A device for removing microplastics from water. The device has a tank containing water and an oil layer floating on the water. The tank has an inlet for making a mixture of microplastics and water and an outlet for draining clean water. The device has a provision for causing the mixture of microplastics in water to flow through the oil layer wherein microplastics are trapped and clean water flows through the oil layer.

A process is disclosed for treating water, such as wastewater, with air or oxygen-enriched air under alkaline conditions to decompose and remove acrolein and acrolein byproducts from the water and/or wastewater. The process is able to lower the concentration of acrolein and acrolein byproducts from water to a sufficiently low level suitable for discharge to a municipal sewer collection system with reduced occurrence of the decomposition by-products of acrolein converting back to acrolein in the water. One embodiment of the process treats contaminated water containing acrolein with air or oxygen-enriched air by sparging or bubbling air or oxygen-enriched air through the contaminated water. The contaminated water can be treated with air or oxygen-enriched air where the contaminated water is initially adjusted to a pH greater than 7.0 for a time to convert at least a portion of the acrolein to 3-hydroxypropanal to obtain fully treated water and prevent conversion of 3-hydroxypropanal back to acrolein.

A composition for use in remediation of soil and groundwater containing hydrocarbons and halogenated compounds. The remediation composition includes: (a) a first bioremediation material including a first blend of organisms capable of degrading the hydrocarbons; (b) a second bioremediation material including a second blend of organisms differing from the first blend of organisms that is chosen for degrading the halogenated compounds; (c) an organic compound such as a complex carbohydrate (e.g., food grade starch); and (d) a third blend of organisms capable of degrading the organic compound. The degrading of the organic compound by the third blend of organisms breaks the complex carbohydrate into smaller molecules that are utilized by the microorganisms of at least one of the first and second bioremediation materials during the degrading of the hydrocarbons and the halogenated compounds. The first bioremediation composition typically includes activated carbon capable of adsorbing the hydrocarbons and the halogenated compounds.

The present disclosure relates generally to a method comprising: providing an aqueous medium comprising at least one of microplastics and nanoplastics; combining an agglomerizer and the aqueous medium, wherein the agglomerizer has at least one C.sub.8-C.sub.32 hydrocarbon group; mixing the agglomerizer and aqueous medium to form at least one agglomerate of the at least one microplastics and nanoplastics having a d.sub.50 particle size in the range of 1 to 100 mm; and separating the at least one agglomerate from the aqueous medium. The present disclosure also generally relates to a method comprising: providing an aqueous medium comprising at least one of microplastics and macroplastics; adding a solubilizer to the aqueous medium, wherein the solubilizer has at least one C.sub.6-C.sub.32 hydrocarbon group; and mixing the solubilizer and the aqueous medium to form a suspension of plastic particles, wherein the plastic particles in the suspension of plastic particles have a d.sub.50 particle size in the range of 10 nm to 10 μm.

The present invention relates to a method of treating aqueous fluid and apparatus therefor. The method comprises adding an organic compound to a mass of aqueous fluid comprising at least one Kinetic Hydrate Inhibitor (KHI). The organic compound comprises a hydrophobic tail and a hydrophilic head. The hydrophobic tail comprises at least one C—H bond and the hydrophilic head comprises at least one of: a hydroxyl (—OH) group; and a carboxyl (—COOH) group.

The present invention discloses an electrocatalytic Fenton oxidation-electrochemical oxidation coupling process and apparatus for efficient treatment of chemical wastewater, and belongs to the field of sewage treatment. The process includes an electrocatalytic Fenton oxidation step, an electrochemical oxidation step, and a pH adjustment step. A spacing between a cathode and an anode in the electrocatalytic Fenton oxidation step is controlled, so that oxygen produced at the anode reacts at the cathode to produce H.sub.2O.sub.2. The treatment requirements can be met without external aeration or external addition of H.sub.2O.sub.2, and meanwhile, the efficiency of COD removal by electro-Fenton oxidation is effectively improved. Further, by connecting a pH adjusting tank with the electrocatalytic Fenton oxidation-electrochemical oxidation coupling apparatus in series, a coupling treatment process with near-zero production of iron sludge is realized

A process for decontaminating a contaminated aqueous liquid comprising methyl-tert-butyl ether (MTBE) involving pretreating the contaminated aqueous liquid with chlorine and/or a hypochlorous acid salt and irradiating the aqueous liquid with an ultraviolet wavelength to produce a radical molecular species that degrades the MTBE. MTBE is degraded into at least one degradation byproduct including tert-butyl formate (TBF), tert-butyl alcohol (TBA), acetone, carbon dioxide, and water.

Method for isolating carboxylic acid from an aqueous metal carboxylate-containing side stream of an organic peroxide production process, involving the protonation of the carboxylate, separation of liquid and organic phases, and the removal of residual peroxides.

The present invention relates to a saturator. The present invention further relates to a method for reusing a waste water stream from a Fischer-Tropsch reactor. The invention further relates to system for recycling waste water from a Fischer-Tropsch reactor preferably within a gas-to-liquids (GTL) plant.

The present disclosure provides compositions and methods for treating volatile fatty acids and bacteria capable of producing volatile fatty acids. The compositions can convert acid-producing bacteria environments to nitrate-reducing bacteria environments. The compositions and methods can lower the amount of acid-producing bacteria present in the environment and thereby reduce the amount of volatile fatty acids present in the environment. The control agent may also inhibit the growth of acid-producing bacteria and volatile fatty acid concentrations. The compositions and methods can be used with any aqueous industrial system.