The present invention relates generally to a shelf assembly for products and, more specifically, to a shelf assembly with gravity-feeding shelves to be placed in a limited space, which shelf assembly is rotatable between at least one display position, in which the shelves are accessible from the front of the shelving section, and a refill position, in which the shelves are accessible from the rear of the shelving section.
In supermarkets and department stores there are many different types of shelf assemblies, which are filled with products offered for sale. Many of these products must for various reasons, such as open-dating or refrigerating reasons, be supplied in such a manner that the last supplied products are positioned in the rear part of the shelf. At the same time this satisfies the requirement that the product first supplied is also first sold. A large amount of the time of the shop staff is used to supply additional products. This means that there is a great interest in getting rid of conventional types of shelf assembly where the remaining products from previous supplies first must be removed from the shelf assemblies before supplying new products. One way of solving this problem is to design shelf assemblies which are adapted to be refilled from behind. This can be achieved by wheels being mounted on the shelf assemblies so that the shelf assembly is completely pulled out, or alternatively pivoted out, from its position to make the rear accessible for refilling. Since the shelf assemblies are in many cases quite heavy and difficult to steer, it may be necessary to take care of this by using supports and/or guide tracks which guide the movement, like in shelf assemblies in refrigerators according to European patent application 1683449 A1.
A certain drawback of this type of solution is that some shops are limited in respect of space in aisles. It causes inconvenience to customers and staff that the aisles are blocked by shelf assemblies when supplying additional products. The staff will then be inclined not to pull out the shelf assembly, and therefore the construction will not be used as intended.
An object of the present invention is to provide an improved solution for a shelf assembly which can be refilled from behind without suffering from drawbacks indicated in connection with prior art.
The above object is achieved by a shelf assembly according to the invention.
More specifically, according to one aspect to the present invention a shelf assembly is provided for products, which is adapted to be placed in a space, which at least is limited in depth by a rear boundary surface and laterally by lateral surfaces. The shelf assembly has a shelving section with a front an a rear, which shelving section comprises a plurality of spaced-apart gravity-feeding shelves, which are arranged above each other. The shelving section is rotatable about a vertical axis of rotation between at least one display position, in which the shelves are accessible from the front of the shelving section, and a refill position, in which the shelves are accessible from the rear of the shelving section. The shelf assembly further comprises a shelving section support placed on the base, and the shelving section comprises a base plate. Moreover the shelving section is placed on the shelving section support. The axis of rotation extends through a first engaging means which is arranged on the underside of the base plate and which is rotatably engaged with a second engaging means which is arranged on the upper side of the shelving section support. The rear of the shelving section is in the refill position located further away from said rear boundary surface than is said front of the shelving section in the display position. Further the shelving section is rotatable substantially within the limited space.
As a result, a shelf assembly is provided, which can be rotated between a display position and a refill position in situ in a limited space about an axis of rotation and whose shelving section's rear in the refill position is located further away from the rear boundary surface of the limited space than is the front of the shelving section in the display position. This facilitates refilling of the shelf assembly from behind. The rear of the shelf assembly is not only facing the person who is to supply additional products but also has a small projecting portion so that, for refilling, the person does not have to reach into the limited space. In addition, the floor surface in front of the limited space is not occupied by the shelving section in refilling.
In one embodiment of the shelf assembly, the first engaging means, and thus the position of the shelving section, is movable in depth between a first position and a second position relative to the shelving section support, the first position corresponding to the display position and the second position corresponding to the refill position. This difference between the first and the second position corresponds at least to the distance in depth between the pivot radius of the shelving section and the rear of the shelving section in the display position.
This results in a shelf assembly, which makes it possible for a rotation of the shelving section from the display position to the refill position to occur in a limited space by the axis of rotation being moved so that the pivot space available in the space corresponds to the pivot radius of the shelving section. This produces the advantage that a shelving section which in fact is too large to be rotated in the space can obtain sufficient space to move in order to rotate from the display position to the refill position. A corresponding movement back to the original position of the axis of rotation during rotation back to the display position from the refill position resets the position of the shelving section in the space. In the refill position, the rear of the shelving section is made accessible for refilling. The shelving section then protrudes from the front edge of the space. This is advantageous when the shelves are to be supplied with products.
In one embodiment of the shelf assembly, the axis of rotation in the lateral direction is arranged substantially centrally while the axis of rotation in depth is arranged closer to the front of the shelving section than the rear of the shelving section, the axis of rotation substantially coinciding with the centre of a geometric circle, whose diameter corresponds to the width of the space and is tangent to the lateral surfaces and the rear boundary surface of the space.
This results in a shelf assembly which by asymmetric location of a stationary axis of rotation can rotate in a limited space where the pivot radius of the shelf assembly in one embodiment according to prior art would prevent rotation from the display position to the refill position in the space. A further advantage of the asymmetric location of the stationary axis of rotation is that in the refill position the shelving section protrudes from the limited space and facilitates refilling of the shelf assembly.
In one embodiment of the shelf assembly, the second engaging means is a groove, in which the first engaging means can move. This is a solution which both stabilises the rotation and limits the degree of freedom of the movement.
In one embodiment, a gear wheel is arranged on the first engaging means, which gear wheel meshes with a gear rack arranged on the shelving section support, the gear rack positions of the gear wheel corresponding to different movements of the axis of rotation in depth. This means that the movement of the axis of rotation, forward and backward in depth, is controlled while the shelving section is being rotated between the display position and the refill position.
To facilitate the rotation of the shelving section, roller means are arranged on the underside of the base plate in one embodiment of the invention. In an alternative embodiment of the invention, roller means are also/instead placed on the upper side of the shelving section support. These roller means may be, for instance, wheels, but should not be restricted thereto.
In another embodiment, the roller means are arranged substantially in a circle, but also other ways of placing the wheels are conceivable and not excluded by this example.
The design of the shelves of the shelf assembly can be performed in various ways. In one embodiment, gravity feeding is achieved by letting the shelves be inclined. Gravity feeding means that the products on the shelf slide forward to the front edge of the shelf, for instance during refilling or when a vacancy has occurred because a product has been removed from the front edge by a customer. The inclined shelves also produce the advantage that the centre of gravity of the shelving section in the refill position will not be positioned outside the shelving section support. The total weight of the remaining products and the last supplied products will thus be positioned closer to the front edge of the shelf assembly, which front edge in the refill position is facing the rear wall of the space.
For further improvement of the gravity feeding, the shelves are in one embodiment provided with sliding surfaces, which may be sliding tracks or roller tracks. This is also advantageous since it will be possible to easily renovate the shelf assembly by only replacing worn out sliding tracks or roller tracks with new ones instead of making the more complicated and expensive exchange of entire shelves.
In one embodiment of the shelf assembly, the shelves are provided with channels for stabilisation and advantageous exposure of advanced products.
In one embodiment of the shelf assembly, the shelving section is provided with side walls which each is a metal sheet, which metal sheet is provided with rotation- and deflection-resistant bends. This significantly improves the stability of the shelf assembly compared to a solution in which entire side plates without bends are used.
In one embodiment, the shelves are designed based on a substantially rectangular shape, the rear corners of the shelves being trimmed for optimal adjustment of the shelving section in the limited space. Trimming of the rear corners is made to assist the rotation of the shelving section while achieving a maximum total shelving surface, that is load area, relative to the available area in the space. Due to the solution according to the invention involving the asymmetric location of the axis of rotation, the front corners, however, need in principle not be trimmed, which will be explained in more detail in connection with the description of the embodiments. The shelf assembly thus uses as large a portion of the load area as possible for the shelf assembly inside the limited space while at the same time the shelf assembly with the asymmetric location of the axis of rotation is rotatable within the space. The alternative of a shelf assembly which is not designed according to the invention but, for instance, has an entirely symmetric location of the axis of rotation, would be to provide it with shelves the area and maximum pivot radius of which are substantially smaller than the area available in the space.
In one embodiment, the front edges of the shelves are straight.
In one embodiment, the space, and the shelf assembly, has a greater width than its depth. The invention is particularly advantageous with such proportions.
The invention will now be described in more detail by way of non-limiting embodiments and with reference to the accompanying drawings. Equivalent components in the embodiments have the same reference numerals.
a and b are exploded views which show details of an embodiment according to
a shows a display position and 3b a refill position for an embodiment of a shelf assembly according to the invention.
a is a cross-sectional view from above of an embodiment of a shelf assembly according to the invention, the shelf assembly being placed in a cabinet.
b shows details of the embodiment according to
a and b show folded lateral metal sheets and 5c a shelf attachment which is included in another embodiment of the shelf assembly according to the invention.
In
a and 2b are exploded views which illustrate further details of the shelf assembly 100. The shelving section 101 comprises, in addition to the shelves 102, a base plate 207 and an upper part 116, also side walls 214. The base plate 207 has a first engaging means in the form of a shaft end 208 which engages a second engaging means arranged on the shelving section support 110 in the form of a shaft seat 209, the shaft end 208 being rotatable in the shaft seat 209.
In an alternative embodiment, the shaft end 208 and the shaft seat 209 are arranged in reverse order in such a manner that the shaft end 208 is placed on the shelving section support 110 while at the same time the shaft seat 209 is placed on the base plate 207, the shaft end 208 being rotatably engaged with the shaft seat 209.
Roller means 211, which in this embodiment are wheels 211 mounted in ball bearings, are arranged on the upper side of the shelving section support 110. As mentioned above, the wheels 211 can also be placed on the underside of the base plate 207 of the shelving section 101. The purpose of the wheels 211 is to use a plurality of contact points to stabilise the shelving section 101 and reduce the frictional force during rotation of the shelving section 110. A non-limiting example of locating the wheels 211 in an advantageous manner is to arrange them so that they together form substantially a circle along which the wheels 211 roll during rotation between the display position and the refill position.
In one embodiment according to the invention, wheels are also placed on the underside of the shelving section support 101, in which case the shelf assembly 100 is rollable.
Additional stabilisation of the shelving section 101 is provided by the upper part 116 of the shelving section 101 being provided with an extra shaft seat 219 and a support plate 217 which is externally arranged, connected to the shelving section 101, and provided with a shaft end 218. The extra shaft end 218 is in the embodiment engaged with the extra shaft seat 219 and vertically aligned with the shaft end 208 of the base plate 207 and the shaft seat 209 of the shelving section support 210 and thus constitutes a second point for the axis of rotation 103 about which the shelving section 101 is rotated between the display position and the refill position. The upper support plate 217 is adapted to be attached to the roof of the cabinet 130. In other embodiments, the support plate 217 can be attached to surrounding walls or be joined to support plates of other, neighbouring shelf assemblies.
In an alternative preferred embodiment, the shelving section 101 is rotatably suspended from the upper support plate 217. Suspension is performed by, for instance, a ball bearing/shaft, the rotation of the shelving section 101 about the axis of rotation 103 being made possible with a minimum of rotation resistance. In this embodiment, the shaft end 208 and the shaft seat 209 have a supporting function. In addition, roller means 211 can be mounted on, for instance, the base plate 207 as a support for the shelving section 101.
The shelving section 301 is rotatable about an axis of rotation 303, between a display position according to
The shelves 302 are designed based on a substantially rectangular shape, the rear corners of the shelves 302 being trimmed. By trimmed is meant that the corners are, for instance, rounded, arcuate, bevelled or cut off so as to assist the rotatability of the shelving section 301 in the limited space 330. The front edge 302a of the shelves is straight. The design of the shelves 302, with trimmed rear corners, a straight front edge 302 and the axis of rotation 303 which as described above is asymmetrically located, is adapted to maximise the area of the shelves 302 within a boundary line which is defined by the geometric circle 305 and the doors 330d of the cabinet. The pivot radius 304 of the shelves 302 corresponds substantially to the radius of the geometric circle 305. In the display position, the entire shelves 302 are located in the cabinet 330. In the refill position, the rear 301b of the shelving section protrudes, and thus also the rear edges 302b of the shelves protrude, from the front edge 330a of the cabinet 330, which allows smooth access for supply of products also at the trimmed rear corners of the shelves 302.
In this second embodiment, the shelves 302 are divided into product channels 306. The product channels 306 are advantageous in gravity feeding of products since they support the products and allow the products to be displayed in a favourable manner. Also in this embodiment, the base of the product channels 306, or alternatively the entire upper sides of the shelves 302, can be provided with sliding surfaces 320 which assist gravity feeding of products.
A further advantage of gravity feeding as described above is that the centre of gravity of the shelving section 301 in the refill position is automatically moved toward the front edge 302a of the shelves, thus reducing the risk of the shelf assembly 300 tilting and falling out of the cabinet 330.
A third embodiment of a shelf assembly 400 according to the invention is shown in
Moreover, in this embodiment, an upper portion of the shaft end 408 is provided with a gear wheel 412. The teeth of the gear wheel 412 run in a gear rack 413 arranged on the shelving section support 410. On rotation of the shelving section 401 between the display position and the refill position, the teeth of the gear wheel 412 engage the gear rack 413, the respective gear rack positions of the gear wheel 412 corresponding to a predetermined movement of the axis of rotation 403, that is the position of the shaft end 408 in the shaft seat 409, in depth. In this embodiment, with the gear rack 413 arranged according to
The pivot radius 404 of the shelving section 401 describes a circle 405 which in the lateral direction substantially coincides with the width of the space 430, but which in depth substantially falls outside the depth of the limited space 430. As described above, the axis of rotation 403 is movable along the extent of the shaft seat 409, and therefore the shelving section 401 is rotatable to the refill position by simultaneous movement of the position of the axis of rotation 403 in depth, towards the front edge 430a of the cabinet, the circle 405 being moved in the same direction and rotation of the shelving section 401 being made possible. In the refill position, the rear edge 401b of the shelving section is located a distance in front of the front edge 430a of the cabinet. Correspondingly, the shelving section 401 is rotatable from the refill position back to the display position with a reverse direction of rotation and movement of the shaft end 408 toward the rear boundary surface 430c of the limited space. The rear 401b of the shelving section is, in the refill position, further away from said rear boundary surface 430c than is the front 401a of the shelving section in the display position. The shelving section 401 is rotatable substantially within the limited space 430.
As shown in more detail in
Recesses 516 are formed in the lateral plates 512 to attach shelves 502 by shelf attachments 515, as shown in
Number | Date | Country | Kind |
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0602400 | Nov 2006 | SE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE2007/001002 | 11/13/2007 | WO | 00 | 1/5/2010 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/060222 | 5/22/2008 | WO | A |
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Number | Date | Country | |
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20100176074 A1 | Jul 2010 | US |