A method comprising a) mixing and dissolving the solid hazardous heavy metal-containing composition with an acid solution; b) precipitating the heavy metal from the hazardous heavy metal acid composition; c) precipitating the heavy metal from the hazardous heavy metal acid composition with a heavy metal-precipitation agent; and d) separating out the heavy metal precipitate from the aqueous supernatant, whereby the heavy metal-precipitation agent comprises a diorgano-dithiophosphinic acid or the alkali metal or ammonia salts thereof.

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A method comprising a) mixing and dissolving the solid hazardous heavy metal-containing composition with an acid solution; b) precipitating the heavy metal from the hazardous heavy metal acid composition; c) precipitating the heavy metal from the hazardous heavy metal acid composition with a heavy metal-precipitation agent; and d) separating out the heavy metal precipitate from the aqueous supernatant, whereby the heavy metal-precipitation agent comprises a diorgano-dithiophosphinic acid or the alkali metal or ammonia salts thereof.

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The present invention relates generally to composite products, in particular glass-based composite products, and the manufacture thereof.

The present disclosure describes a unique, two-part, water-soluble polymer matrix material and a method of application that immobilizes a wide variety of loose powder or crystalline hazardous materials and renders them “safe” or at least “safer” for handling and transport. The polymer matrix material is a two-part polymer material comprising a liquid cross-linking polymer and a cross-linking agent, initiator, or biocide contained in a solution. The cross-linking agent functions to cross-link the polymer and cause it to harden in place.

The use of bacteria-based binders to bind and strengthen 3D printed compositions; bio-plastic 3D printing materials comprised of combinations of particles of organic substrates such as coffee, pistachio shells and coconut shells, as well as sand (and combinations of one or more of the foregoing); processes for creating scent-free bio-plastic 3D printing material and products from such particles; the application of a copper finish, chrome finish and powder finish to bio-plastics made from such particles; and products and fixtures, such as sinks, toilets, faucets, coffee mug molds, lighting fixtures, and coffee cups, comprising non-flammable bio-plastic created by a process of 3D printing from such particles. Processes for imparting color or structure or surface texture to these and binding and strengthening them using enzyme-secreting bacteria.

The use of bacteria-based binders to bind and strengthen 3D printed compositions; bio-plastic 3D printing materials comprised of combinations of particles of organic substrates such as coffee, pistachio shells and coconut shells, as well as sand (and combinations of one or more of the foregoing); processes for creating scent-free bio-plastic 3D printing material and products from such particles; the application of a copper finish, chrome finish and powder finish to bio-plastics made from such particles; and products and fixtures, such as sinks, toilets, faucets, coffee mug molds, lighting fixtures, and coffee cups, comprising non-flammable bio-plastic created by a process of 3D printing from such particles. Processes for imparting color or structure or surface texture to these and binding and strengthening them using enzyme-secreting bacteria.

The present invention provides methods for preparing the nut waste composites from a nut waste component, one or more binders, and an oil using a compounder/extruder.

A process for the treatment of thick fine tailings that include constituents of concern (CoCs) and suspended solids is provided. The process includes subjecting the thick fine tailings to treatments including chemical immobilization of the CoCs, polymer flocculation of the suspended solids, and dewatering. The chemical immobilization can include the addition of compounds enabling the insolubilization of the CoCs. Subjecting the thick fine tailings to chemical immobilization and polymer flocculation can facilitate production of a reclamation-ready material, which can enable disposing of the material as part of a permanent aquatic storage structure (PASS).

A method of recycling tires comprising the comprising the steps of: placing tires and/or pieces of tires within a casing or mold, applying a binder (e.g. adhesives and/or pining with screws, nails, nuts and bolts, pins, wire and steel or nylon bands etc) to the tires and/or pieces of tires so that the tires are bound together; applying a reinforcing means to the tires and/or pieces of tires (e.g. fitting the reinforcing means around, in between and/or through the tires etc); and melting or pouring an encapsulating means over the top of the tires and reinforcing means to encapsulate them inside the casing or mold and the encapsulating means; and causing or allowing the encapsulating means to set such that a recycled product is formed.

The present invention relates to a method for producing a recycled insulating material from insulating wool, said method comprising the steps of: comminuting insulating wool to give a first intermediate comprising fibre balls; adding binder to the first intermediate to give a second intermediate; hot-pressing the second intermediate into the desired shape, to give a third intermediate; and curing the third intermediate to give the recycled insulating material. The present invention further relates to a method for recycling insulating wool, an apparatus for processing insulating wool, and a fibre-reinforced foam. The invention additionally embraces a fire-resistant wood-based material and a method for producing it.