Chapter 8 Biomedical waste and bioenergy: prospects and challenges
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Divya Joshi
Abstract
Healthcare operations depend heavily on the management of biomedical waste (BMW), which has important consequences for environmental sustainability and public health. Because of its toxic nature and possible threats to the environment and public health, disposing of BMW can be difficult. Nevertheless, this waste stream also has the potential to be a great resource for energy generation, providing a twofold advantage for trash management and the production of renewable energy. Several processes, such as pyrolysis, anaerobic digestion, gasification, and incineration, have been developed to turn BMW into energy. The most popular method, incineration, involves burning waste at high temperatures to generate energy or heat. Despite its effectiveness, incineration causes air pollution and leaves behind ash residue. Medical waste (MW) presents an intriguing opportunity to generate clean energy while mitigating the negative impacts associated with its accumulation. Embracing energy production from MW represents a viable solution to this pressing challenge, offering a unique opportunity to promote sustainability and improve public health outcomes worldwide. This chapter explores the prospects of energy generation from MW, highlighting both technological advancements and potential obstacles as well as draw attention to concept and benefits of waste-to-energy for BMW which can reduce landfill waste, creation of substantial energy, and recovery of excess metals for recycling purposes.
Abstract
Healthcare operations depend heavily on the management of biomedical waste (BMW), which has important consequences for environmental sustainability and public health. Because of its toxic nature and possible threats to the environment and public health, disposing of BMW can be difficult. Nevertheless, this waste stream also has the potential to be a great resource for energy generation, providing a twofold advantage for trash management and the production of renewable energy. Several processes, such as pyrolysis, anaerobic digestion, gasification, and incineration, have been developed to turn BMW into energy. The most popular method, incineration, involves burning waste at high temperatures to generate energy or heat. Despite its effectiveness, incineration causes air pollution and leaves behind ash residue. Medical waste (MW) presents an intriguing opportunity to generate clean energy while mitigating the negative impacts associated with its accumulation. Embracing energy production from MW represents a viable solution to this pressing challenge, offering a unique opportunity to promote sustainability and improve public health outcomes worldwide. This chapter explores the prospects of energy generation from MW, highlighting both technological advancements and potential obstacles as well as draw attention to concept and benefits of waste-to-energy for BMW which can reduce landfill waste, creation of substantial energy, and recovery of excess metals for recycling purposes.
Chapters in this book
- Frontmatter I
- Contents V
- List of contributing authors IX
- Chapter 1 Current status of biomedical waste generation in the world 1
- Chapter 2 Conventional and modern biomedical waste management technologies 15
- Chapter 3 Biomedical waste management: challenges and opportunities 39
- Chapter 4 Technological advancements for biomedical waste management 51
- Chapter 5 Segregation of biomedical waste: methodologies and importance 65
- Chapter 6 Metal recovery from biomedical waste: prospects and Perspectives 85
- Chapter 7 Biomedical waste treatment and energy generation 103
- Chapter 8 Biomedical waste and bioenergy: prospects and challenges 115
- Chapter 9 Utilization of biomedical waste as construction substitute 131
- Chapter 10 Segregation of biomedical waste: methodologies and importance 147
- Chapter 11 Biomedical waste management strategies: prospects and future scenario 161
- Chapter 12 The significance of information technology in enhancing revenue generation from biomedical waste management 179
- Chapter 13 Economics and market scenario of biomedical waste management 193
- Chapter 14 Biomedical waste: economics and market trends 207
- Chapter 15 Government initiatives and futuristic plans for waste management and revenue generation 219
- Chapter 16 Biomedical waste: environmental impacts and sustainable management 231
- Chapter 17 Environmental impact of diverse biomedical waste and their sustainable management strategies 261
- Chapter 18 Recovery of silver from used X-ray film for Sphingomonas paucimobilis MX8 273
- Index 283
Chapters in this book
- Frontmatter I
- Contents V
- List of contributing authors IX
- Chapter 1 Current status of biomedical waste generation in the world 1
- Chapter 2 Conventional and modern biomedical waste management technologies 15
- Chapter 3 Biomedical waste management: challenges and opportunities 39
- Chapter 4 Technological advancements for biomedical waste management 51
- Chapter 5 Segregation of biomedical waste: methodologies and importance 65
- Chapter 6 Metal recovery from biomedical waste: prospects and Perspectives 85
- Chapter 7 Biomedical waste treatment and energy generation 103
- Chapter 8 Biomedical waste and bioenergy: prospects and challenges 115
- Chapter 9 Utilization of biomedical waste as construction substitute 131
- Chapter 10 Segregation of biomedical waste: methodologies and importance 147
- Chapter 11 Biomedical waste management strategies: prospects and future scenario 161
- Chapter 12 The significance of information technology in enhancing revenue generation from biomedical waste management 179
- Chapter 13 Economics and market scenario of biomedical waste management 193
- Chapter 14 Biomedical waste: economics and market trends 207
- Chapter 15 Government initiatives and futuristic plans for waste management and revenue generation 219
- Chapter 16 Biomedical waste: environmental impacts and sustainable management 231
- Chapter 17 Environmental impact of diverse biomedical waste and their sustainable management strategies 261
- Chapter 18 Recovery of silver from used X-ray film for Sphingomonas paucimobilis MX8 273
- Index 283
