The pallet assembly comprises a top plate, a load-force plate, a runner, and a plurality of load blocks disposed between the load force plate and the runner. The load-force plate is disposed between the top plate and the runner and increases the load bearing capacity of the top plate while adding strength to the pallet assembly. The pallet assembly includes a biocidal coating material that protects shipment of foodstuffs and other products requiring sanitary conditions, preventing the growth of mold, fungi, bacteria, and viruses. The pallet assembly includes a pallet integrated module positioned between the top plate and the runner, that collects journey data on location, temperature, humidity and shock along with store forward capability during not connected times of each journey of the pallet assembly. The load-force plate has either an X-form configuration or a cross-form configuration. In one preferred embodiment, an antenna is embedded in the cross-form configuration.

Modular pallet system for transporting bulky and fragile goods in a multi-story constellation, the system consists of the modules basic-pallet, vertical-pillars, longitudinal-reinforce-elements and transversal-reinforce-elements. The basic-pallet provides the surface for placing the cargo and for lashing via integrated tie-down points. Further junction points at the edges of the basic-pallet are for the connection with the vertical-pillars and through these with the reinforce elements, necessary to provide the assembly's stability, enabling stack ability with additional basic-pallets on top.

The present invention relates to a pallet with impact resistant columns (3) comprising a structure for the distribution of impact energy (4) configured for the distribution of impact forces, at the same time as its internal structure deforms and is compacted upon receiving impacts, such that the pallet remains functional although its columns (3) are permanently deformed and/or partially fractured.

The present invention relates to a pallet with impact resistant columns (3) comprising a structure for the distribution of impact energy (4) configured for the distribution of impact forces, at the same time as its internal structure deforms and is compacted upon receiving impacts, such that the pallet remains functional although its columns (3) are permanently deformed and/or partially fractured.

Modular pallet system for transporting bulky and fragile goods in a multi-story constellation, the system consists of the modules basic-pallet, vertical-pillars, longitudinal-reinforce-elements and transversal-reinforce-elements. The basic-pallet provides the surface for placing the cargo and for lashing via integrated tie-down points. Further junction points at the edges of the basic-pallet are for the connection with the vertical-pillars and through these with the reinforce elements, necessary to provide the assembly's stability, enabling stack ability with additional basic-pallets on top.

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 shock and vibration isolation assembly for absorbing the energies generated from movement of a product carried thereon includes a pallet or a lower panel having an upper surface, an upper panel above the upper surface, the upper panel configured to support the product or a pallet thereon. The assembly further includes a plurality of flexible visco-elastic rings affixed to at least one of said upper surface of said pallet or lower panel and a facing surface of the upper panel. A frame member disposed between and affixed to the upper surface of the pallet or lower panel and the upper panel to seal the space therebetween. The frame member encircles the plurality of flexible rings and is formed of a resilient substantially liquid-impermeable material.

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 shock and vibration isolation assembly for absorbing the energies generated from movement of a product carried thereon includes a pallet or a lower panel having an upper surface, an upper panel above the upper surface, the upper panel configured to support the product or a pallet thereon. The assembly further includes a plurality of flexible visco-elastic rings affixed to at least one of said upper surface of said pallet or lower panel and a facing surface of the upper panel. A frame member disposed between and affixed to the upper surface of the pallet or lower panel and the upper panel to seal the space therebetween. The frame member encircles the plurality of flexible rings and is formed of a resilient substantially liquid-impermeable material.

A glass roving package 200 is provided which has a simple configuration which can prevent shifting and collapse of the glass roving package 200 during transportation of the package, and for which it is easier to package glass rovings 100 and unpack, and the cost of the glass roving package 200 can be reduced. The glass roving package 200 includes groups of glass rovings 100 stacked on top of each other on a base board 20, the glass rovings 100 in each group being arranged, and a wrapping material wrapped around an outer circumferential portion of the groups of glass rovings 100. A displacement prevention sheet 10 is interposed between a lower group of glass rovings 100 and an upper group of glass rovings 100 in order to prevent the upper group of glass rovings 100 from being displaced during transportation of the package.