A print agent filtration apparatus is disclosed. The filtration apparatus is to remove non-liquid contaminant from liquid carrier. The apparatus comprises an electrode having a first surface, wherein the electrode is to generate an electric field towards liquid carrier containing non-liquid contaminant. The apparatus further comprises a second surface to accumulate non-liquid contaminant removed from the liquid carrier, the second surface being formed at least in part from a ceramic and movable relative to the first surface. A gap between the first surface and the second surface is substantially constant over the extent of the first surface. The first surface and the second surface define a passage therebetween through which the liquid carrier may pass. An electric field formed between the first surface and the second surface is to act on the liquid carrier, to thereby cause non-liquid contaminant to adhere to the second surface. A method and a print apparatus are also disclosed.

An apparatus for the separation of dry matter and liquid from a medium includes: a plurality of press rollers and at least one pore roller, at least one separation chamber for receiving the medium, and at least one filtrate chamber defined in cross section by press rollers and the at least one pore roller. The apparatus is configured for establishing a relative negative pressure inside the pore roller interior, such that liquid in the medium is sucked into the pore roller interior, and for roller rotation such that during separation operation dry matter of the medium initially passes between the pore roller and a press roller when transferring from the separation chamber to the filtrate chamber, and subsequently passes between two press rollers, when exiting from the filtrate chamber.

An apparatus for the separation of dry matter and liquid from a medium includes: a plurality of press rollers and at least one pore roller, at least one separation chamber for receiving the medium, and at least one filtrate chamber defined in cross section by press rollers and the at least one pore roller. The apparatus is configured for establishing a relative negative pressure inside the pore roller interior, such that liquid in the medium is sucked into the pore roller interior, and for roller rotation such that during separation operation dry matter of the medium initially passes between the pore roller and a press roller when transferring from the separation chamber to the filtrate chamber, and subsequently passes between two press rollers, when exiting from the filtrate chamber.

A filter unit (10) for separation of particulate matter from particulate-laden liquid, the filter unit comprising: a chamber (12) defined by an upper axial end wall (14) and an opposing lower axial end wall (16) and a peripheral particle collection wall (18), the upper and lower axial end walls being spaced by the peripheral particle collection wall, the chamber being rotatable about an axis of rotation (30) so as to impart rotational motion to the liquid; an inlet (23) for delivering particulate-laden liquid into the chamber (12); an outlet (24) in the upper or lower axial end wall for discharging filtered liquid from the chamber; a flow path (22) from the inlet to the outlet; wherein the flow path includes a radial component from the inlet to the peripheral particle collection wall and an axial component along the peripheral particle collection wall.

A filter unit (10) for separation of particulate matter from particulate-laden liquid, the filter unit comprising: a chamber (12) defined by an upper axial end wall (14) and an opposing lower axial end wall (16) and a peripheral particle collection wall (18), the upper and lower axial end walls being spaced by the peripheral particle collection wall, the chamber being rotatable about an axis of rotation (30) so as to impart rotational motion to the liquid; an inlet (23) for delivering particulate-laden liquid into the chamber (12); an outlet (24) in the upper or lower axial end wall for discharging filtered liquid from the chamber; a flow path (22) from the inlet to the outlet; wherein the flow path includes a radial component from the inlet to the peripheral particle collection wall and an axial component along the peripheral particle collection wall.

A dip tank and recycling system for applying antimicrobial solution to food items, including a dip tank having a bottom and sides, and holding a liquid antimicrobial solution. A conveyor to convey food items through the tank passes through the liquid antimicrobial solution held in the tank such that food items conveyed on the conveyor are dipped in the liquid antimicrobial solution. At least two discharge nozzles spray fresh antimicrobial solution into the tank. The discharge nozzles are located in the sides of the tank, and are positioned above the level of the conveyor but below an expected top level of the liquid antimicrobial solution contained within the tank such that food items conveyed on the conveyor are agitated by the force of the spray from the discharge nozzles. The spray from the discharge nozzles causes unstacking of items on the conveyor, producing an even application of the antimicrobial solution.

A dip tank and recycling system for applying antimicrobial solution to food items, including a dip tank having a bottom and sides, and holding a liquid antimicrobial solution. A conveyor to convey food items through the tank passes through the liquid antimicrobial solution held in the tank such that food items conveyed on the conveyor are dipped in the liquid antimicrobial solution. At least two discharge nozzles spray fresh antimicrobial solution into the tank. The discharge nozzles are located in the sides of the tank, and are positioned above the level of the conveyor but below an expected top level of the liquid antimicrobial solution contained within the tank such that food items conveyed on the conveyor are agitated by the force of the spray from the discharge nozzles. The spray from the discharge nozzles causes unstacking of items on the conveyor, producing an even application of the antimicrobial solution.

A dip tank and recycling system for applying antimicrobial solution to food items, including a dip tank having a bottom and sides, and holding a liquid antimicrobial solution. A conveyor to convey food items through the tank passes through the liquid antimicrobial solution held in the tank such that food items conveyed on the conveyor are dipped in the liquid antimicrobial solution. At least two discharge nozzles spray fresh antimicrobial solution into the tank. The discharge nozzles are located in the sides of the tank, and are positioned above the level of the conveyor but below an expected top level of the liquid antimicrobial solution contained within the tank such that food items conveyed on the conveyor are agitated by the force of the spray from the discharge nozzles. The spray from the discharge nozzles causes unstacking of items on the conveyor, producing an even application of the antimicrobial solution.

A dip tank and recycling system for applying antimicrobial solution to food items, including a dip tank having a bottom and sides, and holding a liquid antimicrobial solution. A conveyor to convey food items through the tank passes through the liquid antimicrobial solution held in the tank such that food items conveyed on the conveyor are dipped in the liquid antimicrobial solution. At least two discharge nozzles spray fresh antimicrobial solution into the tank. The discharge nozzles are located in the sides of the tank, and are positioned above the level of the conveyor but below an expected top level of the liquid antimicrobial solution contained within the tank such that food items conveyed on the conveyor are agitated by the force of the spray from the discharge nozzles. The spray from the discharge nozzles causes unstacking of items on the conveyor, producing an even application of the antimicrobial solution.

The invention includes an automatic effluent filter cleaning system that prevents sewage backups. The system includes an outlet baffle with filter, spray assembly, inlet and outlet flappers, pump, and strainers. The spray assembly actuates the baffles to control effluent flow prior, during, and after the cleaning process. During a high-water level condition, the pump engages and pumps effluent water from the septic tank to close the inlet flapper to prevent additional effluent water from entering the outlet baffle. Similarly, effluent water is pumped to close the outlet flapper to prevent effluent water from leaving the baffle. Spray outlets spray effluent water to remove debris from the filter. An outer chamber receives and channels the debris to strainers, which retain the removed debris while allowing the effluent water to return to the septic tank. Once the water level recedes to a safe level, the flappers are opened, and operation resumes.