A half pallet includes a deck having opposite front and rear edges and opposite end edges. The end edges are shorter than the front and rear edges. End supports below the deck are adjacent end edges of the deck. The deck extends forward and rearward of the end supports. Each of the end supports includes a front edge recessed from the front edge of the deck and a rear edge recessed from the rear edge of the deck. Each end support prevents entry of a fork tine between the front edge of the end support and the rear edge of the end support.

A composite pallet is made of concrete. The concrete material can include various concrete mixtures, such as Fiber Reinforced Concrete (FRC) or an Engineered Cementitious Composite (ECC). It also can include microspheres. The concrete material can be cast in a mold or formed via an extrusion process and then cured. The pallet components can include a core material that can form various voids or cavities. The core material can include polystyrene foam, and the foam forms a honeycomb, which is then filled with the concrete material. The concrete material can also be dyed to create different colors to identify the pallets. The pallets can further include plastic and/or rubber bumpers on the corners and/or edges to prevent or minimize chipping. The resulting pallet can be cured using carbon dioxide (CO.sub.2) curing which reduces the cure time to about an hour or less.

A pallet assembly includes an upper portion including an upper deck and a plurality of upper column portions extending downward from the upper deck. A lower portion includes a plurality of lower column portions extending upward and a plurality of runners connecting the plurality of lower column portions. An upper reinforcement member is between an upper surface of the lower column portions and a lower surface of the upper deck. A lower reinforcement member between a lower surface of the upper column portions and an upper surface of the runners.

A pallet comprising upper and lower platforms connected by a plurality of blocks. The upper platform includes a plurality of upper platform pedestals and the lower platform includes a plurality of lower platform pedestals. The lower platform pedestals are aligned with the upper platform pedestals such that the lower platform pedestals and the upper platform pedestals extend towards one another. The plurality of blocks interlockingly engage with and extend between the upper and lower platform pedestals to connect the upper and lower platforms. Each block includes an upper recess and a lower recess. The upper recess matches the shape of and receives one of the upper platform pedestals. The lower recess matches the shape of and receives one of the lower platform pedestals. The upper platform, the lower platform, and the plurality of blocks are made of a polymeric material.

A pallet having a deck with a generally planar upper surface with a peripheral edge defining a first area, and a ground engaging structure connected to the deck is provided. A mechanism is connected to the pallet and is moveable from a stowed position to a deployed position. When in the deployed position, a portion of the mechanism defines an overhang area adjacent the first area to increase a total support area of the pallet.

A pallet assembly includes an upper deck having an upper panel portion from which a plurality of ribs extend downward. A plurality of channels are formed in an underside of the upper deck. The pallet assembly includes a plurality of columns below the upper deck. A plurality of reinforcement assemblies, including an inner reinforcement member, are each received within an outer case. The inner reinforcement members are received in the channels in the upper deck.

The present disclosure is directed to a vibration isolation pallet, comprising a support platform and a vibration isolation component arranged on top. The vibration isolation component further comprises a top and a bottom supporting plate with a plurality of spherical dampers and support columns strategically disposed in between. The edges of the top and bottom supporting plates are reinforced together with rubber damping pieces at various locations. The vibration isolation component can be detached from the support platform and functions independently. The pallet as whole can be serviced and maintained for repeated use.

Carrier arrangement (1) for storing and/or transporting and/or cleaning dishware or other items, wherein the carrier arrangement (1) has at least one carrier plate (2) with at least one lattice-shaped structure (3), wherein the lattice-shaped structure (3) is formed by lattice rods (5) which are arranged in a rectangular shape, in particular a square shape, and surround rectangular, in particular square, openings (4), and wherein the carrier arrangement (1) has at least one fastening base (6) which is fastenable or fastened with a clamping action on the lattice-shaped structure (3), wherein the fastening base (6) is fastenable or fastened with a clamping action in one of the rectangular, in particular square, openings (4).

The present disclosure is for a vibration isolation pallet, comprising a support platform, a vibration isolation component arranged on top. The vibration isolation component comprises a top and a bottom supporting plate with a plurality of spherical dampers strategically disposed in between. The supporting plates are reinforced with rubber damping pieces around its edges. The vibration isolation component can be independently installed onto various transportation means such as a pushcart or a vehicle. The pallet as whole can be serviced and maintained for repeated use.

A container includes a pallet having a plurality of elongated grooves of predetermined pattern in the upper surface of the pallet, and at least one stackable container body formed with a wall member, the bottom edge surfaces having a plurality of protrusions formed thereon, the top edge surfaces having a plurality of slots formed therein at a corresponding location with the protrusions to allow one container body to stack on another container body with the protrusions of one container body inserted into the slots of the other container body. The container body includes a folding configuration at its side surfaces thereof to allow the container body to fold to reduce its size, wherein the elongated grooves of the pallet are configured to receive the protrusions of the container body both in the unfolded (original) shape and the folded shape.