A food processing apparatus including a tank having an inlet end for receiving food product and an outlet end for discharging food product, the tank having an inner wall defining a compartment and including a solid, imperforate wall portion, fluid being contained in the compartment, and a rotatable auger mounted in the compartment, the auger for advancing food product within the compartment from the inlet end toward the outlet end, the auger including flights having a flight wall with a radial edge, a clearance space being defined between the radial edge of the flights and the solid, imperforate wall portion of the inner wall. Flow of fluid through the clearance space may be inhibited. One of the inner wall and the flight wall may include a perforated wall portion. Flow of fluid between the first auger section and the second auger section may be provided through the perforated wall portion.

An apparatus for cleaning game, fruit, vegetables, fish, or crustacea in a container has a pipe and a connector connected to the pipe adjacent one end of the pipe. The pipe has a plurality of apertures formed in spaced relation to each other along a length of the pipe. The pipe is adapted to extend generally vertical within the container. The plurality of apertures are adapted to direct a flow of water in a generally cyclonic path in the container. The connector is adapted to introduce water into and through the pipe from a water hose or a conduit. A fastener is affixed to the pipe or the connector so as to removably affix the pipe to the a container. A spacer is affixed to the pipe so as to position the pipe a distance away from a wall of the container.

A roller brush bed and a fluid delivery system are provided. The fluid deliver system includes a fluid source, a fluid supply tube connected to the fluid source, a movable fluid delivery bar in fluid communication with the fluid supply tube and a drive system attached to the movable fluid delivery bar and configured to move the movable fluid delivery bar relative to the at least one roller brush and along the roller brush bed, wherein the movable fluid delivery bar is configured to spray fluid toward the at least one roller brush as the movable fluid delivery bar is moved along the roller brush bed.

A mounting assembly 100 for mounting a roller brush 12 onto a cleaning apparatus includes a mounting flange 102 and an end cap 104 interconnected together by extension springs 176 spanning therebetween. An idle shaft 106 is slidably mounted in the mounting flange 102 by a bearing interface 108. The distal end of the idle shaft 106 is fixed to the end cap 104 so that the springs 176 that urge the end cap 104 into engagement with the mounting flange 102 also bias the idle shaft to extend forwardly of the mounting flange while also permitting the idle shaft to retract to facilitate assembly and disassembly of the roller brush with the mounting assembly 100. The bearing interface 108 is designed to permit the projecting proximal end of the idle shaft to tilt upwardly to facilitate engagement with and disengagement from the roller brush 12.

A mounting assembly 10 for mounting a roller brush 12 onto an operating apparatus includes a mounting structure 14 configured to be mountable on the operating apparatus. The mounting structure has a through hole for receiving an idle shaft 16 that is sized to be engageable within a blind hole 42 formed in the adjacent end hub 32 of the brush 12. The idle shaft 16 is resiliently loaded in the direction toward the brush hub 12 by a loader assembly 18 which includes a compression spring 16 acting against retaining ring 48 engaged with the idle shaft 16.

A food processing apparatus including a tank having an inlet end for receiving food product and an outlet end for discharging food product, the tank having an inner wall defining a compartment and including a solid, imperforate wall portion, fluid being contained in the compartment, and a rotatable auger mounted in the compartment, the auger for advancing food product within the compartment from the inlet end toward the outlet end, the auger including flights having a flight wall with a radial edge, a clearance space being defined between the radial edge of the flights and the solid, imperforate wall portion of the inner wall. Flow of fluid through the clearance space may be inhibited. One of the inner wall and the flight wall may include a perforated wall portion. Flow of fluid between the first auger section and the second auger section may be provided through the perforated wall portion.

A mounting assembly 10 for mounting a roller brush 12 onto an operating apparatus includes a mounting structure 14 configured to be mountable on the operating apparatus. The mounting structure has a through hole for receiving an idle shaft 16 that is sized to be engageable within a blind hole 42 formed in the adjacent end hub 32 of the brush 12. The idle shaft 16 is resiliently loaded in the direction toward the brush hub 12 by a loader assembly 18 which includes a compression spring 16 acting against retaining ring 48 engaged with the idle shaft 16.

A mounting assembly 100 for mounting a roller brush 12 onto a cleaning apparatus includes a mounting flange 102 and an end cap 104 interconnected together by extension springs 176 spanning therebetween. An idle shaft 106 is slidably mounted in the mounting flange 102 by a bearing interface 108. The distal end of the idle shaft 106 is fixed to the end cap 104 so that the springs 176 that urge the end cap 104 into engagement with the mounting flange 102 also bias the idle shaft to extend forwardly of the mounting flange while also permitting the idle shaft to retract to facilitate assembly and disassembly of the roller brush with the mounting assembly 100. The bearing interface 108 is designed to permit the projecting proximal end of the idle shaft to tilt upwardly to facilitate engagement with and disengagement from the roller brush 12.

A mounting assembly 10 for mounting a roller brush 12 onto a cleaning apparatus includes a mounting housing 14 configured to be mountable on the cleaning apparatus. The mounting housing has a through hole for receiving an idle shaft 16 that is sized to be engageable within a blind hole 42 formed in the adjacent end hub 32 of the brush 12. The idle shaft 16 is resiliently loaded in the direction toward the brush hub 12 by a loader assembly 18 which includes a compression spring 16 acting against retaining ring 48 engaged with the idle shaft 16.

A method of subsiding foam resulting from an industrial process and moving it in a predetermined direction on the surface of an industrial-process liquid includes establishing a foam-displacement direction and a foam-displacement path. At least two fluid-spray sources from which a foam-subsiding fluid can be ejected are arranged serially above the industrial-process liquid and foam accumulating thereon. The fluid-spray sources are oriented and caused to eject foam-subsiding fluid such that foam impacted by foam-subsiding fluid ejected from the first fluid-spray source is wetted, partially subsided and displaced in the foam-displacement direction toward the spray being ejected from the second fluid-spray source by which the foam is further wetted, subsided and displaced in the foam displacement direction. In implementations including three or more fluid-spray sources, foam is moved sequentially through the sprays of the fluid-spray sources such that it is increasingly subsided as it moves through the foam-displacement path.