The present inventions relate to a display deck for use in a temperature controlled case. The present inventions relate more particularly to a display deck having multiple product support surfaces configured to provide contact cooling to products within the temperature controlled case. The present inventions relate more particularly to a display deck having multiple product support surfaces configured at various angles and/or elevations.
It is generally known to provide for display surfaces to support products (e.g. decks, pans, etc.) for use in a temperature controlled case. Such display surfaces are typically flat or planar and may be provided in one or more segments. Such display surfaces may also be configured for circulation of a coolant through the segments to provide cooling to products within the temperature controlled case. However, such known display surfaces typically do not realize certain advantageous features (and/or combinations of features). For example, it would be desirable to provide a display deck for a temperature controlled case that includes any one or more of the following advantageous features:
1. An increased amount of surface area to support products, relative to a conventional flat deck.
2. Multiple product support surfaces configured to display the products to a user and to provide contact cooling of the products.
3. A cooling system configured to circulate a coolant to the product support surfaces so that the product support surfaces may provide contact cooling to the products.
4. An insulation layer to provide improved thermal performance and to reduce accumulation of moisture and condensation.
5. A cover layer that can be aesthetically and/or functionally coordinated with some or all of the design elements of the temperature controlled case.
6. A generally planar deck that is configurable as multiple shelves (e.g. “mezzanine shelves,” etc.) within the temperature controlled case.
7. A fluid heating system to provide heated or warmed fluid for circulation to the product support surfaces to provide contact warming of the products.
8. A frame configured to provide “steps” having multiple levels of generally planar pans to provide a multi-tiered display surface.
9. Increased surface area of the product support surfaces provided by an angular (e.g. slanted, etc.) orientation of one or more of the product support surfaces.
10. Multiple product support surfaces that can be provided in a variety of different orientations (e.g. planar, curved, non-planar, slanted, horizontal, etc.) within the display deck.
According to one embodiment, a temperature controlled case defines a space for storage of products and includes a cooling system configured to circulate a coolant to maintain a temperature of the products in the space. A deck is positioned within the space and has a stepped configuration to provide multiple product support surfaces configured to support the products. At least one cooling element is coupled to the deck and receives a coolant from the cooling system so that the product support surfaces provide contact cooling to the products.
According to another embodiment, a temperature controlled case defines a space for storage of products, and includes a system to circulate a fluid to maintain a temperature of the products in the space. A deck having tiers formed by a plurality of separate product support surfaces is supported on a frame member positioned within the space. One of the product support surfaces and the frame member is integrated with the cooling system so that the product support surfaces provide contact cooling to the products displayed at different elevations.
According to another embodiment, a temperature controlled case defines a space for storage of products and includes a cooling system to circulate a fluid to maintain a temperature of the products in the space. Multiple product support surfaces are coupled to the case and stacked in a generally vertical orientation within the space. A cooling element is associated with the product support surfaces to receive a heat transfer fluid from the cooling system so that the product support surfaces provide contact cooling to the products.
According to a further embodiment, an apparatus for the display of temperature controlled products includes a case defining an enclosure. A sheet having a plurality of contiguous stepwise surfaces is located within the space A cooling element is integrated with at least one of the stepwise surfaces and configured to facilitate conductive heat transfer with the products. A cooling system circulates a coolant to the cooling element, and a control system configured to regulate a flow of coolant to the cooling element to maintain a desired temperature of the products.
According to a further embodiment, a temperature controlled apparatus for display of food products includes a display deck having product support surfaces that receive the food products and maintain a temperature of the products within a predetermined range. A fluid delivery system circulates a fluid in at least one of a chilled state and a heated state, and in thermal communication with the product control surfaces. A control system regulates a temperature of the product support surfaces, which have an appearance indicative of a type of food product displayed thereon.
According to a further embodiment, a temperature controlled apparatus for display of food products includes a display deck having one product support surface to receive heated food products and another product support surface to receive chilled food products. A fluid delivery system circulates a fluid in a heated state to the first product control surface and in a chilled state to the second product control surface. A control system regulates a temperature of the first and second product support surfaces.
Referring to the FIGURES, various embodiments of a display deck are disclosed for use in a temperature controlled case or other device for storing or displaying chilled or heated products. Although the disclosure is described in the context of a “refrigerated” display deck configured for use with a chilled coolant in a temperature controlled case (e.g. merchandiser, etc.), the coolant may be warmed to provide a heated or warmed display device (e.g. food service or preparation tables, heated food cases, etc.). According to the illustrated embodiments, the display deck has multiple surfaces intended to increase the capacity for storage and/or display of products within a case, and to provide a cooling (or heating) element formed within, or coupled to, portions of the deck to provide contact cooling to the products placed on the deck.
Referring to
The display deck 20 may be formed or constructed in any suitable configuration for supporting and displaying products 12. For example, display deck 20 may be formed from a single sheet or multiple sheets into a shape or configuration with single or multiple steps (e.g. tiered, terraced, staggered ridges/valleys, waves, etc.), and various or multiple slopes, slants or angles, etc. (see for example,
Referring to
The coil(s) 32 of cooling element(s) 30 may include fins or other structure (not shown) to promote and/or distribute heat transfer and the coil(s) 32 may be attached to a back surface of the sheet in a suitable manner (e.g. by a thermal conducting paste, gel, or other substance, welding, brazing, brackets, clips, etc.) to promote contact cooling of the products through the sheet. The cooling element(s) may also be provided in modular form and configured for attachment at any suitable location on the backside of the sheet (e.g. by flexible hose connections, articulating joints, releasable clips, etc.—not shown). The cooling element(s) are intended to be positioned on the sheet corresponding to the location of the surfaces for supporting the products so that the cooling element(s) provide contact cooling through the sheet to the products. In applications involving multiple cooling elements, the cooling elements may be configured in a series flow arrangement (shown for example in
A layer of insulating material (not shown) may be provided over the back of the sheet and/or the cooling element(s) and may be a blanket, molded or foamed insulation layer. A layer of a cover material may be provided over the layer of insulation material to provide an attractive and water resistant surface. The layers of insulation material and cover material are intended to prevent liquids such as water (e.g. moisture, condensation, frost, etc.) from accumulating and/or dripping from the underside of the sheet and to improve the thermal performance of the display deck.
The display deck 20 is generally intended for use as a multi-level or multi-surface display structure within an internal portion of a case. However, a top surface of the case may be provided with a panel 16, such as a generally planar (e.g. “flat”) panel, with an upper surface that is cooled by cooling elements for storage of other objects 18 (e.g. above or external to the case). For example, the display deck 22 within the case may store products such as cold cuts, pre-made meals, etc. within the case and panel 16 in the top cover of the case may be used as a platform to store/display other products 18 such as beverages (e.g. soda, etc.) that are chilled by direct contact (such as shown for example in
Referring further to
Referring further to
In an embodiment having a series or parallel flow arrangement for the cooling element(s), a supply header 42 and return header 44 are provided to circulate a fluid from cooling system 40 through the cooling elements 30. A flow regulating or control device such as a valve 46 (such as a balance valve, etc.) may be provided at the outlet of each cooling element 30 to regulate the flow rate of fluid through the cooling element and to control the amount of cooling provided at surface 22. A valve may also be provided on the return header after the last cooling element to control the rate of flow of fluid through all of the cooling elements. Alternatively, other types of valves (e.g. “on/off” valve) may be provided to permit intermittent flow (e.g. pulsed, etc.) of fluid through the cooling elements to provide a desired cooling performance for all product support surfaces 22 of the display deck 20, or for “customized” thermal performance for separate product support surfaces. For example, separate product support surfaces may be maintained at different temperatures to suit the particular temperature requirements of different products. Further, the valve may be another type of valve, such as a control valve configured to “modulate” the flow of fluid based on signals representative of the cooling demand on the surfaces 22 (e.g. surface temperature, air temperature, simulated product temperature, etc.) that are provided to the valve from the control system.
According to an alternative embodiment, the cooling element(s) may be integrated within the sheet of the display deck by formation of passages within the sheet that provide a flow path for the fluid to circulate through the sheet. The passages may be one or more individual passages formed in a pattern (as shown for example in
The fluid from the cooling system may be a liquid coolant (e.g. secondary coolant, etc.) such as a glycol solution, chilled water, etc. The cooling system may have any suitable configuration and include conventional components. For example, a primary cooling system 48 (e.g. circuit, loop, etc.—shown in
The temperature of the product support surface 22 may be controlled by the control system 60 by regulating the rate of flow of the fluid. For example, the rate of the flow of the fluid may be varied (e.g. metered, regulated, etc.) by devices such as valve 46 (e.g. flow control valves, balance valves, metering valves or the like), or may be controlled by providing a flow of the fluid through the cooling element intermittently (e.g. periodically, etc.) by opening and closing (e.g. cycling, pulsing, etc.) valve 46 (e.g. a flow regulating device such as a “shut-off” valve such as solenoid operated valve, etc.). For applications involving a fluid that is a refrigerant, the flow of the fluid may be regulated by a thermostatic expansion valve or the like. A separate valve 46 may be provided for each cooling element so that the product support surfaces may be maintained at different temperatures to facilitate display of products having different storage temperature requirements to be displayed in the same case. The control system 60 may also regulate the flow rate of the fluid by providing a suitable output signal to a flow generating device (such as a pump and variable speed motor or the like).
According to any preferred embodiment, the cooling system 40 includes a supply header 42 for supplying fluid to display deck 20 and a return header 44 for receiving fluid from the display deck. The supply and return headers may be “flexible” (e.g. hoses, tubing, etc.) or “hard-piped” (e.g. copper tubing, PVC tubing, pipes, etc.), or a combination of flexible and hard-piped. The supply and return headers may be provided with fittings (e.g. quick-disconnects fittings, etc.) to permit convenient coupling or interconnection of the headers with cooling system supply and return lines. The supply header and return header may also be provided with branch supply lines having a fitting (e.g. quick-disconnect fittings, spring-clip fittings, hose clamps, etc.) for interconnecting with the cooling element(s) and/or product support surfaces. Other fitting types, such as universal joints, articulating joints, or the like may be provided to facilitate removal of the cooling element(s) or the product support surface(s) (e.g. for cleaning, maintenance, etc.).
Control system 60 is provided to control operation of cooling system 40 by controlling the flow of fluid to regulate the temperature of the products stored on the sheet. Suitable sensors may be provided within the case or integral (or otherwise operably coupled) with the sheet and/or cooling elements(s) to provide input to the control system. For example, one or more temperature sensing devices 62 (e.g. thermocouples, RTDs, etc.) are shown to be provided at suitable location(s) within, or on the top side or underside of the product support surface(s) 22 to provide a signal representative of temperature of the surface to the control system. The control system is configured process the input signal(s) and provide an output signal (e.g. to regulate the position of a valve, regulate the speed of a pump, etc.) when the temperature of the product support surface reaches certain temperature limits or set points. According to a preferred embodiment, a “high” temperature limit is approximately 33 degrees F. and a “low” temperature limit is approximately 30 degrees F., however, other suitable temperature limits or set points may be provided to suit a particular display deck, case, application or facility.
Control system 60 may include a processor such as programmable logic controller or the like for receiving and monitoring input signals, sending output signals, permitting change or adjustment of set points, providing appropriate indications (e.g. alarms, status, temperature, fluid flow rates, mode of operation (such as cooling or defrost), etc.) and to interface with local or remote monitoring equipment or stations.
Control system 60 may also be configured to initiate and terminate a defrost mode of operation. Defrosting of the product support surface(s) 22 and/or cooling element(s) 30 may be accomplished by stopping the flow of fluid for a period of time to allow frost and/or ice to melt (e.g. “time-off”), or energizing electrical heating elements (e.g. wires, etc.—not shown) formed in or located adjacent to the product support surface(s) and/or cooling element(s), or circulating a “warmed” fluid through the cooling elements (such as may be warmed by “hot gas” from the primary loop, etc.) or other suitable method. The defrost mode may be initiated and terminated based on suitable signals received by the control system, or by a timer, or other suitable method.
Referring to
Referring to
Referring to
According to other embodiments, the heat transfer fluid may be heated by a suitable device (e.g. electric immersion heater, heat exchange with hot gas from a refrigeration system, etc.) to provide heating to heating elements associated with the product support surface(s). According to further embodiments, the stepped configuration of the display deck lends itself to application of surface treatments intended to aesthetically compliment other features as part of an overall product display or marketing strategy. For example, certain images (e.g. agricultural images for produce products, farm images for meat or dairy products, seascape images for seafood products, etc.) may be superimposed on, embossed on, formed in or applied on the product support surfaces. The product support surfaces may also be provided with an appropriate color, texture or finish to compliment the facility or other portions of the case. The images may be provided (for example) as thin appliques 19 (e.g. foils, films, etc. —shown for example in
According to other embodiments, multiple cases may be arranged in a symbiotic relationship. For example, “cold” cases and “warm” cases may be configured side-by-side (or in another suitable relationship) so that waste heat from a refrigeration system of the cold case may be used to warm the fluid in the warm case, and so that heat from the warm case may be used to defrost cooled surfaces in the cold case. In other alternative embodiments, cooling elements such as coils may be provided in other locations within the case, such as along end panels to reduce warming of the case from exterior temperature influences. According to further alternative embodiments, a single case may be configured with both heated and cooled product support surfaces. For example, a product support surfaces for heated entrees may be arranged adjacent to a product support surface for chilled items, such as appetizers, salads, side dishes, beverages, etc. According to another example, such a display deck may take a form similar to that shown in
It is also important to note that the construction and arrangement of the elements of the display deck for a temperature controlled case as shown schematically in the embodiments is illustrative only. Although only a few embodiments have been described in detail in this disclosure, those skilled in the art who review this disclosure will readily appreciate that many modifications are possible (e.g., angles and configurations of stepped portions of the deck, variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, mounting arrangements, use of materials, colors, orientations, etc.) without materially departing from the novel teachings and advantages of the subject matter recited. For example, elements shown as integrally formed may be constructed of multiple parts or elements, the operation of the heat transfer elements, cooling (or heating) system, frame member and product support surfaces may be reversed, reconfigured or otherwise varied, the length or width of the structures and/or members or connectors or other elements of the system may be varied, the nature or number of the product support surfaces may be varied (e.g. by variations in the number of product support surfaces or size and shape of the product support surfaces or type of engagement between the product support surfaces and the cooling system).
It should be noted that the elements and/or assemblies of the display deck for a temperature controlled case may be constructed from any of a wide variety of materials that provide sufficient strength or durability or heat transfer characteristics, in any of a wide variety of colors, textures and combinations. It should also be noted that the display deck for a temperature controlled case may be used in association with other refrigeration devices or in combination with multiple refrigerated preparation tables, or any of a wide variety of other equipment in other applications. Further, a wide variety of heat transfer fluids may be used in connection with the display deck for a temperature controlled case, and the cooling system may be configured to provide the flow of coolant to the product support surfaces in a series or a parallel flow path configuration, and the flow of coolant to the product support surfaces may be controlled for individual surfaces or group(s) of surfaces. Accordingly, all such modifications are intended to be included within the scope of the present inventions. Other substitutions, modifications, changes and omissions may be made in the design, operating conditions and arrangement of the preferred and other exemplary embodiments without departing from the spirit of the present inventions.
The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. In the claims, any means-plus-function clause is intended to cover the structures described herein as performing the recited function and not only structural equivalents but also equivalent structures. Other substitutions, modifications, changes and omissions may be made in the design, operating configuration and arrangement of the preferred and other exemplary embodiments without departing from the spirit of the present inventions as expressed in the appended claims.
The present Application claims the benefit of priority, as available under 35 U.S.C. § 119(e)(1), to U.S. Provisional Patent Application No. 60/527,140 titled “Display Deck for a Temperature Controlled Case” filed on Dec. 5, 2003 (which is incorporated by reference in its entirety).
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