This invention relates to palletised loads of containers, such as illustrated by
In
As indicated by
Because the strapping 24, after securing ends together (not shown) before removing the downward loading, is of finite length, any subsequent settling of the stack S, e.g. due to variation in bottle height, e.g. plus or minus up to 1.0 mm, and/or vibration and/or stretching of the strapping 24, especially resulting from temperature rise subsequent to the strapping operation, results in loss of tension in the strapping that can lead to instability of the stack, especially as vibration or shock loading of the palletised load during transport can cause ‘bottle-walking’ (or ‘can-walking’) from within the confines of the slip sheets 22, with disastrous results, especially breaking of bottles.
It is, therefore, as shown in
The object of the invention is to provide slip sheets that inhibit ‘walking’ and prevent slipping upon shock loading.
FR-A-2 593 782 discloses a plate for closing one or more open boxes forming a pallet load, the plate having along its perimeter a series of tabs protruding upwardly and downwardly in alternation from the plane of the plate and inclined outwardly, whereby the downwardly protruding tabs locate round the tops of a lower layer of boxes on a pallet and the upwardly protruding tabs locate the bottoms of an upper layer of boxes.
The form of slip sheet 32 shown in
As indicated by
From curved corner portions of the board 33 radiate fingers 35X and 36X with curved downward and upward respective projections 37X and 38X to ensure that ‘walking’ of bottles 20 from the corners of layers L is not possible.
Upon arrival at the point of use, and after the vertical strapping 24 has been cut off and the rigid board 23 removed, the set of fingers 35 of the slip sheet below the topmost layer L of bottles 20 spring back out of the plane of the board 33, thus enabling the layer of bottles to slide up the upwardly inclined fingers 35 as the bottles are pushed laterally over a side of the slip sheet 32, as indicated by
When the slip sheets 32 are used between layers L of cans 41, as shown in
However, such projections 37, 38 and fingers 35, 36 are very liable to damage during the usual rough handling of slip sheets, and so
The form of slip sheet 42 illustrated by
It will be appreciated that a continuous ‘throat’ TC is created between the outer edges of respectively the upper leaf 44 of a lower slip sheet 42 and the lower leaf 45 of an upper slip sheet 42, through which ‘throat’ the outermost bottles in the intervening layer L cannot walk and—indeed—could only be pulled with great difficulty. This ‘throat’ can be compared with the discontinuous ‘throat’ TD created between the upward projections 38 on a lower slip sheet 32 and the downward projections 37 on an upper slip sheet 32, which ‘throat’ TD is effective provided that—as shown by FIG. 8—there is at least one downward projection 37 overlapping each top 40 in the outermost row of bottles 20 in a layer L.
Reference is now made to EP-A-1 291 306 which discloses an interlay sheet for stacked layers of light-weight containers, in particular polyethylene terephthalate (PET) bottles, the sheet having upper and lower marginal portions formed by separate leaves diverging towards the edges of the sheet. Furthermore, the separate leaves are stiffened against vertical deformations by webs between them, which is relevant with regard to a second attempt to provide a more robust slip sheet as illustrated by
Whichever form of slip sheet 32, 42 or 52 is adopted there is the difficulty that a plurality of such slip sheets cannot be stacked compactly for return transportation to the suppliers of the containers. Therefore it is the object of the present invention to provide a slip sheet that overcomes this difficulty.
Thus, according to one aspect of the present invention, a slip sheet comprises a flat substantially rectangular board having marginal portions formed with corrugations extending perpendicularly from their edges and merging into the general plane of the board.
In use, the downwardly projecting corrugations restrain the tops of the containers in a layer on which the slip sheet is placed, then the bottoms of the next layer of containers can slide down the upwardly projecting corrugations along one side of the slip sheet as that layer is pushed laterally en masse on to the board, whereafter the upwardly projecting corrugations restrain the bottoms of those containers. However, upon arrival at the point of use, and after the vertical strapping has been cut off and the rigid board and top slip sheet removed, the bottoms of each successive layer of containers can slide up the upwardly projecting corrugations along a side of the slip sheet below as the layer is pushed laterally en masse from the board.
The board preferably has curved corners from which radiate diverging corrugations, to ensure that ‘walking’ of containers from the corners of layers is not possible.
Because the corrugations can be moulded into a board of uniform thickness throughout with no increase in thickness along the sides and even a thinning towards the edges, a plurality of such slip sheets can be stacked compactly and with great stability by virtue of the corrugations of any one slip sheet nesting in the corrugations of neighbouring slip sheets.
With the thickness of the board of the order of 1.0 to 4.0 mm, a maximum height of the upwardly projecting corrugations and a maximum depth of the downwardly projecting corrugations of the order of 2.0 to 4.0 mm causes an adequate reduction of the gap or creates a ‘throat’ between the edges of slip sheets above and below a layer of containers to prevent ‘walking’ of the layer of containers en masse after strapping of a completed stack as aforesaid or prevent slipping upon shock loading.
The pitch of the corrugations is preferably such that at least one downwardly projecting corrugation is in register with each bottle top in the outermost rows, then there will be more than one upwardly projecting corrugation in register with each bottle bottom in the outermost rows.
Reference will now be made to
Therefore, the slip sheet 62 as shown in
In use, the downwardly projecting corrugations 65 restrain the tops of the bottles 20 (or cans) in a layer L on which the slip sheet 62 is placed, then the bottoms of the next layer of bottles can slide down the upwardly projecting corrugations 66 along one side of the slip sheet 62 as that layer is pushed laterally en masse on to the board 63, whereafter the upwardly projecting corrugations 66 restrain the bottoms of those bottles, while their tops are restrained by the downwardly projecting corrugations 65 of the next slip sheet 62.
From curved corner portions of the board 63 radiate diverging corrugations 65X, 66X to ensure that ‘walking’ of bottles 20 from the corners of layers L is not possible.
It will be appreciated from
Furthermore, tests have also revealed that vibration causes the bottles 20 in any layer L to move closer together, so that horizontal strapping 31 becomes redundant.
Because the corrugations can be moulded into a board of uniform thickness throughout with no increase in thickness along the sides and, as shown, even a thinning towards the edges, a plurality of like slip sheets 62 can be stacked compactly and with great stability by virtue of the corrugations 65, 66 of any slip sheet nesting in the corrugations of neighbouring slip sheets.
According to another aspect of the present invention, a palletised load of containers comprises upright containers stacked in layers on a pallet or dolly with slip sheets between the layers, also one below the bottom layer, the completed stack being topped-off by a further slip sheet and a rigid board, and strapping applied vertically between the pallet or dolly and the board, across under the platform of the pallet or dolly and across the top of the board, whilst subjected to a downward loading, characterised in that each slip sheet comprises a flat substantially rectangular board having diverging marginal portions in accordance with the previous aspect of the invention, creating between successive slip sheets a ‘throat’ preventing ‘walking’ of the containers from between those slip sheets or slipping upon shock loading.
Formation of the corrugations can be effected by injection moulding of the slip sheets or by hot pressing preformed sheets between platens with appropriate formations along the margins.
Upon arrival at the point of use, and after vertical strapping has been cut off and the rigid board and top slip sheet removed, the bottoms of each successive layer of bottles can slide up the upwardly projecting corrugations 66 along a side of the slip sheet 62 below as the layer is pushed laterally en masse from the board 63.
If the slip sheets 62 are used in conjunction with a device for alleviating slackening of vertical strapping 24 on palletised loads on containers such as is described in Co-pending Application No. 0512155.3 then it may be possible to reduce the number of vertical straps from, say, seven to four, without jeopardising the security of the layers L of bottles 20.
Number | Date | Country | Kind |
---|---|---|---|
0426517.9 | Dec 2004 | GB | national |
0428145.7 | Dec 2004 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/GB2005/003608 | 9/21/2005 | WO | 00 | 5/24/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2006/059054 | 6/8/2006 | WO | A |
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Number | Date | Country | |
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20090223856 A1 | Sep 2009 | US |