This invention relates to thermally insulated doors for temperature controlled environments.
Refrigerated enclosures are used in commercial, institutional, and residential applications for storing and/or displaying refrigerated or frozen objects. Refrigerated enclosures may be maintained at temperatures above freezing (e.g., a refrigerator) or at temperatures below freezing (e.g., a freezer). Refrigerated enclosures have one or more thermally insulated doors or windows for viewing and accessing refrigerated or frozen objects within a temperature-controlled space. Doors for refrigerated enclosures generally include thermally insulated glass panel assemblies.
In some circumstances, plastic door assemblies may provide advantages over glass panel assemblies. However, plastic panel doors can be more expensive than glass to mold and manufacture.
In a first general aspect, innovative features of the subject matter described in this specification can be embodied a display case door. The door includes a panel assembly including a first transparent pane and a second transparent pane. The first transparent pane includes, in cross-section, respective flanges extending from each of a first edge and a second edge of a shaped portion, where the shaped portion extends out of a plane formed by the flanges. The second transparent pane is adhered to both flanges of the first pane to define a space between facing surfaces of the second transparent pane and the shaped portion of the first transparent pane and extending between openings at opposite ends of the panel assembly. Caps are coupled to the panel assembly and cover the openings at each of the first end and second end. Each of the caps includes a body portion and a cap flange. The body portion is shaped to correspond with the cross-section of the panel assembly and is configured to couple to both the first transparent pane and the second transparent pane at an end of the panel assembly, thereby, covering one of the openings. The cap flange extends away from the body portion of the cap. The door further includes a hinge coupled to one of the flanges of the first transparent pane, a door handle secured to a surface of one of the flanges of the first pane, and an edge guard coupled along an edge of at least one of the flanges, where the edge guard includes a flexible wiper configured to form a seal with another surface with the door in a closed position. This and other implementations can each optionally include one or more of the following features.
In some implementations, the first pane comprises acrylic or polyethylene terephthalate (PETG).
In some implementations, the second pane is welded to the flanges.
In some implementations, the flanges and shaped portion, together, form a top hat-shaped cross-section.
In some implementations, the handle is secured to the surface of the one of the flanges with an adhesive.
In some implementations, the handle is secured to the one of the flanges with a mechanical fastener.
In some implementations, edges of the second pane are substantially coextensive with edges of the flanges of the first pane.
In some implementations, the first pane is an extruded plastic material having a substantially constant cross-section along its length parallel to the flanges.
In some implementations, the caps are coupled with an adhesive
In some implementations, the caps are mechanically coupled to the panel assembly.
In a second general aspect, innovative features of the subject matter described in this specification can be embodied in installation methods for a display case door that include the actions of trimming a panel assembly, where the panel assembly includes a first pane and a second pane. The first pane includes, in cross-section, a flange extending from each of a first edge and a second edge of a shaped portion, the shaped portion extending out of a plane formed by the flanges. The second pane a second pane is adhered to both flanges of the first pane forming a space between the respective facing surfaces of the second pane and the shaped portion of the first pane and openings at first end and second end of the panel assembly. Trimming the panel assembly includes cutting the panel assembly to a desired height by cutting across the panel assembly substantially parallel to one of the openings and from one of the flanges to the other of the flanges. Installing caps over the openings at the first end and the second end of the trimmed panel assembly, where each cap includes a body portion shaped to correspond with the cross-section of the panel assembly with a cap flange extending away from the body portion. This and other implementations can each optionally include one or more of the following features.
In some implementations, the trimming further comprises cutting the panel assembly to a desired width by trimming at least one of the flanges.
In some implementations, the method includes installing the hinges on the cap flange.
In some implementations, the method includes installing the door into a frame of a display case.
In some implementations, the method includes installing a handle on the panel assembly.
In some implementations, the method includes installing edge guards along respective edges of the flanges.
In a first general aspect, innovative features of the subject matter described in this specification can be embodied a display case including a frame with a first display case door and a second display case door mounted to the frame. Each of the first display case door and the second display case door include a panel assembly with caps coupled to the panel assembly. The panel assembly includes a first transparent pane and a second transparent pane. The first transparent pane includes, in cross-section, respective flanges extending from each of a first edge and a second edge of a shaped portion, the shaped portion extending out of a plane formed by the flanges. The second transparent pane is adhered to both flanges of the first pane to define a space between facing surfaces of the second transparent pane and the shaped portion of the first transparent pane and extending between openings at opposite ends of the panel assembly. The caps are coupled to the panel assembly and cover the openings at each of the first end and second end. Each of the caps includes a body portion and a cap flange. The body portion is shaped to correspond with the cross-section of the panel assembly and configured to couple to both the first transparent pane and the second transparent pane at an end of the panel assembly, thereby, covering one of the openings. The cap flange extends away from the body portion. Each of the doors further include a hinge coupled to one of the flanges of the first pane and the hinge is configured to couple to the hinge receiving portion of the frame, a door handle secured to a surface of one of the flanges of the first pane, and an edge guard coupled along an edge of at least one of the flanges where the edge guard includes a flexible wiper. The first door and the second door are positioned within the frame such that the flexible wiper of the first door forms a seal with the flexible wiper of the second door of each door, with both doors in a closed position. This and other implementations can each optionally include one or more of the following features.
In some implementations, edges of the second pane are substantially coextensive with edges of the flanges of the first pane.
In some implementations, the first pane is an extruded plastic material having a substantially constant cross-section along its length parallel to the flanges.
In some implementations, the flanges and shaped portion, together, form a top hat-shaped cross-section.
The concepts described herein may provide several advantages. For example, implementations of the invention may a size configurable plastic panel assembly for a refrigerated cabinet door. For example, the plastic panel assembly may be molded in only two dimensions, thereby, permitting more efficient use of materials and more cost effective molding and manufacturing techniques. Furthermore, the plastic panel may permit customization of door sizes at the installation site instead of at the manufacturer. The ability to customize door sizes at the installation site may provide improved door fit, e.g., for retrofitting doors to existing cases. Improved door fit may translate to better thermal insulation and improved energy efficiency.
Implementations may provide lighter weight doors compared to existing glass panel doors. Implementations provide improved consumer safety. For example, plastic panel doors may be shatterproof. Implementations may provide improved thermal insulation compared to some glass panel doors. Implementations may be entirely or nearly entirely transparent, thereby, improving the visibility of products displayed behind the door while jointly improving energy efficiency of a refrigerated cabinet.
The details of one or more embodiments of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
As illustrated, refrigerated display case 10 has multiple display case doors 12 mounted on a frame 14. Each door 12 is pivotally mounted on hinges 18 that connect the door 12 to frame 14. In some implementations, doors 12 can be sliding doors configured to open and close by sliding with respect to case frame 14. For example, hinges 18 can be replaced by a pair of corresponding rails coupled, respectively, to each door 12 and frame 14.
Referring to
Panes 21 and 23 are coupled together to form panel assembly 20. Panes 21 and 23 are configured to define a space between their respective inner surfaces 28 and 29 when the two panes 21 and 23 are joined. For example, pane 21 includes a shaped portion 26 with two flanges 27 extending outward from the shaped portion 26. The flanges 27 provide a mating surface for joining pane 21 with pane 23. The shaped portion 26 is arranged to extend away from pane 23, thereby, defining the space between the two panes 21 and 23. In some implementations, flanges 27 form a plane (not shown) from which the shaped portion 26 extends. In other words, both flanges 27 can be positioned substantially within a common plane with the shaped portion 26 extending outside of the plane formed by the flanges 27.
Pane 23 can be a substantially flat pane, as illustrated. Pane 23 is joined to pane 21 by being adhered to flanges 27 of pane 21. For example, pane 23 is approximately the same width and length as pane 21 such that edges 23a of pane 23 are substantially coextensive with edges 21a at each end of flanges 27. Pane 23 can be adhered to flanges 27 of pane 21 using, e.g., an adhesive or by welding/bonding. Inner surfaces 28 and 29 are exposed to the space formed between panes 21 and 23.
Referring to
Pane 21 can be made of an extruded plastic material with a constant cross-section along its length parallel to flanges 27. In some implementations, pane 21 may be made using a different method such as vacuum forming or compression molding. The shaped portion 26 is illustrated as forming a “U-shape” which, together with the flange 27 forms a “top-hat” shaped cross-section along the length of pane 21. In some implementations, shaped portion 26 may be formed to have different shapes (e.g., an arched-shape).
Panel assembly 20 has an opening at each end 12a and 12b. The openings are covered by caps 22 (as shown in
Cap 22 also includes cap flange 31 that extends away from body portion 32. Flange 31 provides a structure for attaching hardware (e.g., hinges or slide rails) for mounting door 12 within frame 14. For example, hinge 18 is coupled to the cap flange 31 for connecting the display case door 12 to the display case frame 14, as shown in
Door handle 16 is secured to the surface of one of the flanges 27 of pane 21. Handle 16 may be attached to panel assembly 20 by using an adhesive or epoxy. In some implementations, handle 16 can be secured to panel assembly 20 with mechanical fasteners (e.g., bolt/screw). Handle 16 may be used to open, close, lock, unlock, seal, unseal, or otherwise operate display case door 12. Handle 16 can be made from extruded aluminum tubes that are cut to a specified dimension and bonded to a surface of panel assembly 20. Handle 16 is illustrated as being attached to the outer surface of pane 21, however, in some implementations, handle 16 can be attached to the outer surface of pane 23.
Edge guards 17 are coupled to panel assembly 20. Edge guards 17 may protect, seal and/or improve the aesthetic appearance of door 12. Edge guards 17 are coupled to an edge of flanges 27. Edge guards 17 can include a flexible wiper configured to form a seal with another surface or another edge guard with the door in a closed position (see
In some implementations, panel assembly 20 may be used as part of a door 12 configured to provide a thermal insulation (e.g., for a refrigerated display case) or otherwise used as any type of transparent or substantially transparent panel that provides a thermal insulation effect (e.g., a sliding or hinged window, a fixed-position window, a revolving or sliding door, a hinged door, etc.). In some implementations, panel assembly 20 may be used as an insulated window for a refrigerated display case.
The design of the panel assembly to have a substantially consistent cross-section along its entire length allows the doors to be customized to more precisely fit refrigerated case openings. The ability to customize door sizes at the installation site may reduce manufacturing costs and provide many benefits, such as increased customization and versatility of the display case door. Also, the ability to customize door sizes may provide improved door fit, e.g., for retrofitting doors to existing cases. Improved door fit may translate to better thermal insulation and improved energy efficiency.
The elements and assemblies discussed herein may be constructed from any of a wide variety of materials that provide sufficient strength or durability, in any of a wide variety of colors, textures, and combinations. Further, elements shown as integrally formed may be constructed of multiple parts or elements.
As used herein, the terms “generally,” “substantially,” and similar terms are intended to have a meaning consistent with the common and accepted usage by those of ordinary skill in the art to which the subject matter of this disclosure pertains. For example, the use of such terms indicates values or measurements that are within acceptable engineering, machining, or measurement tolerances within the art. Accordingly, these terms should be interpreted as indicating that insubstantial or inconsequential modifications or alterations of the subject matter described and claimed are considered to be within the scope of the invention as recited in the claims.
It should be noted that the orientation of various elements may differ according to other exemplary implementations, and that such variations are intended to be encompassed by the present disclosure.
While a number of examples have been described for illustration purposes, the foregoing description is not intended to limit the scope of the invention, which is defined by the scope of the appended claims.
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