This disclosure relates to a transport structure, such as a platform for supporting items, to be lifted and moved using various types of transportation vehicles including forklifts.
A pallet is a flat transport structure used to support goods in a stable manner. It provides a platform for items to be loaded securely onto and enables forklifts or other utility vehicles to insert arms underneath the platform for lifting and manipulation. For example, a pallet has a top supporting surface higher than the ground to allow transportation equipment to reach under the top supporting surface. Transportation equipment can include a forklift, pallet jack, front loader, work saver or other jacking devices, or a crane. Goods may be secured to the pallet by strapping, with stretch wrap, or with shrink wrap. Pallets can be made of wood, plastic, metal, paper, or materials that are strong enough to support the cargo while light enough to avoid adding substantial weight for transportation. Because pallets are handled with various transportation vehicles during shipping, collision, tear, shear, or overloading often cause structural damage to the pallets, in addition to the other significant mechanical stresses sustained by such pallets in supporting heavy loads.
This disclosure describes a maintainable pallet that includes at least two side supports, a central support positioned between the at least two side supports, a plurality of top transverse supports positioned above the at least two side supports and the central support to form a top loading surface and fastened at least partially with two-part releasable fasteners; and two bottom transverse supports positioned adjacent and fastened at least partially to bottom ends of the at least two side supports to form a bottom surface, and fastened at least partially with two-part releasable fasteners.
In some embodiments, the at least two bottom transverse supports are fastened to the central support with two-part releasable fasteners.
In some other embodiments, the at least two side supports forms an “M” shape in a side view, wherein the “M” shape is scaled to receive forks of forklifts.
In yet some other embodiments, each of the “M” shape of the at least two side supports further comprises a center leg, wherein at least one center transverse support is fastened to each of the center leg of the at least two side supports with two-part releasable fasteners. The central support has an “M”′ shaped side cross section and a center leg as the two side supports; and the at least one center transverse support is fastened to the center leg of the central support with one or more two-part releasable fasteners.
In some embodiments, the at least two end supports each couples the at least two side supports end-to-end, using one of a comb joint, finger joint, or box joint.
In some other embodiments, the at least two side supports, the central support, the plurality of top transverse supports, and the at least two bottom transverse supports all comprise composites made from biomass material embedded in a polymer matrix. The composites have an aligned direction same as an length direction of the at least two side supports, the central support, the plurality of top transverse supports, and the at least two bottom transverse supports.
In yet some other embodiments, the two-part releasable fasteners include nuts and bolts having tee nut inserts, and plain wood screws, but excluding nails.
In some embodiments, the at least two side supports, the central support, the plurality of top transverse supports, and the at least two bottom transverse supports are configured to receive forks of a forklift from one end of the at least two side supports.
In some other embodiments, the maintainable pallet comprises one or more sensors embedded in one or more of the at least two side supports. The sensors include at least one of an accelerometer, a global positioning system (GPS) receiver, an inertial sensor, and an radio frequency identifier (RFID). The sensors may record data indicating structural integrity of the maintainable pallet and upon determining that an acceleration or stress signal has exceeded a predefined value, at least one of the at least two side supports, the central support, the plurality of top transverse supports, and the at least two bottom transverse supports is replaced with a same interchangeable part.
In yet some other embodiments, the at least two side supports and the central support are shaped to receive the plurality of top transverse supports in full half lap joints, cross halving joints, or T half lap joints, such that the at least two side supports and the central support are flush with the plurality of top transverse supports to form the top loading surface.
In some embodiments, each of the at least two side supports comprises three layers of composite boards; the central support comprises at least two layers of composite boards, and each of the plurality of top supports comprises one layer of composite boards. A center layer of the three layers of composite boards of the at least two side supports is embedded with one or more from the group that includes an accelerometer, location sensor, a strain sensor, and a transmitter. The at least two side supports, the at least two bottom transverse supports, and the at least two end supports further comprise chamfered edges for reducing resistance during insertion of forks of a forklift.
A method for maintaining a maintainable pallet includes detecting an acceleration or stress via a sensor embedded in the maintainable pallet, wherein the pallet comprises interchangeable parts fastened using two-part releasable fasteners. Based on the acceleration or stress detected, one or more damaged pieces in the maintainable pallet are identified. The two-part releasable fasteners on the identified damaged pieces are released to remove the damaged pieces. Then one or more corresponding new pieces are used to replace the damaged pieces.
In some embodiments, the sensor comprises at least one from the group that includes an accelerometer, a GPS, an inertial sensor, and an RFID.
In some other embodiments, the maintainable pallet further includes two side supports, two end supports coupled to the two side supports end-to-end to form a rectangle, a central support position between the two side supports, a plurality of top transverse support fastened onto the two side supports to form a top loading surface and the central support with two-part releasable fasteners, and two bottom transverse supports fastened to the ends of the two side supports to form a bottom surface with two-part releasable fasteners.
At a high level, this disclosure describes a maintainable pallet assembled from interchangeable parts using multiple two-part releasable fasteners, wherein some of the interchangeable parts may be embedded with sensors to track the usage and identify damages. If one or more of the interchangeable parts are damaged, the damaged pieces can be replaced, thus minimizing material waste. For example, the sensors may be used to identify the pallet and its shipment content, to track its location, to measure forces experienced by the pallet for fragile shipments, or to measure the integrity of the pallet. Further, in other embodiments, the interchangeable pieces are made from biomass materials grown in a short life cycle, such that the cost and any negative impact to the environment is very low.
Like elements are labeled using like numerals.
The two side supports 102 and the two end supports 130 are coupled with each other end-to-end to form a rectangle, according to one implementation. In the example illustrated in
Returning to
In some embodiments, an accelerometer or an inertial sensor enables the maintainable pallet 100 to report to a central data gathering system or communication station about the forces experienced during a particular shipment. The force history data can be used to assess any risks associated with shipping fragile items. In another embodiment, a GPS sensor 150 enables end users or the carrier to track a shipment carried on the maintainable pallet 100. In yet another embodiment, an identification sensor (e.g., an RFID) may enable carriers or users to identify a bundle of shipment loaded on a particular pallet or for other logistic uses.
In some embodiments, the two side supports 102, the central support 106, the plurality of top transverse supports 123, 125, and 127, and the two bottom transverse supports 140 comprise composites made from biomass material embedded in a polymer matrix. For example, the composites may be corn-based structural composites that include a fibrous component of corn. In some embodiments, the composites include a structural polymeric composite having a polymer matrix and intact corn husks. The corn husks may be laminated using a polymer matrix of epoxy resin, phenol-formaldehyde, or a polyester, or using any other suitable binder.
The corn husks may have elongate fibers aligned with a first line along the length of each husk, and the corn husks are disposed in a corn husk layer such that the first lines of the corn husks are aligned in the corn husk layer. In some other embodiments, the corn husks may further have elongate fibers aligned with a first line along the length of each husk, and the corn husks are disposed in a corn husk layer such that the first lines of the corn husks are randomly oriented in the corn husk layer. The composites may have an aligned direction same as an length direction of the two side supports 102, the central support 106, the plurality of top transverse supports 123, 125, and 127, and the two bottom transverse supports 140.
In the present embodiment, the two side supports 102 and the central support 106 are shaped to receive the plurality of top transverse supports 123, 125, and 127 such that the two side supports 102 and the central support 106 are exposed to form the top loading surface 121.
Referring now to
The disclosure above provides enumerated examples. Other implementation and embodiments are possible within scopes of the following claims.