This invention relates to thermally insulated doors for temperature-controlled enclosures.
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.
The present disclosure relates to a display case door for a refrigerated enclosure.
In a general aspect, a display case door includes a sealed glass unit assembly, a door frame, and an electronic display. The sealed glass unit assembly includes a sealed glass unit and a subframe extending about and coupled to the sealed glass unit. The subframe includes a set of two or more subframe rails configured to hold the sealed glass unit. The door frame is coupled to the subframe and configured to support the sealed glass unit assembly in the door frame. The electronic display is coupled to the door frame in front of the sealed glass unit. The door frame is configured to couple with a display case enclosure in an opening of the display case enclosure.
In some implementations, at least one of the subframe rails defines a channel configured to receive an edge of the sealed glass unit.
In some implementations, at least one of the subframe rails includes a front rim. The front rim is secured to the door frame.
In some implementations, the door frame includes one or more rails, at least one of the rails of the door frame includes an inner rim, and the front rim of at least one of the subframe rails is coupled to the inner rim.
In some implementations, at least one of the subframe rails includes high-loaded polymer, and the door frame includes one or more rails including an aluminum alloy.
In some implementations, at least one of the subframe rails includes a front rim and defines a channel. The channel is configured to receive an edge of the sealed glass unit. The front rim extends outwardly from the channel and is coupled to the door frame.
In some implementations, the door frame further includes a back cover coupled to at least one of the subframe and the door frame. The back cover includes a slot configured to hold a gasket such that the gasket contacts a sealing surface on the display case enclosure when the display case door is installed on the display case enclosure.
In some implementations, at least a portion of the sealed glass unit is recessed relative to a sealing surface of the display case enclosure when the display case door is installed on the display case enclosure.
In some implementations, the display case further includes a back cover including a body and a blade. The body is coupled with at least one of the subframe and the door frame, the body defining a slot configured to receive a gasket. The blade extends from the body. A distal portion of the blade is configured to contact an outer surface of at least one of the subframe rails when the back cover is installed on at least one of the subframe and the door frame.
In some implementations, the display case further includes a thermally conductive material at least partially covering a front surface of at least one of the two or more subframe rails.
In some implementations, the display case door further includes a sealant between at least one of the subframe rails and a corresponding rail of the door frame.
In some implementations, the display case door further includes two or more self-clinching studs configured to couple at least one of the subframe rails to the door frame.
In some implementations, the display case door further including one or more bezels coupled to the door frame. The electronic display assembly includes one or more sensors along an edge of the electronic display. At least one of the bezels defines a cutout for at least one of the one or more sensors.
In some implementations, the display case door further including one or more cable assemblies configured to supply electrical power to the electronic display and one or more heaters for the display case door. At least one of the cable assemblies includes a switch operable by a user to turn off power to the electronic display.
In some implementations, the display case door further including one or more cable assemblies configured to supply electrical power to the electronic display and one or more heaters for the display case door. At least one of the rails includes a service access opening for at least one of the cable assemblies.
In some implementations, the display case door includes one or more heater wires coupled to at least one of the rails.
In some implementations, the display case door further including one or more left side mounting blocks coupled to the door frame and one or more right side mounting blocks coupled to the door frame. The electronic display is coupled to at least one of the one or more left side mounting blocks. The electronic display is coupled to at least one of the one or more right side mounting blocks. The electronic display is at least partially supported in the door frame on at least one of one or more left side mounting blocks and at least one of the one or more right side mounting blocks.
In some implementations, at least one of the left side mounting blocks or the right side mounting blocks includes a spacer plate configured to define a lateral spacing of the electronic display with respect to the door frame.
In some implementations, at least one of the rails of the door frame includes an inner rim. At least one of the two or more mounting blocks is coupled to the inner rim.
In some implementations, the door frame includes one or more display supports. The electronic display further includes one or more hangers configured to couple with at least one of the display supports. The hangers are configurable to support the electronic display in the door frame.
In a general aspect, a rail system for a display case door includes a rear rail and a front rail. The rear rail is configured to hold an edge of a sealed glass unit of the display case door. The front rail coupled to the rear rail. At least one of the front rail and rear rail is configurable to couple with a gasket such that the gasket contacts a sealing surface on a display case enclosure when the display case door is coupled to the display case enclosure.
In some implementations, the rear rail is included in a subframe for the sealed glass unit. The front rail is included in a door frame. The subframe is configurable to couple with the door frame to support the sealed glass unit in the door frame.
In some implementations, the rear rail defines a channel configured to receive an edge of the sealed glass unit.
In some implementations, the rear rail includes a front rim extending outwardly from the channel. The front rail is configured to couple with the front rim.
In some implementations, the rail system further includes a back cover. The back cover including a body and a blade. The body is coupled with at least one of the rear rail and the front rail. The body defining a slot configured to receive a gasket. The blade extends from the body. A distal portion of the blade is configured to contact an outer surface of the rear rail when the back cover is installed on at least one of the subframe and the door frame.
In some implementations, the rear rail includes high-loaded polymer, and the front rail includes an aluminum alloy.
In some implementations, the rail system further includes a thermally conductive material disposed on at least a portion of a front surface of the rear rail.
In a general aspect, a method of making a display case door includes installing two or more subframe rails on a sealed glass unit to form a subframe around the sealed glass unit; and coupling each of at least one of the two or more subframe rails to a corresponding rail of a door frame to install the sealed glass unit in the door frame.
In some implementations, at least one of the two or more subframe rails includes a channel installing the two or more subframe rails on the sealed glass unit to form a subframe around the sealed glass unit includes installing an edge of the sealed glass unit in the channel.
In some implementations, at least one of the two or more subframe rails includes a front rim. Coupling each of at least one of the two or more subframe rails to the corresponding rail of the door frame to install the sealed glass unit in the door frame; includes securing the front rim of the subframe rail to a corresponding rail of the door frame.
In some implementations, the method further includes installing a back cover on at least one of the subframe and the door frame. The back cover is configured to hold a gasket.
In some implementations, the method further includes installing a thermally conductive material on a front surface of at least one subframe rail.
In some implementations, the method further includes installing an electronic display on the door frame in front of the sealed glass unit.
The method further includes installing the display case door on a display case enclosure.
In a general aspect, a display case door includes a sealed glass unit assembly, a door frame, and an electronic display. The sealed glass unit assembly a sealed glass unit one or more rear rails coupled to the sealed glass unit. The sealed glass unit including three or more panes of glass spaced from one another. The door frame includes two or more front rails. At least one of the rear rails is coupled to at least one of the front rails. The electronic display is coupled to the door frame in front of the sealed glass unit. The door frame is configured to couple with a display case enclosure in an opening of the display case enclosure.
In some implementations, at least a portion of the sealed glass unit is recessed relative to a sealing surface of the display case enclosure when the display case door is installed on the display case enclosure.
In some implementations, at least one of the rear rails includes high-loaded polymer, and one or more of the front rails includes an aluminum alloy.
In some implementations, at least one of the rear rails defines a channel configured to receive an edge of the sealed glass unit.
In a general aspect, a rail system for a display case door includes a rear rail, a front rail, a back cover, and a gasket. The rear rail is configured to hold an edge of a sealed glass unit of the display case door. The front rail is coupled to the rear rail. The back cover is coupled to at least one of the front rail and the rear rail. The gasket is coupled to the back cover. The gasket is configured to contact a sealing surface on a display case enclosure when the display case door is coupled to the display case enclosure.
In some implementations, the front rail is configured to couple with an edge of an electronic display.
In some implementations, the back cover includes a rear surface and defines a slot. The gasket is coupled in the slot on the rear surface of the back cover.
In some implementations, the back cover includes a body and a blade. The body is coupled with at least one of the rear rail and the front rail. The body defines a slot configured to receive a gasket. The blade extends from the body. A distal portion of the blade is configured to contact an outer surface of the rear rail when the back cover is installed on at least one of the subframe and the door frame.
In some implementations, the back cover includes a blade. The blade includes a distal tip. The distal tip is configured to bear against an outer surface of the rear rail when the back cover is coupled to at least one of the front rail and the rear rail.
In some implementations, contact between the blade and an outer surface of the rear rail inhibits condensation on the display case door when the display case door is installed on a refrigerated enclosure.
In some implementations, the rear rail includes high-loaded polymer, and the front rail includes an aluminum alloy.
In some implementations, the rail system further includes a thermally conductive material disposed on at least a portion of a front surface of the rear rail.
In some implementations, the thermally conductive material on the front surface of the rear rail includes tape.
In some implementations, the thermally conductive material on the front surface of the rear rail inhibits condensation on the display case door when the display case door is installed on a refrigerated enclosure.
In some implementations, the rear rail defines a channel configured to receive an edge of the sealed glass unit.
In some implementations, the rear rail includes a front rim extending outwardly from the channel. The front rail is configured to couple with the front rim.
In a general aspect, a rail system for a display case door includes a rear rail, a front rail, and a back cover. The rear rail is configured to hold an edge of a sealed glass unit. The front rail coupled to the rear rail. The back cover includes a body and a blade. The body is configured to couple with at least one of the rear rail and the front rail. The body defining a slot configured to receive a gasket. The blade extends from the body. A distal portion of the blade is configured to contact the outer surface of the rear rail when the back cover is installed on at least one of the front rail and the rear rail.
In some implementations, the distal portion of the blade of the back cover is configured to be deflected by the rear rail when the back cover is installed on at least one of the front rail and the rear rail.
In some implementations, the blade is angled relative to an outer surface of the rear rail when the back cover is installed on at least one of the front rail and the rear rail.
In some implementations, the distal portion of the blade of the back cover includes a flexible material.
In some implementations, the body of the back cover includes a first polymeric material. At least the distal portion of the blade of the back cover includes a second polymeric material that is more flexible than the first polymeric material.
In some implementations, the back cover is produced by co-extrusion such that at least the distal portion of the blade includes a material that is more flexible than the body of the back cover.
In some implementations, the distal portion includes a flexible PVC elastomer.
In a general aspect, a rail system for a display case door includes a rear rail, a front rail, and a thermally conductive material. The rear rail is configured to hold an edge of a sealed glass unit of the display case door. The front rail is coupled to rear rail. The thermally conductive material at least partially covers a front surface of the rear rail.
In some implementations, the thermally conductive element includes a metal tape.
In some implementations, the thermally conductive element includes an aluminum tape with a thermally conductive adhesive.
In some implementations, the thermally conductive element includes a coating.
In some implementations, the thermally conductive element is configured to conduct heat from the front rail.
In some implementations, the thermally conductive material on the front surface of the rear rail is configured to inhibit condensation on the front surface of the rear rail.
In some implementations, the thermally conductive material is in contact with the front rail.
In some implementations, the thermally conductive material is thermally coupled to the front rail.
In some implementations, the front rail includes an aluminum alloy. The thermally conductive material substantially covers the front surface of the rear rail between a front glass surface of the sealed glass unit and a front rail.
In some implementations, the rear rail includes a polymer.
In some implementations, the rear rail includes a high loaded polymer.
In some implementations, the front rail includes an aluminum alloy.
In some implementations, the rail system includes a back cover and a gasket. The back cover is coupled to at least one of the front rail and the rear rail. The gasket is coupled the back cover. In some implementations, the gasket is configured to contact a sealing surface on a refrigerated enclosure when the display case door is coupled to the refrigerated enclosure.
In a general aspect, a display case door includes an insulated panel assembly, one or more rear rails, a door frame, an electronic display, and a wire harness. The one or more rear rails are coupled to the insulated panel assembly. The door frame includes two or more front rails. The electronic display is coupled to the door frame in front of the insulated panel assembly. The wire harness is configured to supply electrical power to the electronic display. At least one of the one or more rear rails is coupled to at least one of the one or more front rails. The door frame is configured to couple with a display case enclosure in an opening of the display case enclosure.
In some implementations, at least one of the front rails includes one or more wireways. A portion of the wire harness passes through at least one of the wireways in at least one front rail.
In some implementations, the wire harness includes one or more branches configured to supply electrical power to the electronic display, one or more branches configured to supply electrical power to one or more door rail heaters, and one or more branches configured to supply electrical power to one or more glass heaters.
In some implementations, the wire harness is configurable to connect and disconnect power individually to each of the electronic display, at least one of the rail heaters, and at least one of the glass heaters.
In some implementations, the wire harness includes one or more branches configured to supply electrical power to one or more sensors of the electronic display.
In some implementations, the wire harness includes one or more switches operable by a user to switch power to the electronic display on and off.
In some implementations, at least one of the switches is on a bottom rail of the door frame.
In some implementations, the wire harness includes one or more branches configured to transmit data to and from the electronics display.
In some implementations, at least one of the two or more front rails includes one or more cable access openings adjacent to a portion of the wire harness.
In some implementations, a first portion of the wire harness passes through a wireway on the left side of the electronic display, and a second portion of the wire harness passes through a wireway on the right side of the electronic display.
In some implementations, the wire harness includes a hinge pin connector. Electrical power is supplied to the display case door through the hinge pin connector.
In some implementations, the insulated panel assembly includes a sealed glass unit includes three or more panes of glass.
In some implementations, at least a portion of the sealed glass unit is recessed relative to a sealing surface of the display case enclosure when the display case door is installed on the display case enclosure.
In a general aspect, a display case door includes an insulated panel assembly, a door frame, an electronic display, and a wire harness. The door frame includes two or more rails coupled to the insulated panel assembly. The electronic display is coupled to the door frame in front of the insulated panel assembly. The wire harness is configured to supply electrical power to the electronic display. The door frame is configured to couple with a display case enclosure in an opening of the display case enclosure. At least one of the two or more rails includes one or more wireways. At least a portion of the wire harness passes through at least one of the one or more wireways in at least one rail. At least one rail includes one or more cable access openings adjacent to a portion of the wire harness.
In some implementations, the display case door includes a cover configured to couple in at least one of the one or more cable accessing openings.
In a general aspect, a display case door includes an insulated panel assembly, a door frame, and one or more bezels. The door frame includes two or more rails coupled to the insulated panel assembly. The electronic display is coupled to the door frame in front of the insulated panel assembly. The one or more bezels are configured to couple to the door frame on one or more edges of the electronic display. The door frame is configured to couple with a display case enclosure in an opening of the display case enclosure. The electronic display includes one or more sensors along an edge of the electronic display. At least one of the bezels defines one or more cutouts for at least one of the one or more sensors.
In some implementations, at least one of the one or more bezels includes a flat plate. At least a portion of at least one of the cutouts is in the flat plate.
In some implementations, at least one of the one or more cutouts is a notch along an edge of the bezel.
In some implementations, at least one of the one or more cutouts is an aperture in the bezel.
In some implementations, at least a portion of at least one of the one or more sensors protrudes through at least one of the one or more cutouts.
In some implementations, at least one of the sensors includes a camera.
In some implementations, at least one of the sensors includes a TOF sensor.
In some implementations, at least one of the bezels is configured to cover at least a portion of a mounting block between the electronic display and at least one of the rails of the door frame.
Particular implementations of the subject matter described in this specification can be implemented so as to realize one or more of the following advantages.
Implementations of the present disclosure may improve the maintainability of electronic displays mounted to a display case door. For example, implementations of the present disclosure may provide for easy replacement or maintenance of SGU assemblies.
Implementations of the present disclosure may reduce handling costs and simplify logistics.
Implementations of the present disclosure may simplify display case door removal and increase the safety of the operation.
Implementations of the present disclosure may reduce a risk of condensation on a display case door.
Implementations of the present disclosure may provide a single system that complies with governmental requirements for both normal temperature and low temperature applications (e.g., Department of Energy requirements).
Implementations of the present disclosure may reduce a risk of installing a normal temperature door into a low temperature opening, which may result in condensation.
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.
In some implementations, a display case door includes one or more bezels (omitted from
Insulated panel assembly 104 can include one or more panes of glass. In some implementations, insulated panel assembly 104 includes two or more layers of transparent panes bounding a sealed space in between, forming a sealed glass unit (SGU).
In some implementations, the gap or sealed space can between two or more panels can be filled with an insulating gas such as a noble gas (e.g., Argon, Krypton, etc.) which functions as a thermal insulator to reduce heat transfer through the panel. In some examples, the sealed space can be evacuated below atmospheric pressure.
Door frame 106 extends around and is secured to a peripheral edge of insulated panel assembly 104. As further described in detail below, door frame 106 defines a channel or tunnel that receives one or more power cables that provide electrical power to the electronic display assembly.
Display case door 100 can include a single electronic display or multiple electronic displays. For example, display case door 100 can include two or more electronic displays vertically stacked and together covering the insulated panel assembly 104.
Electronic display 110 can include, but is not limited to, a liquid crystal display (LCD), a light emitting diode (LED) display, an organic light emitting diode (OLED) display, a field emission display (FED), a plasma display panel (PDP), or an electroluminescent (EL) display. For example, electronic display 110 can be a smart television with streaming capabilities for receiving content over a wireless network (e.g., a Wi-Fi network). Electronic display 110 is generally opaque and, when mounted on the display case door 100 partially or completely obstructs the view through the insulated panel assembly 104. In some implementations, electronic display 110 can be a custom sized display configured to correspond with dimensions of the display case door 100. In some implementations, electronic display 110 can be a commercial off the shelf (COTS) display.
Electronic display assembly 102 includes electronic display 110, left side hinge brackets 112, right side brackets 114, and hangers 116. Left side hinge brackets 112 are attached to electronic display 110 along the left side of electronic display 110. Right side brackets 114 are attached to electronic display 110 along the right side of electronic display 110. Each of left side hinge brackets 112 and right side brackets 114 is secured to a corresponding one of mounting blocks 108 by way of screws 113 and screws 115, respectively. Door frame 106 includes top rail 120 and side rails 122. Electronic display assembly 102 is mounted on mounting blocks 108 on the left side rail 122 of door frame 106 and mounting blocks 108 on the right side rail 122 of door frame 106. Each of hangers 116 can be coupled on a corresponding one of display supports 118.
In the example shown in
Display case door 100 includes handle 130. Electronic display assembly 102 includes circuitry module 132, top sensor 134, and handle-side sensor 136. The outside edges of circuitry module 132 are secured to left rail 206 and right rail 208 of door frame 106. Left bezel 124 and right bezel 128 can be attached to their respective rails. Top sensor 134 passes through an opening or cutout in top bezel 126. Handle-side sensor 136 is accessible through a corresponding aperture in right bezel 128.
Hold open bracket 138 is provided on a top edge of display case door 100. One end of hold open bracket 138 is pivotally coupled to door frame 106. In service, hold open bracket 138 can be used to maintain door in a desired open position.
Circuitry module 132 is positioned in a bottom portion of door frame 106. Circuitry module 132 overlays a portion of insulated panel assembly 104. Circuitry module 132 can be attached to electronic display 110 such that, with electronic display 110 releasably coupled to door frame 106, circuitry module 132 is releasably coupled to door frame 106. Circuitry module 132 can include a media player in electronic communication with electronic display 110 to control media content presented on electronic display 110.
In the example shown in
In some implementations, one or more of the mounting blocks serve as a spacer plate. The mounting blocks can define a position of the electronic display relative to a door frame.
To install sealed glass unit assembly 104 in door frame 106, each of the subframe rails 204 of sealed glass unit assembly 104 is secured to a corresponding rail of the door frame. For example, the one of left subframe rails 204 is coupled to left rail 206 and the right one of subframe rails 204 is coupled to right rail 208. Back cover 210 is coupled to left rail 206 and the adjacent subframe rail 204. Back cover 212 is coupled to right rail 208 and the corresponding subframe rail 204. In a similar manner, the top and bottom subframe rails can be secured to corresponding top and bottom rails of the door frame, and top and bottom back covers can be secured to the corresponding top and bottom rails of the door frame.
In this example, left rail 206 of door frame 106 (shown in
Subframe rail 204 and left rail 206 can be coupled to one another by way of fasteners, such as screws or rivets. In one implementation, subframe rail 204 is attached using self-clinching studs. SGU assembly 202 is installed in the door frame by securing each of subframe rails 204 (left, right, top, and bottom) to a corresponding rail of door frame 106.
Display case door 100 includes sealed glass unit assembly 104. Sealed glass unit assembly 104 is installed on door frame 106. In this example, front rim 224 of subframe rail 204 is contained between inner rim 216 of left rail 206 and the front face of back cover 210. In some implementations, subframe 204 is connected to left rail 206 by way of studs (for example, studs 226) and secured by way of a nuts installed on the studs.
Sealed glass unit 200 includes glass panes 240 and spacers 242. In the example shown in
Back cover 210 is attached to left rail 206. Gasket 244 is installed in slot 230 of back cover 210. When display case door 100 is closed on display case enclosure 240, gasket 244 contacts sealing surface 246 of display case enclosure 240 to seal air in display case enclosure 240. In some implementations, sealing surface 246 is included on a frame installed in an opening in display case enclosure 240. Blade 248 of back cover 210 bears against an outer surface 250 of subframe rail 204. As will be further discussed below, blade 248 can serve as a thermal break for air in display case enclosure 240.
Sealed glass unit 200 can be at least partially recessed relative to the front of display case enclosure. In this example, two of the three panes 240 are to the rear of sealing surface 246 of display case enclosure 240.
Subframe rail 204 includes slots 252. Screws 254 can be installed in slots 252 to couple adjacent subframe rails 204 of SGU subframe 202 to secure SGU subframe 202 on sealed glass unit 200. Slots 252 can receive screws to join the miters of the subframe rail 204, which creates the SGU subframe 202.
Display case door 100 includes thermally conductive tape 256 on a front surface of subframe rail 204. As will be further described below, thermally conductive tape 256 can inhibit condensation on display case door 100. Heater wire 257 can be included between back cover 210 and left rail 206. In some implementations, sealed glass unit 200 includes one or more heater wires (omitted for clarity in
In some implementations, back cover 210 is co-extruded from two or more polymeric materials. For example, distal portion 264 can be extruded from one polymeric material and the rest of back cover 210 can be extruded from another polymeric material. In one implementation, distal portion 264 is a PVC elastomer. In some implementations, distal portion 264 is a flexible PVC and the rest of back cover 210 is a rigid PVC, coextruded as a single plastic piece.
When back cover 210 is installed on the rail system, distal tip 264 of blade 248 may contact and bear against an outer surface of the rail system. For example, referring again to
In some implementations, a thermally conductive material is applied to a front surface of a subframe rail.
Thermally conductive tape 256 can be in contact with the front edge of the adjacent rails of door frame 104. In some implementations, the rails of the door frame are made of an aluminum alloy or other thermally conductive material. In certain implementations, thermally conductive tape can be applied over a portion of a front rail of the door frame. Thus, in this example, an outer edge of thermally conductive tape 256 can be applied on side rail 274 and top rail 276.
As illustrated in
In one implementation, thermally conductive tape 256 is an aluminum tape with a thermally conductive adhesive. In another implementation, thermally conductive tape 256 is a copper tape with a thermally conductive adhesive. Other examples of thermally conductive materials include acrylic tape, or a thermally conductive coating, such as a thermally conductive epoxy. In certain implementations, a surface rail is covered with a tape that includes a closed cell PVC foam of light density with a PVC backing, with an acrylic adhesive on one side.
Similar to the display case door shown in
In certain implementations, circuitry module 526 can include one or more quick disconnect plugs. A quick disconnect plug can be attached to the first end of a control cable. The quick disconnect plug can also attached to power cable 529. The quick disconnect plug may include a power, audio, visual, or ground wire.
Referring also to
In some implementations, a power switch for a display case door is inset into the door frame below a bottom surface of the frame.
Referring again to
Electrical power is provided to display case door 600 through hinge pin connector 614. Power lines can be paired such that different branches of the power lines provide power to each of the loads of display case door 600. Splitters 616 branch electrical power between electronic display assembly 602 and the heaters. Splitters 618 branch electronic power between door rail heaters 604 and glass heaters 606.
Wires from red wire assembly 704 and white wire assembly 706 can be paired and attached to individual loads, including door rail heaters and glass heaters. In this example, one pair of wires forms a branch 714 that supplies power to door rail heaters 714 and another pair of wires forms a branch that supplies power to glass heaters 716.
Power is passed from frame to door through hinge pin connector 702. Power can then be split into two or more connections. In one implementation, power is split into two connection so that one circuit powering the door heaters. The other connection than be split again into two connections to power the display and glass heaters.
Switch 720 can be used to turn power on or off to the electronic display. Connectors 712 can be used (e.g., by maintenance personnel) to connect and disconnect power individually to the door rail heaters or glass heaters. In some implementations, a field service technician can power/depower each of electronic display, door rail heater, and glass heater individually. In some implementations, a switch is provided on one or more of the lines to some or all of the door rail heaters or glass heaters.
In some implementations, wire harness 700 is provided in a left hand configuration and a right hand configuration. One of the configurations can be used on each side of the electronic display.
In this example, rail 720 is on the hinge-side of a display case door. In other implementations, access openings are provided in other locations on a display case door.
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. There are and will be other examples and modifications within the scope of the following claims. Furthermore, one of skill in the art would appreciate that features described in reference to a specific embodiment are not limited to that embodiment and can be interchanged with features of other embodiments.
This application claims priority to, and the benefit of, U.S. Application Ser. No. 63/287,930, filed on Dec. 9, 2021, and entitled “Electronic Display Mounting in Display Case Door,” the entire contents of which is incorporated by reference herein.
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Number | Date | Country | |
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20230180948 A1 | Jun 2023 | US |
Number | Date | Country | |
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63287930 | Dec 2021 | US |