Bag-in-box dispensing systems (1100) are provided which include an outer box (1101) enclosing an inner flexible container (1103), wherein the outer box includes: a top panel (1107); a bottom panel (1105); a first side panel (1125); a second side panel (1127); a first front panel (231, 329) including at least one front perforation (233, 331) configured to allow a user to separate a portion of the front panel, expose the dispensing system, and secure a portion of the dispensing system in the first front panel; a second front panel (243, 343) disposed adjacent to the first front panel and forming an outer surface of the box, wherein the second front panel includes a perforation extending from an edge of the second front panel and allowing a portion of the second front panel to be removed, thereby exposing at least a portion of the first front panel.

A system for compensating for atmospheric pressure changes for high-altitude transport of packages containing powdered and/or granular material may include: one or more packages including a one-way degassing valve configured to flow gaseous substances produced by the powdered and/or granular material outside the one or more packages. Each package may include: a casing; and a containment element configured to wrap the casing. The casing may include: a main body made of expandable material; a capping device associated with the main body; and an insertion opening in the main body. The capping device may include: a tubular sleeve including a first coupling and a bottom wall; a closure element including a second coupling; and first and second one-way valves associated with the bottom wall. The first one-way valve can be configured to allow insertion of gases. The second one-way valve can be configured to allow outflow of gases.

A bulk material shipping container including a pallet, a compartment mounted on the pallet, a material unloading assembly, and a material loading assembly.

Reusable, flexible, lightweight, low cost flexible intermediate bulk containers (FIBCs) for the delivery of granular proppant material for fracing that will allow the transport of higher weights of proppant, such as sand, per truck load. The invention includes a container made of a high strength, flexible material with a top opening for loading and deploying the proppant. The container can be lifted and deployed with a fork truck or crane. Alternatively, proprietary deployment systems, such as a conveyor system, can be used to quickly and efficiently deploy the proppant from the container at a desired site.

An example fluid container includes a main body and a support leg. The main body has a bottom wall and a sidewall that extends from the bottom wall. The bottom wall has a bottom wall first internal surface and the sidewall has a sidewall first internal surface, a sidewall second internal surface, and defines a passageway. The bottom wall first internal surface extends from the sidewall second internal surface toward the passageway at a downward slope. The support leg extends from the main body and is sized and configured to support the fluid container.

Reduction of contamination and the proportion of fines fractions in the packaging of rod form polysilicon is achieved by directly filling a plastic bag with polysilicon from a cleaning bowl by a rotating motion which causes polysilicon chunks to slide into the bag.

Reusable, flexible, lightweight, low cost flexible intermediate bulk containers (FIBCs) for the delivery of granular proppant material for fracing that will allow the transport of higher weights of proppant, such as sand, per truck load. The invention includes a container made of a high strength, flexible material with a top opening for loading and deploying the proppant. The container can be lifted and deployed with a fork truck or crane. Alternatively, proprietary deployment systems, such as a conveyor system, can be used to quickly and efficiently deploy the proppant from the container at a desired site.

A a squeezer and fluid discharge system and method are disclosed. The fluid discharge system includes a container, a liner bag, a squeezing device and a driving device, the liner bag is installed in the container, and the driving device is connected to the squeezing device and used to drive the squeezing device. The squeezing device comprises at least two rollers, and the liner bag is formed by welding a front panel and a rear panel and is provided with a discharge port which is arranged adjacent to the weld line at the bottom of the liner bag.

An integrated container with a box and pallet is provided that is made entirely of corrugated materials, and is fully compatible with automated systems and methods for the safe collection, transfer, and treatment of infectious and hazardous waste. The integrated box and pallet made entirely of corrugated materials provides an improved high strength packaging solution that allows for safe transport of waste to a disposal location. The corrugated pallet and box are compatible with shredders and does not require metal fasteners. The corrugated pallet and box are completely recyclable, and may be made of a cardboard or of plastic. Separate waste collection containers may be collected and placed in the box of integrated container.

An air cushion having first and second rooms bends at a partition at a corner of a multi-function peripheral (MFP) and contacts a first face of the MFP at a first room outer surface and a second face of the MFP at an second room outer surface. An outer case applies pressure to the outer surfaces of the first and second rooms and presses the first and second rooms to the MFP. When the first room receives a force from outside the outer case, gas moves from the first room to the second room against pressure the outer case applies to the second room, such that a side wall of the outer case contacting the second room deforms. Upon removal of the force, the side wall returns to an original flat state and presses the second room, such that the gas returns from the second room to the first room.