The current disclosure is directed to a pallet spacer, and more particularly, to a pallet spacer configured to provide spacing between stored items.
Pallet spacers are often used to aid in stacking items that are stored on a pallet or the like. Such items are often stored in temperature-controlled environments, such as a cooler or freezer. In some existing pallet spacer systems, the stored items may not be properly aligned, which causes the items to lean against and contact an adjacent item, which in turn can restrict air flow and inhibit proper temperature control of the items. When the items are perishable or store perishables therein, such as food products, lack of sufficient air circulation can lead to spoilage or cause improper processing of the food product once it is thawed. Insufficient air flow can also increase blast-freezing and tempering cycles, resulting in increased inventory losses and utility costs.
Accordingly, one embodiment of the present invention is a pallet spacer configured to ensure proper spacing between adjacent items which can lead to improved air flow around the palletized items. More particularly in one embodiment the invention is a pallet spacer system including a pallet spacer having a pallet spacer body with a plurality of upper portions. Each upper portion has a generally flat upper surface that is aligned with the upper surfaces of the other upper portions. The pallet spacer body further includes a plurality of lower portions, each lower portion having a generally flat lower surface that is aligned with the lower surfaces of the other lower portions. The pallet spacer system includes a plurality of spacers positioned on the upper portions and configured to receive at least an item therebetween.
With reference to
With reference to
In one case the spacer body 12, including the upper portions 14, lower portions 16 and transition portions 18, can each have generally the same thickness. However, the thickness dimensions of the upper portions 14, lower portions 16 and/or transition portions 18 can be varied as desired.
In the illustrated embodiment, each upper portion 14 includes a generally flat and planar upper surface 24 and a generally, parallel flat and planar lower surface 26, and each lower portion 16 includes a generally flat and planar upper surface 28 and a generally parallel, flat and planar lower surface 30. In this manner the upper surfaces 24 of the upper portions 14 together form a discontinuous outermost (upper) surface of the spacer body 12 on one side thereof, and the lower surfaces 30 of the lower portions 16 form another (lower) discontinuous outermost surface of the spacer body 12 on an opposite side thereof. The upper surfaces 24 of the upper portions 14 are generally aligned (e.g. in a plane) so that items or cases 32 can be stacked and supported thereon, as shown in
The lower portions 16 can be recessed relative to the upper portions 14 such that, for example, the lower surfaces 30 of the lower portions 16 are positioned below, and not aligned with, the lower surfaces 26 of the upper portions 14. Similarly, the upper surfaces 24 of the upper portions 14 are positioned above, and not aligned with, the upper surfaces 28 of the lower portions 16. In the illustrated case, however, the lower surfaces 26 of the upper portions 14 are aligned (along a plane) with the upper surfaces 28 of the lower portions 16.
Each transition portion 18 can have parallel outer surfaces that are angled relative to the upper surface 24 of the upper portions 14, and/or the lower surfaces 30 of the lower portions 16. In the illustrated embodiment each transition portion 18 extends at an angle of about 45 degrees although the transition portions 18 can have other shapes and extend at other angles.
Since the upper surfaces 28 of the lower portions 16 form the base/bottom surface of the upper channels 20, this arrangement leads to upper channels 20 that have a depth about equal to a thickness of the upper portions 14. Providing upper channels 20 with this depth helps to provide sufficient clearance and air circulation around items 32 positioned on the pallet spacer 10. Similarly, in the illustrated embodiment the lower surfaces 26 of the upper portions 14 define an upper surface of the lower channels 22 such that the lower channels 22 have a depth about equal to a thickness of the lower portions 16 in the illustrated embodiment. However, the upper 20 and/or lower channels 22 can have various other thicknesses including in one case a thickness equal to at least about one half the thickness of the upper 14 and/or lower portion 16.
The pallet spacer 10 can include a plurality of spacers, spacer components or spacer rails 34 that extend along the longitudinal direction Lo of the spacer body 12. Each spacer 34 can extend outwardly/upwardly from the upper surface 24 of each upper portion 14, and define a spacer distance D (
In one case each item 32 has a lateral dimension that is at least about 90 percent of the spacer distance D. Accordingly, the pallet spacer 10 can define a plurality of gaps 36 having a lateral dimension D positioned between adjacent spacers 34. Each of the gaps 36 can have equal spacing in the illustrated embodiment, and each gap 36 spans at least one channel 20 in the illustrated case. Four gaps 36 are provided in the illustrated embodiment although the pallet spacer 10 can provide at least one gap 36 in one case, or at least two gaps 36 in another case or at least three gaps 36 in another case, or more as desired.
In the illustrated embodiment, each spacer 34 takes the form a raised rail having a rectangular cross section and extending generally the entire longitudinal dimension of the pallet spacer body 12. However, if desired each spacer 34 can take a variety of shapes and forms and can, for example, have other cross sectional shapes and/or take the form of a discontinuous series of spacer components 34, such as knobs, cylinders or the like spaced along the length of the pallet spacer body 12.
The pallet spacer body 12 can also include a plurality of openings or holes 38 formed through a thickness thereof to aid in air circulation. In the illustrated embodiment the openings 38 are located at the bottom of the upper channels 20 and extend through the lower portions 16 in a direction generally perpendicular to the upper surfaces 28 of the lower portions 16. However, if desired, the holes 38 can be located at different positions and have different shapes.
The pallet spacer 10 can have a variety of shapes and configurations to correspond to the shape of the items 32 to be stored thereon. In the particular illustrated embodiment, the spacer body 10 includes alternating relatively laterally-short upper portions 14a and relatively laterally-long upper portions 14b. This configuration can provide a relatively laterally-short upper portion 14a positioned between two relatively laterally-long upper portions 14b. As shown in
In the illustrated embodiment the spacers 34 are positioned only on the relatively laterally-long upper portions 14b, and no spacers 34 are positioned on the relatively laterally-short upper portions 14a. Moreover, in the illustrated embodiment, none of the lower portions 16 include any spacers positioned 34 thereon. In the illustrated embodiment each lower portion 16 has generally the same lateral dimension. However, the spacer positioning, configuration and spacing of the upper 14 and lower portions 16 can be varied as desired to accommodate differently sized and shaped items 32 to be stored on the pallet spacer 10.
In order to utilize the pallet spacer 10, with reference to
The pallet spacer system as described herein provides increased air flow around palletized cases or items 32 such that, when the palletized system is positioned in a temperature controlled environment, efficient heat transfer is enabled. The spacer rails 34 of the pallet spacers 10 also position and retain the items 32 to establish consistent, controlled spacing between adjacent items 32. In addition, the pallet spacer 10 provides channels 20, 22 above and below the items 32, and provide a relatively small surface area supporting the stored items 32, to thereby increase the size of the channels 20, 22. The generally flat surfaces 24, 30 of the upper 14 and lower 16 panels enable items 32 to be flatly stacked thereon and thereunder, and provide sufficient surface area to transfer weight forces so that items 32 can be stacked without being crushed. The openings 38 further increase air circulation to help yield consistent temperatures in the items 32, and also reduce the weight of the pallet spacer 10. Finally, when not in use the pallet spacers 10 can be stacked in a nested arrangement to provide space saving.
Although the pallet spacers 10 can be made from a variety of materials and in a variety of manners, in one embodiment the pallet spacers 10 are manufactured of manifold-injected polypropylene, but also can be extruded due to a uniform thickness or cross-sectional shape (except for the openings 38 which can be formed after extrusion). Thus, in one embodiment, the pallet spacer 10 has a constant or generally constant cross-sectional shape, excluding the openings 18, along its entire length. In another embodiment, the pallet spacer 10 has a cross-sectional shape that is constant (excluding the openings 18) or generally constant for at least about one foot of length or at least about two feet of length in the longitudinal direction, to accommodate commonly-sized items 32. Further alternately, each upper portion 14 and/or lower portion 16 and/or transition portion 18 can have a constant thickness or shape excluding the openings 18 along the entire length of the pallet spacer 10, or for at least about one foot or at least about two feet in the longitudinal direction.
Having described the invention in detail and by reference to the various embodiments, it should be understood that modifications and variations thereof are possible without departing from the scope of the claims of the present application.
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Product Information featuring “40×48 FRS Plastic Nestable Pallet” by Orbis (Aug. 9, 2017). |