Blending apparatuses and related methods and computer program products are disclosed. In an aspect, blending apparatuses and related methods and computer program products of the present disclosure may include at least one energy source associated with the blending apparatuses such that at least one energy source may be used to provide at least one portion of the energy required for a given blending apparatus to function, thereby reducing or eliminating need for a separate energy source to power the blending apparatus, which reduces the overall spatial footprint required by the blending apparatus and other device(s) associated therewith. Energy generated by the at least one energy source may also be used to power one or more additional devices. Blending apparatuses of the present disclosure may additionally comprise at least one control station that allows one or more users to monitor, adjust, control, interact with the blending apparatuses, thereby increasing efficiency.

A mixer and a mixing unit for mixing and handling industrial side-stream materials. The mixer (6) is arranged onto a movable work machine (5) and it is used for mixing at least two side-stream materials to form a geopolymer. The mixer (6) comprises: a bucket part (27) for loading and transferring the side-stream material; a mixer apparatus (26) for mixing the side-stream material which has been loaded into the space delimited by the bucket part (27); a connecting device (25) for connecting the mixer (6) to a boom of a work machine (5); and at least one measuring device (S1, S2, S3) for determining properties of the material in the mixer (6).

An arrangement and a method for mixing and handling industrial side-stream materials. The mixer (6) is arranged onto a movable work machine (5) and it is used for mixing at least two side-stream materials to form a geopolymer. The side-stream materials are processed between a waste pile (4) and a casting area (13) in the mixer (6). Cast paste is allowed to harden and after that it is crushed to obtain an earthwork material.

A cleaning system for washing an internal surface of a container located on a vehicle, the cleaning system comprising an elongate boom with at least one nozzle located at a first end of the boom, a support assembly for supporting the boom, wherein the boom is movable with respect to the support assembly, a controller configured to control movement of the boom, and a vehicle identification system comprising an identification reader configured to identify the vehicle and communicate with the controller, wherein one or more parameters of the vehicle can be stored on or retrieved from the vehicle identification system upon identifying the vehicle, and wherein the boom is configured to extend into the container to wash the internal surface based on the one or more parameters.

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.

Provided is a discharge apparatus using an aerosol container, including a holding container for holding contents, a pressurizing unit configured to inject a filling material within the holding container by the aerosol container to pressurize the holding container, and a discharge unit configured to discharge the contents to the outside of the holding container. An unmanned aerial vehicle including the above-described discharge apparatus is also provided. A discharge method using an aerosol container, comprising: holding contents of a holding container; injecting a filling material within the holding container by the aerosol container to pressurize the holding container; and discharging the contents to the outside of the holding container is also provided.

A concrete mixing machine for indoor preparation of fluid concrete for disposition as flooring. The concrete mixing machine includes a mixer tank capable of mixing of twenty-three bags of concrete concurrently. Mixing propellers inside of the mixer tank attach to a shaft, whereby a hydraulic propeller drive motor rotationally moves the shaft, and the mixing propellers mix the concrete. The concrete mixing machine produces a large batch of concrete, and the concrete mixing machine moves and deposits the concrete for application using a flow control mechanism with a flow control mixer attached to the mixer tank that regulates concrete flow through a valve and chute and synchronizes with a flow control drive-wheel. The concrete mixing machine is hydraulically operated and self-propelled. The concrete mixing machine does not emit gases harmful to indoor air quality and thus is environmentally friendly.

The present disclosure includes embodiments of a recirculation system and methods for mitigating release of silica dust at a hydrocarbon well site. The embodiments of the recirculation system may include a blender hopper, one or more proppant silos, a footed hood, a conveyor, one or more amplifiers, one or more compressed air sources, one or more vacuum hoses, an augur, and a blender. In one or more embodiments, the methods of recirculating silica dust to mitigate the release of silica dust includes conveying sand proppant on a conveyor from the one or more proppant silos to a blender hopper, directing sand proppant from the conveyor into the blender hopper, supplying compressed air to one or more amplifiers, directing sand proppant from the blender hopper to a blender via an augur, and adjusting the extent of at least one of the two or more leg segments and the leg adjustment arrangement.

A proppant metering and loading apparatus for a hydraulic fracturing blender unit is provided. A continuous loop conveyor belt receives proppant from a source location on the blender, such as a hopper, and delivers the proppant to a blender device of the blender. A measurement device (e.g. weigh scale) measures and provides an indication of amount (e.g. weight, volume and/or density) of the proppant delivered to the blender device by the conveyor belt.

A dual chamber assembly for continuously injecting slurry into a wellhead by displacing it from chambers with pressurized clean fluid.