting air substantially and evenly through the evaporator heat exchanger. The system of claim 31, wherein the evaporator heat exchanger section has a plurality of curved surfaces for ducting air substantially and evenly through the evaporator heat exchanger. The system of claim 31, wherein the evaporator shell defines an air passageway between the air inlet port and the air outlet port, the evaporator casing including assemblies for positioning a Circuit board in the dear passage. The system of claim 34, wherein the circuit board is a controller for the system. The system of claim 34, wherein the panel is positioned downstream of the evaporator air impeller. A system according to claim 31, wherein the evaporator wrap includes at least one condensation manifold formed integrally with the evaporator wrap and configured to collect condensation produced by an evaporator. The system of claim 37, wherein at least one condensation manifold is a depression formed in the evaporator shell. The system of claim 37, wherein at least one condensation collector defines an aperture for the condensation release of the collector. The system of claim 37, wherein the evaporator shell comprises a plurality of condensation manifolds.