In accordance with presently disclosed embodiments, systems and methods for using one or more pre-filled, portable containers, instead of pneumatic transfer, to move bulk material from a transportation unit to a blender receptacle of a blender are provided. A transportation unit may deliver one or more containers of bulk material to the well site, where the containers may be disposed in an elevated position around the blender receptacle. A gravity feed outlet may extend from one or more containers to route bulk material from the one or more containers directly into the blender receptacle. Since the transportation unit is able to unload the portable containers of bulk material without pneumatic transfer, the stackable containers may enable a cleaner and more efficient bulk material transfer at the site.

In accordance with presently disclosed embodiments, systems and methods for using one or more pre-filled, portable containers, instead of pneumatic transfer, to move bulk material from a transportation unit to a blender receptacle of a blender are provided. A transportation unit may deliver one or more containers of bulk material to the well site, where the containers may be disposed in an elevated position around the blender receptacle. A gravity feed outlet may extend from one or more containers to route bulk material from the one or more containers directly into the blender receptacle. Since the transportation unit is able to unload the portable containers of bulk material without pneumatic transfer, the stackable containers may enable a cleaner and more efficient bulk material transfer at the site.

A drive coupling assembly includes a housing having a first wall, a second wall, a first end and a second end. A first aperture extends through the second wall adjacent to the first end and a second aperture extending through the second wall adjacent to the second end. The first aperture receives a motor drive shaft and the second aperture receives a sweep drive shaft. Each of the first and second apertures has one of a pair of sprocket hubs aligned therewith. A pair of drive hubs each has an opening extending therethrough and each opening engages one of the motor or sweep drive shafts. The drive hubs have a plurality of pins thereon extending into corresponding slots in the sprocket hubs. A continuous belt engages the sprocket hubs. The slots each have a length allowing limited rotation of the sprocket hubs with respect to the drive hubs.

A drive coupling assembly includes a housing having a first wall, a second wall, a first end and a second end. A first aperture extends through the second wall adjacent to the first end and a second aperture extending through the second wall adjacent to the second end. The first aperture receives a motor drive shaft and the second aperture receives a sweep drive shaft. Each of the first and second apertures has one of a pair of sprocket hubs aligned therewith. A pair of drive hubs each has an opening extending therethrough and each opening engages one of the motor or sweep drive shafts. The drive hubs have a plurality of pins thereon extending into corresponding slots in the sprocket hubs. A continuous belt engages the sprocket hubs. The slots each have a length allowing limited rotation of the sprocket hubs with respect to the drive hubs.

Provided is a dispersion and supply apparatus and a combination weighing apparatus capable of uniformly supplying articles to a plurality of positions from a dispersion table. A dispersion and supply apparatus 20 includes an acquisition unit 64 that acquires a load amount of an article on a dispersion table 22, a calculation unit 104 that calculates a deviation in a loading state of the article based on the load amount acquired by the acquisition unit 64, and a control unit 106 that controls a driving unit 30 such that a conveying direction of the article on the dispersion table 22 is changed based on the deviation in the loading state of the article calculated by the calculation unit 104.

A loose component supply device provided with component supply apparatus that stores multiple components, frame to which the component supply apparatus is detachably attached, claw member for locking the component supply apparatus to the frame, and a component support member that supports multiple component in a scattered state, the components having been ejected from an entrance of the component supply apparatus that is attached to the frame; the locking of the component supply apparatus to the frame is released by an operator grasping grip of the component supply apparatus. The component supply apparatus is swung, and with the swinging linking mechanism is operated such that shutter rotates downwards. That is, with the releasing of the locking of the component supply apparatus, the entrance of the component supply apparatus is covered by the shutter.

A bulk cargo blending hopper has a hollow interior volume that is selectively communicated with a source of vacuum pressure. A first conduit has a first end that is connected to the housing of the hopper and communicates with the interior volume of the housing of the hopper. An opposite second end of the first conduit is configured for communication with a source of bulk cargo that is separate from the hopper. A second conduit has a first end that is also connected to a portion of the housing of the hopper and communicates with the interior portion of the housing. A second end of the second conduit is also connected to a portion of the housing of the hopper and communicates with the interior volume of the housing of the hopper.

A bulk cargo blending hopper has a hollow interior volume that is selectively communicated with a source of vacuum pressure. A first conduit has a first end that is connected to the housing of the hopper and communicates with the interior volume of the housing of the hopper. An opposite second end of the first conduit is configured for communication with a source of bulk cargo that is separate from the hopper. A second conduit has a first end that is also connected to a portion of the housing of the hopper and communicates with the interior portion of the housing. A second end of the second conduit is also connected to a portion of the housing of the hopper and communicates with the interior volume of the housing of the hopper.

A delivery system for feeding particulate matter to a target location at a well site, including a transportable conveyor belt assembly; one or more silos in fluid communication with a particulate supply line, each of the silo inlets extending through a side wall of the respective silo and disposed at a different location from the others along a longitudinal axis of the respective silo; and for each silo an enclosed chute detachably attachable thereto so as to receive into the chute particulate matter gravity fed out of the respective silo and convey such matter into the housing of the conveyor belt assembly. The silos, the chutes and the housing enclose the particulate matter as it passes from the silos through the chutes and conveyor belt assembly to the target location, to inhibit the release of dust generated from movement of the particulate matter from the silos to the target location.

A delivery system for feeding particulate matter to a target location at a well site, including a transportable conveyor belt assembly; one or more silos in fluid communication with a particulate supply line, each of the silo inlets extending through a side wall of the respective silo and disposed at a different location from the others along a longitudinal axis of the respective silo; and for each silo an enclosed chute detachably attachable thereto so as to receive into the chute particulate matter gravity fed out of the respective silo and convey such matter into the housing of the conveyor belt assembly. The silos, the chutes and the housing enclose the particulate matter as it passes from the silos through the chutes and conveyor belt assembly to the target location, to inhibit the release of dust generated from movement of the particulate matter from the silos to the target location.