The present invention related generally to a refrigeration system having modular components for ease of servicing and installation. More particularly, the refrigeration system may be environmentally friendly and efficient.
Refrigeration appliances are generally provided with a refrigeration system to cool the interior of the refrigerator enclosure. Refrigeration systems may include a compressor, evaporator, condenser, and expansion device connected by a plurality of conduits. The system also includes control electronics for operation of the system. Some refrigeration appliances include a refrigeration system having the components thereof individually mounted within the appliance. In the case of failure of one of the components, the malfunctioning component must be replaced. In order to repair the system, the refrigerant charge in the failed component and the conduits interconnecting the component to the system must be removed. The component is replaced via a welding process, and the system is then recharged with refrigerant then leak checked.
A problem with this type of system is that if the component is replaced on site, the repair could be time consuming and messy, and require a substantial amount of equipment to be brought to the job site to effect the repair. If the entire refrigeration appliance is taken off-site to be repaired, the time necessary to complete the repair and return the appliance may be substantial. The cost of the repair and travel time may also significant.
In Example 1, a refrigeration system includes a housing; a cabinet arranged within the housing and including an opening configured to operate as a cooling or freezing space; a modular refrigeration assembly including a condenser assembly, a compressor, and an evaporator, the modular refrigeration assembly being configured to arrange the evaporator within the cabinet and arrange the condenser assembly and compressor within the housing and external to the cabinet; and one or more conduits arranged between the condenser assembly, the compressor, and the evaporator forming a closed loop system configured to contain refrigerant.
In Example 2, further to the refrigeration system of Example 1, the one or more conduits are configured to contain the refrigerant and facilitate temperature control within the modular refrigeration assembly free of a refrigerant reservoir.
In Example 3, further to the refrigeration system of Example 1, the one or more conduits are configured to contain the refrigerant.
In Example 4, further to the refrigeration system of Example 3, the one or more conduits are configured to maintain the refrigerant within the system without direct contact with any ignition source.
In Example 5, further to the refrigeration system of Example 4, the refrigerant is R290 propane.
In Example 6, further to the refrigeration system of Example 1, the modular refrigeration assembly is configured to remove from the cabinet and the housing for service and replacement of one or more parts of the modular refrigeration assembly.
In Example 7, further to the refrigeration system of Example 1, the modular refrigeration assembly includes modular connections configured to connect to power and control connections.
In Example 8, further to the refrigeration system of Example 1, the modular refrigeration assembly is configured to insulate and seal the evaporator within the cabinet.
In Example 9, further to the refrigeration system of Example 1, the condenser assembly and the compressor are arranged on a base plate that includes a substantially linear surface.
In Example 10, further to the refrigeration system of Example 1, the evaporator is arranged laterally adjacent the opening in the cabinet, and the evaporator is configured to intake hot air from the opening, cool and return the air in a first direction, and the cabinet is configured to direct the cooled air in a second direction and a third direction perpendicular to the first direction evaporator back toward the opening.
In Example 11, refrigeration system includes a housing; a cabinet arranged within the housing and including an opening configured to operate as a cooling or freezing space, and a wherein the evaporator is arranged laterally adjacent the opening in the cabinet, a diverter configured to facilitate air circulation relative to the opening; a modular refrigeration assembly including a condenser assembly, a compressor, and an evaporator, the modular refrigeration assembly being configured to removably insert the evaporator within the cabinet to intake hot air from the opening, cool and return the air in a first direction, and direct the cooled air toward the diverter to circulate the cooled air in a second direction and a third direction perpendicular to the first direction evaporator back toward the opening; and one or more conduits arranged between the condenser assembly, the compressor, and the evaporator forming a closed loop system configured to contain refrigerant.
In Example 12, further to the refrigeration system of Example 11, the modular refrigeration assembly is configured to arrange the condenser assembly and compressor within the housing and external to the cabinet and seal the evaporator within the cabinet.
In Example 13, further to the refrigeration system of Example 12, the modular refrigeration assembly is configured to the condenser assembly and compressor external to the cabinet and above the opening within the cabinet.
In Example 14, further to the refrigeration system of Example 12, the opening is configured to house one or more food racks.
In Example 15, further to the refrigeration system of Example 11, the modular refrigeration assembly is configured to arrange the evaporator directly adjacent the opening.
In Example 16, further to the refrigeration system of Example 11, the housing includes a controller configured to interface with the modular refrigeration assembly and facilitate multiple levels of cooling cycles.
In Example 17, a method of servicing a refrigeration system that includes a housing, and a cabinet arranged within the housing having an opening configured to operate as a cooling or freezing space, and a modular refrigeration assembly having a condenser assembly, a compressor, and an evaporator, the method includes: removing the panels of the housing to reveal the condenser assembly and the compressor of the modular refrigeration assembly; disconnecting the modular refrigeration assembly from the cabinet; removing the modular refrigeration assembly to lift the evaporator from within the cabinet; and repairing or replacing one or more parts of the modular refrigeration assembly.
In Example 18, the method of Example 17, the modular refrigeration assembly includes a base configured to hold the condenser assembly, the compressor, and the evaporator in place.
In Example 19, the method of Example 17, the method also includes placing the modular refrigeration assembly within the housing and the cabinet after repairing or replacing the one or more parts of the modular refrigeration assembly
In Example 20, the method of Example 18, the method also includes sealing the evaporator within the cabinet after placing the modular refrigeration assembly within the cabinet.
The foregoing Examples are just that, and should not be read to limit or otherwise narrow the scope of any of the inventive concepts otherwise provided by the instant disclosure.
The foregoing and other objects, features, and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:
Various aspects of the present disclosure are directed toward apparatuses, systems, and methods that include a refrigeration system. In certain instances, the refrigeration system may include refrigeration assembly. The refrigeration assembly may secure or include all aspects directed toward the functionality or operability of cooling air. More specifically, the refrigeration assembly may include a condenser assembly, a compressor, and an evaporator (as well as conduits and electrical components arranged between these aspects). The refrigeration assembly securing each of these aspects may facilitate efficient serviceability as explained in further detail below.
The refrigeration assembly, in certain instances, is an environmentally friendly and efficient unit. The refrigeration assembly, for example, may be configured to use a refrigerant that is recognized as being highly efficient. In addition, the refrigerant may safely contain the refrigerant within the system while maintaining enhanced serviceability.
The modular refrigeration assembly 15 may include a base plate 38 to which the condenser assembly 32, the compressor 30, and the evaporator 35 are releasably secured. The base plate 38 may include a top surface 38A and a bottom surface 38B. As shown, the condenser assembly 32 and the compressor 30 are secured on the top surface 38A of the base plate 38 and the evaporator 35 is secured on the bottom surface 38B of the base plate 38.
The modular refrigeration assembly 15 may also include conduits 40 that connect the refrigeration system components (e.g., the condenser assembly 32, the compressor 30, and the evaporator 35). Further, the base plate 38 may include a handle 41 for ease of lifting the assembly 15 in and out of a refrigeration enclosure (shown in
In certain instances and as shown in
As discussed in further detail below, the conduits 40 may contain the refrigerant in a closed-loop system with the condenser assembly 32, the compressor 30, and the evaporator 35. The refrigerant may be a highly efficient and environmentally friendly component (e.g., propane). In certain instances, the refrigerant loaded in to the closed-loop system is approximately 100 grams to 200 grams. The closed-loop system is without a reservoir and contains the refrigerant within the loop formed by the conduits 40 and the condenser assembly 32, the compressor 30, and the evaporator 35.
The assembly 15 is configured to be removed and installed seamlessly into the opening 25 (shown in
As noted above, the base plate 38 includes a sealing interface 45 rigidly attached to the bottom surface 38B of the base plate 38 and/or the top surface 35A of evaporator 35. Upon removal of assembly 15 from the cabinet 20 connection plugs 70 may be disconnected from the assembly 15 and from portions of the housing as shown in
As shown in
The removable panels 50A, 50B, 50C, 50D and 50E form a housing 50 over the assembly 15. The panels 50A, 50B, 50C, 50D and 50E may be secured together to form the housing 50 or the panels 50A, 50B, 50C, 50D and 50E may be individual removable to reveal the assembly 15. In certain instances, at least two panels include vents 50F (or louvers) for ventilation of heat generated by the assembly 15.
The housing 50 also includes an operator interface and controller 60 having a microprocessor based programmable computer for controlling the operation of assembly 15 components. The operator interface and controller 60 may be integrated into or mounted on a removable panel by any suitable type of fasteners. Upon removal of assembly 15 from refrigeration cabinet 20 cover 50 panels are removed and controller 60 is disconnected via connection plugs 70.
The controller 60 may be configured to interface with the modular refrigeration assembly 15 and facilitate multiple levels of cooling cycles. During servicing of the refrigeration system, one or more of the panels 50A, 50B, 50C, 50D and 50E of the housing 50 may be removed to reveal the condenser assembly 32 and the compressor 30 of the modular refrigeration assembly. The modular refrigeration assembly 15 may be disconnected the cabinet 20 (e.g., by uncoupling, unscrewing, or detaching the base plate 38 from the top 20E of the cabinet 20). In certain instances, the connection plugs 70 between the controller 60 and the assembly 15 may be disconnected. In addition, the conduits 40 that connect the assembly 15 may be disconnected. The modular refrigeration assembly 15 may be removed from the cabinet 20, which includes lifting the evaporator 35 from within the cabinet 20.
The assembly 15 may be completely separated and removed from the cabinet 20 to easily and accessible service the assembly 15. The assembly 15 is modular in that the parts can be removed from the assembly 15 and quickly repaired or replaced. This ensures the safety of technicians, as well as minimizing the downtime of your blast chiller in the event a repair is needed. To service the assembly 15, one or more of the parts (e.g., condenser assembly 32, compressor 30, and evaporator 35, conduits 40, refrigerant contained within the conduits 40) may be repaired or replaced. The parts (e.g., condenser assembly 32, compressor 30, and evaporator 35, conduits 40) may by coupled together by the connection plugs 70 (and in some instances the conduits 40), which enable modular quick disconnection of the parts of the assembly 15 and reinstallation of the new or repaired part.
After repairing or replacing one or more of the parts, the assembly 15 may be placed back the housing 50 and the cabinet 20. In addition, the evaporator 35 may be sealed within the cabinet after placing the modular refrigeration assembly 15 within the cabinet 20. Thus, in the event of component failure, the modular refrigeration assembly 15 may be removed from the cabinet 20, and a new component may be replaced on the assembly 15. In other instances, a new assembly 15 entirely may be installed within the cabinet 20. The assembly 15, new or with a component replaced or repaired, is slid into and out of the cabinet as a unit, with the only installation steps including bolting the assembly 15 in place and connecting the connection plugs 70.
As shown in
The one or more conduits 40 are configured to contain the refrigerant and facilitate temperature control within the modular refrigeration 15 assembly free of a refrigerant reservoir. In certain instances, the conduits 40 are also configured to maintain the refrigerant within the system without direct contact with any ignition source. In addition, the refrigerant may be R290 propane. Prior refrigeration systems or blast chillers use refrigerants with high global warming potentials. The assembly 15 may use R290 propane refrigerant, which is non-toxic with a low global warming potential (e.g., GWP rating of 3 and no Ozone Depleting Properties (ODP)). The Environmental Protection Agency (EPA) has named R290 as its preferred hydrocarbon alternative.
Although R290 propane may be highly flammable, the assembly 15 fully contains and seals the R290 propane within the closed loop system of the conduits 40 and the condenser assembly 32, the compressor 30, and the evaporator 40. As a result, there risk of leaking is minimized and there is no direct contact with any ignition source. It has been shown that the assembly 15, using R290 propane, has a substantially similar fire risk as compared to a similar appliance using a different refrigerant.
In addition to the environmentally friendly nature of the assembly 15, the assembly 15 is also highly serviceable. For example, the modular refrigeration assembly 15 is configured to remove from the cabinet 20 and the housing 50 for service and replacement of one or more parts of the modular refrigeration assembly 15 (as shown in
In certain instances, the modular refrigeration assembly 15 is configured to insulate and seal the evaporator 35 within the cabinet 20. The base plate 38 may also include a sealing interface 45 attached to the bottom surface. The sealing interface 45 (e.g., insulative foam) may seal the evaporator 35 within the cabinet 20 and seal out the condenser assembly 32 and the compressor 30. In addition and as shown, the condenser assembly 32 and the compressor 30 are arranged on the base plate 38 that includes a substantially linear surface. The evaporator 35 being arranged within the cabinet 20 facilitates direct and efficient cooling of interior items within the cabinet 20 (e.g., refrigeration enclosure) than a system that incorporates components both interior and exterior to refrigerator interior. The opening 25 into which items to be cooled or frozen is situated directly land laterally adjacent to the evaporator 35. As shown in FIG. in the proximity of back wall 20D to facilitate the orientation of evaporator 35 towards the rear of the internal refrigeration space. This allows for the placement of food racks 75 (or other aspects) directly forward of the evaporator 35 such that the evaporator 35 can intake hot air from a front side 35B of the evaporator 35 and output cooled air to a back side 35C of the evaporator 35.
The position and arrangement of the evaporator 35 to facilitate efficient air flow within the interior refrigeration space of cabinet 20. Left 20A, right 20B, and rear 20D walls include surfaces 20A1, 20B1, and 20D1 interior to cabinet 20. A space for airflow is created between interior surfaces 20A1, 20B1, and 20D1 and the periphery of evaporator 35. As illustrated by arrows indicating the direction of the airflow, there exists three way circulation of air within the refrigeration cabinet 20.
In certain instances, the evaporator 35 is arranged laterally adjacent the opening (in which the food racks 75 are arranged) in the cabinet 20, and the evaporator 35 is configured to intake hot air from the opening, cool and return the air in a first direction as shown. In addition, the cabinet 20 is configured to direct the cooled air in a second direction and a third direction perpendicular to the first direction evaporator back 35 toward the opening as shown. The back wall 20D1 of the cabinet 20 may deflect cooled air back toward the side walls 20A1, 20B1 and back toward the opening (in which the food racks 75 are arranged). The cabinet 20 includes space between the side walls 20A1, 20B1 and the evaporator 35 such that cooled air can circulate back toward the opening (in which the food racks 75 are arranged). In certain instances, the evaporator 35 is positioned co-extensively with opening (in which the food racks 75 are arranged) to draw heat evenly from the opening (in which the food racks 75 are arranged) into the evaporator 35 (a heat exchanger). In certain instances, the cabinet 20 may include an air deflector 80 positioned between evaporator rear surface 35C1 and back wall interior surface 20D1 to split airflow to opposite sides of opening (in which the food racks 75 are arranged). In certain instances, the air deflector 80 is angled inward towards surface 35C1, is āVā shaped, and is coextensive with evaporator 35C.
The invention of this application has been described above both generically and with regard to specific embodiments. It will be apparent to those skilled in the art that various modifications and variations can be made in the embodiments without departing from the scope of the disclosure. Thus, it is intended that the embodiments cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.
This application is a continuation-in-part of U.S. patent application Ser. No. 14/999,763, filed Jun. 23, 2019, which is incorporated herein by reference in its entirety for all purposes.
Number | Date | Country | |
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Parent | 14999763 | Jun 2016 | US |
Child | 17027934 | US |