The present invention discloses a feeding system that comprises a plurality of material tanks having air outlets, a plurality of blowers, a dust remover having an air inlet, and a connecting pipe. Air inlets of the plurality of blowers are in communication with the air outlets of the material tanks in one-to-one correspondence. The first end of the connecting pipe is in communication with the air inlet of the dust remover, and the second end of the connecting pipe is movable between being connected with the air outlet of a first one of the plurality of blowers and being connected with the air outlet of a second one of the plurality of blowers. The disclosed feeding system a simple structure and zero dust leakage. Also disclosed is a glass production apparatus that comprises the disclosed feeding system.

Systems and methods for recovering dry bulk material from a blender at a job site are provided. The systems include at least one container having in which dry bulk material can be placed and a skid-mounted vacuum unit comprising a tank having an interior space and an outlet for interfacing with the inlet of the container when the vacuum unit is positioned proximate to the container, a vacuum pump in communication with the interior space of the tank, and a conduit coupled to an inlet of the vacuum pump for interfacing with an inlet of a blender.

A dust cover for a stand mixer bowl includes a disc-shaped body defining a central aperture therethrough and extending from the central aperture to an outer extent and a rim extending from the outer extent of the disc-shaped body to define an interior portion of the dust cover with the disc-shaped body. The interior portion of the dust cover is configured to removably receive an upper portion of a mixing bowl with the disc-shaped body extending inwardly from a lip of the mixing bowl positioned adjacent the outer extent of the disc-shaped body over at least a portion of an interior of the mixing bowl. The central aperture is configured for a portion of a planetary hub of a stand mixer to extend therethrough with an outer surface of the portion of the planetary hub adjacent an inner edge of the central aperture.

The present invention is a dust shield device that secures over a mixing pail. Powdery material, such as plaster, cement, grout or the like, is poured through the device, and mixed with water inside the pail. The device includes a mounting sleeve, a radial manifold housing and a funnel shaped lid. The manifold housing and lid form a radial pneumatic channel with a circumferentially disbursed air intake that generates a radially uniform airflow that draws in airborne dust that would otherwise escape to the surrounding air. The manifold is connected to a vacuum with an air filter, and generates a dust shield zone and air intake zone above the device. The manifold lid forms a radial guard to prevent downward flows of material and water from entering the manifold, and forms a splash guard to retain upwardly projected splashes of material and water inside the pail.

Controlling the dust emissions from the discharge of bulk materials from a container provides many benefits. A support structure may include a plurality of outlets or chutes for discharging the bulk material. A dust control damper coupled to the outlets not currently in use for the discharge of bulk material may prevent dust from escaping into the surrounding air. The dust control dampers may automatically transition between a closed position and an open position. A flexibly collapsible shroud may also be coupled to a discharge gate of a container. The shroud may expand to seal against the outlet when bulk material is discharge. A vacuum system at or near an outlet may reclaim any dust that escapes during discharge of the bulk material.

An apparatus for preventing proliferation of dust during mixing of material, including a semi-dome shaped element configured for placement over a top opening of a mixing container, a fastener extending along a bottom circumference of the semi-dome shaped element, such that the fastener is configured to couple to the top brim of the mixing container, and an opening in the semi-dome shaped element, the opening configured to accept a vacuum hose.

A flange member for sealing a mouth extending from a reservoir, includes an annular body for receiving and connecting with the mouth of the reservoir, and a membrane coupled to a flange surface defined at a distal end of the annular body.

A connector including a body defining a flange and cutting element sliding between a first position within the body and a second position external of the flange.

A solids charging containment apparatus and method for mixing a solvent with a dry powder, comprising a dual compartment isolator for safely removing the dry powder from a dry powder container, a mixing vessel, and a negative cascading pressure controller. The dual compartment isolator comprises a staging compartment, a charging compartment and a raw material entry port, which is connected to the staging compartment and configured to isolate the dry powder container from the surrounding atmosphere. The mixing vessel includes a mixing chamber and a solids charging port fluidly connecting the mixing chamber to a containment valve in the charging compartment of the dual compartment isolator. The negative cascading pressure controller generates negative pressure in both the staging compartment and the charging compartment. The containment apparatus and method may be used to produce a slurry or solution mixture of solvent and dry powder during drug processing.

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.