(19)
(11)EP 3 686 131 A1

(12)EUROPEAN PATENT APPLICATION

(43)Date of publication:
29.07.2020 Bulletin 2020/31

(21)Application number: 20153289.2

(22)Date of filing:  23.01.2020
(51)International Patent Classification (IPC): 
B65G 1/04(2006.01)
(84)Designated Contracting States:
AL AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MK MT NL NO PL PT RO RS SE SI SK SM TR
Designated Extension States:
BA ME
Designated Validation States:
KH MA MD TN

(30)Priority: 25.01.2019 BE 201905043

(71)Applicant: STOW INTERNATIONAL N.V.
8587 Spiere-Helkijn (BE)

(72)Inventor:
  • VANDEMERGEL, Luc
    8820 TORHOUT (BE)

(74)Representative: Cardoen, Annelies Andréa C. et al
KOB NV President Kennedypark 31c
8500 Kortrijk
8500 Kortrijk (BE)

  


(54)SHELVING STRUCTURE


(57) Shelving structure (1) comprising side lanes for storing pallets (2) and on which a shuttle (3) is displaceable, and at least one main lane on which a shuttle (3) is displaceable, wherein the main lane comprises several crossings (4) for providing access to respective side lanes, wherein the main lane comprises a first and a second rail (5a, 5b) which extend at a distance apart and along a first direction (A), wherein the first rail (5a) extends opposite and near the end sections of respective side lanes, wherein each crossing (4) comprises two tracks (6) which are each connected to the two rails (5a, 5b) of the main lane and substantially extend between these two rails (5a, 5b), wherein each track (6) comprises a supporting surface (7) on which the shuttle (3) is displaceable along a second direction (B), wherein the supporting surface (7) of each track (6) adjoins the first rail (5a).




Description


[0001] The present invention relates to a shelving structure comprising one or several storeys, wherein each storey comprises several side lanes for storing pallets and on which a shuttle is displaceable, and at least one main lane on which a shuttle is displaceable, wherein a said main lane comprises several crossings for providing access to respective side lanes, so that a shuttle is movable between the respective side lanes via the main lane, wherein the main lane extends along a first direction and the several side lanes extend along a second direction which makes an angle with the first direction, and wherein the first and the second direction extend virtually horizontally, wherein the main lane comprises a first and a second rail which extend along the first direction and at a distance apart, viewed in the second direction, and on which a shuttle is displaceable along the first direction.

[0002] The present invention also relates to an assembly of such a shelving structure and a shuttle which is displaceable on this shelving structure.

[0003] Many companies already use a shelving structure or 'storage racks' for storing goods by means of pallets. In order to optimize the storage space, shelving structures comprising several storeys are used, with every storey comprising at least one main lane which extends virtually horizontally and along the first direction, and several side lanes which extend virtually horizontally and along the second direction. By means of shuttles which are able to move along the first direction and along the second direction and which can thus travel both on a said main lane and on the side lanes, pallets are placed at the desired location in the shelving structure and also removed therefrom. These shuttles are often referred to by the term '2D shuttles'. The position of the main lane with respect to the side lanes is very important here, since the shuttles have to be able to move quickly between the main lane and said side lanes. This means that the person installing the shelving structure has to ensure that the transition between the main lane and the side lanes is smooth, so that there is little margin for errors with regard to the height of the main lanes and side lanes and/or the distance between the main lanes and side lanes. Even limited margins for errors during the production of the shelving structure may result in a shuttle not being able to move quickly or not being able to move at all on the shelving structure and/or the transition between a specific main lane and a specific side lane not being possible. During production of the shelving structure, the main lanes with crossings and the side lanes are often produced separately. During production of the main lanes with the crossings, it is important that the position of the crossings makes it possible for the position of the crossings to virtually correspond precisely with the position of the side lanes after the shelving structure has been mounted. As a result thereof, one already has to know exactly where the side lanes will be situated during the production of the main lanes with crossings. Therefore, positioning of the side lanes has be carried out very accurately, since this has to correspond to the crossings. All this means that producing and installing a shelving structure is quite complicated, labour-intensive and involves the use of specialists. Thus, in many cases, complicated welded and ground components have to be used in order to make a smooth transition between the main lane and respective side lanes possible.

[0004] FR2730715 illustrates an existing shelving structure. This shelving structure comprises several side lanes for storing pallets and at least one main lane. The side lanes intersect the main lane. In order to be able to displace the shuttle, the main lane is consequently interrupted at the location of the side lanes. The possible tolerances between the side lanes and the main lane are therefore limited.

[0005] It is thus an object of the invention to manufacture a shelving structure which is simpler to manufacture, simpler to install and on which shuttles are nevertheless readily movable.

[0006] This object is achieved by providing a shelving structure comprising one or several storeys, wherein each storey comprises several side lanes for storing pallets and on which a shuttle is displaceable, and at least one main lane on which a shuttle is displaceable, wherein a said main lane comprises several crossings for providing access to respective side lanes, so that a shuttle is movable between the respective side lanes via the main lane, wherein the main lane extends along a first direction and the several side lanes extend along a second direction which makes an angle with the first direction and which is preferably perpendicular to the first direction, and wherein the first and the second direction extend virtually horizontally, wherein the main lane comprises a first and a second rail which extend along the first direction and at a distance apart, viewed in the second direction, and on which a shuttle is displaceable along the first direction, wherein at least the first rail extends opposite and near the end sections of respective side lanes, wherein each crossing of the main lane comprises two tracks which are each connected to the two rails of the main lane and substantially extend between these two rails at the location of a respective side lane, wherein the tracks each comprise a supporting surface on which the shuttle is displaceable along the second direction, wherein the supporting surface of each track adjoins at least the first rail, preferably adjoins both rails. Preferably, said tracks are detachably connected to the two rails.

[0007] In this case, tracks are used which are connectable to the rails of the main lane and extend substantially between these rails. Preferably, the tracks are elongate and extend along the second direction. In this case, installing the shelving structure is easy, since it is simple to connect the tracks to said rails before, during and/or after mounting the rails of the one or several main lanes. In this case, it is also possible to connect the tracks in a correct and desired way to the rails of the main lane in a simpler way, so that there is already a good transition between the main lane and said side lanes and vice versa. This also means that complicated components, which are welded and ground, can be avoided. As a result thereof, the tracks and/or any other elements of the shelving structure can be made from galvanized sheet steel, thus making a wear-resistant finish obsolete. If the tracks are detachably connectable to the rails, it is possible still to change the position of the tracks with respect to the side lanes, in order thus to compensate for inaccuracies during mounting and/or production.

[0008] Since the tracks in this case extend substantially between the rails of the main lane, they also occupy a reduced volume, as a result of which the shelving structure can be designed to be compact and the storage space in which the shelving structure extends can be used in an optimum manner. Due to the position of the tracks, in this case, the surface of the rail on which the shuttle is intended to move, i.e. being the driving surface, may be provided as a virtually uninterrupted assembly, as a result of which the shuttle can be moved on the main lane smoothly and without too much resistance. Since the supporting surface adjoins the first rail, the first rail may also be used to effect the transition between the main lane and the respective side lane (or vice versa), as a result of which a (limited) distance between the first rail and the end portion of said side lane is possible which will not form a hindrance for the transition or only to a lesser extent. The tolerances allowed when mounting the shelving structure are consequently larger. In this case, the crossing may also be of a simple design. Thus, a said crossing may comprise only the two said tracks. Preferably, the tracks are arranged in such a way that the supporting surface extends substantially between the first rail and the second rail, viewed in the second direction, and thus the supporting surface extends substantially next to the first rail.

[0009] The first rail extends opposite and near the end sections of respective side lanes. The second rail then extends at a greater distance from the abovementioned end sections than the first rail. The first rail may extend at a distance from said end sections, but may also virtually abut them. The main lane may extend at the location of the edge of the shelving structure. However, the main lane may also extend more centrally in the shelving structure. The second rail may then also extend opposite and near the end sections of other respective side lanes. Preferably, the supporting surface of each track adjoins both rails of the main lane. This makes it possible for the shuttle to rest on both rails during the transition of the shuttle from the main lane to the respective side lane and vice versa, as a result of which the shuttle can be supported over a larger surface. In this case, the entire shelving structure is then used in as optimum a manner as possible. In this case, the opening which the shuttle has to bridge at the transition between the side lane and the main lane and vice versa may also be minimized, so that these transitions may run smoothly.

[0010] The supporting surface of each track preferably adjoins both rails and the tracks are preferably arranged in such a way that the supporting surface extends substantially between the first rail and the second rail, viewed in the second direction, and thus the supporting surface extends substantially next to the first rail and next to the second rail. In this case, a shuttle can rest on both rails during the transition from the main lane to the respective side lane and vice versa. If the shuttle comprises wheels for moving along the second direction, said wheels, which are at the front of the shuttle, are able to move at the transition between the side lane and the main lane, viewed in the direction of travel of the shuttle, first on the first rail, followed by the supporting surfaces of the respective tracks and finally on the second rail. In this way, both rails are used during the transition of the shuttle between the main lane and the side lane and vice versa. Since the supporting surface adjoins both rails, the shuttle is readily able to move from the first rail to the supporting surface and from the supporting surface to the second rail.

[0011] The tracks also allow easy detection by means of sensors. Specifically, a shuttle which is displaceable on the shelving structure may be provided with sensors in order to determine its position in the shelving structure. In this case, the tracks are easily detectable, as a result of which the positions of the side lanes can easily be recognized by a shuttle by means of the tracks and the transition between the main lane and a said side lane can then also occur easily.

[0012] In order to be able to connect the tracks detachably to the rails, the rails may each be provided with a groove which extends along the first direction and the tracks may be provided with hooking elements which are hookable into the respective grooves. This makes a strong connection between the tracks and the rails possible.

[0013] In a preferred embodiment, each rail of the main lane comprises a driving surface on which a shuttle is intended to move along the first direction, wherein the supporting surface of each track at least adjoins the driving surface of the first rail and each driving surface is virtually uninterrupted and extends virtually along a plane. Preferably, a shuttle is designed to move along the second direction on both driving surfaces at the location of the side lanes and, also preferably, the supporting surface of each track adjoins the driving surface of both rails of the main lane. During displacement of a shuttle on the rails, this shuttle will not be impeded and the shuttle can always move smoothly. Preferably, the driving surface of each rail forms virtually the entire top surface of the rail. This is a very simple embodiment of the rails. This driving surface is virtually in the shape of a rectangle, for example. Since the supporting surface of each track adjoins at least the driving surface of the first rail and preferably adjoins the driving surface of both rails, the shuttle, during the transition between the main lane and the respective side lane and vice versa, may rest on at least the first rail while moving along the second direction, as a result of which the shuttle is supported both by the tracks and by the first rail when moving from the main lane to the respective side lane and vice versa and the shuttle is always reliably supported by the shelving structure. For example, with a shuttle which comprises wheels for moving along the second direction, at the transition between a said side lane and the main lane, the front wheels, being the wheels of the shuttle which will be the first to come into contact with the main lane during said transition, will be first to contact and move on the driving surface of the first rail, then contact and move on the supporting surface and finally contact and move on the driving surface of the second rail. In this way, the main lane is used in an optimum manner, viewed in the second direction. The tracks are preferably arranged in such a manner that the supporting surface extends completely between the driving surface of first rail and the driving surface of the second rail, viewed in the second direction, and thus the supporting surface extends next to the driving surface of the first rail and next to the driving surface the second rail. Preferably, the distance between the supporting surface and the driving surface of the first rail, viewed in the second direction, is between 0 mm and 6 mm, more preferably between 0 mm and 5 mm and most preferably between 0 mm and 3 mm. Furthermore preferably, the shelving structure also comprises adjusting means in order to, at the location of the connection of the supporting surface to a said driving surface, adjust the distance of the supporting surface with respect to the driving surface, viewed in the second direction.

[0014] Furthermore preferably, at the location of the connection of each supporting surface to a respective driving surface, the supporting surface and this driving surface extend virtually at the same height. To this end, the supporting surface and this driving surface preferably extend entirely alongside each other, so that there is no overlap, viewed in the second direction. In this case, the transition between the driving surface and the supporting surface is virtually undetectable for a shuttle which moves along the second direction in order to go from the main lane to a said side lane or vice versa. In this case, a shuttle can move smoothly between the main lane and a said side lane and vice versa and this without the shuttle experiencing too many jerks which might cause damage to the shuttle. This also makes it possible to place several side lanes above one another at the smallest distance apart.

[0015] Still more preferably, at the location of the connection of each supporting surface to a respective driving surface, the deviation between the height of the supporting surface and the height of the driving surface is between 0 mm and 6 mm, preferably between 0 mm and 5 mm and still more preferably between 0 and 3 mm. This minimal deviation still allows a smooth transition between the driving surface and the supporting surface and vice versa. Allowing a minimal deviation makes the installation/mounting of the shelving structure easier.

[0016] Also furthermore preferably, the shelving structure comprises adjusting means in order to adjust the height of the supporting surface at the location of the connection of the supporting surface to a said driving surface. For example, the supporting surface rests on a profiled section or forms part of a profiled section which is height-adjustable by means of the adjusting means. This profiled section is then, for example, said track. The height may, for example, be adjusted in a continuously variable way using adjusting screws or height-adjustable sole plates, wherein said profiled section then rests on the sole plates. After the tracks have been connected to the rails, the desired height/position of the supporting surface can still easily be adjusted by means of adjusting means, so that connecting the tracks to the rails does not require a great deal of precision and can also be performed easily and quickly.

[0017] In a preferred embodiment, the supporting surface is directed downwards at the location of the first rail of the main lane in the direction of this first rail. Thus, a part of the supporting surface may be curved and/or run at an angle and make, for example, a specific angle with a horizontal plane. When the shuttle moves between the main lane and a said side lane and vice versa, the wheels of the shuttle which rest on the tracks will consequently assume a higher position, as a result of which the shuttle comes to lie higher and said transition between the main lane and a said side lane can be effected more smoothly. As a result thereof, the position of the main lane and the positions of the side lanes may deviate slightly from their ideal positions and more tolerance is possible. The installation of the shelving structure thus requires less precision and can therefore be carried out more easily and quicker. In the preferred embodiment in which the supporting surface also adjoins the driving surface of the second rail of the main lane, the supporting surface is preferably directed downwards at the location of the second rail of the main lane in the direction of this second rail.

[0018] Furthermore preferably, the supporting surface comprises an inclined face which makes an angle with a horizontal plane of between 0.2° and 3° at the location of the first rail. Still more preferably, said angle is between 1.0° and 2.0°. This small incline of the supporting surface in the vicinity of the first rail makes it possible for a shuttle to be easily displaceable between the main lane and a said side lane and vice versa, while at the same time making it possible for small differences in height between the different components of the shelving structure to be compensated for in order not to impede the satisfactory displacement of a shuttle. This incline may, for example, have a dimension along the second direction of between 10 cm and 30 cm, so that the incline is sufficiently large. This ensures that when the shuttle moves between the main lane and the respective side lane, the wheels of the shuttle and in particular the front wheels, viewed in the direction of travel, contact the driving surfaces of the respective side lane. Thus, the incline may have a dimension along the second direction of virtually 20 cm and the difference in height which needs to be covered by this incline may be virtually 0.5 cm. Each supporting surface then preferably comprises centrally, viewed in the second direction, a part which extends along a plane which extends virtually horizontally, this part preferably adjoining said inclined face. If the supporting surface also adjoins the driving surface of the second rail of the main lane, then the supporting surface preferably successively comprises: a said inclined face which is directed downwards, towards the first rail, a central part which extends along a horizontal plane and a second inclined face which is directed downwards, towards the second rail.

[0019] In a preferred embodiment, each said side lane which extends opposite and near the first rail, extends at a distance from the first rail, viewed in the second direction, this distance being between 3 cm and 7 cm, preferably between 4 cm and 6 cm. This small distance makes it possible for a shuttle, which is configured to travel on the shelving structure, to be guided continuously while travelling on the main lane. This may be achieved, for example, by means of lateral guide wheels which form part of the shuttle and help to move the shuttle along the first direction in a reliable way. This small distance results in an uncoupling of the main lane and the side lanes and thus also facilitates the mounting of the shelving structure, since in this case, no side lanes have to be installed right up against the main lane. Thus, it is possible to install the main lanes and the side lanes separately. In this case, the adjustment of the position of the main lane with respect to the side lanes may be carried out for each side lane, as a result of which the requirements during assembly and manufacturing are less stringent and the shelving structure is installable more quickly and easily. It is also possible to convert existing warehouses which only comprise shelving structures with side lanes, since all that is required in these cases is to install the main lanes and position them with respect to the side lanes. In addition, this small distance does not impede the transfer of the shuttle between the main lane and a respective side lane and vice versa.

[0020] Furthermore preferably, the shelving structure comprises spacers by means of which the distance between the first rail and said side lanes is adjustable. Thus, the desired distance can readily be adjusted after the shelving structure has been (partly) installed. Furthermore preferably, these spacers are directly connected to the main lane and directly connected to a said side lane, so that the main lane and the side lanes are easily positionable with respect to each other by means of these spacers after the shelving structure has been (partly) installed. The correct installation and positioning of the shelving structure is consequently greatly facilitated, as a result of which people who are less experienced and/or skilled can install this shelving structure. These spacers may be configured in such a way that they are also useful to adjust the height of the side lanes.

[0021] In a preferred embodiment, each side lane which extends opposite and near the first rail comprises two rail elements, each having a driving surface on which the shuttle is displaceable along the second direction, wherein the driving surfaces of a said side lane extend at the same height or at most 5 mm lower than the minimum height of the driving surface of the first rail of the main lane. This makes a smooth transition between the main lane and a said side lane possible. Furthermore preferably, the shelving structure comprises adjusting means to adjust the heights of the driving surfaces of the rail elements. This makes it possible to adjust these heights even after the shelving structure has already been (partly) installed, as a result of which the installation can take place more easily and quicker. Thus, the rail elements can rest on sole plates which are height-adjustable. These driving surfaces preferably extend as a continuation of the tracks of the respective crossing. In a specific embodiment, each rail element may, at the location of the first rail, comprise a mounting edge which adjoins the driving surface of this rail element in order to ensure a smooth transition between the main lane and the respective side lane.

[0022] Preferably, the driving surface of the first rail is directed downwards in the direction of the respective side lanes which extend opposite and near the first rail. This makes a smooth transition between the main lane and the side lane possible. If the supporting surface is directed downwards in the direction of the first rail at the location of this first rail of the main lane, then the supporting surface and the first rail preferably have virtually the same curve or incline. At the location of the transition of the supporting surface and the driving surface of the first rail, the incline or the curve of the supporting surface is continued, as a result of which a smooth transition of a shuttle from the main lane to a said side lane and vice versa is possible.

[0023] Furthermore preferably, the driving surface of the first rail at least partly extends along a plane which makes an angle with a horizontal plane of between 0.2° and 3°. Still more preferably, said angle is between 1.0° and 2.0°. Still more preferably, the driving surface extends substantially along this said plane.

[0024] Also furthermore preferably, the driving surface of the second rail is directed downwards in the direction away from the respective side lanes which extend opposite and near the first rail extend. Still more preferably, the first and the second rail are each others mirror image, viewed in a virtually vertical plane which extends along the first direction.

[0025] In a preferred embodiment, a said track comprises two upright walls which extend along the second direction and at a distance apart, viewed in the first direction, wherein the respective supporting surface extends between these upright walls and these upright walls are configured to guide a shuttle which travels on the tracks of the respective crossing. Thus, one track per crossing may comprise said upright walls. Preferably, all tracks comprise such upright walls. By providing these upright walls, a shuttle which moves along the second direction is guided reliably if it is (partly) supported by tracks. If the shuttle in addition also has guide wheels for guiding the movement along the second direction when the shuttle travels on a said side lane, the movement of the shuttle will be guided along the second direction by both the upright walls and the guide wheels for a specific time period during the transition between the main lane and the side lane and vice versa, as a result of which the shuttle will not deviate from its path along the second direction during said transitions.

[0026] The present invention also relates to an assembly of a shelving structure and a shuttle which is displaceable on this shelving structure, wherein the shelving structure is a shelving structure as represented above. In this case, the shuttle is then preferably modified to be able to travel on this shelving structure.

[0027] Preferably, the shuttle comprises sensors for detecting the tracks. By detecting the tracks, for example with optical sensors, the shuttle can easily determine where the side lanes are situated. Obviously, the shuttle may comprise still other detection systems to optimize the displacement of the shuttle. Thus, it is possible to measure the speed and detect the positions for accelerating, decelerating and/or stopping. Preferably, the shuttle is automatically actuated by means of a computer system.

[0028] When the driving surface of the first rail extends at least partly along a said plane which makes an angle with a horizontal plane, the shuttle preferably comprises first wheels for travelling on the first and the second rail of the main lane, respectively, wherein the first wheels which are configured to travel on the first rail have a chamfer which corresponds to the driving surface of the first rail. In this case, these first wheels are then chamfered and very suitable to travel on this first rail.

[0029] Preferably, the shuttle comprises second wheels for travelling on the side lanes, wherein the shuttle comprises at least 8 second wheels. Thus, two mutually opposite sides of the shuttle each comprise 4 second wheels. The shuttle is reliably supported by means of 8 wheels when it moves along the second direction and thus also during the transition from a said side lane to the main lane and vice versa, as a result of which this transition may take place smoothly.

[0030] The present invention will now be explained in more detail by means of the following detailed description of a preferred embodiment of a shelving structure and an assembly according to the present invention. The sole aim of this description is to give illustrative examples and to indicate further advantages and features, and can therefore by no means be interpreted as a limitation of the area of application of the invention or of the patent rights defined in the claims.

[0031] In this detailed description, reference numerals are used to refer to the attached drawings, in which:
  • Fig. 1 shows a perspective view of a part of a shelving structure according to the invention, wherein a shuttle which is displaceable on the shelving structure, is visible;
  • Fig. 2 shows another perspective view of a part of a shelving structure according to the invention;
  • Figs. 3, 4 and 5 show diagrammatic views of a cross section through a part of the shelving structure along a plane perpendicular to the first direction at the location of the transition between a said side lane and the main lane, wherein a shuttle is shown which travels from the side lane to the tracks of the respective crossing of the main lane, the shuttle being situated on the side lane in Fig. 3, the shuttle being partly situated on the side lane and partly on the main lane in Fig. 4, and the shuttle being completely situated on the main lane in Fig. 5;
  • Fig. 6 shows a detail view of Fig. 2.


[0032] The shelving structure (1) comprises several storeys, wherein each storey comprises several side lanes on which pallets (2) are storable and on which a shuttle (3) is displaceable, and one main lane on which a shuttle (3) is displaceable. The main lane of each storey comprises one crossing (4) per side lane. In this way, a shuttle (3) is movable between the various side lanes of the storey by means of the main lane. The side lanes are situated on one side of the main lane. The main lane extends along a first direction (A) and the several side lanes extend along a second direction (B) which is perpendicular to the first direction (A). The first and the second direction (A, B) extend virtually horizontally, so that the shuttle (3) is readily movable on the main lane and the side lanes.

[0033] The main lane comprises a first and a second rail (5a, 5b) which extend along the first direction (A) at a distance apart and on which a shuttle (3) is displaceable along the first direction (A). Each side lane comprises two rail elements (11) which extend along the second direction (B) at a distance apart and on which a shuttle (3) is displaceable along the second direction (B). Each side lane has a first end portion and a second end portion situated opposite the first end portion, wherein each first end portion extends near the first rail (5a) of the main lane.

[0034] Each crossing (4) comprises two tracks (6) which are each connected to the two rails (5a, 5b) of the main lane and substantially extend between these two rails (5a, 5b) and along the second direction (B). Each track (6) comprises a supporting surface (7) on which the shuttle (3) is displaceable along the second direction (B), and the rails (5a, 5b) each comprise a driving surface (8) at the top which forms virtually the entire top of the rail (5a, 5b) and virtually extends along a plane, wherein the supporting surface (7) of each track (6) adjoins both said driving surfaces (8). The shuttle (3) is configured to travel on these said driving surfaces (8) along the first direction (A) and, at the location of the tracks (6), the shuttle (3) is additionally configured to travel on these said driving surfaces (8) along the second direction (B). Each driving surface (8) forms an uninterrupted plane, so that the displacement of the shuttle (3) can always take place smoothly. Each supporting surface (7) extends completely between the driving surfaces (8) of both rails (5a, 5b).

[0035] At the location of the connection of each supporting surface (7) to a respective driving surface (8), the supporting surface (7) and this driving surface (8) extend at virtually the same height. To this end, the shelving structure (1) comprises adjusting means (9) by means of which the height of the supporting surface (7) can be adjusted with respect to said driving surfaces (8). The supporting surface (7) extends between two upright walls of the tracks (6), so that the shuttle (3) is reliably guided in its movement.

[0036] Furthermore, each supporting surface (7) is directed downwards in the direction of the rail (5a, 5b) at the location of each respective rail (5a, 5b) of the main lane. To this end, the supporting surface (7) comprises an incline which extends along a plane which makes an angle of virtually 1.5° with a horizontal plane. This incline has a dimension, viewed in the second direction, of virtually 20 cm. Each supporting surface (7) thus comprises, successively, a first incline which adjoins the driving surface (8) of the first rail (5a), a horizontally running part and a second incline which adjoins the driving surface (8) of the second rail (5b).

[0037] Each rail element (11) comprises a driving surface (12) which extends along the second direction (B) and the shuttle (3) is configured to travel on the driving surfaces (12) during its displacement on the side lane along the second direction (B).

[0038] The distance of the first rail (5a) to the driving surface (12) of each rail element (11) of a said side lane, viewed in the second direction (B), is virtually 5 cm. To this end, the shelving structure (1) comprises spacers (10) which are each connected to both the first rail (5a) and a rail element (11) of a said side lane, by means of which said distance is settable as desired.

[0039] The driving surface (8) of the first rail (5a) is directed downwards in the direction of the side lanes and extends along a plane which makes an angle of virtually 1.5° with a horizontal plane. The driving surface (8) of the second rail (5b) also extends along a plane which makes an angle of virtually 1.5° with a horizontal plane. The second rail (5b) is the mirror image of the first rail (5a).

[0040] The driving surfaces (12) of the rail elements (11) are at virtually the same height as the minimum height of the driving surface (8) of the first rail (5a) of the main lane.

[0041] The shuttle (3) which is configured to travel in this shelving structure (1) is adapted to this shelving structure (1). Thus, this shuttle (3) comprises first wheels by means of which the shuttle (3) is displaceable along the first direction (A), wherein these wheels are chamfered, so that they bear completely againt the respective driving surfaces (8) of the main lane during travel along the first direction (A). The shuttle (3) also comprises 8 second wheels for travel on the side lanes, with in each case 4 second wheels being provided to travel on the driving surface (12) of the one rail element (11) of a said side lane and 4 second wheels being provided to travel on the driving surface (12) of the other rail element (11) of a said side lane. By means of 8 second wheels, the transition between a said side lane and the main lane and vice versa is readily and easily accomplishable.

[0042] The transition between a said side lane and the main lane is shown in Figs. 3, 4 and 5. As is visible in Fig. 3, the shuttle (3) is largely situated in the side lane and still rests completely on the side lane. Two second wheels, which are situated on either side of the shuttle (3), are partly situated between the side lane and the main lane. Subsequently, said last two second wheels first make contact with the driving surface (8) of the first rail (5a) and subsequently with the supporting surfaces (7) of the tracks (6) until they reach the position in Fig. 4, in which the shuttle (3) is partly supported by the side lane and partly by the tracks (6). Thereafter, the shuttle (3) moves further along the second direction (B), so that the position in Fig. 5 is reached and the shuttle (3) is supported substantially by the tracks (6) and the shuttle (3) can transform in order to allow displacement along the first direction (A). The inclines of the rails (5a, 5b) and the inclines of the supporting surfaces (7) facilitate this transition.


Claims

1. Shelving structure (1) comprising one or several storeys, wherein each storey comprises several side lanes for storing pallets (2) and on which a shuttle (3) is displaceable, and at least one main lane on which a shuttle (3) is displaceable, wherein a said main lane comprises several crossings (4) for providing access to respective side lanes, so that a shuttle (3) is movable between the respective side lanes via the main lane, wherein the main lane extends along a first direction (A) and the several side lanes extend along a second direction (B) which makes an angle with the first direction (A), and wherein the first and the second direction (A, B) extend virtually horizontally, wherein the main lane comprises a first and a second rail (5a, 5b) which extend along the first direction (A) and at a distance apart, viewed in the second direction (B), and on which a shuttle (3) is displaceable along the first direction (A), characterized in that at least the first rail (5a) extends opposite and near the end sections of respective side lanes, and in that each crossing (4) of the main lane comprises two tracks (6) which are each connected to the two rails (5a, 5b) of the main lane and substantially extend between these two rails (5a, 5b) at the location of the respective side lane, wherein the tracks (6) each comprise a supporting surface (7) on which the shuttle (3) is displaceable along the second direction (B), wherein the supporting surface (7) of each track (6) adjoins at least the first rail (5a).
 
2. Shelving structure according to Claim 1, characterized in that each supporting surface (7) extends substantially between the first rail (5a) and the second rail (5b), viewed in the second direction (B), and thus the supporting surface (7) extends substantially next to the first rail (5a).
 
3. Shelving structure (1) according to Claim 1 or 2, characterized in that each rail (5a, 5b) of the main lane comprises a driving surface (8) on which a shuttle (3) is intended to move along the first direction (A), wherein the supporting surface (7) of each track (6) at least adjoins the driving surface (8) of the first rail (5a) and each driving surface (8) is virtually uninterrupted and extends virtually along a plane.
 
4. Shelving structure (1) according to Claim 3, characterized in that, at the location of the connection of each supporting surface (7) to a respective driving surface (8), the supporting surface (7) and this driving surface (8) extend virtually at the same height, so that the deviation between the height of the supporting surface (7) and the height of the driving surface (8) is preferably between 0 mm and 6 mm, still more preferably between 0 mm and 5 mm and most preferably between 0 mm and 3 mm.
 
5. Shelving structure (1) according to Claim 4, characterized in that the shelving structure (1) comprises adjusting means (9) in order to adjust the height of the supporting surface (7) at the location of the connection of the supporting surface (7) to a said driving surface (8).
 
6. Shelving structure (1) according to one of the preceding claims, characterized in that the supporting surface (7) is directed downwards at the location of the first rail (5a) of the main lane in the direction of this first rail (5a).
 
7. Shelving structure (1) according to Claim 6, characterized in that the supporting surface (7) comprises an inclined face which makes an angle with a horizontal plane of between 0.2° and 3° at the location of the first rail (5a).
 
8. Shelving structure (1) according to one of the preceding claims, characterized in that each said side lane which extends opposite and near the first rail (5a), extends at a distance from this first rail (5a), viewed in the second direction (B), this distance being between 3 cm and 7 cm.
 
9. Shelving structure (1) according to Claim 8, characterized in that the shelving structure (1) comprises spacers (10) by means of which the distance between the first rail (5a) and said side lanes is adjustable.
 
10. Shelving structure (1) according to one of the preceding claims, characterized in that each side lane which extends opposite and near the first rail (5a) comprises two rail elements (11), each having a driving surface (12) on which the shuttle (3) is displaceable along the second direction (B), wherein the driving surfaces (12) of a said side lane extend at the same height or at most 5 mm lower than the minimum height of the driving surface (8) of the first rail (5a) of the main lane.
 
11. Shelving structure (1) according to one of the preceding claims, characterized in that the driving surface (8) of the first rail (5a) is directed downwards in the direction of the respective side lanes which extend opposite and near the first rail (5a), and in that the driving surface (8) of the first rail (5a) preferably at least partly extends along a plane which makes an angle with a horizontal plane, wherein this angle is between 0.2° and 3°.
 
12. Shelving structure (1) according to Claim 11, characterized in that the driving surface (8) of the second rail (5b) is directed downwards in the direction away from the respective side lanes which extend opposite and near the first rail (5a).
 
13. Shelving structure (1) according to one of the preceding claims, characterized in that a said track (6) comprises two upright walls which extend along the second direction (B) and at a distance apart, viewed in the first direction (A), wherein the respective supporting surface (7) extends between these upright walls and these upright walls are configured to guide a shuttle (3) which travels on the tracks (6) of the respective crossing (4).
 
14. Assembly of a shelving structure (1) and a shuttle (3) which is displaceable on the shelving structure (1), characterized in that the shelving structure (1) is a shelving structure (1) as defined in one of Claims 1 to 13.
 
15. Assembly according to Claim 14 and according to Claim 11, characterized in that the shuttle (3) comprises first wheels for travelling on the rails (5a, 5b) of the main lane, wherein the first wheels which are configured to travel on the first rail (5a) have a chamfer which corresponds to the driving surface (8) of the first rail (5a).
 




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Cited references

REFERENCES CITED IN THE DESCRIPTION



This list of references cited by the applicant is for the reader's convenience only. It does not form part of the European patent document. Even though great care has been taken in compiling the references, errors or omissions cannot be excluded and the EPO disclaims all liability in this regard.

Patent documents cited in the description