E-WASTE RECYCLING UNIT

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Electronic waste or e-waste describes discarded electrical or electronic devices. Used electronics which are destined for refurbishment, reuse, resale, salvage recycling through material recovery, or disposal are also considered e-waste. Informal processing of e-waste in developing countries can lead to adverse human health effects and environmental pollution.

Electronic scrap components, such as CPUs, contain potentially harmful materials such as lead, cadmium, beryllium, or brominated flame retardants. Recycling and disposal of e-waste may involve significant risk to health of workers and their communities.

There cannot be a material in god’s creation which can be called ‘waste’. Every material / object has certain use in appropriate place. Therefore, placing it in the right place solves the problem.

This is the technology that we adopt. We see to that there is minimal processing in waste management so that there is no environmental pollution. Our strength lies in identifying who needs the components most and what best is the use for various parts of e-waste.

For example, a cooler fan in CPU may be used as such by the computer service centre. If the same fan is broken it sells for a lesser value as metal and plastic.

Every screw or bolt if segregated properly can be reused at appropriate place.

Following are the steps involved in e-waste handling

1. Sorting
2. Identify Usefulness
3. Identify hazardousness
4. Dismantling
5. Segregation
6. Treatment / Disposal

For treatment we follow national guidelines and best international practices.

Process description is given in the following flow charts.

ELECTRONIC WASTE WORLD WIDE

E-waste is considered the “fastest-growing waste stream in the world” with 44.7 million tonnes generated in 2016- equivalent to 4500 Eiffel towers. In 2018, an estimated 50 million tonnes of e-waste was reported, thus the name ‘tsunami of e-waste’ given by the UN. Its value is at least $62.5 billion annually.

Rapid changes in technology, changes in media (tapes, software, MP3), falling prices, and planned obsolescence have resulted in a fast-growing surplus of electronic waste around the globe. Technical solutions are available, but in most cases, a legal framework, a collection, logistics, and other services need to be implemented before a technical solution can be applied.

Display units (CRT, LCD, LED monitors), processors (CPU, GPU, or APU chips), memory (DRAM or SRAM), and audio components have different useful lives. Processors are most frequently out-dated (by software no longer being optimized) and are more likely to become “e-waste” while display units are most often replaced while working without repair attempts, due to changes in wealthy nation appetites for new display technology. This problem could potentially be solved with modular smartphones or Phonebloks. These types of phones are more durable and have the technology to change certain parts of the phone making them more environmentally friendly. Being able to simply replace the part of the phone that is broken will reduce e-waste. An estimated 50 million tons of E-waste are produced each year. The USA discards 30 million computers each year and 100 million phones are disposed of in Europe each year. The Environmental Protection Agency estimates that only 15–20% of e-waste is recycled, the rest of these electronics
go directly into landfills and incinerators.

Society today revolves around technology and by the constant need for the newest and most high-tech products we are contributing to a mass amount of e-waste. Since the invention of the iPhone, cell phones have become the top source of e-waste products because they are not made to last more than two years. Electrical waste contains hazardous but also valuable and scarce materials. Up to 60 elements can be found in complex electronics. As of 2013, Apple has sold over 796 million iDevices (iPod, iPhone, iPad). Cell phone companies make cell phones that are not made to last so that the consumer will purchase new phones. Companies give these products such short lifespans because they know that the consumer will want a new product and will buy it if they make it. In the United States, an estimated 70% of heavy metals in landfills comes from discarded electronics.

While there is agreement that the number of discarded electronic devices is increasing, there is considerable disagreement about the relative risk (compared to automobile scrap, for example), and strong disagreement whether curtailing trade in used electronics will improve conditions, or make them worse. According to an article in Motherboard, attempts to restrict the trade have driven reputable companies out of the supply chain, with unintended consequences.

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Description

INTRODUCTION
FOLLOWING ARE THE STEPS INVOLVED IN E-WASTE HANDLING
ELECTRONIC WASTE WORLD WIDE
THE ENVIRONMENTAL IMPACT OF THE PROCESSING OF DIFFERENT ELECTRONIC WASTE COMPONENTS
TYPES OF E-WASTE
THE MOST COMMON TYPES OF E-WASTE
SMALL EQUIPMENT
LARGE EQUIPMENT
TEMPERATURE EXCHANGE EQUIPMENT
BENEFITS AND IMPORTANCE OF E-WASTE RECYCLING
THE PROBLEMS WITH NOT RECYCLING E-WASTE
THE BENEFITS OF RECYCLING E-WASTE
CHALLENGES AND OPPORTUNITIES IN E-WASTE MANAGEMENT IN INDIA
GLOBAL CHALLENGES OF RECYCLING E-WASTE
E-WASTE MANAGEMENT
MARKET OVERVIEW OF E-WASTE RECYCLING
E-WASTE RECYCLING
SCENARIO OF E WASTE IN UTTAR PRADESH
DETAILS OF E-WASTE RECYCLING PROCESS
STEP ONE — COLLECTION
STEP TWO — STORAGE
STEP THREE — MANUAL SORTING, DISMANTLING, SHREDDING
STEP FOUR — MECHANICAL SEPARATION
MAGNETIC SEPARATION
WATER SEPARATION
STEP FIVE: RECOVERY
HOW THE UNIVERSAL RECYCLING PROCESS DIFFERS ACROSS COMMON ITEMS
THE RECYCLING PROCESS FOR BATTERIES
THE RECYCLING PROCESS FOR CATHODE RAY TUBES
THE E-WASTE RECYCLING PROCESS FOR COMPUTERS AND LAPTOPS
PCB CIRCUIT BOARD RECYCLING MACHINE
PRODUCTS STRUCURE
PROCESS DESCRIPTION
PRODUCT FEATURES
TECHNICAL PARAMETERS
WORKING PROCESS OF PCB RECYCLING MACHINE
CLASSIFICATION OF E-WASTE
COMPOSITION OF E-WASTE
COMPONENTS OF E-WASTE
TABLE 1: RECOVERED MATERIAL 1000 KG. OF PC
TABLE: 2 SALEABLE MATERIALS RECOVERED FROM 1000 KG.
ASSORTED E-WASTE (CONTAINING PC. TV, MOBILE PHONE ETV.
TABLE 3: MARKET VALUE OF THE METAL RECOVERED FROM 1000 KG. OF PCBS
TABLE 4: RECOVERABLE QUANTITY OF ELEMENTS IN A PC (TYPICAL)
TABLE 5: RECOVERABLE QUANTITY OF ELEMENTS IN A TV (TYPICAL)
(1) PLASTICS CONTAINING BROMINATED FLAME RETARDANTS (BFRS)
(2) INSULATION
(3) ASBESTOS
(4) REFRACTORY CERAMIC FIBERS (RCFS)
(5) LIQUID CRYSTAL DISPLAY (LCDS)
(6) COMPONENTS CONTAINING PLASTICISERS/STABILISERS
(7) CIRCUIT BOARDS
(8) FLAME RETARDANTS
(9) LEAD
(10) MERCURY
(11) BERYLLIUM
(12) CAPACITORS
(13) ELECTROLYTE CAPACITORS
(14) CAPACITORS CONTAINING POLY CHLORINATED BIPHENYLS (PCBS)
E-WASTE SCENARIO
RECYCLING, REUSE AND RECOVERY OPTIONS
(I) DISMANTLING:
(II) SEGREGATION OF FERROUS METAL, NON-FERROUS METAL AND PLASTIC
(III) REFURBISHMENT AND REUSE:
(IV) RECYCLING/RECOVERY OF VALUABLE MATERIALS
(V) TREATMENT/DISPOSAL OF DANGEROUS MATERIALS AND WASTE
TREATMENT & DISPOSAL OPTIONS
LANDFILLING – INCINERATION
LANDFILLING
INCINERATION
E-WASTE RECYCLING/TREATMENT TECHNOLOGIES IN INDIA
ENVIRONMENTALLY SOUND TREATMENT TECHNOLOGY FOR E-WASTE
ENVIRONMENTALLY SOUND E-WASTE TREATMENT TECHNOLOGIES
ANALYSIS
FIGURE 1: SIMPLIFIED VERSION OF EST FOR E-WASTE
EST FOR 1ST LEVEL TREATMENT
1. DECONTAMINATION
2. DISMANTLING
3. SEGREGATION
OUTPUT:
EST FOR 2ND LEVEL TREATMENT
FIGURE 2: PROCESS FLOW OF NON CRT BASED E-WASTE TREATMENT
THE SALIENT FEATURES OF THIS TREATMENT TECHNOLOGY AND PROCESS IS GIVEN BELOW.
FIGURE .3: NON- FERROUS METAL DISTRIBUTION VS SIZE RANGE FOR PC SCRAP
CRT TREATMENT TECHNOLOGY
DIFFERENT TYPES OF SPLITTING TECHNOLOGY USED ARE GIVEN BELOW
– NICHROME HOT WIRE CUTTING
– THERMAL SHOCK
– LASER CUTTING
– DIAMOND WIRE METHOD
– DIAMOND SAW SEPARATION
– WATER-JET SEPARATION
3RD LEVEL E-WASTE TREATMENT
INPUT/ OUTPUT AND UNIT OPERATIONS
PLASTIC RECYCLING
MECHANICAL RECYCLING PROCESS
FIGURE 4: RECYCLING OPTIONS FOR MANAGING PLASTICS FROM END-OF-LIFE ELECTRONICS
FIGURE 5: REPRESENTATIVE PROCESS FLOW DIAGRAM FOR THE MECHANICAL RECYCLING OF POST CONSUMER PLASTICS
CHEMICAL RECYCLING PROCESS
FIGURE 6: DE-POLYMERIZATION OF PLASTICS & CONVERSION PROCESSES
GUIDELINES FOR ESTABLISHMENT OF INTEGRATED E-WASTE RECYCLING & TREATMENT FACILITY
FACILITY OPERATION REQUIREMENTS
COLLECTION SYSTEMS FOR E-WASTE
STORAGE AREAS
DISMANTLING & SEGREGATION OF DISMANTLED PARTS
RECYCLING
TREATMENT & DISPOSAL
ANNEX IA
ANNEX IB
1. LARGE HOUSEHOLD APPLIANCES
2. SMALL HOUSEHOLD APPLIANCES
3. IT AND TELECOMMUNICATIONS EQUIPMENT
4. CONSUMER EQUIPMENT
5. LIGHTING EQUIPMENT
6. ELECTRICAL AND ELECTRONIC TOOLS (WITH THE EXCEPTION
LARGE-SCALE STATIONARY INDUSTRIAL TOOLS)
7. TOYS, LEISURE AND SPORTS EQUIPMENT
8. MEDICAL DEVICES (WITH THE EXCEPTION OF ALL IMPLANTED AND INFECTED PRODUCTS)
9. MONITORING AND CONTROL INSTRUMENTS
10. AUTOMATIC DISPENSERS
PROCESS FLOW DIAGRAM OF AN INTEGRATED FACILITY
PRINCIPLES OF PLANT LAYOUT
MAJOR PROVISIONS IN ROAD PLANNING FOR MULTIPURPOSE SERVICE ARE:
PLANT LOCATION FACTORS
PRIMARY FACTORS
1. RAW-MATERIAL SUPPLY:
2. MARKETS:
3. POWER AND FUEL SUPPLY:
4. WATER SUPPLY:
5. CLIMATE:
SPECIFIC FACTORS
6. TRANSPORTATION:
A. AVAILABILITY OF VARIOUS SERVICES AND PROJECTED RATES
7. WASTE DISPOSAL:
8. LABOR:
9. REGULATORY LAWS:
10. TAXES:
11. SITE CHARACTERISTICS:
12. COMMUNITY FACTORS:
13. VULNERABILITY TO WARTIME ATTACK:
14. FLOOD AND FIRE CONTROL:
EXPLANATION OF TERMS USED IN THE PROJECT REPORT
1. DEPRECIATION:
2. FIXED ASSETS:
3. WORKING CAPITAL:
4. BREAK-EVEN POINT:
5. OTHER FIXED EXPENSES:
6. MARGIN MONEY:
7. TOTAL LOAD:
8. LAND AREA/MAN POWER RATIO:
PROJECT IMPLEMENTATION SCHEDULES
INTRODUCTION
PROJECT HANDLING
PROJECT SCHEDULING
PROJECT CONSTRUCTION SCHEDULE
TIME SCHEDULE
FOR LICENCE AND CLEARANCES
SUPPLIERS OF METAL TESTING LABORATORY
SUPPLIERS OF PLANT AND MACHINERY
SUPPLIERS OF E-WASTE RECYCLING MACHINE
SUPPLIERS OF E-WASTES

APPENDIX – A:

01. PLANT ECONOMICS
02. LAND & BUILDING
03. PLANT AND MACHINERY
04. OTHER FIXED ASSESTS
05. FIXED CAPITAL
06. RAW MATERIAL
07. SALARY AND WAGES
08. UTILITIES AND OVERHEADS
09. TOTAL WORKING CAPITAL
10. TOTAL CAPITAL INVESTMENT
11. COST OF PRODUCTION
12. TURN OVER/ANNUM
13. BREAK EVEN POINT
14. RESOURCES FOR FINANCE
15. INSTALMENT PAYABLE IN 5 YEARS
16. DEPRECIATION CHART FOR 5 YEARS
17. PROFIT ANALYSIS FOR 5 YEARS
18. PROJECTED BALANCE SHEET FOR (5 YEARS)

Additional information

Plant Capacity

5000 Kg/Day
Land & Building

(6000 sq.mt.)
Plant & Machinery

US$ 68571
Rate of Return

44%
Break Even Point

42%

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