The document discusses the environmental and health impacts of e-waste. It begins by introducing different types of pollution like indoor and outdoor air pollution, water pollution, soil pollution, and food contamination. It then focuses on the health hazards caused by improper e-waste disposal, like reproductive, developmental and respiratory issues. Next, it discusses the environmental impact of e-waste recycling in developing countries, releasing heavy metals into soil, water and air. Finally, it outlines the human health effects on residents living near sites, children, and e-waste workers through occupational exposures.
E-waste is electronic products such as computers, phones, and TVs that are discarded and not recycled properly. Over 40 million tons of e-waste is produced worldwide each year, but only 13% is recycled. E-waste contains toxic materials like lead, mercury, and cadmium that can cause health issues if they leach into soil and water from landfills. Burning e-waste releases dioxins and fine particles that cause respiratory problems. The toxic materials in e-waste can damage almost every human organ system and cause problems like learning issues in children. Improper disposal of e-waste poses serious threats to both human health and the environment.
E-waste refers to obsolete, broken, or discarded electrical or electronic devices. The document discusses the sources, composition, impacts, and proper disposal of e-waste. It notes that e-waste is one of the fastest growing waste streams and contains hazardous materials like lead, mercury, and cadmium. Improper disposal of e-waste through landfilling or incineration can pollute the environment and harm human health. Recycling e-waste helps reduce these impacts and recover valuable materials. Individual actions like recycling old electronics can help address the growing problem of e-waste.
This document discusses electronic waste (e-waste) and its management. It defines e-waste as waste from electronic items like computers and cell phones. E-waste is generated from sources like IT equipment, households, and medical devices. Improper disposal of e-waste can contaminate groundwater and release toxic heavy metals that pose health risks. The document outlines roles for governments, industries, and citizens in managing e-waste through inventory control, waste minimization, recovery, and proper disposal.
The document discusses the growing problem of electronic waste (e-waste) and its environmental impacts. It notes that e-waste contains valuable but also harmful materials, and that the life span of electronics is decreasing due to advances in technology, leading to more e-waste. The e-waste is polluting due to toxic heavy metals in components and improper disposal practices, especially in developing countries where e-waste is often dumped. Proper e-waste management through reducing waste, reusing electronics, and responsible recycling is needed to limit environmental degradation and health impacts from this waste stream.
This document discusses electronic waste (e-waste), including its definition, production, composition, disposal issues, health problems, and management. It notes that e-waste includes obsolete or discarded electrical/electronic equipment like computers, TVs, and cell phones. About 50 million metric tons of e-waste are produced globally each year, with improper disposal releasing toxic materials that can harm the environment and human health. The document outlines some steps to properly manage e-waste, including detoxification to remove hazardous components, shredding the materials into pieces, and refining to extract reusable components.
This document discusses electronic waste (e-waste), its sources and characteristics. It notes that e-waste is the fastest growing waste stream and is composed of both valuable and hazardous materials. The document outlines the Indian e-waste scenario, noting that e-waste generation is expected to significantly increase by 2020 and that most e-waste management is currently unorganized. It concludes by stressing the need for a national e-waste policy and framework in India to properly manage increasing e-waste in an environmentally sound manner.
E-waste, or electronic waste, refers to old, end-of-life electronic devices such as TVs, computers, phones, and other electronics. It is difficult to quantify the total amount of e-waste globally due to much of it being undocumented or categorized differently in different areas. Estimates suggest around 40 million tons of e-waste are generated worldwide annually. Only about 13% of e-waste is properly recycled, with the rest often being shipped illegally to developing countries or improperly disposed of. E-waste contains toxic heavy metals like lead, cadmium, and mercury that can harm human health and the environment if not handled properly.
This document discusses electronic waste (e-waste) and its management. It begins by defining e-waste as discarded electronic devices such as computers, TVs, and cell phones. It then notes that 50 million tons of e-waste are produced annually, much of which is improperly disposed of. The document outlines the various sources of e-waste and how electronics become waste. It also describes the toxic constituents in e-waste and their environmental and health impacts if not handled properly. Current e-waste disposal and recycling practices are discussed, along with their advantages and challenges. The conclusion emphasizes the need for safer e-waste management and increased awareness.
E-waste is electronic products such as computers, phones, and TVs that are discarded and not recycled properly. Over 40 million tons of e-waste is produced worldwide each year, but only 13% is recycled. E-waste contains toxic materials like lead, mercury, and cadmium that can cause health issues if they leach into soil and water from landfills. Burning e-waste releases dioxins and fine particles that cause respiratory problems. The toxic materials in e-waste can damage almost every human organ system and cause problems like learning issues in children. Improper disposal of e-waste poses serious threats to both human health and the environment.
E-waste refers to obsolete, broken, or discarded electrical or electronic devices. The document discusses the sources, composition, impacts, and proper disposal of e-waste. It notes that e-waste is one of the fastest growing waste streams and contains hazardous materials like lead, mercury, and cadmium. Improper disposal of e-waste through landfilling or incineration can pollute the environment and harm human health. Recycling e-waste helps reduce these impacts and recover valuable materials. Individual actions like recycling old electronics can help address the growing problem of e-waste.
This document discusses electronic waste (e-waste) and its management. It defines e-waste as waste from electronic items like computers and cell phones. E-waste is generated from sources like IT equipment, households, and medical devices. Improper disposal of e-waste can contaminate groundwater and release toxic heavy metals that pose health risks. The document outlines roles for governments, industries, and citizens in managing e-waste through inventory control, waste minimization, recovery, and proper disposal.
The document discusses the growing problem of electronic waste (e-waste) and its environmental impacts. It notes that e-waste contains valuable but also harmful materials, and that the life span of electronics is decreasing due to advances in technology, leading to more e-waste. The e-waste is polluting due to toxic heavy metals in components and improper disposal practices, especially in developing countries where e-waste is often dumped. Proper e-waste management through reducing waste, reusing electronics, and responsible recycling is needed to limit environmental degradation and health impacts from this waste stream.
This document discusses electronic waste (e-waste), including its definition, production, composition, disposal issues, health problems, and management. It notes that e-waste includes obsolete or discarded electrical/electronic equipment like computers, TVs, and cell phones. About 50 million metric tons of e-waste are produced globally each year, with improper disposal releasing toxic materials that can harm the environment and human health. The document outlines some steps to properly manage e-waste, including detoxification to remove hazardous components, shredding the materials into pieces, and refining to extract reusable components.
This document discusses electronic waste (e-waste), its sources and characteristics. It notes that e-waste is the fastest growing waste stream and is composed of both valuable and hazardous materials. The document outlines the Indian e-waste scenario, noting that e-waste generation is expected to significantly increase by 2020 and that most e-waste management is currently unorganized. It concludes by stressing the need for a national e-waste policy and framework in India to properly manage increasing e-waste in an environmentally sound manner.
E-waste, or electronic waste, refers to old, end-of-life electronic devices such as TVs, computers, phones, and other electronics. It is difficult to quantify the total amount of e-waste globally due to much of it being undocumented or categorized differently in different areas. Estimates suggest around 40 million tons of e-waste are generated worldwide annually. Only about 13% of e-waste is properly recycled, with the rest often being shipped illegally to developing countries or improperly disposed of. E-waste contains toxic heavy metals like lead, cadmium, and mercury that can harm human health and the environment if not handled properly.
This document discusses electronic waste (e-waste) and its management. It begins by defining e-waste as discarded electronic devices such as computers, TVs, and cell phones. It then notes that 50 million tons of e-waste are produced annually, much of which is improperly disposed of. The document outlines the various sources of e-waste and how electronics become waste. It also describes the toxic constituents in e-waste and their environmental and health impacts if not handled properly. Current e-waste disposal and recycling practices are discussed, along with their advantages and challenges. The conclusion emphasizes the need for safer e-waste management and increased awareness.
A complete PPT on E-Waste.
PPT: E-waste or Electronic Waste is the inevitable by-product of a technological revolution. Driven primarily by faster, smaller and cheaper microchip technology, society is experiencing an evolution in the capability of electronic appliances and personal electronics.E-waste is the most rapidly growing waste problem in the world. It is a crisis of not quantity alone but also a crisis born from toxic ingredients, posing a threat to the occupational health as well as the environment.
Visit www.topicsforseminar.com to Download
The document discusses e-waste, its sources, composition and effects. It defines e-waste as electrical and electronic equipment that is discarded after use. Sources include large and small household appliances, IT equipment, medical devices, etc. E-waste contains toxic heavy metals like lead, mercury, cadmium and chemicals that can cause health issues if not properly disposed. The document outlines the need for e-waste management and discusses techniques like waste minimization, sustainable product design, and recycling to reduce environmental pollution from e-waste.
The document discusses e-waste, which refers to electronic products like computers, phones, TVs that have reached the end of their useful life. E-waste is growing rapidly due to the increasing production and planned obsolescence of electronic equipment. It contains toxic heavy metals like lead, mercury, cadmium which can harm human health and the environment if e-waste is not disposed of properly. While landfilling and incineration are common disposal methods, recycling and reuse of e-waste is recommended to recover valuable materials and reduce environmental pollution.
This document discusses e-waste, which refers to discarded electrical or electronic devices. It notes that e-waste is growing rapidly and currently only 27% is recycled globally each year. The sources of e-waste include outdated computers and devices, entertainment electronics, and communication devices. Improper disposal of e-waste through landfilling, incineration, or acid baths can lead to groundwater pollution, soil contamination, and toxic fumes. The document emphasizes the importance of proper e-waste management and increasing recycling and reuse to reduce environmental harm.
E-waste is a major problem world wide. Therefore managing e-waste becomes challenged. This Slides describes the sources through which e-waste is generated and its consequence on human health. it also describes the major country and city generating most e-waste. Generation of e-waste can be reduce and the same is describe in this presentation. Part 2 of this will be uploaded soon. all the data is taken from journals and from internet. Suggestions are invited. Special Thank you to Dr. Rajesh Timane.
Thank you
This document discusses electronic waste (e-waste) in India, including the problems caused by improper management and recycling of e-waste. It notes that e-waste is one of the fastest growing and most toxic waste streams. Large amounts of e-waste are generated each year in India, much of which is handled by informal recycling sectors that expose workers and the environment to harmful toxins. The document calls for improved government regulation, industry responsibility, and public awareness to address the challenges of e-waste in India.
This document discusses e-waste, its effects on the environment, and management strategies. It defines e-waste as electronic and electric products nearing the end of their usable life. E-waste comes from sources like IT equipment, appliances, consumer devices, and medical equipment. When improperly disposed, e-waste releases toxic heavy metals like lead, chromium, cadmium, and mercury that can damage human health and the environment. Effective e-waste management requires efforts from governments, industries, and citizens to implement regulations, reduce waste, encourage recycling and reuse, and make more sustainable product choices.
This document discusses electronic waste (e-waste) and its management. It defines e-waste and explains its classification. It describes the hazardous materials in e-waste like lead, cadmium, and mercury, and their health effects. It also discusses valuable materials in e-waste that can be recovered. The document outlines responsibilities for e-waste management by governments, industries, and citizens. It recommends techniques like recycling, recovery, and proper disposal to deal with the growing problem of e-waste.
E-waste refers to electronic products that are near or at the end of their useful life. It contains toxic materials like lead, cadmium, and mercury that can harm the environment and human health. The amount of e-waste is increasing rapidly as electronics usage grows. Most e-waste in India is handled by the informal sector using unsafe methods. Proper e-waste management includes collection, sorting, recycling, and treatment to safely handle toxins. The government is working with organizations and implementing regulations, but increased awareness and producer responsibility are still needed to address this challenging waste stream.
E-waste refers to discarded electronic products such as computers and televisions. Only 15-20% of e-waste is recycled, with the rest going to landfills and incinerators. This improper disposal has negative effects on human and environmental health as electronics contain toxic heavy metals. Recycling e-waste through sophisticated processes recovers valuable and scarce materials like gold, silver, and lead while avoiding pollution. The benefits of recycling include reducing greenhouse gas emissions from manufacturing and making efficient use of resources to protect the environment.
The document discusses electronic waste (e-waste) and its management. It provides background on e-waste, noting that it is waste from discarded electronic devices that are quickly replaced due to technological advances. It then discusses several key points around e-waste including that it contains hazardous materials, the short lifespans of electronics contribute to large volumes of e-waste, and that improper disposal can harm human health and the environment. The document concludes by emphasizing the importance of proper e-waste recycling and management.
The document proposes establishing a business to extract precious metals from e-waste in India. It summarizes that India produces 3 million tons of e-waste annually, which is increasing by 20% each year and contains 5% precious metals. It outlines plans to collect, dismantle, separate and recover materials from e-waste using an automated electronic scrap recycling system to produce high purity metals, with an expected annual profit of 12 lakh rupees.
The document discusses electronic waste (e-waste) management trends and technologies. It covers:
1) What e-waste is, why it is a growing problem, and the toxic components commonly found in e-waste.
2) Why e-waste prioritization is important today given rapidly growing waste streams and environmental/health concerns from improper disposal.
3) The need for national e-waste legislation in countries like Kenya to help formalize recycling processes and measure success over time.
4) Challenges like complex device designs that make separation of materials difficult, as well as lack of awareness about e-waste issues.
The presentation aims to educate about global e-waste trends and
E-waste is electronic equipment that is nearing or at the end of its useful life. It contains toxic chemicals like lead, cadmium, and mercury. India generates large amounts of e-waste but only a small portion is recycled properly. Most e-waste is handled by informal recyclers who do not protect themselves from toxins, polluting the environment and harming health. Exposure to e-waste toxins can damage organs and increase risks of cancer, neurological impairments, and other diseases. India needs better regulations and incentives for formal recycling to safely manage its growing e-waste problem.
E-waste refers to improperly disposed electronics. Rapid development of new electronics and disposal of old ones has created a large problem, as recycling in places like rural China leads to toxic materials seeping into the environment. One example is Guiyu, China, which has become a center for e-waste recycling, with waste recycling areas being a focal point for toxic poisoning impacting human development and the surrounding environment. Toxins from e-waste like lead, cadmium, mercury, and plastics contaminate water and land, threatening human health and the environment. Efforts are underway to combat e-waste dumping internationally and reduce e-waste through individual actions like recycling electronics and purchasing less toxic devices.
Seminar presentation on Electronic waste/E wasteEr Gupta
Electronic waste or E waste may be defined as, computers, office electronic equipment, entertainment devices & many other electronic or electrical devices which are unwanted, broken & discarded by their original users are known as ‘E-Waste’ or ‘Electronic Waste’
This document discusses e-waste management. It defines e-waste as discarded electrical or electronic devices, and describes its sources as obsolete electronics from data processing, entertainment, communication, and household devices. E-waste contains toxic heavy metals like lead, chromium, cadmium, and mercury that can damage human health and pollute the environment when improperly disposed of. E-waste increases due to technology advances and limited product lifespans. Proper e-waste recycling has advantages like asset recovery, reduced landfill use, and job creation, while making disposal safer than practices like landfilling and incineration that spread toxins. Effective e-waste management is needed due to issues like soil and groundwater pollution caused by its rapid
This presentation provides an overview of e-waste management strategies. It defines e-waste as discarded electrical and electronic equipment, which is one of the fastest growing waste streams. E-waste contains hazardous materials like lead, cadmium, and mercury, which can damage human health and pollute the environment if not properly managed. The presentation outlines guidelines for proper e-waste collection, sorting, transportation, and recycling to reduce environmental and health impacts. It also discusses the roles and responsibilities of industries, citizens, and governments in promoting sustainable e-waste management.
The document discusses e-waste, its sources, composition, and effects on human health and the environment. E-waste is any electrical or electronic equipment that is discarded after use and includes items like computers, phones, TVs, and appliances. It contains toxic heavy metals like lead, mercury, cadmium, which can cause health issues if e-waste is not properly disposed of. Large amounts of e-waste are dumped illegally instead of being recycled, polluting the environment. Proper e-waste disposal is needed to recover valuable materials and prevent environmental contamination and health impacts from its toxic components.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
A complete PPT on E-Waste.
PPT: E-waste or Electronic Waste is the inevitable by-product of a technological revolution. Driven primarily by faster, smaller and cheaper microchip technology, society is experiencing an evolution in the capability of electronic appliances and personal electronics.E-waste is the most rapidly growing waste problem in the world. It is a crisis of not quantity alone but also a crisis born from toxic ingredients, posing a threat to the occupational health as well as the environment.
Visit www.topicsforseminar.com to Download
The document discusses e-waste, its sources, composition and effects. It defines e-waste as electrical and electronic equipment that is discarded after use. Sources include large and small household appliances, IT equipment, medical devices, etc. E-waste contains toxic heavy metals like lead, mercury, cadmium and chemicals that can cause health issues if not properly disposed. The document outlines the need for e-waste management and discusses techniques like waste minimization, sustainable product design, and recycling to reduce environmental pollution from e-waste.
The document discusses e-waste, which refers to electronic products like computers, phones, TVs that have reached the end of their useful life. E-waste is growing rapidly due to the increasing production and planned obsolescence of electronic equipment. It contains toxic heavy metals like lead, mercury, cadmium which can harm human health and the environment if e-waste is not disposed of properly. While landfilling and incineration are common disposal methods, recycling and reuse of e-waste is recommended to recover valuable materials and reduce environmental pollution.
This document discusses e-waste, which refers to discarded electrical or electronic devices. It notes that e-waste is growing rapidly and currently only 27% is recycled globally each year. The sources of e-waste include outdated computers and devices, entertainment electronics, and communication devices. Improper disposal of e-waste through landfilling, incineration, or acid baths can lead to groundwater pollution, soil contamination, and toxic fumes. The document emphasizes the importance of proper e-waste management and increasing recycling and reuse to reduce environmental harm.
E-waste is a major problem world wide. Therefore managing e-waste becomes challenged. This Slides describes the sources through which e-waste is generated and its consequence on human health. it also describes the major country and city generating most e-waste. Generation of e-waste can be reduce and the same is describe in this presentation. Part 2 of this will be uploaded soon. all the data is taken from journals and from internet. Suggestions are invited. Special Thank you to Dr. Rajesh Timane.
Thank you
This document discusses electronic waste (e-waste) in India, including the problems caused by improper management and recycling of e-waste. It notes that e-waste is one of the fastest growing and most toxic waste streams. Large amounts of e-waste are generated each year in India, much of which is handled by informal recycling sectors that expose workers and the environment to harmful toxins. The document calls for improved government regulation, industry responsibility, and public awareness to address the challenges of e-waste in India.
This document discusses e-waste, its effects on the environment, and management strategies. It defines e-waste as electronic and electric products nearing the end of their usable life. E-waste comes from sources like IT equipment, appliances, consumer devices, and medical equipment. When improperly disposed, e-waste releases toxic heavy metals like lead, chromium, cadmium, and mercury that can damage human health and the environment. Effective e-waste management requires efforts from governments, industries, and citizens to implement regulations, reduce waste, encourage recycling and reuse, and make more sustainable product choices.
This document discusses electronic waste (e-waste) and its management. It defines e-waste and explains its classification. It describes the hazardous materials in e-waste like lead, cadmium, and mercury, and their health effects. It also discusses valuable materials in e-waste that can be recovered. The document outlines responsibilities for e-waste management by governments, industries, and citizens. It recommends techniques like recycling, recovery, and proper disposal to deal with the growing problem of e-waste.
E-waste refers to electronic products that are near or at the end of their useful life. It contains toxic materials like lead, cadmium, and mercury that can harm the environment and human health. The amount of e-waste is increasing rapidly as electronics usage grows. Most e-waste in India is handled by the informal sector using unsafe methods. Proper e-waste management includes collection, sorting, recycling, and treatment to safely handle toxins. The government is working with organizations and implementing regulations, but increased awareness and producer responsibility are still needed to address this challenging waste stream.
E-waste refers to discarded electronic products such as computers and televisions. Only 15-20% of e-waste is recycled, with the rest going to landfills and incinerators. This improper disposal has negative effects on human and environmental health as electronics contain toxic heavy metals. Recycling e-waste through sophisticated processes recovers valuable and scarce materials like gold, silver, and lead while avoiding pollution. The benefits of recycling include reducing greenhouse gas emissions from manufacturing and making efficient use of resources to protect the environment.
The document discusses electronic waste (e-waste) and its management. It provides background on e-waste, noting that it is waste from discarded electronic devices that are quickly replaced due to technological advances. It then discusses several key points around e-waste including that it contains hazardous materials, the short lifespans of electronics contribute to large volumes of e-waste, and that improper disposal can harm human health and the environment. The document concludes by emphasizing the importance of proper e-waste recycling and management.
The document proposes establishing a business to extract precious metals from e-waste in India. It summarizes that India produces 3 million tons of e-waste annually, which is increasing by 20% each year and contains 5% precious metals. It outlines plans to collect, dismantle, separate and recover materials from e-waste using an automated electronic scrap recycling system to produce high purity metals, with an expected annual profit of 12 lakh rupees.
The document discusses electronic waste (e-waste) management trends and technologies. It covers:
1) What e-waste is, why it is a growing problem, and the toxic components commonly found in e-waste.
2) Why e-waste prioritization is important today given rapidly growing waste streams and environmental/health concerns from improper disposal.
3) The need for national e-waste legislation in countries like Kenya to help formalize recycling processes and measure success over time.
4) Challenges like complex device designs that make separation of materials difficult, as well as lack of awareness about e-waste issues.
The presentation aims to educate about global e-waste trends and
E-waste is electronic equipment that is nearing or at the end of its useful life. It contains toxic chemicals like lead, cadmium, and mercury. India generates large amounts of e-waste but only a small portion is recycled properly. Most e-waste is handled by informal recyclers who do not protect themselves from toxins, polluting the environment and harming health. Exposure to e-waste toxins can damage organs and increase risks of cancer, neurological impairments, and other diseases. India needs better regulations and incentives for formal recycling to safely manage its growing e-waste problem.
E-waste refers to improperly disposed electronics. Rapid development of new electronics and disposal of old ones has created a large problem, as recycling in places like rural China leads to toxic materials seeping into the environment. One example is Guiyu, China, which has become a center for e-waste recycling, with waste recycling areas being a focal point for toxic poisoning impacting human development and the surrounding environment. Toxins from e-waste like lead, cadmium, mercury, and plastics contaminate water and land, threatening human health and the environment. Efforts are underway to combat e-waste dumping internationally and reduce e-waste through individual actions like recycling electronics and purchasing less toxic devices.
Seminar presentation on Electronic waste/E wasteEr Gupta
Electronic waste or E waste may be defined as, computers, office electronic equipment, entertainment devices & many other electronic or electrical devices which are unwanted, broken & discarded by their original users are known as ‘E-Waste’ or ‘Electronic Waste’
This document discusses e-waste management. It defines e-waste as discarded electrical or electronic devices, and describes its sources as obsolete electronics from data processing, entertainment, communication, and household devices. E-waste contains toxic heavy metals like lead, chromium, cadmium, and mercury that can damage human health and pollute the environment when improperly disposed of. E-waste increases due to technology advances and limited product lifespans. Proper e-waste recycling has advantages like asset recovery, reduced landfill use, and job creation, while making disposal safer than practices like landfilling and incineration that spread toxins. Effective e-waste management is needed due to issues like soil and groundwater pollution caused by its rapid
This presentation provides an overview of e-waste management strategies. It defines e-waste as discarded electrical and electronic equipment, which is one of the fastest growing waste streams. E-waste contains hazardous materials like lead, cadmium, and mercury, which can damage human health and pollute the environment if not properly managed. The presentation outlines guidelines for proper e-waste collection, sorting, transportation, and recycling to reduce environmental and health impacts. It also discusses the roles and responsibilities of industries, citizens, and governments in promoting sustainable e-waste management.
The document discusses e-waste, its sources, composition, and effects on human health and the environment. E-waste is any electrical or electronic equipment that is discarded after use and includes items like computers, phones, TVs, and appliances. It contains toxic heavy metals like lead, mercury, cadmium, which can cause health issues if e-waste is not properly disposed of. Large amounts of e-waste are dumped illegally instead of being recycled, polluting the environment. Proper e-waste disposal is needed to recover valuable materials and prevent environmental contamination and health impacts from its toxic components.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
A Comprehensive Study On E Waste Management: Present Situation And Future Imp...Mosfiqur Rahman
This document provides an overview of e-waste management in Bangladesh. It discusses the environmental and health hazards posed by e-waste, such as the release of heavy metals into the air, water and soil. Currently, informal and unsafe recycling practices are common in Bangladesh. The document then outlines international initiatives and policies for e-waste management, as well as strategies for reducing e-waste such as inventory management, product redesign, and recovery/reuse programs. It notes challenges in Bangladesh include a lack of awareness and proper regulations. Overall, the document analyzes the current situation of e-waste in Bangladesh and potential solutions to improve management and reduce environmental contamination.
International Journal of Engineering Research and DevelopmentIJERD Editor
This document discusses the emerging health threats posed by electronic waste (e-waste). It begins by defining e-waste and noting that it makes up 2.7-3% of total waste but contains many toxic and hazardous elements. The main constituents of e-waste are discussed, including heavy metals like lead, mercury, and cadmium which can cause health effects when exposed. India's annual e-waste generation is estimated at 400,000 tons and is growing rapidly. While formal recycling systems exist, most e-waste in developing countries is handled by the informal sector without proper health and safety practices, exposing workers and local communities to the toxic materials. Proper regulations and disposal facilities are needed to address this important environmental and public
This document discusses electronic waste (e-waste) and its management in India. It defines e-waste as improperly disposed electronics and describes its harmful effects on the environment and human health through the toxic materials it contains like lead, cadmium, and mercury. Large amounts of e-waste are generated but much of it is handled through dangerous informal recycling in places like Guiyu, China that pollutes the local area. The document calls for better e-waste management policies and producer responsibility in India to address this important issue.
This document discusses e-waste management issues in India. It defines e-waste as old or obsolete electrical and electronic equipment such as computers, mobile phones, televisions, etc. E-waste is growing rapidly due to short life cycles and planned obsolescence of electronic devices. Most e-waste in India is handled by the informal sector using unsafe recycling methods that release toxic substances like lead, cadmium, and mercury into the environment. This poses serious health risks. While e-waste contains recoverable materials, the current practices are inefficient and polluting. The document outlines the responsibilities of producers under India's E-Waste Management Rules and calls for better implementation of regulations to promote formal, safe recycling of e-
Excessive Increment in E-Waste System and its Prohibition through Green Compu...Editor IJCATR
In the current scenario, the information and communication technology have made drastic changes in our daily routine like
industries, institution and almost in each field. In today’s world there is a large amount of usage of electronic equipments which are
giving rise to many problems. The energy consumption from such devices also leading to various global warming issues. At the
same time they are leading to many problems like problems of massive amount 0of hazardous waste and other wastes which are
generated from electronic equipment
Therefore here we will discuss about various consequences of e-waste , their effects and management of these toxic ad dangerous wastes
so as to make the process energy efficient and environment friendly
This is my first research paper publication at international journal of advance researches. tittled "Environment and Health Issues Associated with E-wastage"
Industrial pollution is a major cause of environmental degradation and comes from waste generated by industrial activities. The document discusses various types of industrial pollution like air, water, soil, and noise pollution. It provides examples of wastes produced from different industries like dyes, fertilizers, oil refineries, etc. and the pollution they cause. Methods to control industrial pollution include proper waste treatment and management as well as stringent government regulations.
IRJET- Removal of Cadmium from Electroplating Industrial Waste Water using Na...IRJET Journal
This document discusses a study on removing cadmium from electroplating industrial wastewater using natural adsorbents. The study explores using activated carbon derived from low-cost agricultural waste materials like groundnut shell, Indian beech, and onion skin for cadmium removal. Adsorption experiments were conducted at different pH levels and initial cadmium concentrations. The results showed that these natural adsorbents were effective at removing cadmium from wastewater and provide a low-cost alternative to commercial activated carbon. Utilizing agricultural waste supports waste reduction while enabling affordable pollution treatment.
Electronic Waste Management - Challenges and SolutionsRudradityo Saha
This document discusses electronic waste (e-waste) management challenges and solutions. It covers the growing problem of e-waste, effects on the environment and human health, legislation around e-waste, and approaches to managing e-waste in a more sustainable way, including sustainable product design, waste minimization techniques, environmentally-safe disposal like recycling, and recovery and reuse of materials from e-waste.
The document discusses various types of pollution including air, water, soil, noise, and e-waste pollution. It defines each type of pollution, discusses their causes and effects, and provides suggestions for prevention. Specifically, it covers air pollution from burning fossil fuels and its health impacts. For water pollution, it lists causes like industrial and agricultural waste and effects like diseases. Prevention methods emphasized are proper waste management and reducing chemical usage. The document also analyzes a case study on rising air pollution levels in New Delhi and steps taken to curb it.
Electronics contain substances like lead, chromium, cadmium, and mercury that can be dangerous to human health and the environment if electronics are not recycled properly. Improper disposal of electronics can lead to lethal mercury exposure through breathing, lead and cadmium being left behind in water supplies, and cadmium having permanent negative health effects on people.
This document provides information about various types of environmental pollution - air pollution, water pollution, soil pollution, noise pollution, radioactive pollution and solid waste management. It defines each type of pollution, discusses their causes and effects, and outlines some control measures. Key points covered include major air pollutants and their health impacts, sources and effects of water pollution, causes of soil pollution, health issues from noise pollution, and challenges around solid waste management in India.
This document discusses the growing problem of e-waste and its impacts. It notes that e-waste is increasing rapidly due to factors like changing technology and planned obsolescence. E-waste contains hazardous materials like lead, mercury, and cadmium. When e-waste is improperly disposed of, these materials pollute the environment and harm human health. The document outlines policies and conventions to better manage e-waste, including the Basel Convention and extended producer responsibility. It also discusses various approaches to e-waste disposal and emphasizes the importance of reducing, reusing, and properly recycling e-waste to protect the environment and human health.
This is the report created by me as part of the Environmental Course during my BTech degree.
In this pdf, I discuss about the E-Waste. The factors causing it, the health issues due to e-waste, current scenario, potential business model, statistics related to deaths due to e-waste.
E-waste or electronic waste refers to discarded electrical and electronic devices that have reached the end of their useful life. It contains toxic substances like lead, cadmium, and mercury that can pollute the environment and harm human health if not disposed of properly. Some of the metals in e-waste can be recovered and reused. Common examples include old computers, phones, TVs, and household appliances. The growing amounts of e-waste are challenging to manage due to the waste being complex, heavy, and toxic. Improper disposal of e-waste can lead to soil, water, and air pollution and negative health effects in humans. Key methods for managing e-waste include recycling to recover materials, landfilling, and inc
E-waste describes discarded electrical or electronic devices that contain toxic contaminants such as lead, cadmium, and brominated flame retardants. An estimated 50 million tons of e-waste are produced each year, but only 15-20% is recycled while the rest goes to landfills and incinerators. The disposal and dismantling of e-waste leads to environmental impacts like heavy metal contamination of water, soil, crops and animals from liquid and air releases. While recycling can reclaim valuable materials, reuse through retro computing or reselling used devices can extend product lifespans and delay eventual recycling.
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E waste, health & enviroment-may2019
1. E-Waste, Health &
Environment
Dr. Mahmoud M. Amr
Professor of Occupational & Environmental Medicine
Prime Founder, Ex-Director & Consultant of the
National Toxicology Center NECTR
Faculty of Medicine – Cairo University.
President of the National Toxicology Committee (NTC)
Academy of Scientific Research & Technology (ASRT)
Cairo, Egypt
2. Introduction
Environmental Protection
Env. Medicine.
Health Protection Agency.
Outdoor air pollution.
Indoor air Pollution.
Water Pollution.
Soil Pollution.
Food contamination.
AMR 2019 2
Ecosystem
disturbances
3. Env. Medicine:
Exposures Routes Inhalative
Ingestion
Dermal etc.
Quantification
Outcome
Control
Assessment & health impact
AMR 2019 3
5. Outdoor Pollution : (Air Pollution)
Particles autoexhoust
Industry
Power generation
Natural (i.e volcanoes)
Gases So2
NO2
Ozone (O3)
CO
AMR 2019 5
6. - Others: Carcinogen (i.e benzene)
Heavy metals lead
Mercury etc.
Health Effects
Mortality Asthma Lung
cancer mothers
"Long-term exposure"
Hospital admission Morbidity
AMR 2019 6
7. Indoor air Pollution
- Tobacco smoke - NO2
- Allergens - CO
- Fumes - Ozone
- Dust - Kerosene
- Microorganisms - fuel combustion
- Endotoxins - volatile
substances
- Radon
Health Effects
AMR 2019 7
12. Health hazards caused by e-waste
disposal
Causes of E-waste generation
◦ Upgrade
◦ Lifestyle changes
◦ End of usage
Health hazards – improper e-waste disposal
effects
◦ Reproductive issues
◦ Developmental problems
◦ Damage to the immune system
◦ Interference with regulatory hormones
◦ Damage to the nervous system
◦ Kidney damage
◦ lung cancer
AMR 2019 12
◦ Chronic beryllium disease
◦ Skin diseases
◦ Cadmium accumulations on liver and
kidney
◦ Asthmatic bronchitis
◦ DNA damage
◦ Muscle weakness
◦ Endocrine system disruption
13. E-waste management – who’s
responsible?
1. The Government
2. Equipment Manufacturers
3. The Society
AMR 2019 13
14. Electronic waste
Electronic waste or ̏ e-waste ̋ of electrical or electronic devices:
◦ Reuse
◦ Resale
◦ Recycling
◦ or disposal
Informal processing of e-waste in developing countries can lead
to adverse human health effects and environmental pollution.
E-waste contains potentially harmful materials such
as lead, cadmium, beryllium, etc...
E-waste involve significant risk to health of workers and
communities
Great care must be taken to avoid unsafe exposure in recycling
operations and leaking of materials such as heavy metals
from landfills and incinerator ashes.
AMR 2019 14
15. • E-waste Environmental impact
&
Its Human health and safety effects
among:-
◦ Residents living near the recycling sites
◦ Prenatal exposure and neonates' health
◦ Children
◦ E-waste recycling workers
AMR 2019 15
17. "Ghana E-Waste Country
Assessment", found that of
215,000 tons of electronics
imported to Ghana, 80% of the
imports into Ghana were being
burned in primitive conditions.
AMR 2019 17
18. Amount of electronic waste
worldwide
In 2006, the United Nations estimated
the amount of worldwide electronic
waste discarded each year to be 50
million metric tons.
The amount of e-waste could rise by
as much as 500 percent over the next
decade.
Electrical waste contains hazardous
but also valuable and scarce
materials.
In the United States, an estimated 70%
of heavy metals in landfills comes from
AMR 2019 18
19. Global trade issues
Transfer of pollution-generating
activities, such as smelting of copper
wire & electronic waste is being sent
to developing countries for
processing, sometimes illegally. Many
laptops are routed to developing
nations as “dumping grounds for e-
waste”.
BASEL Action Network estimates
that about 80% of the electronic waste
directed to recycling in the U.S. does
not get recycled there at all but in
developing countries.
AMR 2019 19
20. Thousands of men, women, and
children are employed in reuse,
repair, and re-manufacturing.
China:
Uncontrolled burning, disassembly, and
disposal has led to a number of
environmental problems such as
groundwater contamination,
atmospheric pollution, and water
pollution either by immediate discharge
or from surface runoff (especially near
coastal areas), as well as health
problems including occupational safety
and health effects among those directly
and indirectly involved, due to the
methods of processing the waste.
AMR 2019 20
22. Environmental impact
The processes of disposing of electronic waste in
developing countries led to a number of
environmental impacts as liquid and atmospheric
releases end up in bodies of water, groundwater,
soil, and air and therefore in land and sea
animals, in crops eaten by both animals and
human, and in drinking water.
< ECOSYSTEM Changes >
AMR 2019 22
23. Environmental effects:-
◦ Airborne dioxins.
◦ Levels of carcinogens in cadmium, copper,
nickel, and lead.
◦ Heavy metals ̋ lead ̏ over 300 times
Ghana found a presence of lead levels as high
as 18,125 ppm in the soil.
US EPA standard for lead in soil is
400 ppm -1200 ppm.
AMR 2019 23
24. The environmental impact of the processing of
different electronic waste components
AMR 2019 24
E-waste Component Potential Environmental Hazard
• Cathode ray tubes (used
in TVs)
Lead, barium and other heavy metals
leaching into the ground water and
release of toxic phosphor
• Board
Air emissions and discharge into rivers
of glass dust, tin, lead, brominated
dioxin, beryllium cadmium, and mercury
• Chips
PAHs, heavy metals, brominated flame
retardants discharged directly into rivers
acidifying fish and flora. Tin and lead
contamination of surface and groundwater. Air
emissions of brominated dioxins, heavy
metals, and PAHs
• Plastics Emissions of brominated dioxins, heavy
metals, and hydrocarbons
• Computer PAHs released into air, water, and soil.
25. E-waste Management
Recycling
Recycling is an essential element of e-waste
management.
The circuit boards contain such precious metals as gold,
silver, platinum and metals as copper, iron, aluminum, etc.
Properly disposing of or reusing electronics can help
prevent health problems, reduce greenhouse-gas
emissions, and create jobs, offer a more environmentally
friendly and socially conscious alternative
to downcycling processes.AMR 2019 25
26. Consumer awareness efforts
The U.S. Environmental Protection Agency
encourages
electronic recyclers to become certified.
The Certified Electronics Recycler program for
electronic
recyclers is a comprehensive, integrated management
system standard that incorporates key operational and
continual improvement elements for quality,
environmental
and health and safety performance.
There have also been efforts to raise awareness of
AMR 2019 26
27. Benefits of recycling
1. Reuse of various materials “ferrous (iron-
based) and non-ferrous metals, glass, and
various types of plastic.”
2. Avoid Air and Water Pollution.
3. Reduce of Greenhouse gas emissions.
AMR 2019 27
28. Electronic waste substances
Fiberglass, PCBs, PVC (polyvinyl
chlorides), thermosetting plastics, lead, tin,
copper, silicon, beryllium, carbon, iron, and
aluminum.
Cadmium, mercury, and thallium.
Americium, antimony, arsenic, barium, bismuth,
boron, cobalt, europium, gallium, germanium,
gold, indium, lithium, manganese, nickel, niobium,
palladium, platinum, rhodium, ruthenium,
selenium, silver, tantalum, terbium, thorium,
titanium, vanadium, and yttrium.
Lead and tin (as solder) and copper (as wire
and printed circuit board tracks).AMR 2019 28
Hazardous
Non-Hazardous
29. Hazardous
AMR 2019 29
E-Waste Component Adverse Health Effects
Americium (The radioactive
source in smoke alarms)
Carcinogenic
Lead impaired cognitive function
behavioral disturbances
attention deficits
hyperactivity
conduct problems
and lower IQ
most damaging to children
Mercury sensory impairment
Dermatitis
memory loss
muscle weakness
fetal deficits in motor function
Attention
reduced fertility
slower growth and development.
30. Cadmium Severe damage to the lungs and is also
known to cause kidney damage.
Deficits in cognition, learning, behavior,
and neuromotor skills in children.
Hexavalent
chromium
Carcinogen
Cytotoxic and genotoxic effects
Inhibit cell proliferation
Sulphur liver damage
kidney damage
heart damage
eye and throat irritation
Brominated Flame
Retardants (BFRs)
impaired development of the nervous
system
thyroid problems
liver problem.
Environmental effects: similar effects as
in animals
AMR 2019 30
31. Perfluorooctanoic
acid (PFOA)
Hepatotoxicity
developmental toxicity
Immunotoxicity
hormonal and carcinogenic effects
abortion (miscarriage)
stillbirth.
low birth weight
Beryllium oxide lung cancer
beryllium sensitization
chronic beryllium disease
acute beryllium disease
Polyvinyl
chloride(PVC)
dioxins
pollutants in the air, water, and soil
reproductive and developmental health
effects.
AMR 2019 31
33. Human health and safety
① Residents living near the recycling sites
o The environmental exposure due to the food, water,
and environmental contamination caused by e-waste,
because main exposure pathways: inhalation, ingestion,
and dermal contact.
o They have a higher daily intake of heavy metals and a
more serious body burden. Potential health risks include
mental health, impaired cognitive function, and general
physical health damage.
o DNA damage.
AMR 2019 33
34. ② Prenatal exposure and neonates'
health
o Increased umbilical cord blood lead
concentration of neonates
o Adverse birth outcomes (still birth, low
birth weight, etc.) and longterm effects
such as behavioral and learning
problems of the neonates in their future
life.
AMR 2019 34
35. ③ Children
Children are especially sensitive to e-waste
exposure because of several reasons, size, higher
metabolism rate, larger surface area, and multiple
exposure pathways.
Children's exposure to developmental neurotoxins
containing in e-waste such as lead, mercury,
cadmium, chromium and PBDEs can lead to a
higher risk of lower
IQ, impaired cognitive function
a decreased lung function of children
impaired coagulation
hearing loss
decreased vaccine antibody tiltersAMR 2019 35
36. ④ E-waste recycling workers
Hazards of recycling workers:
crushing hazards
hazardous energy released
toxic metals.
AMR 2019 36
37. Hazards applicable to recycling in general
Slips, trips, and falls
Crushing hazards
Hazardous energy released
Cuts and lacerations
Noise
Toxic chemicals
OSHA has also specified some chemical components of
electronics
that can potentially do harm to e-recycling workers' health,
such as
lead, mercury, PCBs, asbestos, refractory ceramic fibers
(RCFs), and
radioactive substances.AMR 2019 37
38. Occupational exposure limits (OELs) of some
hazardous chemicals
AMR 2019 38
Hazardous
chemicals
OELs (mg/m^3) Type of OELs
lead (Pb)
0.05 NIOSH recommended
exposure limits (REL), time
weighted average (TWA)
mercury (Hg)
0.05
NIOSH REL, TWA
cadmium (Cd)
0.005 OSHA permissible exposure
limit (PEL), TWA
hexavalent
chromium
0.005 OSHA PEL, TWA
sulfer dioxide
5
NIOSH REL, TWA
39. Hazard controls
For occupational health and safety of e-
waste
recycling workers, both employers and
workers should take actions.
AMR 2019 39
40. Safety Measures:
Hazards What should workers do
General
wear PPE (personal protective equipment)
report anything unsafe
Dust
clean the workplace
Shower before going home
test the blood lead
use respirator
Cuts and
lacerations
using special gloves and oversleeves.
Noise
Wear the hearing protection
Lifting injuries When handling e-waste, try to decrease the
load per time.
AMR 2019 40