BACKGROUND OF THE INVENTION This invention relates to an insulated refrigeration panel assembly for an insulated cooling structure, such as a walk-in cooler, a refrigerated display cabinet, a beverage cooler and other insulated structure.
Refrigerated goods are typically stored in an insulated space prior to their use or consumption. Such a space, such as offered by a walk-in cooler, may be erected and/or constructed on-site from a number of panels. For example, a walk-in cooler is typically constructed from insulated refrigeration panels. Each insulated refrigeration panel has an inner and outer skin. These skins sandwich an insulated foam, such as urethane. The inner and outer skins provide a smooth surface for cleaning while the insulating foam serves to keep goods cool.
The insulated refrigeration panels may form the walls, the ceiling and the floor of the insulated space. For a walk-in cooler, the various wall, ceiling and floor panels are brought to the job site, erected, and then assembled using fasteners to attach the panels together. The fastening of these panels is both time consuming and costly. It is therefore desirable to eliminate the need for fasteners and to reduce the amount of time required to assemble these insulated refrigeration panels together.
One particular panel design eliminates the need for fasteners between panels by allowing the panels to be joined by a snap-fit connection at the end of each panel. Accordingly, each panel is inserted to another panel from end to end to create the walls or roof of the cooler. This design eliminates the need for separate fasteners.
These existing snap-fit panels are produced on a conveyor belt in sections. Because these panels are produced in this fashion, the snap-fit connectors are located only at the ends of the panel. Due to this limitation, the number of structural configurations that may be made from these snap-fit panels is also thereby limited.
A need therefore exists for an insulated refrigeration panel assembly that offers the convenience of a snap-fit connector without the limitation of the foregoing design.
SUMMARY OF THE INVENTION The present invention comprises an insulated refrigeration panel assembly that offers a greater variety of panel configurations than existing designs. Like existing panel assemblies, the inventive insulated refrigeration panel has two skins that sandwich an insulating foam. In contrast to existing designs, however, integrated snap fit connectors permit connection of one panel to another panel not only along the panel but also across the panel. In this way, a single panel may be connected to two panels: one panel that fits end-to-end and another panel that intersects the other panel. Further, panels may engage one another in both a vertical and horizontal direction. Accordingly, a greater variety of structural configurations are available for the design of an insulated space.
The insulated refrigeration panel assembly has a first skin and a second skin spaced generally parallel to the first skin. The skins sandwich an insulating body, such as a urethane foam. A first snap-fit connector allows flexible engagement of a mating connector along one direction while a second snap-fit connector allows flexible engagement of a second mating connector along another direction. The snap-fit connectors are formed by the panels themselves, i.e., skins and insulating body, rather than by any separate connector. In this way, assembly time of the insulated space is greatly reduced because there is no need to install separate connectors to attach one panel to another.
The snap-fit connector may have features that allow flexing between two different dimensions. One dimension of the snap-fit connector allows a mating connector to be received while the other dimension locks the two connectors together.
Like the snap fit connector, the mating connector may be an integrated part of a panel or may be just another insulating body. This second insulating body may have a first end portion and a second end portion. The first end portion fits within the snap-fit connector while the other end portion may allow another snap-fit connector to fit over. Accordingly, the mating connector may serve to join two of the same type of snap-fit connectors. A flange may be attached to the second insulating body that covers a joint between two panels. The flange may be curved. This flange serves to cover the seam between panels to facilitate clean-up of the refrigerated panels and prevent the collection of food between panels.
A panel may comprise two distinct bodies. One body may define part of the snap-fit connector while the other body may define the other part of the snap-fit connector. The snap-fit connector may further be a female member engageable to a mating connector, such as a male member which is insertable into the female member. The female member may flex between a first dimension larger than a second dimension to receive the male member. The male member may then be engaged to the female member when in the second dimension.
The inventive panel assembly may thus be constructed from three different panels, each comprising two skins sandwiching an insulating body. A single panel may be connected to two others in two different directions. In addition, the inventive refrigerated panel assembly permits another panel to intersect the single panel.
BRIEF DESCRIPTION OF THE DRAWINGS The various features and advantages of this invention will become apparent to those skilled in the art from the following detailed description of the currently preferred embodiment. The drawings that accompany the detailed description can be briefly described as follows:
FIG. 1 illustrates a plan view of the inventive insulated refrigeration panel assembly.
FIG. 2 illustrates a snap-fit connector prior to insertion of a mating connector.
FIG. 3 illustrates the insertion of the mating connector into the snap-fit connector ofFIG. 2.
FIG. 4 illustrates the mating connector completely inserted into the snap-fit connector.
FIG. 5 illustrates the panel ofFIGS. 1-4 attached to another panel with a mating connector.
FIGS. 6A-6C illustrates various mating connectors.
FIG. 7 illustrates panels constructed from two distinct bodies to form snap-fit connectors.
FIG. 8 illustrates panels forming an insulated refrigeration space.
FIG. 9 illustrates one panel simply intersecting another panel with the inventive features.
FIG. 10 illustrates a method of constructing the inventive insulated refrigeration panels.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTFIG. 1 illustrates inventiverefrigeration panel assembly10. Here,panel assembly10 is made from three panel units:first panel unit20,second panel unit80, andthird panel unit120.First panel unit20 hasfirst skin24 spaced generally parallel along the X-axis tosecond skin28. First insulatingbody32 is sandwiched between the twoskins24,28. In contrast to existing wall panel assemblies,first panel unit20 is made by placing panel skins24 and28 in a press with a foam, such as a urethane foam, shot between the twoskins24,28. The urethane foam may have a density of two pounds per cubic foot. Becausefirst panel unit20 is constructed by a press rather than a conveyor operation,first panel unit20 may have two snap-fit connectors: first snap-fit connector36 is constructed to receive a mating connector along the Y-axis while second snap-fit connector44 is constructed to receive a mating connector along the X-axis. Axes X and Y are transverse to each other.
Accordingly,first panel unit20 may flexible engage mating connectors in two different directions. One direction may be horizontal while the other direction may be vertical, for example. This increased freedom of engagement allowsfirst panel unit20 to be used for the construction of a wall to wall corner, a ceiling and wall corner, or a floor and wall corner.
Second panel unit80 is constructed in like fashion tofirst panel unit20.Third skin84 andfourth skin88 sandwich second insulatingbody92, a urethane foam, and may form an integralfirst mating connector40 that may be received in a snap-fit fashion by first snap-fit connector36.Second panel unit80 may have a snap-fit connector on the other end or alternatively another mating connector depending upon the particular configuration desired.
Likewise,third panel unit120 hasfifth skin124 spaced generally parallel fromsixth skin128. A urethane insulating foam forms third insulatingbody132.Fifth skin124 andsixth skin128 and thirdinsulating body132 formsecond mating connector48 to be received by second snap-fit connector44.Third panel unit120 may also have another snap-fit connector on its other end or another mating connector. As shown inFIG. 1,first panel unit20 may receivesecond panel unit80 in the direction of arrow V along the Y-axis and receivethird panel unit120 in the direction of arrow H along the X-axis in a snap-fit fashion.
The snap-fit connection will now be explained.FIG. 2 illustrates how first snap-fit connector36 may flexibly engage withfirst mating connector40. As shown, first snapfit connector36 comprises a female member sized to mate withfirst mating connector40, here a male member that is inserted along the direction of arrow Y into the female member. Asmating connector40 moves in the direction of arrow V along the Y-axis into first snap-fit connector36,mating connector40 will encounter firstflexible portion22 and secondflexible portion26. Firstflexible portion22 and secondflexible portion26 each comprise a gasket or sponge placed between insulatingbody32 andsecond skin28. The space between firstflexible portion22 and secondflexible portion26 has dimension D2, which is smaller than the outer width W0ofmating connector40. Accordingly, asmating connector40 is inserted into snap-fit connector36, as shown inFIG. 3,mating connector40 causes firstflexible portion22 and secondflexible portion26 to retreat in the direction of arrows A and B, respectively, to causeopening37 to expand from dimension D2to dimension D1, which is the same dimension as width W0offirst mating connector40. Oncefirst mating connector40 is completely received within opening37 of first snapfit connector36, firstflexible portion22 and secondflexible portion26 spring back to their original form as shown inFIG. 4 to thereby engage or lockfirst mating connector40 to first snap-fit connector36. In this fashion, each snap-fit connector may engage with each mating connector.
As further shown inFIG. 4,second panel unit80 may form a wall of a walk-in cooler or other refrigeration space whilefirst panel unit20 may form a top panel. In the event thatsecond panel unit80 is located onfloor66, second insulatingbody52 may be used to fill another snap-fit connector57 and provide a better foundation onfloor66. As shown, a joint orseam76 is formed betweenfloor66 andsecond panel unit80.Flange64, having a curved portion, may cover joint/seam76.Flange64 prevents debris from collecting between panels and presents a rounded corner to facilitate cleaning.
As shown inFIG. 5, alternatively, rather than placingsecond panel unit80 onfloor66,second panel unit80 may intersect another panel unit, herefloor panel unit136, which is constructed in like fashion as the other panel units. Rather than use second insulatingbody52, another insulatingbody54 havingfirst end portion56 to mate with snap-fit connector57 is provided as well assecond end portion60 to mate with another snap-fit connector59. In this way,wall panel assembly80 may be flexibly engaged tofloor panel unit148.
FIGS. 6A-6C illustrate in a close-up view of each of the unique insulating bodies used with snap-fit connector57.FIG. 6A and 6B illustrate a close-up view of insulatingbody54. The only difference betweenFIG. 6A andFIG. 6B is the type of flange employed.FIG. 6A hasflange64 andflange65.Flange64 has first portion68 to receivesecond panel unit80 as well as second portion72, here a curved surface, to cover joint76.Flange65 merely has first portion68.FIG. 6B illustrates insulatingbody54 having two of the same flanges, here flange64.FIG. 6C illustrates insulatingbody52 ofFIG. 4 havingflange64.
As shown inFIG. 7, panel units may be formed in sections. Here,top panel unit152 comprisesfirst body156 andsecond body160. First body166 is pressed intosecond body160 atborder164 in the direction of arrow H. Similarly, secondbottom panel unit164 hasthird body168 andfourth body172.Fourth body172 is pressed intothird body168 atborder164 in the direction of arrow H as well. Becausesecond body160 is pressed intofirst body156, snap-fit connector166 may still flexibly engagefirst mating connector40 ofsecond panel unit80. Similarly, becausefourth body172 is pressed intothird body168, snapfit connector176 may engage insulatingbody54 in a snap-fit fashion.
FIG. 8 illustrates the increased construction flexibility offered by this particular design. This design permits panel units to be constructed in shorter lengths. Accordingly, rather than employ a single panel unit having a length L as shown inFIG. 8, fourpanel units200,202,204 and206, may all be snap-fit together to form length L. Having shorter panel lengths facilitates the manufacturer of these panel units in a press.
As shown inFIG. 9, top panel unit180 may be provided with only a single snap-fit connector36 to receivepanel unit80, here a wall panel, whilefloor panel184 may have a single snap-fit connector210 to receive insulatingbody54. Such a design may be used to define the wall ends of a walk-in cooler.
As shown inFIG. 10, a panel unit is constructed by a press, here press218.Press218 is constructed from known designs and hasmoveable press220, which may be moved toward press table224 in the direction of arrow P. As shown,first skin24 andsecond skin28 are spaced generally parallel from each other withinpress218.Spacers230,232,234 and236 are used to define the space betweenfirst skin24 andsecond skin28.Cavity222 is defined byspacers230,232,234 and236 as well as byfirst skin24 andsecond skin28. In addition, firstflexible portion22 and secondflexible portion26 are placed in their proper positions incavity222.Foam injector228 then sprays foam240, here a urethane foam, intocavity222 and fillscavity222 under pressure frommoveable press220 as applied in the direction of arrow P. Oncefoam240 has dried and hardened,press220 is moved in the direction of arrow Q andspacers230,232,234, and236 are removed from completedpanel unit220.
While the foregoing designs are shown primarily in a top panel, wall panel and floor configuration, the invention encompasses the use of these panels in other configurations requiring an insulated panel assembly. Indeed, the aforementioned description is exemplary rather that limiting. Many modifications and variations of the present invention are possible in light of the above teachings. The preferred embodiments of this invention have been disclosed. However, one of ordinary skill in the art would recognize that certain modifications would come within the scope of this invention. Hence, within the scope of the appended claims, the invention may be practiced otherwise than as specifically described. For this reason the following claims should be studied to determine the true scope and content of this invention.