The present invention relates to a method of producing an iron containing compound, iron containing precursor, or iron containing aqueous solution comprising the steps of: providing direct reduced iron; dissolving the direct reduced iron in organic and/or inorganic acids to provide an iron containing aqueous solution, wherein insoluble impurities of the direct reduced iron are maintained in solid form throughout the dissolution process, to obtain an iron containing aqueous solution with suspended insoluble impurities; separating the said insoluble impurities from the iron containing aqueous solution obtaining a purified iron containing aqueous solution; and optionally solidifying said purified iron containing aqueous solution to provide the iron containing compound or iron containing precursor, by drying. The present invention further relates to iron containing compounds, iron containing precursors, and iron containing aqueous solutions, and their use in battery components.

The present disclosure provides for devices, systems, and methods of separating PFAS compounds from wastewater leachate. After separation, the PFAS compounds can be rendered less harmful. The present disclosure provides for devices, systems, and methods that uses aeration-induced foaming to isolate PFAS from landfill leachate into a concentrated, volume reduced liquid (coalesced foam), which can be separated and treated.

A drainage device is provided. The device includes a novel floating surface drain or skimmer to manage draining of liquid, such as draining of water from stormwater impoundment ponds or structures.

The present disclosure relates generally to systems, apparatuses, and processes for preparing a gas-infused additive that is useful within gas-floatation systems configured to separate solids and/or oils from a liquid within a suspension. The gas-infused additive can be injected into systems having a floatation consolidator to provide additional dissolved gas to the system. Advantageously, the processes and apparatuses disclosed herein are compatible with systems and processes having a single injection point for the addition of an additive or gas, without requiring substantial modification or reconfiguration of the system. The inventions described herein additionally teach that the gas-infused additive can be prepared and injected downstream of any pump present within the system, thereby protecting the pump from the damaging effects of cavitation corrosion and similar phenomena.

The present invention relates to the field of dihydromyricetin extraction and purification, and in particular to a dihydromyricetin extraction and purification process. Technical problem: the dihydromyricetin extraction and purification process aims to resolve the technical problems of increased cost of subsequent impurity removing and safety risks in high-temperature centrifugation in the prior art. Technical solution: a dihydromyricetin extraction and purification process: step 1: weighing a raw material, adding an extraction solvent in an amount 5 times that of the raw material to perform reflux extraction, concentrating the filtrate to an extract, and recovering acetone; step 2: resting for crystallization for 24 hours; step 3: performing suction filtration to obtain light-green sediment underneath, and dry the sediment; step 4: adding 5%-10% activated carbon for decolorization and impurity removing; step 5: performing suction filtration; step 6: drying to obtain white powder of dihydromyricetin; and step 7: detecting a content with HPLC.

The present disclosure provides for devices, systems, and methods of separating PFAS compounds from wastewater leachate. After separation, the PFAS compounds can be rendered less harmful. The present disclosure provides for devices, systems, and methods that uses aeration-induced foaming to isolate PFAS from landfill leachate into a concentrated, volume reduced liquid (coalesced foam), which can be separated and treated.

A two-step process for recovering useable solids from food processing wastewater and for significantly reducing the pollutants, chemical, bacterial, and viral load. The first step is the addition of pretreatment chemicals such as metal-based coagulant, pH adjuster, oxidant or a combination thereof. The second step is pumping the chemically pretreated wastewater into a foam fractionation system where a gas is introduced into the chemically treated wastewater to create a rising foam that captures and remove solid materials from the remaining wastewater effluent. The solids are recovered for additional post-processing and the effluent is discharged for post-processing or to existing bodies of water.

The present invention relates to the field of dihydromyricetin extraction and purification, and in particular to a dihydromyricetin extraction and purification process. Technical problem: the dihydromyricetin extraction and purification process aims to resolve the technical problems of increased cost of subsequent impurity removing and safety risks in high-temperature centrifugation in the prior art. Technical solution: a dihydromyricetin extraction and purification process: step 1: weighing a raw material, adding an extraction solvent in an amount 5 times that of the raw material to perform reflux extraction, concentrating the filtrate to an extract, and recovering acetone; step 2: resting for crystallization for 24 hours; step 3: performing suction filtration to obtain light-green sediment underneath, and dry the sediment; step 4: adding 5%-10% activated carbon for decolorization and impurity removing; step 5: performing suction filtration; step 6: drying to obtain white powder of dihydromyricetin; and step 7: detecting a content with HPLC.