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.

A blending system is disclosed herein. The blending system may comprise a blender base, a container and a blending volume reducing device. The blending volume reducing device may be removably inserted into the container of the blender system at various positions. The positions may alter the working volume of the container when the blending volume reducing device is inserted in the container.

A chemical mixer tool for use in a storage drum is described. The chemical mixer tool typically comprises a mixer housing assembly in which one end of a mixer shaft is secured, the distal end of the mixer shaft having at least one collapsible impeller assembly removably attached thereon. The chemical mixer tool is configured to be removably secured to the top portion of the storage drum, with the distal end of the mixing shaft extending into the interior of the storage drum.

A chemical mixer tool for use in a storage drum is described. The chemical mixer tool typically comprises a mixer housing assembly in which one end of a mixer shaft is secured, the distal end of the mixer shaft having at least one collapsible impeller assembly removably attached thereon. The chemical mixer tool is configured to be removably secured to the top portion of the storage drum, with the distal end of the mixing shaft extending into the interior of the storage drum.

An apparatus for agitation of fluids is described that comprises an agitation chamber, an impeller configured to have a motor, a shaft, and blades, and a plurality of baffles. Further, the plurality of baffles have a predetermined shape and configuration. Further, the plurality of baffles are placed on a side wall of the agitation chamber.

An agitator or mixer installed in a solid-liquid-gas/slurry reactor in which gas removal from the slurry and foam destruction is promoted. The reaction mixer includes a vessel and an agitator assembly. The vessel is for containing the solid-liquid-gas mixture and defines two mixing zones within a given volume; a first mixing zone and a second mixing zone located above the first mixing zone. The agitator assembly is positionable within the vessel and comprises a rotatable shaft and a first and second impeller coupled to the shaft. The first axial impeller is locatable within the first mixing zone and is configured to pump the liquid in a downward direction along a vertical axis of rotation. The second impeller is locatable within the second fluxing zone and is configured to pump the liquid in an upward direction along the vertical axis of rotation.

An agitator or mixer installed in a solid-liquid-gas/slurry reactor in which gas removal from the slurry and foam destruction is promoted. The reaction mixer includes a vessel and an agitator assembly. The vessel is for containing the solid-liquid-gas mixture and defines two mixing zones within a given volume; a first mixing zone and a second mixing zone located above the first mixing zone. The agitator assembly is positionable within the vessel and comprises a rotatable shaft and a first and second impeller coupled to the shaft. The first axial impeller is locatable within the first mixing zone and is configured to pump the liquid in a downward direction along a vertical axis of rotation. The second impeller is locatable within the second fluxing zone and is configured to pump the liquid in an upward direction along the vertical axis of rotation.

A stirring device related to one example of the present invention comprises a stirring vessel including an inner chamber having a stirring space and an outer chamber surrounding the inner chamber, and having a vessel cooling space provided between the inner chamber and the outer chamber, a stirring part including a stirring rod disposed in the stirring space and provided to stir a stirring object accommodated in the stirring space, a plurality of cooling rods each protruding from the inner chamber of the stirring vessel into the stirring space, and connected to the vessel cooling space to enable fluid movement, and a cooling drive part provided to supply cooling water to the vessel cooling space.

A stirring device related to one example of the present invention comprises a stirring vessel including an inner chamber having a stirring space and an outer chamber surrounding the inner chamber, and having a vessel cooling space provided between the inner chamber and the outer chamber, a stirring part including a stirring rod disposed in the stirring space and provided to stir a stirring object accommodated in the stirring space, a plurality of cooling rods each protruding from the inner chamber of the stirring vessel into the stirring space, and connected to the vessel cooling space to enable fluid movement, and a cooling drive part provided to supply cooling water to the vessel cooling space.

A system for making resin solutions includes a washer tub having an inner wall, an outer wall aligned parallel with the inner wall and spaced apart from the inner wall by a gap, and a sloped floor disposed within the inner wall. The inner wall, the outer wall and the sloped floor form a basin including a square cross-sectional shape with four rounded corners. A fluid circulation loop is located in the gap between the inner wall and the outer wall and wraps around the inner wall more than once for controlling a temperature of the washer tub. An impeller is centrally located above the sloped floor, an electric motor rotates the impeller under control of a controller, and a user interface receives instructions for various operating cycles of the impeller.