Motivation The other day I was waiting at the station for my train. Next to me a young lady was nonchalantly leaning against the wall. Suddenly, she took a cigarette pack out of her handbag, pulled out the last cigarette, put it between her lips, crushed the empty pack, threw it on the ground and hedonistically lit the cigarette. I thought to myself, "What a behavior?!". The nearest trashcan was just five meters away. So I bent down, took the crushed pack and gave it back to her, saying that she had lost it. She looked at me in a rather deranged way, but she said nothing and of waste to the trashcan. brought the piece Often people are not aware of the waste they produce. They get rid of it and that's it. As soon as the charming lady dropped the cigarette pack, the problem was solved for her. The pack was on the ground and it suddenly no longer belonged to her. It is taken for granted that somebody else will do the cleaning up. There is a saying that nature does not produce waste. For long as humans obtained the goods they needed from the ground where they lived, the waste that was produced could be handled by nature. This has drastically changed due to urbanization and waste produced by human activities has become a severe burden.

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Inhaltsangabe1 Introduction.- 1.1 The Problem with Waste.- 1.1.1 Economic Aspects of Waste.- 1.1.2 Ecological Aspects of Waste.- 1.1.3 The Social Problem of Waste.- 1.2 History of Waste Management.- 1.3 Directing Material Flows.- 1.3.1 Preventing and Reducing Waste.- 1.3.2 The great R's: Re-use, Recycle, Recover.- 1.3.3 Recovering Materials and Energy from Waste.- 1.4 Conclusions.- References.- 2 Waste Disposal: What are the Impacts?.- 2.1 The Diversity of Municipal Solid Waste (MSW).- 2.1.1 Quantities of MSW Collected.- 2.1.2 The Composition of MSW.- 2.2 Emissions from Municipal Solid Waste Landfills.- 2.2.1 Emission to the Atmosphere.- 2.2.2 Emissions to the Pedosphere and Hydrosphere.- 2.2.3 Problems in Predicting the Long-Term Behavior of Landfills.- 2.2.4 Conclusions.- 2.3 MSW Management and Technology in China.- References.- 3 Recycling, Thermal Treatment and Recovery.- 3.1 Reduce, Reuse, Recycle: The Zero Waste Approach.- 3.1.1 Zero Waste Theory.- 3.1.2 Zero Waste Analysis.- 3.1.3 Storage and Collection.- 3.1.4 Processing, Storage and Marketing.- 3.1.5 Appropriate Technology.- 3.1.6 Local Ordinances.- 3.1.7 Participant Education.- 3.1.8 Determining Costs and Benefits.- 3.1.9 Measuring Diversion.- 3.2 Mechanical Sorting Processes and Material Recycling.- 3.2.1 Glass Recycling.- 3.2.2 Recycling of Paper and Cardboard.- 3.2.3 Recycling of Light Weight Packaging with the Green Dot System.- 3.2.4 RDF-Production from Household Waste.- 3.3 Conventional Thermal Treatment Methods.- 3.3.1 Introduction.- 3.3.2 Process Control in Grate Systems.- 3.3.3 Examples and Results.- 3.4 Emissions from Incinerator Ash Landfills.- 3.4.1 Introduction.- 3.4.2 Concentrations of Heavy Metals in Landfill Leachates.- 3.4.3 Long-Term Predictions.- 3.4.4 Lessons to be Learned for Thermal Use and Treatment of MSW.- 3.5 Secondary Raw Materials from Waste.- 3.5.1 Introduction.- 3.5.2 Technical and Other Requirements for Construction Materials.- 3.5.3 Initial Experiences with Further Thermally Treated MSWI-Slags.- 3.5.4 Possible Applications of Further Thermally Treated MSWI-Slag.- 3.5.5 Conclusions and Outlook.- References.- 4 Biological and Bio-Mechanical Processes.- 4.1 Mechanical-Biological Treatment of Waste (MBP).- 4.1.1 Separation of Organic and RDF Fractions by Mechanical Processing.- 4.1.2 Case Study: RDF Separation by a Two-Step Mechanical Process.- 4.1.3 Improved Material Flows by the 'Dry Stabilate' Process.- 4.1.4 Biological Processing of Waste and Effects on Landfill Characters.- 4.2 Composting and Anaerobic Digestion.- 4.2.1 Overview of the Various Processes.- 4.2.2 Prospects: What Should be Improved for a Sustainable Development?.- 4.3 Active Landfill Control and Stabilization of MSW.- 4.3.2 How to Proceed in ACLSM?.- 4.3.3 Conclusions.- 4.4 Biotechnology for the Treatment of Inorganic Wastes.- 4.4.1 Biogeochemical Element Cycles.- 4.4.2 Organic Aspects: Mechanical-Biological Waste Pre-treatment.- 4.4.3 Inorganic Aspects: Microbe-Metal-Interactions.- 4.4.4 Biological Treatment of Heavy Metal Rich Wastes.- 4.4.5 Conclusions.- References.- 5 Advanced Thermal Treatment Processes.- 5.1 Energy Recovery from Waste.- 5.1.1 Waste to Energy: New Integrated Concepts.- 5.1.2 High Efficiency Waste-to-Energy Concept.- 5.1.3 Using Substitute Fuels in the Basic Materials Industry.- 5.1.4 Hydrothermal Processes.- 5.2 Optimizing Incineration for Heavy Metal Recovery.- 5.2.1 Heavy Metal Volatilization During MSW Incineraton.- 5.2.2 Detoxification of Filter Ash.- 5.2.3 PECK Incineration Technology.- 5.3 High-Temperature Melting of Municipal Solid Waste.- 5.3.1 Development of High-Temperature Melting Technologies.- 5.3.2 Material and Energy Balances of High-Temperature Melting.- 5.3.3 Persistent Chemicals in High-Temperature Melting Processes.- 5.4 The Characteristics, Behavior and Durability of High Temperature Materials.- 5.4.1 Frame of the Study.- 5.4.2 Characteristics of HT Materials: The Static Picture.- 5.4.3 Behavior of HT Materials: The Dynamic Picture.- 5.4.4 Du