The invention relates generally to industrial pallets, and more particularly to a pallet fabricated from sheet metal.
A pallet, or skid, is used in the storage and transport of goods to enable lifting by a forklift, pallet jack, or other type of handling device. Goods are typically secured to a pallet with a suitable strapping. In many cases, pallets are designed and intended to be re-used multiple times.
While pallets are commonly made of wood, in some cases wood is known to present certain disadvantages. For example, laws may require pallets shipped across certain borders to be made of materials that are incapable of being a carrier of invasive species of insects and plant diseases. Wood (and plastic) pallets are considered fire hazards. Pallets made from wood are sometimes treated with pesticides, fungicides and/or other hazardous chemicals to improve weather resistance. Wood pallets used to transport food can possibly harbor pathogens such as E. coli and Listeria.
For these and other reasons, there has been genuine and abiding interest to manufacture pallets from metal. Metal cannot harbor pathogens, invasive species of insects or plant diseases, is not considered a fire hazard, is typically not treated with hazardous chemicals. Metal pallets are strong and thus favored for heavy loads, high-stacking loads, long term dry storage, and loads moved by abusive logistic systems. Metal materials useful in the manufacture of pallets include carbon steel, stainless steel and aluminum to name a few. General advantages of metal pallets are high strength and stiffness, excellent durability, resistance to bugs, the absence of splinters, sanitization, and recyclability.
Despite these advantages, metal pallets also have an array of inherent disadvantages. Higher initial price is one. Metal pallets are more expensive to manufacture compared to wood pallets. However, the higher initial cost can be expected to invert to lower long-term cost due to longer service life of metal pallets compared to wood pallets. Weight is another concern. Metal pallets tend to weight more than wood pallets rated to sustain comparable loads. Metal is slippery compared to wood. The inherent lower friction coefficients of metal mean that loads must be more securely strapped to the metal pallet. The lowest cost type of metal pallets is carbon steel, which is susceptible to rusting. Those materials that are less at risk of corrosion, e.g., stainless steel and aluminum, are considerably more expensive that carbon steel.
Some of these disadvantages, in particular cost and weight, can be mitigated by improvements in design that enable more effective use of lighter-gauge metal stock. However, moving to light gauge sheet metal typically results in a reduction ins load carrying capacity and/or decreased resistance to racking. Racking forces occur in normal use of pallets, such as when a heavily loaded pallet experiences a sideways force. Frictional resistance at the bottom of the assembly (due to the weight force) will introduce racking stresses between the deck and floor of the pallet assembly. The left and right fork tube risers must be capable of resisting this racking load.
Moreover, as mentioned above, the higher initial cost of a metal pallet is often justified by the expectation of a long service life. Unfortunately, a longer service life means more opportunities for exposure to damage. Damage, caused overwhelmingly by fork truck usage, can cause unsafe stacking conditions.
There is therefore a continuing desire within the industrial community for an improved metal shipping pallet that retains all of the normal functionality of pallets in use today, and all of the advantages of a metal pallet in particular, but suffers less from the known shortcomings of metal pallets, namely high initial cost and high weight and service-related damage.
A sheet metal pallet assembly comprises a deck having a top surface and a bottom surface. The deck has left and right longitudinal edges as well as first and second transverse edges. The left and right longitudinal edges define a longitudinal direction of the assembly and a length of the deck. Longitudinal perimeter girding is disposed along the deck adjacent each of the left and right longitudinal edges. Transverse perimeter girding is disposed along the deck adjacent each of the first and second transverse edges. At least one transverse reinforcement rib extends between the left and right longitudinal edges of the deck. Interior longitudinal girding is disposed below the bottom surface of the deck. The interior longitudinal girding is spaced apart from the left and right longitudinal edges. A left fork tube riser is disposed below the bottom surface of the deck adjacent the left longitudinal edge. The left fork tube riser extends generally the length of the deck between the first and second transverse edges. The left fork tube riser has a left inner leg and a left outer leg. The left fork tube riser has a left floor that interconnects the left inner and outer legs. The left outer leg has an upper edge in direct contact with the bottom surface of the deck. The left outer leg has a left outer interface in direct contact with the left floor. The left outer interface defines a left outer angle measured between the left floor and the left outer leg. The left inner leg has an upper edge. The interior longitudinal girding is disposed along the upper edge of the left inner leg. The left inner leg has a left inner interface in direct contact with the left floor. The left inner interface defines a left inner angle measured between the left floor and the left inner leg. A right fork tube riser is disposed below the bottom surface of the deck adjacent the right longitudinal edge. The right fork tube riser extends generally the length of the deck between the first and second transverse edges. The right fork tube riser has a right inner leg and a right outer leg. The right fork tube riser has a right floor that interconnects the right inner and outer legs. The right outer leg has an upper edge in direct contact with the bottom surface of the deck. The right outer leg has a right outer interface in direct contact with the right floor. The right outer interface defines a right outer angle that is measured between the right floor and the right outer leg. The right inner leg has an upper edge. The interior longitudinal girding is also disposed along the upper edge of the right inner leg. The right inner leg has a right inner interface in direct contact with the right floor. The right inner interface defines a right inner angle measured between the right floor and the right inner leg. The right outer angle is asymmetric with respect to the right inner angle, and the left outer angle is asymmetric with respect to the left inner angle.
Having dissimilar or asymmetric outer and inner angles contributes to increased resistance to shear loads such as occur when a pallet assembly is subjected to a racking force. Racking forces are foreseeable in normal use of a pallet assembly. For example, in cases where a heavily loaded pallet assembly experiences a sideways force, frictional resistance at the bottom of the assembly (due to the weight force) will introduce racking stresses between the deck and floor of the pallet assembly. The left and right fork tube risers must be capable of resisting this racking load. Maintaining the one angle greater than the other has been found to improved deflection resistance in the assembly. As a direct consequence, the pallet assembly can be manufactured relatively inexpensively from light-weight sheet metal and still perform to necessary industry specifications.
These and other features and advantages of the present invention will become more readily appreciated when considered in connection with the following detailed description and appended drawings, wherein:
Referring to the figures, wherein like numerals indicate like or corresponding parts throughout the several views, a fabricated sheet metal pallet assembly is generally shown at 20 in
The assembly 20 includes a deck 22 upon which loads/cargo (not shown) are placed. The deck 22 has an upwardly facing top surface, and a downwardly facing bottom surface. The deck 22 can take any number of geometric shapes, but in the most common and traditional configuration has a generally rectangular in shape dimensioned to suit a particular intended application or general class of applications. As perhaps best shown in
The left 24 and right 26 longitudinal edges define a longitudinal direction of the assembly 20, as well as a length of the deck 22. That is to say, when speaking of the length of the assembly 20, or of components of the assembly 20, the measurement is taken in the longitudinal direction. And when speaking of the width of the assembly 20, or of components of the assembly 20, the measurement is taken in the transverse direction—i.e., parallel to the first 28 and second 30 transverse edges.
The deck 22 is shown as an independent member in the exploded view of
In addition to the transverse perimeter girding 32, the deck 22 also includes at least one transverse reinforcement rib 34 extending between the left 24 and right 26 longitudinal edges of the deck 22. In some embodiments, a plurality of spaced-apart transverse reinforcement ribs 34 are employed. The transverse reinforcement ribs 34 cooperate with the transverse perimeter girding 32 to resist bending moments generated by weight force loads and structurally enhance the load-supporting capacity of the deck 22. Each transverse reinforcement rib 34 extends, at least partially, below the bottom surface of the deck 22, as can be easily appreciated from
The left 24 and right 26 longitudinal edges of the deck 22 may include a fold-over or hem 36, as shown clearly in
A left fork tube riser, generally indicated at 38, is disposed below the bottom surface of the deck 22 adjacent the left longitudinal edge 24. Similarly, a right fork tube riser 40 is disposed below the bottom surface of the deck 22 adjacent the right longitudinal edge 26. The left 38 and right 40 fork tubes comprise the undercarriage of the pallet assembly 20. The fork tube risers 38, 40 are spaced apart from one another and each extends generally the length of the deck 22 between the first 28 and second 30 transverse edges, as shown throughout the figures. The fork tube risers 38, 40 support the deck 22 above the ground surface, and provide tunnel-like shafts to receive the tines 42 of a forklift (
The left fork tube riser 38 has a left inner leg 44 and a left outer leg 46. The left outer leg 46 is proximate the left longitudinal edge 24, whereas the left inner leg 44 is proximate to an imaginary longitudinal centerline of the deck 22. The left legs 44, 46 extend the full length of the left fork tube riser 38. That is, each left leg 44, 46 extends generally the length of the deck 22 between the first 28 and second 30 transverse edges. In this manner, the left inner 44 and outer 46 legs provide independent support to the entire length of the deck 22.
A left floor 48 interconnects the left inner 44 and outer 46 legs to complete a box-like construction of the left fork tube riser 38. The left floor 48 is generally parallel to the deck 22 and is adapted to rest directly upon the ground or other underlying support surface. The left floor 48 may be fitted with one or more lightening apertures 50.
The left outer leg 46 has an upper edge in direct contact with the bottom surface of the deck 22, as best shown in
The left outer leg 46 has a left outer interface 54 in direct contact with the left floor 48. The left outer interface 54 defines a left outer angle LO measured inside between the left floor 48 and the left outer leg 46, as indicated in
In a manner somewhat similar to the left outer leg 46, the left inner leg 44 also has an upper edge and a left inner interface 58 in direct contact with the left floor 48. The upper edge of the left inner leg 44 is in direct contact with the bottom surface of the deck 22, as best shown in
The left inner interface 58 defines a left inner angle LI measured on the inside between the left floor 48 and the left inner leg 44, as indicated in
A particularly noteworthy attribute of the present invention is that the left outer angle LO can be asymmetric with respect to the left inner angle LI. Having dissimilar or asymmetric outer LO and inner LI angles is a distinctive design feature of this invention and contributes to increased resistance to shear loads such as occur when a heavily loaded pallet assembly 20 is pushed sideways. In such cases, frictional resistance at the bottom of the assembly 20 will introduce a serious racking stresses. Maintaining the one angle greater than the other will resist deflection in the assembly 20 arising from these types of shear loads. In the illustrated examples, the left outer angle LO is greater than the left inner angle LI. Expressed mathematically: LO>LI. Thus, even though there is overlap in the cited ranges for LO and LI, it should be the case that LO>LI in order to best achieve the several, sometimes competing, desirable attributes of this invention. Establishing the left outer angle LO greater than the left inner angle LI is a distinctive design feature of this invention and contributes to increased resistance to shear loads by directing the shear resistance stresses toward the laterally distal edges 24, 26 of the assembly 20. That is, serious racking stresses can best be resisted over a wider footprint, which occurs when the left outer angle LO is established to be greater than the left inner angle LI.
The left outer leg 46 is formed with a pair of outer windows 62. The left inner leg 44 also has a pair of inner windows 64. The left outer windows 62 are transversely aligned with the left inner windows 64. The significance of the windows 62, 64 will be described subsequently.
The end of the left fork tube riser 38 adjacent the first transverse edge 28 comprises a first left end, and the end of the left fork tube riser 38 adjacent the second transverse edge 30 comprises a second left end. From
Again stated, the left 38 and right 40 fork tube risers are mirror images of one another. The features of the right fork tube riser 40 will be described presently using like or corresponding reference numbers to those of the left fork tube riser 38 but with prime designations.
The right fork tube riser 38 has a right inner leg 44′ and a right outer leg 46′. The right outer leg 46′ is proximate the right longitudinal edge 24, whereas the right inner leg 44′ is proximate to an imaginary longitudinal centerline of the deck 22. The right legs 44′, 46′ extend the full length of the right fork tube riser 38. That is, each right leg 44′, 46′ extends generally the length of the deck 22 between the first 28 and second 30 transverse edges. In this manner, the right inner 44′ and outer 46′ legs provide independent support to the entire length of the deck 22.
A right floor 48′ interconnects the right inner 44′ and outer 46′ legs to complete a box-like construction of the right fork tube riser 38. The right floor 48′ is generally parallel to the deck 22 and is adapted to rest directly upon the ground or other underlying support surface. The right floor 48′ may be fitted with one or more lightening apertures 50′.
The right outer leg 46′ has an upper edge in direct contact with the bottom surface of the deck 22, as best shown in
The right outer leg 46′ has a right outer interface 54′ in direct contact with the right floor 48′. The right outer interface 54′ defines a right outer angle RO measured inside between the right floor 48′ and the right outer leg 46′, as indicated in
In a manner somewhat similar to the right outer leg 46′, the right inner leg 44′ also has an upper edge and a right inner interface 58′ in direct contact with the right floor 48′. The upper edge of the right inner leg 44′ is in direct contact with the bottom surface of the deck 22, as best shown in
The right inner interface 58′ defines a right inner angle RI measured on the inside between the right floor 48′ and the right inner leg 44′, as indicated in
A particularly noteworthy attribute of the present invention is that the right outer angle RO can be asymmetric with respect to the right inner angle RI. Having dissimilar or asymmetric outer RO and inner RI angles is a distinctive design feature of this invention and contributes to increased resistance to shear loads such as occur when a heavily loaded pallet assembly 20 is pushed sideways. In such cases, frictional resistance at the bottom of the assembly 20 will introduce a serious racking stresses. Maintaining the one angle greater than the other will resist deflection in the assembly 20 arising from these types of shear loads. In the illustrated examples, the right outer angle RO is greater than the right inner angle RI. Expressed mathematically: RO>RI. Thus, even though there is overlap in the cited ranges for RO and RI, it should be the case that RO>RI in order to best achieve the several, sometimes competing, desirable attributes of this invention. Establishing the right outer angle RO greater than the right inner angle RI is a distinctive design feature of this invention and contributes to increased resistance to shear loads by directing the shear resistance stresses toward the laterally distal edges 24, 26 of the assembly 20. That is, serious racking stresses can best be resisted over a wider footprint, which occurs when the right outer angle RO is established to be greater than the right inner angle RI. Although not strictly necessary, in most cases the symmetry between the respective fork tube risers 38, 40 will be maintained, such that LO=RO and LI=RI.
The right outer leg 46′ is formed with a pair of outer windows 62′. The right inner leg 44′ also has a pair of inner windows 64′. The right outer windows 62′ are transversely aligned with the right inner windows 64′, and also transversely aligned with the left inner 64 and outer 62 windows, to receive the tines 42 of a forklift. That is to say, the crosswise (transverse) alignment of the windows 62, 64, 62′, 64′ are designed to accept the tines 42 of a forklift so that the assembly 20 can be lifted and moved with a forklift in the normal course of industrial/commercial handling. The provision of windows 62, 64, 62′, 64′ in combination with the previously described function of the fork tube risers 38, 40, allows “four-way” entry so that a forklift can lift the pallet assembly 20 from all four directions.
The end of the right fork tube riser 38 adjacent the first transverse edge 28 comprises a first right end, and the end of the right fork tube riser 38 adjacent the second transverse edge 30 comprises a second right end. From
Having thus described each of the fork tube risers 38, 40 in detail, attention can now be given to the features incorporated into the pallet assembly 20 that further increase structural integrity of the deck 22. These features include longitudinal perimeter girding 68 and interior longitudinal girding 70. The longitudinal perimeter girding 68 are those affects disposed along the deck 22 adjacent each of the left 24 and right 26 longitudinal edges which provide significant enhancement of load carrying capacity. The interior longitudinal girding 70 is disposed below the bottom surface of the deck 22, and located nearer to the imaginary longitudinal centerline of the assembly 20. In combination, the longitudinal perimeter girding 68 and interior longitudinal girding 70 substantially stiffen the deck 22 so that it can support heavy loads in normal usage.
Thus, the longitudinal perimeter girding 68 and interior longitudinal girding 70 each preferably comprise tubular elements that are strategically-located to undergird or brace the deck 22 from below. The interior longitudinal girding 70 spaced apart from the left 24 and right 26 longitudinal edges. As previously mentioned, a rigid connection between the upper edges of each of the inner 44, 44′ and outer 46, 46′ legs to the deck 22 can be achieved by welding and/or mechanical interlock and/or other suitable fixation technique(s). In one embodiment, a quality weld line is applied along the entire lengths of the touch points between the deck 22 and the upper edges of the inner 44, 44′ and outer 46, 46′ legs. By integrating the longitudinal perimeter girding 68 and interior longitudinal girding 70 to the inner 44, 44′ and outer 46, 46′ legs, it will be understood that these girdings 68, 70 are thus fixed directly to the bottom surface of the deck 22.
Also as previously mentioned, interruptions 52, 52′ can be formed on the upper edges of the left 46 and right 46′ outer legs at each intersection with the transverse reinforcement ribs 34. And likewise, interruptions 60, 60′ can be formed on the upper edges of the left 44 and right 44′ inner legs at each intersection with the transverse reinforcement ribs 34. From the perspective of
At least one bridge 72 extends between the left fork tube riser 38 and the right fork tube riser 40. In the example of
A second alternative embodiment of the invention is shown in
Another notable distinction in the second alternative embodiment is that the transverse reinforcement ribs 134 are loose-piece members, whereas in
Moreover, the second alternative embodiment of
As in all of the preceding embodiments, the outer angles LO/RO (not indicated in
Although not visible in
A third alternative embodiment of the invention is shown in
Examination of the views in
Another notable distinction in the third alternative embodiment (compared to the second alternative embodiment) is that only one, centrally-located, loose-piece transverse reinforcement rib 134 is used. Yet another notable distinction of the third alternative embodiment is the inclusion of first 276 and second 278 intermediate risers. The intermediate risers 276, 278 are located between the left 238 and right 240 fork tube risers, generally centered along the longitudinal centerline of the deck 220. Each intermediate riser 276, 278 has a generally U-shaped configuration somewhat mimicking the U-shapes of the fork tube risers 238, 240. That is to say, the intermediate risers 276, 278 can be see as having a floor co-planar with the floors 248, 248′ of the respective fork tube risers 238, 240. In the illustrated example, the floor of each intermediate riser 276, 278 extends integrally from a respective bridge 272, like a tongue. Legs extend upwardly from the floor of the intermediate risers 276, 278 to respective upper edges that flare outwardly, thus forming supplemental interior longitudinal girding 270 for the deck 222.
Furthermore, the end view of
A still further distinction in the third alternative embodiment can be observed in the bridges 272. In this example, the inner legs 244, 244′ of the fork tubes 238, 240 are discontinuous at the junction with the bridges 272. Not only are the bridges 272 fully integrated with the fork tube risers 238, 240, but also their flanges are lengthened to reach to the deck 222. The respective upper edges of these flanges the flare outwardly, thus forming supplemental transverse reinforcement ribs 234 for the deck 222. Also, the lightening apertures are shown as generally round or oval in this embodiment.
A fourth alternative embodiment of the invention is shown in
The foregoing invention has been described in accordance with the relevant legal standards, thus the description is exemplary rather than limiting in nature. Variations and modifications to the disclosed embodiment may become apparent to those skilled in the art and fall within the scope of the invention.
This application claims priority to Provisional Patent Application U.S. 62/923,935 filed on Oct. 21, 2019, the entire disclosure of which is hereby incorporated by reference and relied upon.
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