A waste liquid treatment device (20) treats water to be treated that contains at least hydrogen peroxide, by decomposing the hydrogen peroxide. The waste liquid treatment device (20) is equipped with a housing (21), an introduction port (22) that is provided to the housing (21) and that introduces the water to be treated into the housing (21), a discharge port (23) that is provided to the housing (21) and that discharges treated water to be obtained by treating the water to be treated, and one or more channel-defining members (24) that are disposed within the housing (21) and that have a surface that a catalyst is disposed on, wherein the one or more channel-defining members (24) define, between the introduction port (22) and the discharge port (23), a channel (P) for the water to be treated, the channel (P) having a turning in at least one position.

A waste liquid treatment device (20) treats water to be treated that contains at least hydrogen peroxide, by decomposing the hydrogen peroxide. The waste liquid treatment device (20) is equipped with a housing (21), an introduction port (22) that is provided to the housing (21) and that introduces the water to be treated into the housing (21), a discharge port (23) that is provided to the housing (21) and that discharges treated water to be obtained by treating the water to be treated, and one or more channel-defining members (24) that are disposed within the housing (21) and that have a surface that a catalyst is disposed on, wherein the one or more channel-defining members (24) define, between the introduction port (22) and the discharge port (23), a channel (P) for the water to be treated, the channel (P) having a turning in at least one position.

A synthesis method of an indole derivative capable of efficiently degrading a perfluorinated compound (PFC) and a use of the indole derivative are provided. The synthesis method includes dissolving an appropriate amount of indole, alkylamine, and formaldehyde in an ethanol solution, conducting a reaction at reflux under suitable conditions for a specified period of time with ZnCl.sub.2 or glacial acetic acid as a catalyst to form a reaction product, vacuum-drying the reaction product, and purifying the reaction product through column chromatography to obtain a novel indole derivative with a hydrophobic alkyl branch. The present indole derivative has some hydrophobicity and a positively charged amino group that can effectively capture PFCs in contaminated water to produce a sub-nanoscale self-assembled aggregate. Hydrated electrons generated by light irradiation can directly attack PFCs in the aggregate without long-distance mass transfer, improving the utilization rate of hydrated electrons and reduces the ratio of fed materials.

An ion removal device includes a hard water storage section configured to store hard water; and a fine bubble generation means configured to generate fine bubbles and supply the bubbles to the hard water storage section, wherein, in the hard water storage section, metal ions in the hard water are adsorbed to the fine bubbles to be removed from the hard water.

The present invention relates to a process for the detection and adsorption of arsenic from ground water and industrial waste water using lanthanide doped nanoparticles. More particularly, the present invention provides a process for the detection and adsorption arsenic in ppm level using Eu.sub.0.05Y.sub.0.95PO.sub.4 nanoparticles.

A platform for exploiting the energy of waves operating in a marine environment and floating on the sea is disclosed. This comprises a submerged portion existing below a sea surface, an emerged portion existing above the sea surface, and a partially submerged wave power transfer mechanism portion including the sea surface and coupling the submerged portion and the emerged portion.

A platform for exploiting the energy of waves operating in a marine environment and floating on the sea is disclosed. This comprises a submerged portion existing below a sea surface, an emerged portion existing above the sea surface, and a partially submerged wave power transfer mechanism portion including the sea surface and coupling the submerged portion and the emerged portion.

In an apparatus for treating wastewater, e.g sewage water, the water passes through a standard treatment process stream to promote production of dissolved reactive phosphate ions (PO4). Iron (or aluminum) ions are generated by electrochemical means and added to the process stream at one or more locations to produce metal-P coagulant solids removed in part by pump-out, with the substantial remaining P removed by mineralization and filtration in a biological filter such as a sand filter or leach field. In another apparatus, the water passes through a standard aerobic treatment process stream to promote production of dissolved reactive phosphate ions. Iron (or aluminum) ions are generated by electrochemical means and added to the process stream at one or more locations to produce a flocculant of Fe—P minerals that are separated out by sedimentation, physical filtration or magnetic means.

A method to reduce the generation of waste water comprising the steps of withdrawing a formation water stream from production equipment; introducing the formation water stream to a forward osmosis unit, where the forward osmosis unit comprises a semipermeable membrane, where the formation water stream is introduced to a draw side of the semipermeable membrane; withdrawing a surface water feed from a waste water collection pit, the surface water feed comprises water and contaminants; introducing the surface water feed to the forward osmosis unit, where the surface water feed is introduced to a feed side of the semipermeable membrane; separating the water in the surface water feed through the semipermeable membrane, where the water travels from the feed side to the draw side due to osmotic pressure; withdrawing a diluted stream from the draw side of the semipermeable membrane; and introducing the diluted stream to a water-oil separation plant.

A method to reduce the generation of waste water comprising the steps of withdrawing a formation water stream from production equipment; introducing the formation water stream to a forward osmosis unit, where the forward osmosis unit comprises a semipermeable membrane, where the formation water stream is introduced to a draw side of the semipermeable membrane; withdrawing a surface water feed from a waste water collection pit, the surface water feed comprises water and contaminants; introducing the surface water feed to the forward osmosis unit, where the surface water feed is introduced to a feed side of the semipermeable membrane; separating the water in the surface water feed through the semipermeable membrane, where the water travels from the feed side to the draw side due to osmotic pressure; withdrawing a diluted stream from the draw side of the semipermeable membrane; and introducing the diluted stream to a water-oil separation plant.