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Increasing global consumerism and population has led to an increase in the levels of waste produced. Waste to energy (WTE) conversion technologies can be employed to convert residual wastes into clean energy, rather than sending these wastes directly to landfill. Waste to energy conversion technology explores the systems, technology and impacts of waste to energy conversion.Part one provides an introduction to WTE conversion and reviews the waste hierarchy and WTE systems options along with the corresponding environmental, regulatory and techno-economic issues facing this technology. Part two goes on to explore further specific aspects of WTE systems, engineering and technology and includes chapters on municipal solid waste (MSW) combustion plants and WTE systems for district heating. Finally, part three highlights pollution control systems for waste to energy technologies.Waste to energy conversion technology is a standard reference book for plant managers, building engineers and consultants requiring an understanding of WTE technologies, and researchers, scientists and academics interested in the field. - Reviews the waste hierarchy and waste to energy systems options along with the environmental and social impact of WTE conversion plants - Explores the engineering and technology behind WTE systems including considerations of municipal solid waste (MSW) its treatment, combustion and gasification - Considers pollution control systems for WTE technologies including the transformation of wast combustion facilities from major polluters to pollution sinks
Incineration has been used widely for waste disposal, including household, hazardous, and medical wasteâ€"but there is increasing public concern over the benefits of combusting the waste versus the health risk from pollutants emitted during combustion. Waste Incineration and Public Health informs the emerging debate with the most up-to-date information available on incineration, pollution, and human healthâ€"along with expert conclusions and recommendations for further research and improvement of such areas as risk communication. The committee provides details on: Processes involved in incineration and how contaminants are released. Environmental dynamics of contaminants and routes of human exposure. Tools and approaches for assessing possible human health effects. Scientific concerns pertinent to future regulatory actions. The book also examines some of the social, psychological, and economic factors that affect the communities where incineration takes place and addresses the problem of uncertainty and variation in predicting the health effects of incineration processes.
Sustainable Food Waste-to-Energy Systems assesses the utilization of food waste in sustainable energy conversion systems. It explores all sources of waste generated in the food supply chain (downstream from agriculture), with coverage of industrial, commercial, institutional and residential sources. It provides a detailed analysis of the conventional pathways for food waste disposal and utilization, including composting, incineration, landfilling and wastewater treatment. Next, users will find valuable sections on the chemical, biochemical and thermochemical waste-to-energy conversion processes applicable for food waste and an assessment of commercially available sustainable food waste-to-energy conversion technologies. Sustainability aspects, including consideration of environmental, economic and social impacts are also explored. The book concludes with an analysis of how deploying waste-to-energy systems is dependent on cross-cutting research methods, including geographical information systems and big data. It is a useful resource for professionals working in waste-to-energy technologies, as well as those in the food industry and food waste management sector planning and implementing these systems, but is also ideal for researchers, graduate students, energy policymakers and energy analysts interested in the most recent advances in the field. - Provides guidance on how specific food waste characteristics drive possible waste-to-energy conversion processes - Presents methodologies for selecting among different waste-to-energy options, based on waste volumes, distribution and properties, local energy demand (electrical/thermal/steam), opportunities for industrial symbiosis, regulations and incentives and social acceptance, etc. - Contains tools to assess potential environmental and economic performance of deployed systems - Links to publicly available resources on food waste data for energy conversion
Hazardous waste poses one of the most complex and risky pollution challenges worldwide. As industrialization accelerates globally, volumes of toxic byproducts and emissions continue to grow, requiring urgent solutions. This book provides a practical overview of hazardous waste management approaches, technologies, and policies to reduce environmental and human health damage. The text begins by outlining Pakistan's current hazardous waste situation, including crucial pollution sources like the textile, fertilizer, and leather industries. It summarizes reduction efforts and persisting challenges around enforcement, technology capabilities, and lack of recycling infrastructure. The following chapters delve into biological waste management techniques and an innovative fertilizer production process utilizing steel slag waste. Case studies demonstrate the potential to convert industrial byproducts into economic resources. Several chapters focus on electronic waste (e-waste), examining landfill contamination risks in Africa and the push to transform these sites into urban mining operations. Technical contributions analyze tools like activated carbon filters to reduce toxic e-waste emissions. The book concludes with a look at winery waste recycling and closes with a chapter connecting hazardous waste management to broader sustainable development goals. Together, the chapters in this volume provide a multifaceted look at hazardous waste management strategies, current limitations, and the work still required to reduce ecological damage. The text is valuable for researchers of dangerous waste, industry operators, and policymakers looking to improve abatement practices. With its detailed case studies and technical analyses, the book offers both practical and big-picture insights to support the critical work of sustainable, effective hazardous waste management worldwide.
Advances of Energy from Waste: Transformation Methods, Applications and Limitations Under Sustainability provides advanced, systematic information on the environmental transformation of waste and pollutants of various origins into useful products, contributing to the development of the local economy, and increasing the sustainability of the energy sector. In addition, remarkable competences in design, performance, efficiency, and implementation of diverse systems utilized for waste energy recovery are summarized and evaluated. This book will also include recent advances in biomass-derived green catalysts for various catalytic applications are discussed in this book along with the challenges of controlled synthesis and the impact of morphological, physical, and chemical properties on their adsorption or desorption capability. Advances of Energy from Waste: Transformation Methods, Applications and Limitations Under Sustainability discuss waste management priorities, waste to energy, environmental pollution, remediation, health risks, circular economy, recycling, sustainability, technologies, and more. - Serves as a starting point for further research into waste management and biomass conversion - Provides an overview of recent developments in the field of waste-to-energy - Discusses recent advances in biomass-derived green catalysts for various catalytic applications - Introduces diverse case studies on waste, pollution, sustainability, technologies, health risk, and future prospective
Environmental engineers support the well-being of people and the planet in areas where the two intersect. Over the decades the field has improved countless lives through innovative systems for delivering water, treating waste, and preventing and remediating pollution in air, water, and soil. These achievements are a testament to the multidisciplinary, pragmatic, systems-oriented approach that characterizes environmental engineering. Environmental Engineering for the 21st Century: Addressing Grand Challenges outlines the crucial role for environmental engineers in this period of dramatic growth and change. The report identifies five pressing challenges of the 21st century that environmental engineers are uniquely poised to help advance: sustainably supply food, water, and energy; curb climate change and adapt to its impacts; design a future without pollution and waste; create efficient, healthy, resilient cities; and foster informed decisions and actions.
Energy access is an essential prerequisite for economic, social, and human development. The 2015 United Nations Sustainable Development Goals (SDGs) explicitly recognized affordable and clean energy as a key factor in development, alongside education and poverty alleviation. The UN Sustainable Energy for All initiative (SEforALL) mobilizes international donors, countries, and the private sector to help people in developing countries gain access to modern energy services.To assist in support of SEgorALL goals, this joint study of the Inter-American Development Bank (IDB) and the United Nations Development Programme (UNDP) provides a comprehensive review of energy poverty policies and programs in Latin America and the Caribbean (LAC). This report measures the progress and impact of energy-access programs and also documents the experience of successful projects. This study reviews cutting-edge methodologies to assist in program design, shares of experiences of successful programs and develops a vision for reaching sustainable energy for all in the LAC region. With electricity coverage at more than 96 percent, LAC is close to becoming the world’s first developing region to achieve universal access to electricity. Despite recent progress, within LAC there are still substantial pockets of energy poverty. Approximately 21.8 million people are without electricity access. More than 80 million people rely on firewood and charcoal for cooking that is burned in fuel-inefficient, primitive stoves. These traditional cooking technologies emit a significant amount of indoor air pollution (IAP), which has been linked to respiratory illnesses and adverse environmental impacts. Thus, in addition to promoting electricity, energy access programs also might give priority to the promotion of cleaner methods cooking by making available better stoves and cleaner burning fuels at reasonable costs. The report also explores ways to measure energy poverty and monitor energy access in developing countries. The accuracy and effectiveness of tools such as the IEA’s household energy data efforts and the Global Tracking Framework depend on collecting information through standardized national surveys. Approaches to measure energy poverty and monitor energy access have increasingly focused on the provision of energy services such as lighting, space conditioning and cooking. The transition from low-quality energy services to more modern forms can be accomplished in different ways. As households in developing countries adopt electricity and clean methods of cooking, they benefit from higher quality, lower cost and convenient to use appliances. However, measuring the societal and developmental benefits of energy investments--though difficult--is important. Two basic approaches have evolved over the years to measure the benefits of energy access: (i) consumer surplus and (ii) regression-based techniques. The consumer surplus approach evaluates the economic benefits of energy services through measuring increased demand resulting from lower costs of such energy end uses such as lighting, radio and television. When possible, rigorous impact evaluation techniques based on multivariate models can be used to more directly measure the socioeconomic benefits associated with energy access and modern energy services including higher income and improved education. In recent years, new approaches for meeting the requirements of modern and sustainable energy services have emerged. Due to technical and market changes, new types of equipment have become available for providing energy services to rural areas. In LAC, three basic models have been developed to provide rural populations with electricity service: (i) main grid extension, (ii) community networks, and (iii) individual home-based systems (including clean cookstoves).
"The authors have provided all the elements required for complete understanding of the basic concepts in heat recovery and water minimization in chemical and related processes, and followed these with carefully selected and developed problems and solutions in order to ensure that the concepts delivered can be applied." Simon Perry, The University of Manchester. This graduate textbook covers fundamentals of the key areas of Process Integration and Intensification for intra-process heat recovery (Heat Integration), inter-process heat recovery and cogeneration (Total Site) as well as water conservation. Step by step working sessions are illustrated for deeper understanding of the taught materials. The textbook also provides a wealth of pointers as well as further information for readers to acquire more extensive materials on the diverse industrial applications and the latest development trends in Process Integration and Intensification. It is addressed to graduate students as well as professionals to help the effectively application of Process Integration and Intensification in plant design and operation.