The present disclosure provides a sedimentation tank capable of automatically adjusting liquid level and flow, which comprises one or more sedimentation cells which are connected in sequence, a water inlet pipe is arranged on the left side of the leftmost sedimentation cell; the front end of the water inlet pipe is bent and the input port of it is close to the wall; the highest point of the connecting pipe is lower than the highest point of the grease discharge port of the corresponding sedimentation cell, when the liquid level in the sedimentation cell reaches the discharge level of the connecting pipe, the connecting pipe automatically adjusts the flow according to different discharge level so as to adjust the liquid level of the sedimentation cell, and the settled sewage is discharged out of the tank or discharged into the next-stage sedimentation cell until the last stage, and finally discharged. The sedimentation tank has a compact and attractive structure and high space utilization, and different connecting pipe structures can be selected specifically, so as to change the capacity of adjusting the liquid level and flow of the sedimentation tank, and the sewage separation effect is thorough.

A modular system for reducing the total suspended solids of waste, including scum, sludge and water layers, includes a plurality of chambers each being connected in succession by a corresponding one of a plurality of flow pipe segments including an inlet segment, an outlet segment and at least one middle segment, wherein the waste enters the septic tank via the inlet segment and is transferred between each of the plurality of chambers via the at least one middle segment; a corrugated flow pipe in fluid flow communication with the outlet segment; and the corrugated flow pipe being sized and configured for use as a settling zone for removal of a portion of the total suspended solids and wherein an amount of water from the water layer within the chamber adjacent the outlet segment enters the corrugated flow pipe and passes through the outlet segment.

An example flush station includes an upper cabinet and a lower cabinet. At least one cleaning head is mounted in the upper cabinet, and has an anchoring attachment, a cleaning solution inlet to dispense cleaning solution, and a compressed air inlet to dispense compressed air. A vacuum system may be provided in the upper cabinet to entrain airborne particulates. A catch basin formed in the lower cabinet receives spent cleaning solution from the upper cabinet. At least one settling tank in the lower cabinet receives spent cleaning solution from the catch basin for settling at least some suspended particulate matter in the spent cleaning solution. A grate at an interface between the upper section and the lower cabinet provides a cleaning deck for filters and/or other components to be cleaned during the cleaning operation. During the cleaning operation, cleaning solution and/or compressed air are dispensed through the filters and/or other components.

The present invention discloses an improved multiple filtration cartridge assembly comprising filter cartridges with internal riser tubes mounted on a collection rail via rail couplers. Within this configuration, at least one internal riser tube contains a drain down orifice which corresponds to a matching drain down orifice on the rail coupler. The disclosed assembly increases the lifespan of the filter cartridges. Further, the multiple filtration cartridge assembly may be configured as a filtration mechanism within a variety of Structural Best Practice Management water filtration systems.

Disclosed herein is a device for improving water quality, said device comprising: an inlet for inflow of liquid into the device; a hydraulic circuit for receiving liquid from the inlet, the hydraulic circuit comprising at least a first tank and a second tank, wherein the first tank is upstream of the second tank and wherein one of said first and second tanks is nested within the other of said first and second tanks; an outlet at a downstream end of the hydraulic circuit for discharge of liquid from the device; one or more contaminant separation elements in the hydraulic circuit for separation of contaminants from liquid passing therethrough using at least one of: gravitational separation; sized-based filtration; chemical separation; magnetic separation; electrolytic separation; and adsorption or attraction-based separation, wherein the first tank is a settlement tank for gravitational settlement of contaminants from the liquid.

Provided is a cutting fluid tank for a machine tool, which is capable of sufficiently collecting and removing sludge mixed in a cutting fluid even when a chip conveyor or the like is disposed in a tank main body, and with which a location where sludge remains accumulating on a bottom of the tank main body is less likely to occur even when an operation is restarted after being suspended. A cutting fluid tank includes: a tank main body; a first circulation pump; a sludge transfer nozzle configured to eject the sludge-containing cutting fluid pumped out by the first circulation pump, toward a sludge collection pump; a second circulation; and first agitation nozzles configured to eject the sludge-containing cutting fluid that is pumped out by the second circulation pump, toward predetermined points in the tank main body.

A suspension flow-through separation apparatus includes a flow-through separator including a flow-through separation unit. The flow-through separation unit includes a cavity structure that functions as a channel through which a suspension flows, a side surface portion which extends in an x-direction of the cavity structure, a supply port which is provided at one side surface portion, an outlet port which is provided at the other side surface portion, two planar portions that extend in a y-direction in the cavity structure and face to each other, and an ultrasonic oscillator that is provided at least one of two planar portions, and emits ultrasonic waves to the channel. The suspended matter in the suspension is captured by the ultrasonic waves and separated in a z-direction that is a vertical direction while the suspension flows through the channel of the flow-through separator.

A separator system includes a separator including an inlet configured to receive a mixed fluid, a first outlet, and a second outlet. The separator system includes a pressure tank physically coupled to the separator, and including a partition wall defining a collection chamber and a separation chamber in the pressure tank, a first inlet communicating with the collection chamber and coupled to the separator to receive at least some of the solids component from the separator, and a second inlet communicating with the separation chamber and in communication with the separator. The second inlet is configured to receive at least some of the liquid component and the gaseous component from the separator. The pressure tank also includes a first drain in communication with the collection chamber, and a first liquid outlet in communication with the separation chamber. The pressure tank includes a gas outlet in communication with the separation chamber.

A separation apparatus that includes a weir tank having a plurality of cells and fluid removal apparatus for each cell to remove the fluid from each cell. The fluid removal apparatus includes an actuator and an extension arm whose movement is caused by the actuator. In addition to the actuator and the extension arm, the fluid removal apparatus includes a plunger attached to the extension arm for selectively engaging a first opening in each cell. Furthermore, a method of removing fluid from the separation apparatus via the fluid removal apparatus.

A filter controller which comprises a manifold and at least one filter assembly. The manifold comprises a plurality of portholes and channels into and through which a fluid, such as, e.g., a fuel, may flow. The filter assembly comprises an upper filter subassembly and a lower filter subassembly. The filter assembly can be fitted directly onto the manifold without the use of pipes and fittings and such that the filter assembly is in fluid communication with the portholes and channels necessary for effective filtering, polishing, and flow of the fluid through the system and through the assembly into which the system is integrated.