Pallet shelf system (4) having at least two pallet decks, said system comprising at least two standard pallets (10a, 10b), each standard pallet comprising at least two fork pockets for receiving the forks of a forklift, at least four upright support posts (42a, 42b, 42c, 42d), two lower pallet base units (21a, 21b) comprising respective protrusions matching a respective fork pocket on a lower pallet (10a), and at least two upper pallet base units (41a, 41b), wherein two support frames (40a, 40b) are formed from said pallet base units and said upright support posts, said upper pallet base units (41a, 41b) supporting the upper pallet's outer pallet legs.

A foldable pallet deck is provided. The foldable pallet deck comprises first and second base members connected by a frame member, first and second legs selectively movable with respect to the first base member, third and fourth legs selectively movable with respect to the second base member; first, second, third, and fourth connecting plate assemblies connecting the first, second, third, and fourth legs with the first and second base members such that each of the first, second, third, and fourth legs are movable with respect to the respective first and second base members between a deployed configuration and a folded configuration, first and second cross members configured to securely engage first and second stacking members, respectively, when the pallet deck is in the deployed configuration.

The present invention provides a pallet frame of a unitary body of a molded pulp material having a first surface, a second surface opposed to the first surface, and a generally polygonal shaped peripheral wall. The peripheral wall has four corners, and a first pair of legs and a second pair of legs extending away from the first surface. The first pair of legs being positioned at two corners of the four corners, and the second pair of legs being positioned at another two corners of the four corners. The first pair of legs having a first end surface with a centrally disposed upstanding boss. The second pair of legs having a second end surface with a centrally disposed detent dimensioned to receive a boss when a pair of like pallet frames are in a deployed condition.

Flowline components are assembled into high-pressure fluid transportation systems by a flange union. The flowline component comprises a body defining a substantially cylindrical central conduit. The conduit extends between first and second flat union faces and is adapted to conduct fluids through the body. The union faces are adapted to provide a mating surface for a flange union between the component and another flowline component. Accordingly, the union faces have a plurality of holes adapted to accommodate threaded connectors for forming the flange union. The holes are arranged in a defined array extending angularly around the conduit. Importantly, the array of holes on the first union face and the array of holes on the second union face are offset angularly relative to each other by an angle . It will be appreciated that such components may allow changes in the direction of a flow line.

Aspects of the present disclosure provide techniques and apparatus for multiple physical resource block (PRB) operations for narrowband (NB) systems, such as NB internet-of-things (IoT). In one aspect, a method is provided which may be performed by a wireless device such as a user equipment (UE), which may be an NB-IoT device. The method generally includes performing a cell search based on one or more signals received in an anchor RB within a set of RBs available for narrowband communications with a base station (BS); determining a location of at least one additional RB available for the narrowband communications with the BS based on an indication received in the anchor RB; and performing narrowband communications with the BS using at least one of: the anchor RB or the at least one additional resource block.

Embodiments of this disclosure include a rigid tray container and methods and equipment for using the rigid tray container in batched process operations. In one embodiment, a mass container is sized and dimensioned to receive one or several rigid tray containers. In other embodiments, equipment is configured to lid/unlid, secure, stack, load/unload, and buffer rigid tray containers. In other embodiments, equipment is configured to stack and stage mass containers. In some embodiments, methods are provided for batch processing items.

A pallet-like understructure, in particular for transport and storage containers for liquids, which are equipped with an inner container made of plastic, with a closable filling neck and a draining neck for connecting a tapping armature, wherein the understructure has an outer jacket made of a metal grid or sheet metal, and a bottom (13) for supporting the inner container, corner feet and central feet arranged between the corner feet, as well as a bottom cross member (16), wherein at least the outer jacket and the bottom cross member are attached to at least two central feet, wherein the respective central foot, the outer jacket and the bottom cross member are coupled in a form-fitting fashion with the aid of a screw (45), wherein there is a bracket (28), which reaches around the bottom cross member (16) and around a peripheral edge of the outer jacket, wherein the screw (45) penetrates legs (29, 30) of the bracket.

A packaging for a flexible container, in particular for a disposable bag for use in a bioreactor, including a bottom part for fixing a first portion of the container, a ceiling part for fixing an opposite second portion of the container, a receiving space which on a first side is defined by the bottom part and on an opposite second side is defined by the ceiling part, and struts arranged between the bottom part and the ceiling part, which fix a defined distance between the bottom part and the ceiling part.

The present disclosure relates to a top frame-type structural system for load fixing. The system can be used together with pallets that can support a product/merchandise or goods, which are supported, stowed and/or palletized, and subsequently fastened/fixed by a rope, tape and/or strap. In particular, the top frame of the present system is configured to mechanically interact with the strap and efficiently distribute the generated stresses derived from the force tension to which it is subjected to ensure the integrity and bracing of the product. The present system includes a set of structural components, manufactured in a modular manner, which can be assembled and disassembled/taken to pieces, which offers a practical product, easy to handle and transport, and specifically, being manufactured in a modular manner, such that the present structural system can be advantageously transported, packaged using less space, thus improving its logistics and handling.

A customisable, modular storage system is described where goods are stored in containers and the containers are stored in stacks. The stacks are contained within towers formed of stacks of bin receiving units. A grid network of tracks is provided on the top of the bin receiving units upon which load handling devices run. The load handling 30 devices take containers from the stacks and deposit them at alternative locations in the stacks or deposit then at stations where goods may be picked out.