Provided is a method and system for separating components of a solid and liquid mixture. In an embodiment, the method includes de-sanding a treatment system. Digesters, clarifiers, wastewater apparatuses, self-contained processing tanks, process tanks, and the like, accumulate sand and other undesired inorganic components that ultimately prevent filtering, cleaning, and processing of the solid and liquid mixtures therein. The mixture in the treatment system may initially include sand, water, and biosolids. The mixture may be routed into a pressurized tank to separate the inorganic solids and liquid components based on their density and buoyancy. A de-sanded mixture may then proceed through the remaining cleaning process.

A method and system are provided for clarifying water by passing water through one or more reactor canisters having a flow-through cartridge containing a composition for flocculating or settling solids suspended in the water. After passing through the reactor canisters, the water flows into a primary settling tank to allow solids to precipitate therefrom. The water then flows over a weir into a secondary settling tank to allow further precipitation of suspended solids remaining in the water. The water can then pass through tubular settling media to aid in further precipitation of solids therefrom, and then flow into an outlet chamber where the now clarified water can be withdrawn.

A coolant processing apparatus removes sludge from a coolant discharged from a machine tool. The coolant processing apparatus includes a first reservoir and a second reservoir provided in a tank for retaining the coolant. The first reservoir includes a flow path in which the discharged coolant flows, and a portion downstream of the flow path to retain the coolant such that the sludge remains in the first reservoir. The flow path has at least one bend to bend a flow of the coolant at least once in a horizontal direction. The second reservoir retains the coolant flowing out from the first reservoir. A boundary wall is provided between the first and second reservoirs, at a location downstream of the at least one bend of the flow path, and has such a height that allows a supernatant of the coolant in the first reservoir to flow into the second reservoir.

A sand separation system includes a separator configured to separate a multi-phase process fluid into a solids and a fluid. The system also includes a blowdown vessel coupled to the separator. The blowdown vessel is configured to receive the solids and a portion of the fluid from the separator. The system also includes a fluid removal assembly coupled to the blowdown vessel. The fluid removal assembly is configured to drain at least some of the fluid in the blowdown vessel therefrom, substantially without removing the solids from the blowdown vessel.

A sand separation system and method, of which the sand separation system includes a separator configured to separate a multi-phase process fluid into a solids and a fluid, a blowdown vessel coupled to the separator, wherein the blowdown vessel is configured to receive the solids and a portion of the fluid from the separator, and a fluid removal assembly coupled to the blowdown vessel. The fluid removal assembly is configured to drain at least some of the fluid in the blowdown vessel therefrom, substantially without removing the solids from the blowdown vessel.

A mobile wastewater treatment system wherein a mobile carrier has mounted thereon a wastewater treatment plant. The wastewater treatment plant has a flow equalization tank, an aeration tank, a clarifying tank, a disinfection stage, and a pumping tank. The mobile carrier can be a trailer, a skid, a shipping container, or the like.

A coolant processing apparatus removes sludge from a coolant discharged from a machine tool. The coolant processing apparatus includes a first reservoir and a second reservoir provided in a tank for retaining the coolant. The first reservoir includes a flow path in which the discharged coolant flows, and a portion downstream of the flow path to retain the coolant such that the sludge remains in the first reservoir. The flow path has at least one bend to bend a flow of the coolant at least once in a horizontal direction. The second reservoir retains the coolant flowing out from the first reservoir. A boundary wall is provided between the first and second reservoirs, at a location downstream of the at least one bend of the flow path, and has such a height that allows a supernatant of the coolant in the first reservoir to flow into the second reservoir.

Techniques for recovering a hydrocarbon fluid from a waste fluid include transmitting a plurality of wave energy pulses through a waste fluid, the waste fluid including a mixture of a hydrocarbon fluid and a non-hydrocarbon fluid; receiving a plurality of reflected wave energy pulses transmitted through the waste fluid; determining a level difference between a surface of a hydrocarbon fluid layer that includes the hydrocarbon fluid and a surface of a non-hydrocarbon fluid layer that includes a non-hydrocarbon fluid based, at least in part, on the plurality of reflected wave energy pulses; and operating a hydrocarbon fluid pumping assembly, based on the determined level difference, to circulate a portion of the hydrocarbon fluid in the hydrocarbon fluid layer from the waste fluid.

Techniques for recovering a hydrocarbon fluid from a waste fluid include transmitting a plurality of wave energy pulses through a waste fluid, the waste fluid including a mixture of a hydrocarbon fluid and a non-hydrocarbon fluid; receiving a plurality of reflected wave energy pulses transmitted through the waste fluid; determining a level difference between a surface of a hydrocarbon fluid layer that includes the hydrocarbon fluid and a surface of a non-hydrocarbon fluid layer that includes a non-hydrocarbon fluid based, at least in part, on the plurality of reflected wave energy pulses; and operating a hydrocarbon fluid pumping assembly, based on the determined level difference, to circulate a portion of the hydrocarbon fluid in the hydrocarbon fluid layer from the waste fluid.

A neutralization/water separation device for an esterified product including: a neutralization tank in which a crude product mixture containing alcohol and an ester compound, a neutralizing agent, and water are put to produce a neutralized mixture; a water separation tank disposed below the neutralization tank to divide the neutralization mixture into a floating layer and an aqueous layer; a partition wall extending downward from a ceiling of the water separation tank to provide a lower passage in the water separation tank; and a transfer line that transfers the neutralized mixture from the neutralization tank to the water separation tank, where the water separation tank includes: a first water separation part into which the neutralized mixture is introduced from the neutralization tank through the transfer line; and a second water separation part into which the neutralized mixture is introduced from the first water separation part through the lower passage, where the first water separation part and the second water separation part are partitioned by the partition wall.