The present invention relates to refrigerated merchandisers, and more specifically to door assemblies for refrigerated merchandisers.
Existing refrigerated merchandisers generally include a case defining a product display area that supports and/or displays products visible and accessible through an opening in the front of the case. Some refrigerated merchandisers, such as low-temperature merchandisers that are used to keep product frozen, include doors that enclose the product display area. The doors typically include one or more glass panels that allow a consumer to view the products stored inside the case. The doors are supported by a frame that includes a header, a footer, and a pair of side rails. If the merchandiser includes more than one door, mullions can be positioned between the doors, extending from the header to the footer. The doors on existing merchandisers are pivotally connected to the frame, opening outward toward the consumer. These doors swing outside the envelope of the case and occupy additional floor space in the aisle, requiring relatively wide aisles to accommodate merchandisers on opposite sides of the aisle.
The invention provides a track door assembly for merchandisers that have cases to keep product at a low temperature (e.g., −10° Fahrenheit) and to minimize the footprint taken up by the door when moved between an open position and a closed position. Unlike pivotal or swinging doors, the track door generally stays within the envelope of the case. With a track door design, the aisles can be made narrower without sacrificing accessibility. In addition, the overall footprint of the facility can be reduced, or the additional floor space achieved using the track door can be used to merchandise additional product.
The difficulty of implementing a laterally and outwardly translating door on a refrigerated merchandiser is achieving an air-tight seal between the door and the case. The track door of the present invention solves this problem by incorporating a door that has a path and approach angle relative to the case that combines lateral movement and outward or inward movement of the door. In this manner, the track door can be closed and opened in a direction that is substantially normal or perpendicular to the case or door frame. This angle of approach also facilitates use of a seal (e.g., a magnetic seal) between the door and the frame.
In one aspect, the invention provides a rolling-translating door for a refrigerated merchandiser. For example, the door is configured for movement about more than one axis to move (e.g., glide, slide, roll laterally relative to the case, and to move outward and inward relative to the case on a track system.
In some aspects, a user can engage the door and move the door along the track system, or the motion can be initiated and controlled by a controller that is coupled to a motor that engages the door (e.g., via one or more switches or controls).
In one aspect, the door can include or be connected to an automatic storage and retrieval system (ASRS) by integrating controls between the merchandiser and the ASRS. In one example, the track system of the door has an electro-mechanical switch mechanism that can select one of at least two paths for the door depending on the state of each door in a two-door pair (e.g., one or both doors opened).
In one aspect, the track system includes a four-bar linkage system with a mechanical trip device to select the track or path to be followed. In another aspect, the track system can be controlled with a solenoid actuator to move the switch between alternate paths or tracks.
Before any constructions 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 constructions 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.
The refrigerated merchandiser 10 also includes a refrigeration system (not shown) that is in communication with the case 18 to provide refrigerated airflow to the product display area 54. The refrigeration system generally includes an evaporator located within an air passageway internal to the case 18. As is known in the art, the evaporator receives a saturated refrigerant that has passed through an expansion valve. The saturated refrigerant is evaporated as it passes through the evaporator as a result of absorbing heat from the airflow passing over the evaporator. The absorption of heat by the refrigerant allows the temperature of the airflow to decrease as it passes over the evaporator. The heated or gaseous refrigerant then exits the evaporator and is pumped back to one or more compressors (not shown) for re-processing into the refrigeration system. The cooled airflow exiting the evaporator via heat exchange with the liquid refrigerant is directed through the remainder of the air passageway and is introduced into the product display area 54 where the airflow will remove heat from and maintain the product 14 at desired conditions.
As best shown in
The doors 102, 104 are connected to the upper track 114 and the actuator assembly 118 by a series of rollers connected to respective shafts 120. The shafts 120 extend from the doors 102, 104 toward the upper track 114. In the illustrated embodiment, the rollers have an axis of rotation that is coaxial to the longitudinal axis of the shaft 120. Other embodiments can utilize other axis of rotation.
Referring to
As best shown in
A first gate 148 is positioned at the transition between the first door spur 142 and the center portion 138. The first gate 148 is moveable between a first position where it blocks a path between the first door spur 142 and the center portion 138 and a second position where it opens into the center portion 138 to provide a path between the first door spur 142 and the center portion 138. A first stop 150 is connected to the first gate through a first link 152. The first stop 150 is configured to move with the first gate 148 via the first link 152.
A second gate 154 is positioned at the transition between the second door spur 146 and the center portion 138. The second gate 154 is moveable between a first position where it blocks a path between the second door spur 146 and the center portion 138 and a second position where it opens into the center portion 138 to provide a path between the second door spur 146 and the center portion 138. A second stop 156 is connected to the second gate 154 through a second link 158. The second stop 156 is configured to move with the second gate 154 via the second link 158.
The actuator assembly 118 includes the first actuator rail 128 connected to a first linear actuator 160 and the second actuator rail 136 connected to a second linear actuator 162 so that the actuator rails 128, 136 are independently moveable of one another. The actuator rails 128, 136 each include a hollow body defining a substantially C-shaped channel that receives a respective actuator roller 126, 134. The actuator rails 128, 136 extend at an oblique angle to the center portion of the upper track 114 and away from the case frame 106.
As shown in
As best shown in
The first door 102 includes a first leading lower roller 178 and a first trailing lower roller 180. The first leading lower roller 178 and the first trailing lower roller 180 are connected to the lower track 116. The second door 104 includes a second leading lower roller 182 and a second trailing lower roller 184. The second leading lower roller 182 and the second trailing lower roller 184 are connected to the lower track 116.
The lower track 116 has a body defining a slot. The slot incudes a lower center portion 186 that extends substantially parallel to the case frame 106. A first lower door end 188 is positioned on one side of the lower center portion 186. The lower first door end 188 extends at an oblique angle to the lower center portion 186 and toward the case frame 106. In the closed position, the first lower door end 188 receives the first trailing lower roller 180. A first lower door spur 190 extends from the lower center portion 186 at an oblique angle and toward the case frame 106. In the closed position, the first lower door spur 190 receives the first leading lower roller 178. A second lower door end 192 is positioned on the other side of the lower center portion 186. The second lower door end 192 extends at an oblique angle to the lower center portion 186 and toward the case frame 106. In the closed position the second lower door end 192 receives the second trailing lower roller 184. A second lower door spur 194 extends from the lower center portion 186 at an oblique angle and toward the case frame 106. In the closed position, the second lower door spur 194 receives the second leading lower roller 182.
A first lower gate 196 is positioned at the transition between the first lower door spur 190 and the lower center portion 186. The first lower gate 196 is moveable between a first position where it blocks a path between the first lower door spur 190 and the lower center portion 186 and a second position where it opens into the lower center portion 186 to provide a path between the first lower door spur 190 and the lower center portion 186. A first lower stop 198 is connected to the first lower gate 196 through a first lower link 200. The first lower stop 198 is configured to move with the first lower gate 196 via the first lower link 200.
A second lower gate 202 is positioned at the transition between the second lower door spur 194 and the lower center portion 186. The second lower gate 202 is moveable between a first position where it blocks a path between the second lower door spur 194 and the lower center portion 186 and a second position where it opens into the lower center portion 186 to provide a path between the second lower door spur 194 and the lower center portion 186. A second lower stop 204 is connected to the second lower gate 202 through a second lower link 206. The second lower stop 204 is configured to move with the second lower gate 202 via the second lower link 206.
During closing, the first motor 163 and the rotation of the first lead screw 166 is reversed, causing the first door 102 to move back over the first opening. The first leading roller 122 will engage the first gate 148 which guides the first leading roller 122 into the first door spur 142. As the first leading roller 122 enters the first door spur 142, the first trailing roller 124 enters the first door end 140, which moves the first door 102 toward the case frame 106 and reengages the door seal.
Similar movement is followed when the second door 104 opens, moving into the center portion 138 of the upper track 114 and the lower center portion 186 of the lower track 116 and in front of the first door 102. Accordingly, the first and second doors 102, 104 move at least partially along at the same path to open and close.
In certain aspects, opening and closing the doors can be controlled by an electronic control system and activated by a user input. The control system can include one or more controllers configured to operate the linear actuators and gates. Control logic can be used to ensure that only one door opens at a time. In other aspects, the actuator assembly can be replaced with mechanisms that allow the doors to be operated entirely manually.
In some aspects, the doors 102, 104 can be integrated with an automatic storage and retrieval system (ASRS) where little to no user input is needed to operate the track system 100. In some constructions, the can include a user access device that provides product location information and location notification to a user that directs a user to a specific product area. The doors can be activated to open when a user is near the location so that the user can retrieve the products. Once the product has been retrieved and the user clears the door, the door can be closed. In these embodiments, the user can be a shopper at a store, a store employee, or a robotic system at a store or storage facility.
In some embodiments, the illustrated linear actuator can be replaced with other drive mechanisms, such as a belt drive system, rack and pinon system, or other suitable mechanisms.
Although two doors 102, 104 are shown with the track system 100, other configurations including one door, three doors, four doors, or more can be used as needed. For example, a three door system can be configured so that both of the end doors move over the middle door and the middle door moves over one or more of the end doors.
As best shown in
As best shown in
The first door 212 includes a first leading roller 230 and a first trailing roller 232. The first leading roller 230 and the first trailing roller 232 are connected to the upper track 224. The second door 214 includes a second leading roller 234 and a second trailing roller 236. The second leading roller 234 and the second trailing roller 236 are connected to the upper track 224.
As shown in
A first gate 250 is positioned at the transition between the first door spur 242 and the center portion 238. The first gate 250 includes a first linear channel 252 and a first curved channel 254. The first gate 250 is moveable between a first position where the first linear channel 252 provides an extension across the center portion 238 and a second position where the first gate 250 moves away from the case frame 216 so that the first curved channel 254 provides a path between the first door spur 242 and the center portion 238. The first gate 250 can be moved by a linear actuator, for example a solenoid actuator.
A second gate 256 is positioned at the transition between the second door spur 248 and the center portion 238. The second gate 256 includes a second linear channel 258 and a second curved channel 260. The second gate 256 is moveable between a first position where the second linear channel 258 provides an extension across the center portion 238 and a second position where the second gate 256 moves away from the case frame 216 so that the second curved channel 260 provides a path between the second door spur 248 and the center portion 238. The second gate 256 can be moved by a linear actuator, for example a solenoid actuator.
As best shown in
The first door 212 includes a first leading lower roller 264 and a first trailing lower roller 266. The first leading lower roller 264 and the first trailing lower roller 266 are connected to the lower track 226. The second door 214 includes a second leading lower roller 268 and a second trailing lower roller 270. The second leading lower roller 268 and the second trailing lower roller 270 are connected to the lower track 226.
The lower track 226 has a body defining a slot. The slot incudes a lower center portion 272 that extends substantially parallel to the case frame 216. A first lower door end 274 is positioned on one side of the lower center portion 272. The first lower door end 274 extends at an oblique angle to the lower center portion 272 and toward the case frame 216. In the closed position, the first lower door end 274 receives the first trailing lower roller 266. A first lower door spur 276 extends from the lower center portion 272 at an oblique angle and toward the case frame 216. In the closed position, the first lower door spur 276 receives the first leading lower roller 264. A second lower door end 278 is positioned on the other side of the lower center portion 272. The second lower door end 278 extends at an oblique angle to the lower center portion 272 and toward the case frame 216. In the closed position the second lower door end 278 receives the second trailing lower roller 270. A second lower door spur 280 extends from the lower center portion 272 at an oblique angle and toward the case frame 216. In the closed position, the second lower door spur 280 receives the second leading lower roller 268.
A first lower gate 282 is positioned at the transition between the first lower door spur 276 and the lower center portion 272. The first lower gate 282 includes a first lower linear channel 284 and a first lower curved channel 286. The first lower gate 282 is moveable between a first position where the first lower linear channel 284 provides an extension across the lower center portion 272 and a second position where the first lower gate 282 moves away from the case frame 216 so that the first lower curved channel 286 provides a path between the first lower door spur 276 and the lower center portion 272. The first lower gate 282 can be moved by a linear actuator, for example a solenoid actuator.
A second lower gate 288 is positioned at the transition between the second lower door spur 280 and the lower center portion 272. The second lower gate 288 includes a second lower linear channel 290 and a second lower curved channel 292. The second lower gate 288 is moveable between a first position where the second lower linear channel 290 provides an extension across the lower center portion 272 and a second position where the second lower gate 288 moves away from the case frame 216 so that the second lower curved channel 292 provides a path between the second lower door spur 280 and the lower center portion 272. The second lower gate 288 can be moved by a linear actuator, for example a solenoid actuator.
During closing, the first leading roller 230 will engage the first gate 250 to guide the first leading roller 230 into the first door spur 242. As the first leading roller 230 enters the first door spur 242 the first trailing roller 232 enters the first door end 240, which moves the first door 212 toward the case frame 216 and reengaging the door seal.
In certain aspects, opening and closing the doors can be controlled by an electronic control system and activated by a user input. The control system can include one or more controllers configured to operate the linear actuators and gates. Control logic can be used to ensure that only one door opens at a time. In other aspects, the actuator assembly can be replaced with mechanisms that allow the doors to be operated entirely manually.
In some aspects, the doors can be integrated with an automatic storage and retrieval system (ASRS) where little to no user input is needed to operate the track system 210. Certain embodiments can include a user access device that provides product location information and location notification to a user that directs a user to a specific product area. The doors can be activated to open when a user is near the location so that the user can retrieve the products. After the product has been retrieved and the user clears or moves away from the door, the door can be automatically closed. In these embodiments, the user can be a shopper at a store, a store employee, or a robotic system at a store or storage facility.
Although two doors 212, 244 are shown with the track system 210, other configurations including one door, three doors, four doors, or more can be used as needed. For example, a three door system can be configured so that both of the end doors move over the middle door and the middle door moves over one or more of the end doors.
In some embodiments, a drive system for each door may include combinations of the components described relative to and illustrated in
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