Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

The raw materials industry is widely considered to be too environmentally costly, and causing more losses than benefits. The responsible solving of the problems caused by this industry is not “exporting” its operations to less developed countries, but addressing all recognized hazards with dedicated technological developments. Such an approach is presented by the authors of this book. The contributions deal with the optimization of processes in the raw materials industry, obtaining energy from alternative fuels, researching the environmental aspects of industrial activities. This book determines some guidelines for the sustainable raw materials industry, describing methods of the optimized use of mined deposits and the recovery of materials, reductions in energy consumption and the recuperation of energy, minimizations in the emissions of pollutants, the perfection of quieter and safer processes, and the facilitation of modern materials-, water-, and energy-related techniques and technologies.

Technology: general issues --- History of engineering & technology --- acid leaching --- battery recycling --- Li-ion batteries --- metal recovery --- raw material sustainable use --- sieving screen --- inertial vibrator --- dual-frequency --- spectrum --- FEM simulation --- biomass ash --- coal ash --- sintering --- mechanical test --- pressure drop test --- slagging --- fouling --- ion flotation --- used batteries --- ecological safety --- recovery --- Zn(II) --- Mn(II) --- belt conveyor --- prosumer --- downhill transport of overburden --- specific energy consumption --- recuperation --- energy recovery rate --- air quality monitoring --- SO2 --- VOC --- H2S --- PM10 --- PM2.5 --- PM1.0 --- outdoor air quality --- air flow aerodynamics --- street canyon --- digestate --- biogas plant --- hydrothermal carbonisation --- membrane processes --- water recovery --- thermal lag --- fossil fuels --- pyrolysis --- TG --- thermal analysis --- power --- powered roof support --- hydraulic leg --- bench testing --- dynamic load --- discrete event simulation --- quarry --- mine machine --- cost of production --- fire-side corrosion --- boiler tube wastage --- diagnostics --- industrial-scale boilers --- non-destructive inspection --- pipe inspection --- wall thickness measurement --- stone waste --- waste generation --- waste recycling --- industrial waste treatment --- sustainable manufacturing --- dimension natural stone processing --- GHG emissions --- stable isotopes --- waste management --- energy recovery --- unburned carbon --- fly ash --- activated carbon --- adsorption kinetics --- statistical regression --- sustainable mining --- heating and energy processes --- raw material sustainable-use fossil fuels --- energy conversion and storage --- air pollution --- emission reduction methods --- purification and removal techniques

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

The raw materials industry is widely considered to be too environmentally costly, and causing more losses than benefits. The responsible solving of the problems caused by this industry is not “exporting” its operations to less developed countries, but addressing all recognized hazards with dedicated technological developments. Such an approach is presented by the authors of this book. The contributions deal with the optimization of processes in the raw materials industry, obtaining energy from alternative fuels, researching the environmental aspects of industrial activities. This book determines some guidelines for the sustainable raw materials industry, describing methods of the optimized use of mined deposits and the recovery of materials, reductions in energy consumption and the recuperation of energy, minimizations in the emissions of pollutants, the perfection of quieter and safer processes, and the facilitation of modern materials-, water-, and energy-related techniques and technologies.

acid leaching --- battery recycling --- Li-ion batteries --- metal recovery --- raw material sustainable use --- sieving screen --- inertial vibrator --- dual-frequency --- spectrum --- FEM simulation --- biomass ash --- coal ash --- sintering --- mechanical test --- pressure drop test --- slagging --- fouling --- ion flotation --- used batteries --- ecological safety --- recovery --- Zn(II) --- Mn(II) --- belt conveyor --- prosumer --- downhill transport of overburden --- specific energy consumption --- recuperation --- energy recovery rate --- air quality monitoring --- SO2 --- VOC --- H2S --- PM10 --- PM2.5 --- PM1.0 --- outdoor air quality --- air flow aerodynamics --- street canyon --- digestate --- biogas plant --- hydrothermal carbonisation --- membrane processes --- water recovery --- thermal lag --- fossil fuels --- pyrolysis --- TG --- thermal analysis --- power --- powered roof support --- hydraulic leg --- bench testing --- dynamic load --- discrete event simulation --- quarry --- mine machine --- cost of production --- fire-side corrosion --- boiler tube wastage --- diagnostics --- industrial-scale boilers --- non-destructive inspection --- pipe inspection --- wall thickness measurement --- stone waste --- waste generation --- waste recycling --- industrial waste treatment --- sustainable manufacturing --- dimension natural stone processing --- GHG emissions --- stable isotopes --- waste management --- energy recovery --- unburned carbon --- fly ash --- activated carbon --- adsorption kinetics --- statistical regression --- sustainable mining --- heating and energy processes --- raw material sustainable-use fossil fuels --- energy conversion and storage --- air pollution --- emission reduction methods --- purification and removal techniques