A beverage capsule recycling assembly for preparing a beverage capsule for recycling, the beverage capsule recycling assembly having a body portion, a cutter portion integral with or attachable to the body portion, the cutter portion having a blade member to cut a lid of the beverage capsule, a first crush portion associated with the body portion, and a second crush portion, wherein when the first crush portion and the second crush portion are in a use condition, the beverage capsule can be located between the first crush portion and the second crush portion, and the first crush portion can be moved towards the second crush portion to compact the beverage capsule.

Aqueous slurry which includes solid foreign matter and paper dust is pressed by means of a screw press, provided with a mesh having openings not less than 1.5 mm and not greater than 3 mm, to separate the aqueous slurry into the solid foreign matter and the paper dust, and liquid component passing through the mesh. Then, the liquid component is sieved by means of a sieve having openings not greater than 1 mm to separate from the liquid component the solid foreign matter and the paper dust.

Aqueous slurry which includes solid foreign matter and paper dust is pressed by means of a screw press, provided with a mesh having openings not less than 1.5 mm and not greater than 3 mm, to separate the aqueous slurry into the solid foreign matter and the paper dust, and liquid component passing through the mesh. Then, the liquid component is sieved by means of a sieve having openings not greater than 1 mm to separate from the liquid component the solid foreign matter and the paper dust.

Embodiments of the present invention relate to a system for processing battery waste. The system comprises a decomposing device for mechanically decomposing the battery waste to a, in particular strip-shaped or flake-shaped, lightweight portion and a heavyweight portion. The decomposing device comprises an outlet for commonly discharging the lightweight portion and the heavyweight portion. The system further comprises a separating unit for separating the lightweight portion from the heavyweight portion, wherein the separating unit is coupled with the decomposing device for receiving the lightweight portion and the heavyweight portion. The system further comprises a fiber compactor unit, wherein the fiber compactor unit is coupled with the separating unit for receiving the lightweight portion. The fiber compactor unit is configured for compacting the lightweight portion under a separation of a further active material.

The pelletizing facility (100) according to the present invention allows the manufacture of solid recovered fuel pellets from municipal solid waste without separating parts of the municipal solid waste before starting the pelletizing process. Thus, a higher amount of the municipal solid waste can actually be used to manufacture solid recovered fuel pellets. The pelletizing facility (100) as well as the method according to the invention can be used in particular to manufacture solid recovered fuel pellets that can be used in the production of hydrogen and/or carbon dioxide enriched syngas by a torrefaction of the solid recovered fuel pellets with a subsequent gas treatment.

The pelletizing facility (100) according to the present invention allows the manufacture of solid recovered fuel pellets from municipal solid waste without separating parts of the municipal solid waste before starting the pelletizing process. Thus, a higher amount of the municipal solid waste can actually be used to manufacture solid recovered fuel pellets. The pelletizing facility (100) as well as the method according to the invention can be used in particular to manufacture solid recovered fuel pellets that can be used in the production of hydrogen and/or carbon dioxide enriched syngas by a torrefaction of the solid recovered fuel pellets with a subsequent gas treatment.

A method for manufacturing a magnet from recycled magnets comprising the following steps of: providing: a 1st powder comprising grains of a magnetic phase TR.sub.2Fe.sub.14B, metal-based compounds and a grain boundary phase rich in rare earth, said 1st powder being free of heavy rare earth, a 2nd powder obtained from recycled magnets comprising heavy rare earths, the 2nd powder is subjected to a hydrogenation-disproportionation treatment, the 1st powder is mixed with the 2nd powder obtained at the end of step b), the mixture obtained at the end of step c) is subjected to a compacting step so as to obtain a compacted part, the compacted part obtained at the end of step d) is subjected to a sintering step so as to obtain a magnet.

A method for manufacturing a magnet from recycled magnets comprising the following steps of: providing: a 1st powder comprising grains of a magnetic phase TR.sub.2Fe.sub.14B, metal-based compounds and a grain boundary phase rich in rare earth, said 1st powder being free of heavy rare earth, a 2nd powder obtained from recycled magnets comprising heavy rare earths, the 2nd powder is subjected to a hydrogenation-disproportionation treatment, the 1st powder is mixed with the 2nd powder obtained at the end of step b), the mixture obtained at the end of step c) is subjected to a compacting step so as to obtain a compacted part, the compacted part obtained at the end of step d) is subjected to a sintering step so as to obtain a magnet.

A variety of methods are disclosed, including, in one embodiment, a method including: providing a biomass source; processing the biomass source to remove water from the biomass source; compacting the biomass source to increase density of the biomass source to produce biomass briquettes; wrapping the biomass briquettes with a plastic membrane; and placing the biomass briquettes in an engineered landfill.

A variety of methods are disclosed, including, in one embodiment, a method including: providing a biomass source; processing the biomass source to remove water from the biomass source; compacting the biomass source to increase density of the biomass source to produce biomass briquettes; wrapping the biomass briquettes with a plastic membrane; and placing the biomass briquettes in an engineered landfill.