RACKING BEAM FOR OPEN FACED RACKING
Field of the Invention
The present invention relates generally to storage racking systems and more particularly to a racking beam used in open faced racking systems, such as drive-in and drive -through racking. The invention is described with reference to that context, however it is to be appreciated 10 that the invention has broader application and is not limited to that particular use.
Background of the Invention
In the following description, except where specifically differentiated, the term "drive-in racking" encompasses both drive-in and drive-through racking.
Drive-in style racking systems are widely used in 2 0 warehousing, manufacturing and other industrial facilities. Drive-in racking has advantages of providing very dense storage compared to selective pallet racking and a relatively low capital cost compared to alternative high density solutions. In addition, pallets can be 25 accessed with standard forklift trucks.
In drive-in style racking, the racks are arranged in blocks. Aisles are formed between the rack blocks allowing access to stock via mechanical handling equipment 30 such as forklifts. Each drive-in rack block comprises a number of lanes of pallet storage extending multiple pallets deep into the rack.
Drive-in racks are constructed principally from vertical 35 rack frames which are orientated perpendicular to the main access aisle. Individual lanes of pallet storage are created from adjacent planes of vertical rack frames. Each
lane comprises multiple levels of support beams, commonly referred to as pallet runners or pallet rails. The pallet runners are offset from the vertical rack frames and span in a direction parallel to the rack frames. The pallet 5 runners generally span across multiple frames and are supported at each frame upright by a connecting bracket. The front face of the rack is thus open allowing handling equipment to drive into each lane to store and retrieve pallets in a multiple deep configuration. Pallets are 10 supported along their left- and right-hand edges which bear on the pallet runners.
The vertical rack frames comprise vertical load bearing members commonly referred to as uprights, and metal 15 bracing which extends between adjacent uprights to form the frame. Uprights are typically roll formed channel shaped profiles with extended rear flanges to facilitate bracing connections. The pallet runners extend between these vertical rack frames parallel with the lane.
Drive-in rack, as distinct from drive-through rack, gains its global down-aisle stability through the use of vertical spine bracing located behind the rearmost plane of pallets, and plan bracing located in the horizontal 25 plane at the top of the rack. Due to the obstruction created by the vertical spine bracing, drive-in rack therefore functions as a "last in first out" (LIFO)
system. A pallet is retrieved from the rack by the forklift truck driving into the lane to the pallet 30 location, lifting the pallet, and then reversing out of the lane into the main access aisle.
On the other hand, access in a drive-through rack is not restricted by vertical spine bracing located behind a 35 plane of pallets. In an empty lane of a drive-through system, forklift trucks can drive through the lane from the entry to the exit pallet locations. Such a storage
Received at IPONZ 23 December 2010
system can therefore function in a "first in first out" (FIFO) fashion which might be preferable to a LIFO system for certain types of products.
In drive-through racking, global down-aisle stability is achieved through the flexural stiffness of the connecting beams at the top of the frames, spine bracing towers located through the depth of the rack within one lane, or a combination of these mechanisms.
It is an object of the present invention to provide a racking beam and/or a racking system which overcomes or at least ameliorates one or more disadvantages of the prior art, or alternatively to at least provide the public with 15 a useful choice.
Summary of the Invention
According to a first aspect the present invention provides 20 a racking beam for an open faced racking system, the beam comprising:
a bearing portion that incorporates a bearing surface;
a guiding portion that is disposed along a first 25 longitudinal edge of the bearing portion and extends upwardly from the bearing surface; and a stiffening portion disposed along a second longitudinal edge of the bearing portion and extending downwardly and inwardly therefrom by an amount sufficient 30 to cause a principal axis of bending of the beam to be oriented within 20° relative to a nominal plane of the bearing surface and the shear centre of the beam is positioned so as to be laterally displaced from the second
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longitudinal edge within the range of +30% to -10% of the width of the bearing surface extending between the first and second longitudinal edges.
In the context of the specification the direction of lateral displacement of the shear centre from the second longitudinal edge is taken as being positive when it is towards the first longitudinal edge.
In a particular form, the racking beam is formed from sheet metal and more preferably is made from sheet steel that typically incorporates a corrosion resistant metal 5 coating and may also incorporate a decorate paint finish. Typically the thickness of the sheet steel is between 1.5mm and 3mm. The racking beam may be profiled using a cold roll forming process although it may also be formed by other processes such as a pressing, folding or forging 10 operation or any combination thereof.
Prior art racking beams for open faced racking (otherwise known as pallet runners) have been designed to meet the functional requirements by incorporating a guiding portion 15 and bearing portion. However, such beams have been unsuited to spans that significantly exceed the conventional span of 1.2 m between uprights. In contrast, the racking beam according to this aspect of the present invention has significantly improved structural 2 0 performance characteristics (i.e. bending strength,
lateral deflection, twist) which enable significantly greater spans without increase in the gauge of the metal used in the racking beam. In particular, utilising a beam profile where the principal bending axes are aligned more 25 with the horizontal enables loading on the bearing surface to produce primarily vertical deflection of the beam without significant concomitant lateral deflection. In addition by locating the shear centre so that it is laterally displaced from the second longitudinal edge 30 within the above mentioned range (i.e.+30% to -10% of the width of the bearing surface) reduces the extent of twist in the cross section. A racking beam with improved structural performance may have a significant impact on
the economy of the resulting racking system as it can lead to fewer uprights, cantilever brackets, base plates and other components.
In a particular embodiment, a nominal plane of the bearing surface is disposed generally in the horizontal plane when the beam is in its installed position.
In a particular form, the shear centre is aligned close to 10 the resultant of the load acting on the bearing flange. This resultant is typically located adjacent the second longitudinal edge.
In a particular embodiment, the stiffening portion 15 extending downwards from the bearing surface comprises an upper web, a lower web and an inclined web disposed between the upper and lower webs, the inclined web extending downwardly and inwardly so that the lower web is offset inwardly from the upper web.
The incorporation of an inclined web in the racking beam and the dimensions of that web have been found to have a significant influence on the orientation of the principal bending axes of the beam. Further, the inclined web 25 provides additional depth to the section and also a convenient location for receiving fasteners to secure the beam to the supporting bracket.
In a particular form the inclined web is inclined from the 3 0 plane of the bearing surface at an angle greater than 15°. In one form, this angle is in the range of 15° to 45°.
In a particular embodiment, the inclined web is dimensioned such that the offset of the lower web from the upper web is in the range of 60-120% of the width of the bearing surface extending between the first and second 5 longitudinal edges. In a particular form, the offset is in the range of 70-100% of the bearing surface.
In a further aspect, the invention is directed to a racking beam for an open faced racking system, the beam 10 comprising: a bearing portion that incorporates a bearing surface; a guiding portion that is disposed along a first longitudinal edge of the bearing portion and extends upwardly from the bearing surface; and a stiffening portion disposed along a second longitudinal edge of the 15 bearing portion, the stiffening portion incorporating an upper web and a lower web and an inclined web disposed between the upper and lower webs, the inclined web extending downwardly and inwardly so that the lower web is offset inwardly from the upper web by an amount in the
2 0 range of 60-12 0% of the width of the bearing surface extending between the first and second longitudinal edges.
In yet a third aspect, the invention relates to a racking beam for an open faced racking system comprising: a 25 bearing portion that comprises a bearing surface; a guiding portion that is disposed along a first longitudinal edge of the bearing portion and extending upwardly from the bearing surface; and a stiffening portion disposed along a second longitudinal edge of the
3 0 bearing portion, the stiffening portion comprising an upper web that extends downwardly from the bearing surface, and an inclined web that extends downwardly and inwardly so that a lower portion of the inclined web is
offset inwardly from the upper web, the inclined web further comprising fastener receiving formations arranged to receive fasteners to secure the beam to supporting brackets.
The incorporation of the fastener receiving formations on the inclined web allows easy access for an installer to fix the fasteners yet still enabling the fasteners to be in a position where they are unlikely to form catch points 10 in the racking system.
In a particular embodiment, the fastener receiving formations are in the form of apertures operative to receive respective fasteners to secure the beam to 15 supporting brackets. In other form, these formations may be recesses or even flats that are arranged to receive self tapping screws or the like.
In yet a further aspect, the invention relates to a 20 racking beam assembly comprising a racking beam of the third aspect and a support bracket, the beam being of generally channel shape and the bracket being locatable within the beam channel, the support bracket incorporating a fastening surface locatable behind the inclined web and 25 wherein in use the beam is securable to the support bracket by one or more fasteners that extend through the inclined web and the fastening surface.
In a particular embodiment, the stiffening portion of the 3 0 racking beam in any form described above, further comprises .a lower stiffening formation disposed along a lower distal margin of the beam. In one form, this lower stiffening formation comprises a flange that projects
inwardly from the lower web and a lip return that extends from the flange to a lower terminal edge of the beam.
In a particular embodiment, the guiding portion includes 5 an upper stiffening formation disposed along a distal margin of the guiding portion and a web disposed between the stiffening formation and the bearing portion. In a particular embodiment, the upper stiffening formation is similar to the lower stiffening formation and incorporates 0 a flange that extends from the guiding portion web and a lip return that extends from the flange to an upper terminal end of the beam.
In a particular embodiment, the guiding portion web is 5 inclined to the nominal plane of the bearing surface.
Typically the open angle between the guiding portion web and the plane of the bearing surface is in the range of 90-120° .
0 In yet a further aspect, the invention relates to a racking system incorporating racking beams and/or racking assemblies according to any of the forms described above.
In one form, the racking beams are supported along their 5 length by uprights spaced apart, possibly unequally, such that substantial bending is induced in the beams under normal design loadings.
Brief Description of the Drawings
0
Notwithstanding any other forms that may fall within the scope of the racking beam assemblies and systems as defined in the summary, specific embodiments will now be described by way of example only, with reference to the
accompanying drawings, in which:
FIG. 1 is a front elevation of an open faced racking system;
FIG. 2 is a side elevation of the racking system of FIG.l; FIG. 3 is a perspective view of a racking beam used in the racking system of FIG. 1;
FIG. 4 is an underside perspective view of the racking beam of FIG. 3;
FIG. 5 is an end view of the racking beam of FIG. 3; FIG. 6 is a detailed view of a racking beam assembly comprising a racking beam and bracket when mounted to an upright of the racking system of FIG. 1;
FIG. 7 is a schematic view of five racking beam profiles 15 (A-E);
FIG. 8 is a graph of the orientation of the principal axes against the offset (e) for the profiles of FIG. 7; FIG. 9 is a graph of the position of the shear centre against the offset (e) for the profiles of FIG. 7; and 20 FIG. 10 illustrates the orientation of the principal axes through the centroid C and the shear centre position S of profiles of the racking beams of FIG. 7.
Detailed Description of Specific Embodiments
FIG. 1 depicts an open faced racking system 100 comprising a series of vertical load bearing uprights 101 and multiple levels of racking beam assemblies 50 supported by the uprights 101. These assemblies comprise brackets 51 30 which are mounted to the uprights and racking beams 10,
commonly referred to as pallet runners, which are affixed to the brackets. The open faced racking system 100 is designed such that lanes 102 are formed between the uprights 101 and sized to allow stock handling equipment 35 such as fork lifts or other vehicles to drive into the lanes so as to load pallets 500 onto the racking beams. In this regard, the racking beams 10 extend along the
respective lanes and incorporate a longitudinal edge which opens out into those lanes. In this way, the lanes include pairs of racking beams which oppose one another and the pallets 500 or other stock units are placed 5 between and supported by, those opposing racking beams.
As most clearly shown in FIG. 2, a feature of the racking system 100 is that the uprights 101 in each lane are spaced apart a distance which is significantly greater 10 than the depth of a single pallet 500. In the present case, the spans between upright are approximately 2.4 m which equates to two pallet depths. The racking beams 10 are designed to accommodate these spans as will be discussed in more detail below. Such spans are 15 significantly greater than conventional open style racking where the spacing between uprights 101 is arranged to be largely the same as the depth of a single pallet.
Turning to FIGS. 3 to 5, the racking beam 10 incorporates
2 0 a bearing portion 12 having a bearing surface 13, which in its installed position, is generally horizontal. The bearing surface 13 has an inner or first longitudinal edge 14 that locates proximal the uprights and an outer or second longitudinal edge 15 that extends along the system 25 lanes 102.
A guiding portion 16 is disposed along the inner longitudinal edge 14 of the bearing surface 13 and extends upwardly and outwardly from the bearing surface 13. This
3 0 guiding portion comprises an inclined web 17 which functions to assist in guiding the pallet to locate properly on the bearing surface 13. The open angle of inclination of the guiding portion is generally no greater than 120° from a nominal plane of the bearing surface 13. 35 More preferably the angle of inclination is no greater than 110° from the bearing surface plane. An inclination of 110° is generally sufficient to ensure that a pallet
accidentally placed on the guiding portion will, under its own weight, slide down to the bearing surface 13.
The guiding portion 16 further comprises an upper 5 stiffening formation 18 that extends from the inclined web 17 to a terminal end 19 of the beam 10. The stiffening formation comprises a flange 2 0 and a lip 21 turned downwardly out of the plane of flange 20.
The racking beam 10 further comprises a stiffening portion 22 disposed along the outer longitudinal edge 15 of the bearing surface 13 and extending downwardly and inwardly therefrom. The stiffening portion 22 comprises an upper web 23 extending downwardly from the outer longitudinal 15 edge 15 of the bearing surface 13, an inclined web 24 that extends inwardly and downwardly from the upper web 23, and a lower web 25 that extends downwardly from the inclined web 24. In this way, the lower web 25 is offset inwardly from the upper web by a distance (e).
The stiffening portion further comprises a lower stiffening formation 26 that extends from the lower web 25 to a terminal end 27 of the beam 10. The stiffening formation 26 comprises a flange 28 and a lip 29 turned 25 upwardly out of the plane of the flange 28.
With this configuration, the racking beam 10 is channel-shaped with the terminal ends 19, 27 spaced apart. As best illustrated in FIG. 6 the racking beam is arranged to 3 0 be disposed over brackets 51 which are secured to the uprights 101. These brackets which are of a cantilever-type are tapered towards their distal end 52 so as to locate snugly within the racking beam profile. In particular the distal end 52 of the bracket 51 locates 35 adjacent the upper web 23, an upper surface 53 of the bracket locates under the bearing portion 12, whereas a lower surface 54 locates against the inner side of the
inclined web 24. Both the inclined web 24 and the lower surface 54 of the bracket include fastener receiving formations, which in the illustrated form comprise apertures (3 0 and 55 respectively). These apertures are 5 arranged to receive fasteners (not shown) to secure the racking beam 10 to the respective brackets. The location of the fasteners is convenient, in that it provides easy access for an installer yet locates the fastener in a position where they are unlikely to cause a catch point. 10 Further, the apertures 30 are spaced along the inclined web 24 so as to facilitate the aligning of the beam apertures 30 with the bracket apertures 55, when those brackets are fixed to the uprights 101.
By manipulating the length of the inclined web 24,
significant changes can occur to both the centre of shear S as well as to the orientation (6) of the principal axes. These findings are reflected in the graphs shown in FIGS. 8 and 9 which are derived from an analysis of five 20 profiles (A-E) schematically illustrated in FIG. 7. These profiles differ in the length of the inclined web 24 with the graphs in FIGS. 8 and 9 representing this as a normalised offset (being the offset e, which is the lateral displacement of the upper web 23 to the lower web 25 25, compared to the width of the bearing surface b from the inner 14 to the outer longitudinal edge 15). In FIG. 8 the orientation (8) of the principal bending axes is graphed against the normalised offset (e/b). In FIG. 9, the position of the shear centre S is graphed against this 30 normalised offset. Fig. 10 illustrates the resulting profiles A to E, showing the calculated position of the shear centre S and the orientation 0 of the principal bending axes for each profile.
In general, the inventors have realised that there are advantages in orientating the principal bending axis x of the racking beam so that it is within 20° of the
horizontal. The advantage of this alignment is that vertical loading from a pallet 500 or other stock unit upon the racking beam 10 will induce vertical deflections of the racking beam 10 without resulting in any 5 significant concomitant lateral deflections. The closer the principal axis x is to the horizontal, the less lateral deflection would occur. Reducing the lateral deflection allows the racking beam 10 to be capable of greater span than is available when vertical loading 10 induces lateral deflection. In the illustrated form, a nominal plane of the bearing surface 13 is arranged to extend horizontally when it is installed. As such the plane of the bearing surface can be used as the reference plane for the axes.
In addition, to limit twist in the racking beam, the shear centre S also needs to be taken into account. The inventors have found that to ensure good structural performance, the shear centre S should be located close to
2 0 the resultant of the load acting on the bearing surface
13. This resultant is typically near the longitudinal edge 15 and as such it is beneficial if the shear centre is positioned so as to be laterally displaced from the longitudinal edge 15 within the range of +30% to -10% of 25 the width of the bearing surface.
From the graphs of FIGS. 8 to 10, it can be seen only profiles C, D and E fall within 2 0° of the bearing surface whereas profile A (where there is no offset) is over 40°
3 0 and profile B (where there is only minimal offset) is over
3 0°. Further, it is clear that the offset produces a significant change in the shear centre with profiles A and B having a shear centre that is displaced outwardly of the longitudinal edge 15 (by an amount of 15mm and 4mm 35 respectively), and profiles C, D and E having a shear centre that is displaced inwardly of the longitudinal edge (by 4mm, 9mm and 13mm respectively).
The width b of the bearing surface is typically in the range of 70mm - 10 0mm. Therefore, the lateral displacement of the shear centre S from the longitudinal edge 15 for the profiles A to E is such that profile A 5 falls outside the above-mentioned range of +30% to -10% for all bearing surface widths between 70mm - 100mm, whereas the profiles B to E fall within this range.
As far as structural performance is concerned, the most 10 optimal design of the five profiles is profile D. As can be seen from calculations conducted by the inventors, the principal axes are aligned so that the axis x is parallel to the bearing surface 13 whereas the shear centre S is located just inward from the upper web 23. Nevertheless, 15 profiles C and E may also perform adequately under load. In addition to the structural performance, the incorporation of the inclined web 24 provides a convenient location to fix the beam to its support brackets. In this regard, the longer webs of profiles D and E are better 20 suited for this role.
In the claims which follow and in the preceding description of the invention, except where the context requires otherwise due to express language or necessary 25 implication, the word "comprise" or variations such as
"comprises" or "comprising" is used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the invention.
It is to be appreciated that various alterations and/or additions may be made to the racking beam previously described without departing from the spirit or ambit of the present invention.