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 mixing baffle for mixing a fluid flow includes a longitudinal support structure and a first set of moveable mixing elements integrally molded with and extending from the longitudinal support structure. The first set of moveable mixing elements are molded in a first configuration and deform to a second configuration. The first set of moveable mixing elements may deform when the mixing baffle is inserted into a conduit. A static mixer for mixing a fluid includes a conduit and the mixing baffle inserted in the conduit.

A system for continuously making-down a dry powder material is provided. The system may include a liquid supply system, a material feed system, a vessel, a filter, and an agitator. The vessel may receive a continuous supply of liquid from the liquid supply system and a continuous supply of dry powder from the material feed system. The liquid and material may be discharged continuously from the vessel. A filter may sealingly extend across the outlet to filter the solution exiting the vessel. The filter may include an upstream surface in contact with the inner volume of the vessel. The agitator may be disposed within the vessel and may be configured to agitate the contents of the vessel. The agitator may include a wiping member configured to contact the upstream surface of the filter while agitating the contents.

The invention relates to a method for producing a bone cement with a device comprising a cartridge (1) having a cylindrical interior (2), cement powder (6), and monomer liquid (7) in a monomer liquid container (8), a cartridge head (3) having a discharge opening (9), a closure (10) in the discharge opening (9), which closure is permeable to gases and impermeable to powder particles, a drive piston (5), and a central piston (4), wherein the central piston (4) is permeable to gases and the monomer liquid (7) and impermeable to the powder particles of the cement powder (6) and is arranged between the drive piston (5) and the cartridge head (3), wherein the central piston (4) separates the interior (2) into a first cavity (12) and a second cavity (14), the method comprising the following steps:

A) moving the drive piston (5) toward the cartridge head (3),
B) opening the monomer liquid container (8) via the movement of the drive piston (5) and releasing the monomer liquid (7) in the second cavity (14),
C) expelling residual gases into the surroundings of the device by means of the movement of the drive piston (5),
D) injecting the monomer liquid (7) through the central piston (4) into the cement powder (6),
E) displacing gases between the powder particles with the inflowing monomer liquid (7),
F) wetting the powder particles of the cement powder (6), and
G) depressurizing the second cavity (14), wherein the depressurization takes place by partially removing the contained monomer liquid (7).

The invention also relates to such a device for mixing a bone cement, with a depressurization device (16).

A mobile chemical mixing plant includes an inlet for receiving fluid; a fluid conduit for conveying the fluid from the inlet; a container for containing a chemical therein; a chemical pump for withdrawing the chemical from the container and directing the chemical into the fluid conduit for mixing with the fluid in the fluid conduit to form a chemical mixture; and a homogenization pump for pumping the chemical mixture in the fluid conduit out of the mobile chemical mixing plant. The fluid conduit connects the chemical pump to the homogenization pump. The mobile chemical mixing plant is fixed to a trailer that is attachable to a vehicle. Because the fluid conduit directly connects the chemical pump to the homogenization pump, the mobile chemical mixing plant does not need an intervening mixing tank for mixing the fluid and the chemical.

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 system and method for introducing a slurry mixture for making gypsum board is disclosed. The system includes, for example, a mixer, a foam injector, and a canister for mixing and moving a slurry mixture of foam and gypsum slurry. Also included in the system is an apparatus having a funnel body constructed and arranged to further mix the slurry mixture. The funnel body includes a number of baffles projecting from its inner wall towards a center and that are spaced around the inner wall. The baffles induce turbulence into the slurry mixture as the slurry mixture moves towards its outlet, thus further mixing the mixture and reducing the flow rate of the slurry mixture before its exits from the outlet for depositing onto paper to form the gypsum board.

The present disclosure relates to a stirrer for stirring a raw material such as flour or meat. Two rotating shafts are installed inside the stirrer such that stirring blades intersect with each other. The two rotating shafts are controlled to simultaneously rotate symmetrically or to rotate in the same direction, and the stirred raw material is discharged through a side surface of a stirring tank of the stirrer. The rotating shafts having the stirring blades formed thereon are connected to a driving means that can adjust the phase angle of the two shafts, via a position control device. The raw material is stirred while relative positions are adjusted such that the stirring blades formed on the two rotating shafts do not interfere with each other.

The present disclosure relates to a stirrer for stirring a raw material such as flour or meat. Two rotating shafts are installed inside the stirrer such that stirring blades intersect with each other. The two rotating shafts are controlled to simultaneously rotate symmetrically or to rotate in the same direction, and the stirred raw material is discharged through a side surface of a stirring tank of the stirrer. The rotating shafts having the stirring blades formed thereon are connected to a driving means that can adjust the phase angle of the two shafts, via a position control device. The raw material is stirred while relative positions are adjusted such that the stirring blades formed on the two rotating shafts do not interfere with each other.