The present invention relates to a refrigerated merchandiser that includes a light source. More particularly, the present invention relates to a refrigerated merchandiser including a light emitting diode (LED) light source to illuminate a product display area.
In conventional practice, commercial businesses such as supermarkets and convenience stores are equipped with refrigerated merchandisers. These refrigerated merchandisers may be open or provided with doors and are used for presenting perishable food or beverages to customers while maintaining the fresh food or beverages in a refrigerated environment. Typically, these refrigerated merchandisers include a light source to illuminate the product display area for better marketing of the food product and for higher visibility to the customers.
Conventional refrigerated merchandisers typically include a fluorescent light source to illuminate the product display area. Some refrigerated merchandisers include fluorescent light sources coupled to a canopy of the refrigerated merchandiser to direct light generally downward onto the food product in the product display area. These refrigerated merchandisers also may include fluorescent light sources attached to shelves in the product display area. Generally, the fluorescent light sources used in conventional refrigerated merchandisers are relatively large, and can reduce the amount of space in the refrigerated merchandiser that can be allocated to displaying food product.
The effectiveness of fluorescent light sources is dependent on the temperature of the application where the fluorescent light sources are used. In colder temperature conditions, the fluorescent light source has less light output than in application of the fluorescent light source in warmer temperature conditions. As a result, fluorescent light sources that are coupled to the shelves can have substantially reduced effective illumination of food product within the product display area.
Some refrigerated merchandisers include light emitting diode (LED) light sources to illuminate the product display area. These LED light sources generally operate at a relatively high current (e.g., 300 mA), which produces a substantial amount of heat that can adversely affect the temperature of the food product in the product display area. The large amount of heat produced by these LED light sources can adversely affect the effective life of the light source.
Replacing light sources in existing refrigerated merchandisers can be relatively complex and inefficient. Generally, refrigerated merchandisers must be modified to accommodate a replacement light source from a different manufacturer. Often, additional holes are needed in the existing canopy and/or shelves to adapt the existing refrigerated merchandiser to the replacement light source, which can increase the complexity of the assembly process and the time needed to replace the light source.
The invention provides an improved refrigerated merchandiser configured to illuminate a product display area effectively and efficiently. In one embodiment, the invention provides an improved light source that enables improved illumination of the product display area and reduces the energy required to refrigerate the products within the refrigerated merchandiser.
In another embodiment, the invention provides a light assembly for a refrigerated merchandiser that includes a case that defines a product display area for supporting product and that has at least one mullion. The light assembly includes a housing that is attachable to the mullion and that includes a first receiving portion and a second receiving portion that is spaced apart from the first receiving portion. The light assembly includes at least one specular member that is coupled to the housing within the first receiving portion, and a LED light source that is coupled to the housing within the second receiving portion substantially opposite the specular member. The LED light source includes a first light portion and a second light portion directed along at least one illumination path. The first light portion is directed along the at least one illumination path in a first direction directly toward the product display area, and the second light portion is directed along the at least one illumination path toward the specular member and reflected by the specular member in a second direction that is at least partially opposite the first direction.
In yet another embodiment, the invention provides a refrigerated merchandiser that includes a case that defines a product display area, and that has at least one shelf for supporting product in the product display area. The refrigerated merchandiser also includes a price tag molding that is coupled to a front of the shelf and that displays information related to the product supported on the shelf The refrigerated merchandiser further includes a light assembly that is positioned under the shelf adjacent and behind the price tag molding when viewed from outside the case. The light assembly is substantially hidden from view by the price tag molding, and includes a housing that extends along a substantial width of the shelf and that has a light receiving portion. The light assembly also has at least one LED light source, a first specular member, and a second specular member. The LED light source is coupled to the housing within the light receiving portion to direct light generally toward the product display area. Each of the first specular member and the second specular member is coupled to the housing and located adjacent the LED light source to reflect a portion of the light from the LED light source toward the product display area. The refrigerated merchandiser further includes a magnet that is coupled to the housing opposite the LED light source and that extends along a substantial length of the housing to attach the light assembly to the shelf.
Other aspects of the invention will become apparent by consideration of the detailed description and accompanying drawings.
Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. The use of “including,” “comprising,” or “having” and variations thereof herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Unless specified or limited otherwise, the terms “mounted,” “connected,” “supported,” and “coupled” and variations thereof are used broadly and encompass both direct and indirect mountings, connections, supports, and couplings. Further, “connected” and “coupled” are not restricted to physical or mechanical connections or couplings.
In some embodiments, the case 15 includes a casing 50 adjacent a front of the merchandiser 10.
Each door 65 includes a frame 75 that attaches a translucent member 80 to the door 65 to allow viewing of the food product from outside the case 15. The translucent member 80 can be formed from glass, or alternatively, from other materials that are substantially translucent (e.g., acrylic, etc.). In some embodiments, the case 15 can include doors 65 without attachment of the doors 65 to mullions 55. In still other embodiments, the case 15 can be an open-front case without the mullions 55 and doors 65.
The W-shaped housing is defined by end walls 150, middle walls 155, interior walls 160, and a bridge 165 that connects the interior walls 160 to each other. The end walls 150 extend generally outward from the middle wall 155 to obscure visibility of the LED light sources 105 from outside the merchandiser 10, and include first receiving portions 170 defined on an end of the end walls 150. Each end wall 150 is angularly spaced from one middle wall 155, and is further disposed at a first angle 175 from the axis 130. In the illustrated embodiment, the first angle 175 is about 20 degrees. In other embodiments, the first angle 175 can be larger or smaller than 20 degrees.
Each middle wall 155 is oriented horizontally and perpendicular to the axis 130, and includes a second receiving portion 180 that is formed as part of the extruded body. The interior walls 160 are angularly spaced from the middle walls 155 and the bridge 165, and define a second angle 190 relative to the axis 130. In the illustrated embodiment, the second angle 190 is about 20 degrees. In other embodiments, the second angle 190 can be larger or smaller than 20 degrees. Each interior wall 160 includes light receiving portions 195 formed as part of the extruded body that cooperate to define a stepped-recess 200.
The housing 90 further includes extruded members 205 that define channels 210 located on the extruded body adjacent to and on an opposite side from the light receiving portions 195. The end caps 95 are attached to the housing 90 within the channels 210 to cover the ends of the housing 90. The end caps 95 limit accumulation of debris on the mirrors 100 and LED light sources 105, and are removable from the housing 90.
The mirrors 100 and the LED light sources 105 are generally directed at food product in the product display area 40.
Each mirror 100 extends a substantial length of the mullion light assembly 85, and is bent to conform to the angular spacing between the end wall 150 and the middle wall 155. One end of each mirror 100 is engaged with the end wall 150 within the first receiving portion 170, and another end of each mirror 100 is engaged with the middle wall 155 within the second receiving portion 180. The illustrated mirrors 100 are substantially flat mirror surfaces that are bent to conform to the bend in the W-shaped housing 90. In some embodiments, the mirrors 100 can be rounded mirror surfaces (not shown) positioned in the housing 90 to reflect light into the product display area 40.
Each LED light source 105 is in electrical communication with the case 15 through the mullion 55. The LED light sources 105 are coupled to circuit boards that dissipate heat from the LED light sources 105, and eliminate the need for a heat sink coupled to the LED light sources 105. The circuit boards are made from conventional printed circuit board material without being metal clad, and without an aluminum heat sink. Power is supplied to the LED light sources 105 from a power supply (not shown).
As illustrated in
The mullion light assembly 215 includes the mirror 100, the LED light source 105, a housing 225, and a translucent cover (not shown) that can be attached to the housing 225.
The right-hand portion of the mullion light assembly 215 is generally the same as the right-hand portion of the mullion light assembly 85 described with regard to
The mirror 100 is attached to the housing within the first and second receiving portions 170, 180, and is located only on one side of the housing 225 due to the mullion light assembly 215 being located on the end of the case 15. The LED light source 105 is attached to the housing 225 within the light receiving portion 195, and a portion of the light from the LED light source 105 is aimed directly at the product display area 40. Another portion of the light from the LED light source 105 is directed at the mirror 100, where light is reflected into the product display area 40.
The housing 260 is defined by a generally U-shaped extruded body formed from a high-impact material, and is symmetrical about the axis 252. The housing 260 includes extruded interior flanges 280 and exterior flanges 285 disposed on a side of the extruded body opposite the side of the LED light source 272. The interior flanges 280 cooperate with each other to define a groove 290 that attaches the end caps 265 to the housing 260. Each exterior flange 285 cooperates with one interior flange 280 to define a channel 295. A magnet 300 extends the length of the housing 260, and is attached to the housing 260 within the channels 295 to magnetically couple the shelf light assembly 250 to the shelf 45. In other embodiments, clips or other fasteners (not shown) may be used to attach the shelf light assembly 250 to the shelves 45.
The mirrors 270 include a reflective material (e.g., polished aluminum, polished stainless steel, chrome-plated steel, metalized polymer tape, etc.) to reflect light from the LED light source 272 into the product display area 40. The mirrors 270 are similar to the mirrors 100, and have a reflectance capacity that is above about 70 percent reflectance to reflect a substantial amount of light from the LED light source 272 into the product display area 40.
Each mirror 270 includes a first bent end 325 attached to an end of the housing 260 adjacent the translucent cover 275, and a second bent end 330 engaged with the exterior groove 320. The mirrors 270 are positioned in the housing 260 such that a middle portion of each mirror 270 is disposed at an angle 335 relative to the axis 252. The middle portion of the mirrors 270 are substantially flat to reflect light from the LED light source 272 into the product display area 40. In the illustrated embodiment, the angle 335 is about 20 degrees. In other embodiments, the angle 335 can be more or less than 20 degrees. In some embodiments, the middle portion of the mirrors 270 can include rounded surfaces (not shown).
The LED light source 272 is generally directed at food product in the product display area 40, and is coupled to the housing 260 within the stepped recess 315. The LED light source 272 includes LED packages 340 (
In operation, the opposed, multi-directional mullion light assembly 85 uniformly illuminates the product display area 40 while being substantially hidden from view. A first portion of the light directed from the LED light source 105 coupled to the left-hand interior wall directly illuminates the product display area 40 to the left of the mullion 55. A second portion of the light directed from this LED light source 105 is reflected by the mirror 100 in a direction opposite the direction of the first portion of light generally toward the product display area 40 to the right of the mullion 55. Similarly, a first portion of light directed from the LED light source 105 coupled to the right-hand interior wall directly illuminates the product display area 40 to the right of the mullion 55. A second portion of light directed from this LED light source 105 is reflected by the mirror 100 in a direction opposite the direction of the first portion of light, generally toward the product display area 40 to the left of the mullion 55.
The shelf light assembly 250 generally takes up a relatively small area under the shelf 45, and provides a relatively large space between the shelf 45 (to which the shelf light assembly 250 is attached) and the shelf 45 directly below the light assembly 250 for improved viewability of the food product stored therein. The magnet 300 provides relatively quick attachment of the shelf light assembly 250 to the underside of the shelf 45 without use of additional fasteners and without complicated work processes.
The LED light source 272 directs light generally downward toward the product display area 40, and a substantial amount of light from the LED light source 272 is directed at the food product without being reflected by the mirrors 270. However, some light from the LED light source 272 may be directed toward the mirrors 270, which is reflected by the mirrors 270 toward the product display area 40.
The mullion light assemblies 85, 265, and the shelf light assembly 250 can be used together or separately in the refrigerated merchandiser 10 to illuminate the product display area 40. Use of the low current LED packages 107, 340 in each light assembly 85, 215, 250 provides substantial energy savings. Generally, the overall power required to illuminate and to refrigerate the case 15 using the LED light sources 105, 272 is lower than the power required by cases that use fluorescent light sources or high current LED light sources. The low current LED light assemblies 85, 215, 250 also can be used to replace existing fluorescent and high current LED light assemblies of existing merchandisers to provide similar illumination of the product display area 40 via more economical means.
Various features and advantages of the invention are set forth in the following claims.
This patent application claims priority to U.S. Patent Application Ser. No. 60/878,015, filed Dec. 29, 2006, the entire contents of which are hereby incorporated by reference.
Number | Date | Country | |
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60878015 | Dec 2006 | US |