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Waste Management and Recycling, Industrial Waste Management, Agro Waste, Municipal Garbage, Plastic, Paper, Metal, Iron, Glass, Rubber, Electronic, Medical Waste Recycling, Solid Waste Treatment, Agricultural, Wood Waste, Residue Processing Projects

Waste management is the collection, transport, processing, recycling or disposal, and monitoring of waste materials. Concern over environment is being seen a massive increase in recycling globally which has grown to be an important part of modern civilization. The consumption habits of modern consumerist lifestyles are causing a huge global waste problem.  Industrialization and economic growth has produced more amounts of waste, including hazardous and toxic wastes. There is a growing realization of the negative impacts that wastes have had on the local environment (air, water, land, human health etc.)

Waste management is the collection of all thrown away materials in order to recycle them and as a result decrease their effects on our health, our surroundings and the environment and enhance the quality of life. Waste management practices differ for developed and developing nations, for urban and rural areas, and for residential and industrial producers. Waste Management flows in a cycle: monitoring, collection, transportation, processing, disposal or recycle. Through these steps a company can effectively and responsibly manage waste output and their positive effect they have on the environment.

Waste generation per capita has increased and is expected to continue to climb with growing population, wealth, and consumerism throughout the world. Approaches to solving this waste problem in a scalable and sustainable manner would lead us to a model that uses waste as an input in the production of commodities and value monetized, making waste management a true profit center. The conversion of waste as a potential source of energy has a value as a supplemental feedstock for the rapidly developing bio-fuels sector. A variety of new technologies are being used and developed for the production of biofuels which are capable of converting wastes into heat, power, fuels or chemical feedstock.

Thermal Technologies like gasification, pyrolysis, thermal Depolymerization, plasma arc gasification, and non–thermal technologies like anaerobic digestion, fermentation etc. are a number of new and emerging technologies that are able to produce energy from waste and other fuels without direct combustion. Biodegradable wastes are processed by composting, vermi-composting, anaerobic digestion or any other appropriate biological processing for the stabilization of wastes. Recycling of materials like plastics, paper and metals should be done for future use.

There is a clear need for the current approach of waste disposal in India that is focused on municipalities and uses high energy/high technology, to move more towards waste processing and waste recycling (that involves public-private partnerships, aiming for eventual waste minimization - driven at the community level, and using low energy/low technology resources.

 

 

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PET Bottle Recycling

Polyethylene terephthalate or PET (also known as PETE) is one of the most common types of plastic. Most single-serve plastic bottles, including those for water, soft drinks and juices, are made with PET.PET recycling is the process of reprocessing plastic that already has been used before and giving it some new reusable form. For instance, this could mean melting down soft drink bottles and then casting them as plastic chairs and tables. Recycling of PET bottles has grown to become a Rs 3,500-crore industry and nearly 70 per cent of PET waste is reprocessed in the country.This positioned the market revenues at INR ~ million, which escalated in the successive year to INR ~ million, by growing at an annual growth rate of 29.9%.Nearly 70% of polyethylene terephthalate bottles are recycled in India, and the market is worth an estimated 35 billion rupees (US$ 530+ million) per year. India is expected to grow at a CAGR of 10.19% during the period 2018-2022. Entrepreneurs who invest in this project will be successful.
Plant capacity: Recycled PET Flakes: 8 MT/DayPlant & machinery: Rs. 50 lakhs
Working capital: -T.C.I: Cost of Project: Rs. 233 lakhs
Return: 25.00%Break even: 66.00%
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Lithium Battery & E-Waste (Electronic Waste) Recycling Industry

Lithium Battery & E-Waste (Electronic Waste) Recycling Industry. Battery Recycling as a Business. Electronic Waste Management, Disposal and Recycling E-Waste Electronic waste, or e-waste, is a term for electronic products that have become unwanted, non-working or obsolete, and have essentially reached the end of their useful life. Because technology advances at such a high rate, many electronic devices become “trash” after a few short years of use. In fact, whole categories of old electronic items contribute to e-waste such as VCRs being replaced by DVD players, and DVD players being replaced by Blu-ray players. E-waste is created from anything electronic: computers, TVs, monitors, cell phones, PDAs, VCRs, CD players, fax machines, printers, etc. Electronics (E-waste) Recycling Electronics waste, commonly known as e-scrap and e-waste, is the trash we generate from surplus, broken and obsolete electronic devices. E-waste or electronics recycling is the process of recovering material from old devices to use in new products. Some of the benefits of e-waste recycling include: • Conservation of natural resources: E-waste has a lot of recoverable and valuable resources like plastics, gold, copper, aluminum, and iron. To preserve our natural resources, all e-waste should be recycled and reused instead of dumped into landfills. • Preventing soil contamination by toxic chemicals: E-waste can be loaded with hazardous materials like lead, chromium, mercury, chemical flame retardants, and beryllium, which can be harmful to our water and soil. Computers and servers can contain cadmium, mercury, and chromium. Flat-panel TVs and LCD screens can contain lead. • Buy-back offers for customers: Many computer and phone manufacturers provide buy-back offers for consumers who return their e-waste. By recycling this e-waste manufacturers are able to obtain a continuous supply of raw materials without the need for mining or further exploitation of natural resources. Consumers also enjoy the benefit of reduced pricing by committing to recycle cell phones, computers, and other common e-waste products. • Creating new jobs: Recycling e-waste can create jobs for people involved in professional refurbishing and recycling. It can create new markets for materials and components. Other financial benefits due to e-waste recycling include minimization of transportation costs involved in movement of raw materials from one place to another and associated labor costs. • Energy efficiency: One of the biggest advantages of recycling e-waste is considerable reduction of energy requirements. The energy cost involved in e-waste recycling is comparatively less than the cost involved in mining and processing of new materials from soil. For example, recycling of aluminum will take ninety-five percent less energy than production of fresh aluminum from raw materials. Recycling of plastics can save up to 70% energy, recycling of glass up to 40% energy, while recycling of steel can save up to 60% energy. E-waste recycling also helps reduce air pollution, greenhouse gas emissions, and dependence on oil. Lithium Battery Lithium batteries are disposable (primary) batteries that have lithium metal or lithium compounds as an anode. Depending on the design and chemical compounds used, lithium cells can produce voltages from 1.5 V to about 3.7 V, over twice the voltage of an ordinary zinc-carbon battery or alkaline cell battery. Lithium batteries are commonly used as power sources for portable electronics and implanted medical devices. Lithium batteries are used in many devices present in the workplace. They include pretty much all computers, cell phones, cordless tools, watches, cameras, flashlights, some medical devices, and vehicles ranging from golf carts, electric cars, airplanes and many others. Cell Phone Lithium Battery Batteries of all types are useful because they allow us to store energy for use whenever it is needed. Lithium Ion (Li-Ion) battery is a rechargeable battery with twice the energy capacity of a Nickel-Cadmium battery and greater stability and safety. LiIon batteries use a liquid lithium-based material for one of their electrodes. Lithium-ion batteries are used in applications that require lightweight and high-energy density solutions. These batteries provide the highest energy density per weight and are mostly used in cellular phones, notebook computers, and hybrid automobiles. Lithium Ion Battery Advantages There are many advantages to using a li-ion cell of battery. These li-ion battery advantages include: • High Energy Density: The much greater energy density is one of the chief advantages of a lithium ion battery or cell. With electronic equipment such as mobile phones needing to operate longer between charges while still consuming more power, there is always a need to batteries with a much higher energy density. In addition to this, there are many power applications from power tools to electric vehicles. The much higher power density offered by lithium ion batteries is a distinct advantage. • Self-Discharge: One issue with batteries and ells is that they lose their charge over time. This self-discharge can be a major issue. One advantage of lithium ion cells is that their rate of self-discharge is much lower than that of other rechargeable cells such as Ni-Cad and NiMH forms. • No Requirement for Priming: Some rechargeable cells need to be primed when they receive their first charge. There is no requirement for this with lithium ion cells and batteries. • Low Maintenance: One major lithium ion battery advantage is that they do not require and maintenance to ensure their performance. Ni-Cad cells required a periodic discharge to ensure that they did not exhibit the memory effect. As this does not affect lithium ion cells, this process or other similar maintenance procedures are not required. • Variety of Types Available: There are several types of lithium ion cell available. This advantage of lithium ion batteries can mean that the right technology can be used for the particular application needed. Some forms of lithium ion battery provide a high current density and are ideal for consumer mobile electronic equipment. Others are able to provide much higher current levels and are ideal for power tools and electric vehicles. Market Outlook E-Waste Recycling In India as well as other developing countries, majority of the electronic products are not recycled, which poses a serious environment and health risk. In India, E-Waste management and recycling market faces major challenges due to lack of proper regulatory interface and supporting infrastructure. E-Waste in the country is primarily generated from large household appliances and Information Technology and Telecommunications sectors. In the coming years, as the technology advances, lifespan of products would become shorter, resulting in replacement of existing products with the new ones, which would result in further increasing generation of E-Waste. Presently, the market size of e-waste in India is of 3.2 million MT and expected to touch to 20 million MT by 2020. In terms of value, it is presently of Rs 25,000 crore industry which is expected to touch Rs 125,000 crores by 2020. Fortunately, the entire industry is presently untapped by the formal sector as required under the E-waste management rules of India. India’s E-Waste market has been divided into various segments including IT and Telecom, Large Household Appliances and Consumer Electronics. Some of the key products generating most of the E-Waste in the country includePCs, mobile phones, refrigerators, washing machines, laptops, televisions, etc. Attero, Ecoreco, SIMS Recycling, Earth Sense Recycle, and TSS-AMM are the major E-Waste recycling and management players operating in the country. These players are focusing on increasing consumer awareness, while also working towards bridging the gap between the organized and unorganized E-Waste management market in India. Recycling of electronic waste includes two methods as the traditional manual disassembly method and automated process. The automated process is majorly preferred, it consists of 6 steps which are- picking shed, disassembly, first size reduction process, second size reduction process, over band magnet, non-metallic and metallic components separation and water separation. Global E-Waste Management Market is expected to garner $49.4 billion by 2020, registering a CAGR of 23.5% during the forecast period 2014 - 2020. It is one of the fastest growing waste streams in emerging as well as developed regions. The reduced life spans of electrical, electronic and consumer electronic devices are generating large E-Waste, which is growing rapidly every year. The growth of E-Waste market is supplemented by the growing need for upgrading to the latest technologies. A desire towards the adoption of new technologically advanced devices leads to generation of millions of tons of E-Waste across various regions. The high consumption of electronic goods has also resulted in Asia being the largest e-waste generators in the world. Some of the largest Asian countries that generated the most number of e-waste in terms of quantity are China, Hong Kong, Japan, and India. The awareness on the impact of e-waste has grown over the years. This has resulted in the imposition of strong legislative laws as well as the development of e-waste treatment standards and recycling technologies. Standards have been put in place to recycle waste responsibly, which will lead to the growth of the e-waste management market in India and APAC. Lithium Battery The India lithium-ion battery market is expected to grow at a robust CAGR of 29.26% during the forecast period, 2018-2023. Lithium-Ion batteries are primary batteries in which lithium compound acts as an anode. A lithium cell can produce voltage from 1.5 V to about 3 V based on the types of materials used. These batteries have a potential to achieve very high energy and power densities in high-density battery applications such as electronics, automotive and standby power. Lithium-ion batteries are now widely implemented as the power or energy source for everything from portable electronics to electric vehicles and energy & natural resources. Increasing adoption of smartphones, tablets, wearable’s, toys, power tools, personal care devices, payment devices and digital cameras among users have led to an improved demand for lithium-ion batteries in India. Increase in disposable income has led to rise in demand for electronic devices such as smartphones and tablets fueling the growth of lithium-Ion batteries in the India. Moreover, rise in government initiative to reduce pollution level are the major factors driving the Indian lithium-ion battery market. Growth in automotive sector has led to surge in demand for electric vehicles which has also supplemented the growth of lithium-Ion batteries. However, high cost and risk of fire in electronic devices may hinder the market growth in the coming years. Growth in automobile industry and growing trend of electronic devices among youth consumers would increase the demand for lithium-Ion batteries in the near future. The India lithium-ion battery market has been segmented on the basis of material type and industry vertical. By material type, the market is further segmented into cathode, electrolytic solution, anode, and other materials includes (binders, separators, and others). By industry vertical, the market is bifurcated into electronics (UPS, smart phones, laptops/tablets, and others), automotive (car, buses, and trucks, scooters and bikes, train and aircraft), industrial (mining equipment, construction equipment, smart grid), and other industry verticals. India has set itself an ambitious target of having only electric vehicles (EV) by 2030, which is expected to increase the demand for lithium-ion batteries in India, significantly. The high cost, associated with batteries that are used in the electric vehicles, is considered to be critical for India's ambitious target. To counter this, the Government of India is planning to set up lithium-ion battery manufacturing units in India. The Global Lithium-Ion Battery Market size is expected reach $46.21 billion by 2022, with a CAGR of 10.8% during the forecast period (2016-2022). Lithium-ion (Li-ion) batteries are rechargeable batteries with high energy density and are mainly used in portable equipment. The market for these batteries is expected to witness a significant growth owing to their increasing use in smartphones, tablets/PCs, digital cameras, and power tools. Moreover, the demand for Li-ion batteries in the automobile industry is expected to increase with the increasing demand for electric vehicles. These batteries have gained popularity among the automobile manufacturers as they offer an alternative to nickel metal batteries used in electric vehicles, due to their small size and light weight. Tags E Waste Recycling Plant, E-Waste Recycling, E Waste Management, e Waste Recycling Plant in India, e-Waste Recycling Plant Cost, E-Waste Recycling Plant Project Report, Starting an E-Waste Recycling Plant, E-Waste Recycling Business, Electronic Waste, Business Setup for E-Waste Recycling, Electronics (E-Waste) Recycling, E-Waste or E-Scrap Recycling, Electronic Waste Management, E Waste Recycling and Recovery, Environment Friendly Electronic Waste Management, Electronic Waste Recycling, E-Waste Management, Electronic Waste (E-Waste) Recycling & Disposal, Disposal of Electronic Waste (E-Waste), Electronic Waste Disposal, E-Waste (Electronic Waste) Recycling and Management, Battery Recycling, Recycling of Automotive Lithium-Ion (Li-Ion) Batteries, Lithium-Ion Battery Recycling, Battery Recycling Plant, E – Waste Management Project, e-Waste Management Project Report Pdf, Cost of Setting up E-Waste Recycling Plant in India, E-Waste Project Ideas, e-Waste Management Project in India, Lithium Battery Recycling Process, How to Recycle Batteries, Lithium-Ion Battery Recycling Industry, Recycling the Hazardous Waste of Lithium Ion Batteries, Li-Ion Batteries Recycling, Battery Scrap Recycling, Project Report on Battery Recycling Industry, Detailed Project Report on E-Waste (Electronic Waste) Recycling, Project Report on Li-Ion Batteries Recycling, Pre-Investment Feasibility Study on E-Waste (Electronic Waste) Recycling, Techno-Economic feasibility study on Lithium-Ion Battery Recycling, Feasibility report on e-Waste Management, Free Project Profile on Lithium-Ion Battery Recycling, Project profile on Li-Ion Batteries Recycling, Download free project profile on E-Waste (Electronic Waste) Recycling, E-Waste & Lithium Battery Recycling, Recycling the Hazardous Waste of Lithium Ion Batteries, Lithium Battery Disposal & Recycling, Batteries & Electronic Waste, Electric, Electronic Waste and Batteries Recycling Business, Disposal of Batteries, Battery Recycling Industry
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Caffeine from Tea Waste

Caffeine belongs to a family of naturally occurring compounds known as xanthines. The xanthines, which come from plants, are possibly the oldest known stimulants. Caffeine is widely used in pharmaceuticals as free base and mixtures, such as 'Citrated Caffeine’s caffeine and sodium benzoate. Caffeine is very much used as a stimulant of the central nervous system and also as a diuretic, although its action as a diuretic is weaker than that of the ophyline. There is about 10% demand growth increase per annum. Up to 400 milligrams (mg) of caffeine a day appears to be safe for most healthy adults. That's roughly the amount of caffeine in four cups of brewed coffee, 10 cans of cola or two "energy shot" drinks.The global caffeine market is predicted to expand at a steady CAGR of around 2.5% by 2022.Entrepreneurs who invest in this project will be successful. Few Indian major players are as under • Aarti Drugs Ltd. • Aarti Industries Ltd. • Ankur Drugs &Pharma Ltd. • AstecLifesciences Ltd. • Bajaj Healthcare Ltd. • Bengal Chemicals & Pharmaceuticals Ltd.
Plant capacity: Caffeine: 20 MT/dayPlant & machinery: Rs. 350 lakhs
Working capital: -T.C.I: Cost of Project: Rs. 2268 lakhs
Return: 30.00%Break even: 61.00%
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Cotton Fibers from Waste Cloth

Cotton is a soft, fluffy staple fiber that grows in a boll, or protective case, around the seeds of the cotton plants of the genus Gossypium in the mallow family Malvaceae. The fiber is almost pure cellulose. Under natural conditions, the cotton bolls will increase the dispersal of the seeds. Cotton, one of the world’s leading agricultural crops, is plentiful and economically produced, making cotton products relatively inexpensive. The fibres can be made into a wide variety of fabrics ranging from lightweight voiles and laces to heavy sailcloths and thick-piled velveteens, suitable for a great variety of wearing apparel, home furnishings, and industrial uses. Cotton fabrics can be extremely durable and resistant to abrasion. Cotton accepts many dyes, is usually washable, and can be ironed at relatively high temperatures. Cotton is the most widely produced natural fiber on the planet. Other natural fibers include silk, made from the cocoons of silkworms; wool, made from the fur of sheep or alpacas; and linen, made from fibers in the stems of flax plants. Every part of the cotton plant can be used. The long cotton fibers are used to make cloth, the short fibers can be used in the paper industry. You can make oil or margarine out of the seeds of the cotton plant. The leaves and stalks of the cotton plant are plowed into the ground to make the soil better. Other parts of the plant are fed to animals. Cotton today is the most used textile fiber in the world. Its current market share is 56 percent for all fibers used for apparel and home furnishings and sold in the U.S. Another contribution is attributed to nonwoven textiles and personal care items. The earliest evidence of using cotton is from India and the date assigned to this fabric is 3000 B.C. Cotton generated revenue nearly USD 7 billion in 2016. High strength & elasticity, tear-resistant and less prone to pilling & static are key properties supporting growth in this segment. Further, improved shelf-life, wrinkle free and ease in sewing are the other factors enhancing product scope. Nylon/wool will witness over 3% CAGR by 2024. Benefits including reduced cost, absence of skin irritation and less wear-tear are factors supporting product demand.
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Recovery of Nylon from Nylon Waste

Nylon is one of the most common plastics in the world and has been used to create everything from clothes and parachutes to food packaging and guitar strings. Nylon can also be used in conjunction with other materials, such as glass and carbon fibre, as its wide range of qualities are often beneficial, but sadly lacking from the materials that it teams up with. The global nylon market has been estimated to register a significant growth on account of increasing demand of light weight fuel efficient vehicles. The primary factors driving growth of the market are the rising use of the light weight vehicles, growing demand for light weight, heat resistant and durable material in numerous industrial applications, and ever increasing demand of the product from textile industry. The global automotive market is estimated to grow at higher CAGR to mark over USD 90 billion revenue in 2018. The production and use of light weight cars and other automotive, as projected by Morgan Stanley analysts, is set to rise to 2.9 percent of 99 million new vehicles in 2020 and to 9.4 percent of 102 million new vehicles in 2025, from 1.1 percent of 86.5 million this year. This is anticipated to fuel demand of the nylon in manufacturing light yet durable parts. Additionally, there is growing demand for the demand for organic which is expected to rise globally due to the rising prices of petrochemical-based raw. Bio-based polyamides are a high-quality alternative to substitute petro-based. They can be used in automotive, electronics, and sports applications. As a result, it has been projected that in future the demand of nylon may surge manifolds. Moreover, surging demand for and use of consumer goods and electronic devices is expected to further boost growth of the market.
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Polyester Yarn from Waste

Polyester Yarn is the fundamental items in the polyester classification. Right around 40% of the world creation of polyester is specifically used to make Polyester Yarn. Polyester yarn is made by direct spinning of PTA and MEG. A portion of the world’s biggest PTA items are British Petroleum, Reliance, Sinopec, Sk-Chemicals, Mitsui and Eastman Chemicals. Polyester yarn is likewise utilized as a part of making pressing application like polyester film, insulation tapes, strapping and a few other day by day use things. Polyester filament yarns is utilized as a part of sewing and weaving to make polyester fabrics, for example, customer fabrics and home outfitting like curtains, bed sheets, bed spreads and draperies. The polyester yarn family has many polyester centric yarns within its ranks, such as Spun Polyester Yarn or Ring Spun Polyester Yarn. It is the endeavor of many manufacturers to concentrate on colored ring spun polyester yarn production, as it is in great demand, the world over. SHM Traders understands this point thoroughly, and works towards bringing the best to its esteemed clients. Polyester is the most used and most preferred fibre in the textiles industry due to its better physical properties, lower price, versatility, and recyclability, which offer a completely unique set of benefits unmatched by any other natural or synthetic fibres. Globally, the polyester fibre market accounts for around 50 per cent of the total manmade and natural fibre market.
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Biomedical Waste Recycling Industry

Biomedical Waste Recycling Industry. Start a Medical or Hospital Waste Management Business Biomedical waste (BMW) is any waste produced during the diagnosis, treatment, or immunization of human or animal research activities pertaining thereto or in the production or testing of biological or in health camps. It follows the cradle to grave approach which is characterization, quantification, segregation, storage, transport, and treatment of BMW. Biomedical waste is classified as a biohazard because of the disease that it might contain. Medical waste contains materials that have been contaminated by body fluids and may contain viruses, bacteria and even harmful drugs such as chemotherapy and radiation drugs. The importance of biomedical waste management should be high on any medical facility’s training and safety procedures. Bio Medical waste consists of • Human anatomical waste like tissues, organs and body parts • Animal wastes generated during research from veterinary hospitals • Microbiology and biotechnology wastes • Waste sharps like hypodermic needles, syringes, scalpels and broken glass • Discarded medicines and cytotoxic drugs • Soiled waste such as dressing, bandages, plaster casts, material contaminated with blood, tubes and catheters • Liquid waste from any of the infected areas • Incineration ash and other chemical wastes Biomedical waste can be disposed of through incineration or decontamination by heating with steam under pressure in an autoclave. Trash chutes must not be used for the transfer or disposal of biomedical waste. Classification of Biomedical Waste Approximately 75-90% of the biomedical waste is non-hazardous and as harmless as any other municipal waste. The remaining 10-25% is hazardous and can be injurious to humans or animals and deleterious to environment. It is important to realize that if both these types are mixed together then the whole waste becomes harmful. • Non Hazardous Waste This constitutes about 85% of the waste generated in most healthcare set-ups. This includes waste comprising of food remnants, fruit peels, wash water, paper cartons, packaging material etc. • Hazardous Waste Biohazard: Biological hazards, also known as biohazards, refer to biological substances that pose a threat to the health of living organisms, primarily that of humans. This can include medical waste or samples of a microorganism, virus or toxin (from a biological source) that can impact human health. It can also include substances harmful to animals. The term and its associated symbol is generally used as a warning, so that those potentially exposed to the substances will know to take precautions. Market Outlook India is likely to generate about 775.5 tonnes of medical waste per day by 2022 from the current level of 550.9 tonnes daily. Bio-medical waste in India is projected to grow at a rate higher than the overall healthcare services market driven by the expansion of the increasing awareness, improving efficiencies in the system, medical tourism, number of clinics, hospitals, rising of the ageing population and new BMW guidelines. Medical waste is the waste generated from hospitals, clinics, dental hospitals, veterinary hospitals, blood banks, and medical research institutes, laboratories. The waste may be generated during various treatments and surgeries, it may be generated during test, production or any biological research. Medical waste does not confine to used syringes and other surgical instruments but all the processes, testing and production of various biological operations. Global Medical Waste Management Market is estimated to reach $26.9 Billion by 2025; growing at a CAGR of 5.6% from 2017 to 2025. Medical waste management states to the suitable processing of waste materials produced by the healthcare institutions. These waste materials are generated at, hospitals, research institutions, health care teaching institutes, clinics, laboratories, blood banks, animal houses and veterinary institutes. Health-care waste comprises all the wastes produced by medical activities. It holds activities of diagnosis, curative and palliative, preventive treatments in the field of veterinary medicine and human. In addition, it includes the same types of waste originating from minor and scattered sources, including waste produced in the course of health care undertaken in the home (e.g. home dialysis, self-administration of insulin, recuperative care). The development of innovative manufacturing techniques for drugs and medical devices in the pharmaceuticals industry is growing rapidly. Furthermore, the growth of market is also reflected by the efficient supply of inventories required in day-to-day functioning of hospitals, clinics, and diagnostic centers. This results in generation of more waste. These by products and residues need a proper system or service for collection, transportation, disposal, and recycling of specific materials or byproducts, if required. Given the growing amount of all types of medical wastes, globally, and increasing regulatory pressure to properly dispose these wastes in a non-hazardous way, the global medical waste management market is expected to grow at a steady pace in the coming years. Medical waste refers to the waste originated within medical amenities, such as hospitals, clinics, veterinary hospitals/clinics, dental practices, physician's offices, laboratories, pharmaceutical industry, and blood banks. There are several types of medical wastes including hazardous (such as infectious, radioactive, or toxic), universal, bio hazardous (such as, red bag medical waste and sharps containers), and solid. The process of medical waste management includes transportation, treatment or destruction, disposal, and documentation of waste generated from the facility. Growing volume of medical waste, increasing focus on the management of medical waste, and stringent regulatory framework to manage these wastes safely and in an ecofriendly way are some of the factors driving the medical waste management industry. There are numerous factors driving, restraining and generating opportunities for the world medical waste management market. Rising concerns over employing eco-friendly and safe waste management and treatment process is likely to drive the market in years to come. In addition, the growing healthcare industry would generate more medical waste thereby, generating opportunity for the market. However, lack of awareness about the health hazards associated with medical waste, lack of training for proper disposal coupled with inadequate funds have hindered market growth of world medical waste management. The market is segmented in terms of disposal or treatment site, type of waste, service, treatment and geography. The treatment site for medical waste disposal can either be offsite or onsite. On the other hand, waste materials are classified as hazardous and non-hazardous waste. The market is also bifurcated in terms of waste treatment services which include collection storage, recycling & transportation, recycling and disposal of the waste. These waste could be treated by chemical treatment, incineration & autoclaving and others. On the basis of geography, the report segments the world medical waste management market into North America, Europe, Asia Pacific and LAMEA. Growing geriatric population requiring health care products and services, increasing incidence and prevalence of infectious and lifestyle diseases, expanding health care infrastructure, changing lifestyles, enforcement of various regulations for the management of biomedical waste, and increasing awareness about safety and security against the hazards caused by biomedical wastes are some factors driving the global biomedical waste management market. However, high cost of services provided by biomedical waste management players, lack of education to workers handling the waste and health care workers about importance of biomedical waste treatment and disposal are factors restraining the market. Some of the major players operating in global medical waste management industry include, BioMedical Waste Solutions LLC, Clean Harbors Inc., Daniels Sharpsmart Inc., Hawaii Bio-Waste Systems Inc. (HBW), Healthcare Environmental Services Group, Medclean Technologies Inc., Medasend Biomedical Inc., Miller Group, Republic Services Inc., REMONDIS SE & Co. KG, Suez Environnement S.A., Sharps Compliance Inc., Waste Management Inc., Stericycle Inc., and Gamma Waste Systems. Tags #Biomedical_Waste, #Medical_Waste_Disposal, #Biomedical_Waste_Management_in_India, #Biomedical_Waste_Disposal, #Bio_Medical_Waste_Management_Pdf, Bio Medical Waste Management PPT, Medical Waste Recycling, Solid Medical Waste and Recycling, Biomedical Waste Management, Industrial Waste, Hospital Waste Management, #Biomedical_Waste_and_Collection, Medical Waste Treatment, Medical & Biomedical Waste Disposal, Bio-Medical Waste Management, Biomedical Waste Treatment and Disposal, Biomedical Waste and Solid Waste Management, Hazardous and Biomedical Waste Management, Disposal of Medical Waste, Biomedical Waste Recycling, Hospital Bio-Waste Management, Hazardous Waste Management, How to Dispose of or Recycle Bio-Medical Waste, Project Report on Biomedical Waste Management Industry, #Detailed_Project_Report_on_Biomedical_Waste_Management, Project Report on Biomedical Waste Management, #Pre_Investment_Feasibility_Study_on_Biomedical_Waste_Management, Techno-Economic feasibility study on Biomedical Waste Management, #Feasibility_report_on_Biomedical_Waste_Management, Free Project Profile on Biomedical Waste Management, Project profile on Biomedical Waste Management, #Download_free_project_profile_on_Biomedical_Waste_Management, How to Start a Medical Waste Business, Starting a Medical Waste Disposal, Starting Your Own Medical Waste Disposal, How to Start a Waste Management Business, Medical Waste Disposal Cost, How to Start a Hazardous Waste Disposal Business, How to Start a Waste Disposal Business, How to Start Waste Management Business in India, Waste Management Business Plan, Commercial Medical Waste Disposal, How to Start a Biomedical Recycling Business, Managing and Disposing of Medical Waste, Medical Waste Recycling, Biomedical Waste Recycling Business
Plant capacity: -Plant & machinery: -
Working capital: -T.C.I: -
Return: 1.00%Break even: N/A
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Recovery of Lead from Scrap Batteries

The recovery of metals from metal scrap has the advantage that it is easier and far less energy dependent than the production of primary lead from ores.Lead is a chalcophile metallic element forming several important minerals including galena PbS, angle site PbSO4, crosstie PbCO3 and minimum Pb3O4. Recycling lead is relatively simple and in most of the applications where lead is used, such as lead-acid batteries, it is possible to recover it for use over and over again. The production of lead in India from primary sources accounts for nearly two thirds of the total lead production in the country whereas, the world over, the production from secondary smelters accounts for nearly 60% of the total production of lead.This facilitates the development of new technologies and ensures a high quality product. Few Indian major players are as under • Germania Batteries Pvt. Ltd. • Goldstar Power Ltd. • Greenvision Technologies Pvt. Ltd. • H B L Power Systems Ltd. • High Energy Batteries (India) Ltd. • Kirloskar Batteries Pvt. Ltd. • Livguard Batteries Pvt. Ltd. • Nicco Batteries Ltd.
Plant capacity: Lead Ingot: 8 MT/dayPlant & machinery: Rs 96 lakhs
Working capital: -T.C.I: Cost of Project: Rs 370 lakhs
Return: 29.00%Break even: 54.00%
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Lead Production (Litharge, Refined Lead, Red Lead & Grey Lead)

Lead is a relatively soft metal with bluish-white lusture but on exposure to air, it becomes covered by a dull, gray layer of basic carbonate that adheres closely and protects it from further oxidation or corrosion. It is an important component of batteries, and about 75% of the world's lead production is consumed by the battery industry. Lead is also commonly used in glass and enamel. India Lead Acid Battery Market is projected to grow at a CAGR of over 9% during 2018-24. India lead acid battery market is projected to reach $ 7.6 billion by 2023. Anticipated growth in the market can be attributed to booming demand for automobiles, in addition to increasing focus of the government towards boosting the penetration of electric vehicles in the country. Entrepreneurs who invest in this project will be successful. Few Indian major players are as under • A P L Metals Ltd. • Gravita India Ltd. • Indian Lead Ltd. • Lead Finvest India Ltd. • M T I Materials Pvt. Ltd. • Metal Link Alloys Ltd. • Metaltech Engineering Pvt. Ltd.
Plant capacity: Litharge: 960 MT/Annum Refined Lead: 1800 MT/Annum Red Lead: 440 MT/Annum Grey Lead: 525 MT/AnnumPlant & machinery: 82 lakhs
Working capital: -T.C.I: Cost of Project: Rs 361 lakhs
Return: 31.00%Break even: 54.00%
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E-Waste Recycling Plant

E-WASTE is a collective name for discarded electronic devices that enter the waste stream from various sources. It includes electronic appliances such as televisions, personal computers, telephones, air conditioners, cell phones, electronic toys, etc. The Electronics Recycling operates to the WEEE directive for efficient electronics disposal. The WEEE Directive aims to reduce the quantity of waste from electrical and electronic equipment and increase it’s re-use, recovery and recycling. India’s ‘production’ of e-waste is likely to increase by nearly three times, from the existing 18 lakh metric tons (MT) to 52 lakh MT) per annum by 2020 at a compound annual growth rate (CAGR) of about 30%. A mere 1.5% of India's total e-waste gets recycled. This facilitates the development of new technologies and ensures a high quality product.
Plant capacity: Plastic Granules: 400000 Kgs./Annum Glass Scrap: 300000 Kgs./Annum Copper Scrap: 250000 Kgs./Annum Precious Metals (Nickel, Tin & Zinc): 49996 Kgs./Annum Gold: 1.3200 Kgs./Annum Silver: 2.6400 Kgs./Annum Palladium: 0Plant & machinery: 85 lakhs
Working capital: -T.C.I: Cost of Project: Rs 829 lakhs
Return: 26.00%Break even: 38.00%
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