The present disclosure is directed to a big-bag transfer station for API seed crystals. The transfer station may permit the filling of smaller containers, such as bags or pouches, from a large container, such as a big bag. The transfer station may permit the transfer without contaminating the atmosphere of the room in which the station is housed. Additionally, the transfer station may limit cross-contamination between filling cycles by employing single-use liners.

A temporary, non-fixed partitioning system includes a common assembly bracket that can be readily assembled with a wall panel formed of various standard dimensioned building supplies. The wall panels may include a standard door slab, a standard window sash, standard dimensional lumber, a peg board, a chalk board, a whiteboard, a corrugated cardboard panel, a foam board, a gator board, a fiberglass panel, a cork panel, a plastic panel, an upholstered panel, a wood panel, and an acrylic-based or silica-based glass panel, and may also be suitable for receiving custom or desired printing of designs, indicia or other nomenclature. The partitioning system could be provided in a kit form with a plurality of common assembly brackets and wall panels, which are reconfigurable for a variety of uses such as co-working space, trade show booths, or lobby displays.

A transfer device is designed for contamination-protected transfer of flowable process material between a first container and a second container. The transfer device includes a guide tube having an axial passage for the flow of the process material, which has a connection at one end and terminates with a tube edge at the other end. A transfer unit opens into the guide tube, which allows engagement with the guide tube. A tubular liner supply having a plurality of peelable useful sections, each provided with a first crimp, is stored on the transfer unit. The useful sections can be used to isolate liner remnants from previous transfer operations for disposal. A first tensioner and a second tensioner are arranged circularly on the guide tube and concentrically to each other, which serve for temporary sealed fixing of residual ends and open ends of new liner pieces originating from inner liners from the second containers.

A proppant delivery assembly receives and supports a plurality of containers having proppant stored therein. A cradle has a top surface which receives and supports the plurality of containers when positioned thereon. The cradle enables the plurality of containers to dispense the proppant stored therein. A proppant mover is positioned to underlie and extend along the top surface of the cradle aligned with the plurality of containers to receive proppant from the plurality of containers. The proppant mover carries proppant away from the plurality of containers. A chute is coupled to the cradle for receiving proppant from the proppant mover and directing the proppant to a blender hopper. A hood assembly is disposed at an end of the chute opposite the proppant mover for directing a vacuum air flow that removes a volume of air containing proppant dust particles directed from the chute. The hood assembly includes a curtain extending about a perimeter of the hood assembly and downward therefrom to at least partially define the volume of air being removed by the hood assembly.

A truck dumper including a material receiving hopper, a tilt table configured to dump a load from the truck or truck trailer into the material receiving hopper. The invention includes a stilling shed positioned above the material receiving hopper and at least one curtain baffle suspended below the roof of the stilling shed. The curtain baffles are positioned such that there is a gap located near the roof and an upper margin of the at least one curtain baffle through which air can flow. The invention further includes an air exhaust structure configured to exhaust dust laden air from the interior of the stilling shed.

Embodiments of the present disclosure describe a system for capturing dust and dust-laden air caused by the agitation, movement or transfer of particulate material. The system includes a dust collection assembly positioned proximate and associated with the delivery of particulate material to capture dust particles released by movement and settling of the particulate material when being dispensed and delivered. The dust collection assembly is positioned to direct an air flow in a flow path overlying the dust particles to capture the dust particles and move the dust particles away from the proppant thereby reducing risk of dust exposure.

A conveyor belt system includes a frame with a conveyor belt driven by at least two rollers so that an upper belt functions as transport surface and a lower belt functions as return, wherein the frame has an upper segment extending substantially above the upper belt and a lower segment extending substantially under the upper belt, wherein the upper segment has at least two upper standing walls with a mutual spacing which, at least at the position of the upper belt, is smaller than the width of the conveyor belt, and wherein the lower segment has at least two lower standing walls with a mutual spacing which is greater than the width of the conveyor belt, wherein the upper belt is supported on either side by a plate extending respectively from below the upper belt to an outer side of the lower standing wall.

A dust control device for preventing dust and debris from escaping into the atmosphere during the process of loading rail cars with grain or other granular commodities/products. The dust control device generally includes a dust hood that is moveably supported on a pair of stationary elongated support rails via wheels. The support rails are attached to a delivery spout of an elevator and extend over the path of travel of a rail car to be loaded. An elongated pivotable engagement arm connected to the dust hood extends downwardly into the path of the rail car and is engaged as the car passes beneath the dust hood. The dust hood moves with the rail car from a ready position to an operational position in close proximity to the delivery spout to capture the dust and debris generated during the loading process. When the rail car disengages from the engagement arm, the dust hood returns to the ready position automatically and without a power source under the force exerted by a spring-biased positioning assembly.

Systems and methods for dispensing dry flowable materials used in wellbore operations. In some embodiments, the methods include: providing at least one vessel that contains dry flowable materials, each vessel including an outlet connected to a common vacuum manifold; providing a vacuum source for directing a flow of the dry flowable materials from at least one vessel to the common vacuum manifold; discharging the dry flowable materials from the vessel to the common vacuum manifold through an outlet connected to at least one vessel, wherein a discharge valve is disposed on the outlet; determining an amount of dry flowable materials in at least one vessel at least in part using at least one load cell disposed underneath the vessel; and determining the amount of dry flowable materials being routed to the common vacuum manifold based at least in part on the amount of dry flowable materials measured in the vessel.

A filling and/or emptying apparatus (I) for filling and/or emptying flexible containers (5) having a filling and/or emptying neck (2) with an open end portion and at least one deformable disposable fastening ring (9), wherein the ring (9) is designed in relation to the internal diameter of the neck (2) such that once a container edge (7) is folded over around the ring, it is possible to insert the ring (9) in an end portion of the neck (2) so that the ring (9) is arranged substantially concentrically with the neck (2), and a radially outer fold-over portion (8) of the container edge (7) is arranged and/or clamped between an inner surface of the neck (2) and a radially outer surface. It is possible to press the ring (9) into a sealing portion (15) of the neck (2), which is arranged after the end portion in the axial direction (A) and has a smaller internal diameter than the end portion. The ring (9) undergoes deformation in the radial direction, so that the insertion and/or pressing into the interior of the neck (2) leads to a radial deformation and a counterposed pressure force which presses the outer fold-over portion (8) of the container edge (7) against the inner surface of the neck (2), thereby sealing the container (5) against the neck (2).