04997nam 2200697 450 991082853950332120230828212325.01-78040-531-6(CKB)3280000000003566(EBL)3121149(OCoLC)922996039(SSID)ssj0001399483(PQKBManifestationID)11729913(PQKBTitleCode)TC0001399483(PQKBWorkID)11450820(PQKB)10839820(MiAaPQ)EBC3121149(Au-PeEL)EBL3121149(CaPaEBR)ebr10928968(EXLCZ)99328000000000356620140916d2006 uy| 0engur|n|---|||||txtccrWaste gas treatment for resource recovery /edited by Piet N.L. Lens [and three others]London :IWA Publishing,2006.1 online resource (510 p.)Integrated environmental technology seriesDescription based upon print version of record.1-84339-127-9 Includes bibliographical references and index.Cover; Copyright; Contents; Preface; Contributors; Part I: Socio-economic aspects of gas pollution and gas recovery; Section IA: Gas: pollutant or resource?; 1. Introduction on air pollution: the emission-effect relation; 1.1. Introduction: What is air pollution?; 1.2. Overview of the emission effect relations; 1.3. Emissions; 1.4. Formation of aerosols; 1.5. Lifetimes of pollutants; 1.6. Ambient concentration of pollutants; 1.7. Conclusion; References; 2. Transboundary particulate matter pollution in Europe; 2.1. Introduction; 2.2. European aerosol patterns and trends2.3. Air pollution observation: existing networks2.4. Modelling ambient PM transport; 2.5. Conclusions; References; 3. Abatement strategies for air pollution; 3.1. Introduction; 3.2. Origin and fate of emissions; 3.3. Abatement strategies; 3.4. Outlook; References; Section IB: Pollution control policy; 4. Dealing with waste gas in enhancing sustainable development: the role of the Kyoto mechanisms; 4.1. Introduction; 4.2. Defining sustainable development; 4.3. Waste gas recovery under the CDM; 4.4. Kyoto-based case studies of waste gas capture projects; 4.5. Conclusions; References5. Implementation of the European Solvent Directive (1999/13/EC)5.1. Introduction; 5.2 Information exchange platform as a part of the implementation of the EU Solvent Directive; 5.3 Decision support through mass and energy flow management in the sector of vehicle refinishing; 5.4. Further use of mass and energy flow models; 5.5. Conclusion; References; 6. Integration of biological techniques for air pollution control into sustainable development; 6.1. Introduction; 6.2. VOC control, the case for avoiding unnecessary CO2 emissions; 6.3. High-rate biotrickling filters for H2S control6.4. Concluding remarksReferences; Part II: Characterization of waste gases; Section IIA: Waste gases analysis; 7. Characterization of pollutants in gases; 7.1. Introduction; 7.2. Characterizing atmospheric pollutants; 7.3. Monitoring and analysis; 7.4. Effects; 7.5. Conclusions; References; 8. Isotope characterization of gaseous pollutants; 8.1. Introduction; 8.2. Isotope abundance variations; 8.3. Isotope mass balance; 8.4. Conclusion; References; 9. Use of NMR to study in situ bioconversion of gaseous formaldehyde; 9.1. Introduction9.2. In situ NMR study of bioconversion of gaseous compounds9.3. NMR study of formaldehyde bioconversion; 9.4. Conclusion; References; Section IIB: Waste gases characteristics; 10. Heavy metal release in waste incineration processes; 10.1. Introduction; 10.2. Thermodynamic study; 10.3. Characterisation of ultimate residues; 10.4. Kinetics of HM vaporisation; 10.5. Conclusion; References; 11. Functional interpretation of gas composition; 11.1. Introduction; 11.2. Sources of volatile organic compounds; 11.3. Analysis of NMVOCs; 11.4. NMVOC emission rates11.5. Differentiating processes using the NMVOC profileIntegrated environmental technology series.Waste gasesEnvironmental aspectsAir quality managementResource recovery facilitiesNatural gasEnvironmental aspectsAirPollutionAir qualityStandardsWaste gasesEnvironmental aspects.Air quality management.Resource recovery facilities.Natural gasEnvironmental aspects.AirPollution.Air qualityStandards.628.53Lens P. N. L(Piet N. L.),MiAaPQMiAaPQMiAaPQBOOK9910828539503321Waste gas treatment for resource recovery4031209UNINA