Post on 19-Jun-2015
SOLID WASTE MANAGEMENT
DEFINITION
Solid wastes comprise all the wastes arising from human and animal activities and are normally solid and that are discarded as useless or unwanted.
Solid waste management may be defined as the discipline associated with the control of generation, storage, collection, transfer and transport, processing and disposal of wastes in a manner that is in accord with the best principles of public health, economics, engineering and conservation.
Functional Elements of Solid Waste Management System
Waste generation
Waste handling, separation,storage and processing at the source
Collection
Disposal
Transfer and transportSegregation & processing &
transformation of solidwaste
Factors Contributing to Increasing Amounts of MSW
Increasing population Changing lifestyles Disposable materials* Excessive packaging*
*two largest contributors to waste volume
Increasing Population
TYPES OF SOLID WASTES
Based on the source of generation Residential wastes
• Commercial wastes: Packaging material• Institutional wastes: Hospital• Construction and demolition wastes- campus• Municipal services • Treatment plant wastes• Industrial wastes: Biogas from distillery waste• Agricultural wastes: fodder to animals and
energy resource
Domestic/household wastes (including kitchen refuse), wastes from commercial units and markets that are related to items sold, e.g. foodstuffs, vegetable choppings, cloth cuttings and sweepings from streets and shops, institutional refuse and wastes from public places and that generated by hawkers
Medical or clinical waste from medical institutions. These can be classified into the following types; general waste, sharp objects such as used needles, blades and scissors; syringes, pathological wastes, including contaminated bandages, dressings, linens, dead tissues, organs etc; and radioactive wastes
Industrial wastes generated by industrial processes and some of which is hazardous
Debris from construction, excavation and/or demolition sites.
TYPES OF SOLID WASTES
TYPES OF SOLID WASTES
Based on the contents of the waste Rubbish Food waste Ashes Dead animals Treatment plant waste Industrial waste Mining waste
Classification of MSW
Based on decomposability• Non-decomposable • Decomposable waste: Biogas generation
Based on combustibility• Combustible waste: useful from energy point of view
• Non-combustible waste
Biodegradable waste (mainly organic wastes such as peelings of potatoes, bananas, saw dust and water hyacinth dumped within the municipal environs, etc), and these constitute the bulk of the wastes generated
Non-biodegradable waste, e.g. polythene bags, plastic products, pesticide residues, process wastes, highly inflammable and volatile substances, furniture, abandoned vehicles, used tyres; industrial wastes including metal scrap and medical wastes such as used needles, plastic and glass bottles and syringes.
Classification of MSW
Classification of MSW
MSW can be classified into "dry and "wet" materials, on the basis of their moisture content.
The unpleasant odors and liquids associated with "garbage" are due to the putrescible organic components of food and plant wastes in the ‘wet form’. These materials are less than 30% of the total MSW.
From the perspective of energy recovery, the non-recyclable ‘dry fraction’ can be divided into combustible materials, such as paper, plastics and wood; and non-combustible or "inert" materials, are metals and glasses.
Options for handling the "wet" fraction: combustion, aerobic - anaerobic bioconversion and land filling.
Small towns 100g/p/day Medium towns 300-400g/p/day Large towns 500g/p/day
In general varies between 0.3-0.6 kg/p/day TOTAL WASTE GENERATION IN INDIA
@0.45kg/P=120,0000000*.45/1000=0.54MT/day
and 197.1 MT/annum
TYPICAL WASTE GENERATION TYPICAL MSW GENERATION
Characteristics of Municipal Solid Waste Generated by Metro Cities
Sl. No
Metro city Paper Textile Leather Plastic Metal Glass Ash, Fine
earth & others
Compostable matter
1 Mumbai 10.0 3.6 0.2 2.0 - 0.2 44.0 40.0
2 Delhi 6.6 4.0 0.6 1.5 2.5 1.2 51.5 31.78
3 Hyderabad 7.0 1.7 - 1.3 - - 50.0 40.0
4 Jaipur 6.0 2.0 - 1.0 - 2.0 47.0 42.0
5 Kanpur 5.0 1.0 5.0 1.5 - - 52.5 40.0
6 Chennai 10.0 5.0 5.0 3.0 - - 33.0 44.0
7 Visakhapatnam 3.0 2.0 - 5.0 - 5.0 50.0 35.0
Characteristics ( Percent by wt. )
Composition of Waste
Characteristics of the waste
Physical Composition Density Moisture content
CHARACTERSTICS OF THE WASTECHARACTERSTICS OF THE WASTE
Physical properties of MSW (These properties are important to estimate volume or weight of waste for transportation, disposal, or processing)
Specific weight or density Moisture content Particle size and size distribution Permeability or hydraulic conductivity
CHARACTERSTICS OF THE WASTECHARACTERSTICS OF THE WASTE
Chemical properties of MSW Proximate analysis: moisture, volatiles, ash and fixed carbon
Fusing point of ash Ultimate analysis: C, H, N and O Energy content: Heating value Leaching properties (applicable to Hazardous
waste fraction in MSW waste): permeability in soil
CHARACTERSTICS OF THE WASTECHARACTERSTICS OF THE WASTE
Biodegradable fraction is important for estimation of gas generation potential of waste or odor potential
Majority of odors from decomposition of waste are due to conversation of
sulfur into H2S, NH3, methyl mercaptan (CH3SH) and/or aminobutryic acid.
Mercaptans: R–SHR represents an alkane, alkene, or other carbon-containing group of atoms.
Various functional elements of municipal solid waste management system
Storage Movable bins - Type I: Bins with lid (5-20 litre), Type II: Bins of
50 litre capacity, Type III: Bins of capacity from 50-200 litres, Type IV: M.S. Bins (4.5 cum)
Fixed bins - Masonry bins of 3.6 cum capacity (Type V)
Collection (H/H (house to house) collection system, Community bin system
Transportation Hand cart (Type I), Hand cart with six containers (Type II),
Trycycle, Animal cart, Tipper trucks, Dumper placer, Bulk refuse carrier
Waste Transfer Stations (Relay Centre Facility) Transfer stations near or far off
Collection system Low rise buildings
Curb or Alley Setout-setback Backyard carry
CURB SET OUT: Place your cart in the street with its wheels up against the curb and the front of the cart facing the street.
ALLEY SET OUT: Place your cart in the alley with the front of your cart facing towards the alley and at least 4 feet from any obstructions, including your garage, dumpsters or cars. Do not block access to your neighbors' driveway, gate or garage.
High rise buildings Crew can collect waste Waste taken to service area by tenants Tenants putting the waste in chute
Garbage chute works in the same way as a chimney; with odours and harmful airborne microorganisms being sucked up the chute (hot air rising), to be inhaled by residents as they open the chute doors to dispose of their waste.
Types of Collection system
Haul container system (HCS)
Stationary container system (SCS)
NEED OF NEED OF TRANSPOTATION TRANSPOTATION SYSTEMSYSTEM
Illegal dumps Disposal site too far Small capacity collection truck Low density area More waste to large distance
Transportation system
Motor vehicle: most common Railways Hydraulic Pneumatic Compressed air/vacuum
MSW = Pollution or Resource?
“Ecosystems dispose of wastes and replenishnutrients by recycling all elements”
PROCESSING OF WASTES
Segregation To reduce the volume, quantity and separate
components
Compaction
Shredding
Biomethanation
Processing facility of municipal solid waste
Source reduction Reduce the amount and toxicity of trash you discard Reusing items by repairing them, donating them to charity and
community groups, or selling them also reduces waste Recycling to turn materials that would otherwise become waste into
valuable resources Composting It is nature's way of recycling organic wastes into new soil used in
vegetable and flower gardens, landscaping, and many other applications
Energy recovery by incineration/pyrolysis In addition to minimizing volume, combustors, when properly
equipped, can convert water into steam to fuel heating systems or generate electricity. A variety of pollution control technologies reduce the toxic materials emitted in combustion smoke.
TRANSFORMATION OF SOLID WASTETRANSFORMATION OF SOLID WASTE
Efficient storage, handling and transport Reduce disposal cost Stabilize waste Destroy toxic element (chemical or biological
entities) Generate electrical energy Re-use
TRANSFORMATION OF SOLID WASTE
Physical method Chemical method Biological method
PHYSICAL TRANSFORMATION
1.Component separation or sorting Done mechanically or manually, at source or at a transfer
station Key process to recover recyclable and remove hazardous
waste component
2. Mechanical volume reduction or densification Reduce storage, transport and disposal cost Waste collection vehicles are equipped with compaction
mechanisms
PHYSICAL TRANSFORMATION
3. Mechanical size reduction Makes waste more uniform and reduces the average
size. Shredding, grinding and milling Tree mulchar (shreds trees into wooden chips for
landscaping application ) Tire shredder
Tires Shredding- Off-The-Road_OT(D) - YouTube.MP4
Shredding of organic waste improves efficiency of composting
CHEMICAL TRANSFORMATION
COMBUSTION Thermal processing of solid waste by chemical
oxidation with stoichiometric or excess amounts of air.
End products-hot gases, water vapour (flue gas), and non-combustible residue (ash).
Energy can be recovered by heat exchange from the hot combustion gases.
Incineration
Pyrolysis
Thermal processing of waste in the complete absence of air.
End products-solids (char), liquids (tar/oil) and gases (hydroggen, methane, carbon monoxide, carbon dioxide etc.)
Endothermic process, external source of heat is required.
PYROLYSIS OF URBAN WASTE
Gasification
Thermal processing of waste with limited air.
End products- gases (hydrogen, methane, carbon monoxide, carbon dioxide etc.) and ash
Waste to Energy: WTE
Waste to Energy: WTE
ENERGY ROUTES OF URBAN WASTE TO ENERGY
BIO-CHEMICAL CONVERSION
The process makes use of the enzymes of bacteria and other micro-organisms to break down biomass to produce liquid and gaseous fuels
In most cases micro-organisms are used to perform the conversion process: anaerobic digestion, fermentation and composting.
Other chemical processes such as converting vegetable or animal oils (waste) into biodiesel is transesterification.
ANAEROBIC DIGESTION
Biological treatment can be done either in presence of oxygen (aerobic) or in absence of oxygen (anaerobic).
In India, anaerobic digestion plants are commonly known as Biogas Plants or Gobar Gas Plants. In such plants slurry of cow dung and water is fed to the digester and is allowed to ferment for a few weeks. The biogas is released. The biogas contains methane and carbon dioxide. This gas is used as a fuel.
There are two types of Biogas Plants Fixed dome Floating dome
ENERGY ROUTE OF BIOGAS
TYPICAL BIOGAS COMPOSITION
Sl. No. Constituents % (V/V)
1 CH460
2 CO238
3 H2S < 1
4 H2O vapors ~ 1
Heating value = 18-20 MJ/Nm3
SCHEMATIC OF A FIXED DOME TYPE BIOGAS PLANT
SCHEMATIC OF A FIXED DOME TYPE BIOGAS PLANT
Position a of dome with less gas in the dome. Position b of dome with more gas in the dome.
COMPARISON OF FIXED AND FLOATING HEAD BIOGAS PLANT
Janta/Fixed dome type Floating Dome type Biogas Plant
1 Gas is released at variable pressure Gas is released at constant pressure
2 Identifying defects is difficult Identifying the defects in gas holder easy
3 Cost of maintenance is low Cost of maintenance is high/corrosion
4 Capital cost is low Capital cost is high (for same capacity)
5 Space above the drum can be used Floating drum does not allow the use of space for other purpose
6 Temperature is high during winter Temperature is low during winter
7 Life span is comparatively longer Life is short
8 Requires more excavation work Requires relatively less excavation
Composting
Conventional Composting Vermi-composting
Composting Biological transformation of the waste. Transformation of biodegradable waste into
biologically stable matter using micro organisms. Reduces the volume of waste. Destroy pathogens/insects. End product is a humus like material called compost
that is rich in nutrients. Compost can be used to support plant growth and as a
soil amendment.
Vermicomposting
Worms
Eudrilus eugineae Eisena foetida
DISPOSAL Open dumping
Land filling Disposal of residual solid wastes in the surface
soils of the earth.
Barging into sea
Feeding to pigs/hogs
LANDFILL
Primary means of MSW disposal Disposal of residual solid wastes in the surface
soils of the earth.
Land fillingLandfills include: any site which is used for more than a year for the temporary
storage of waste; and, any internal waste disposal site, that is to say a site where a
producer of waste is carrying out its own waste disposal at the place of production.
Landfills do not include: any facility where waste is unloaded in order to permit its
preparation for further transport for recovery, treatment or disposal elsewhere;
any site where waste is stored for a period of less than one year prior to disposal.
LANDFILL CLASSIFICATION
1. Secure landfills /Class 1 landfills Designed to handle hazardous wastes.
2. Monofills /Class 2 landfills Designed to handle particular types of wastes such as
incinerator ash or sewage sludge that are relatively uniform in characteristics and require special handling.
3. Sanitary landfills /Class 3 landfills Engineered facilities designed to handle MSW.
TemporaryHolding area
Environmentalmonitoring facilities
Equipmentworkshop
Inspection/Screening facility
Weighingscale
Accessroad
Leachatetreatmentfacility
Gasflaringfacility
Surfacewatercollectionfacility
Typical Layout of a Landfill
Completed fill
Active filling area
Future fill area
Stock piled cover material
Office
Landfill Cell
Postclosure care Activities associated with the long-term monitoring
and maintenance of the landfill (typically 30-50 years).
Numerical Problem:Estimating Landfill Requirements
Estimate the landfill area needed to handle one year’s MSW for a town of 100,000 people. Assume US national average discards (146.6 million tonnes of MSW per year for US population of roughly 260 million), no combustion, a landfill density of 600 kg/m³, and a single 3m lift. Assume that 20 percent of the cell volume is soil used for cover.
Vmsw=(146.6×10^6 tonne ×10³ kg/tonne ×100000 people)
260 × 10^6 people × 600 kg/m³
= 93,975 m³
Since only 80 percent of a cell is landfill, the volume of cell needed is
Vcell = 93,975 m³/0.8 = 117,468 m³
The area of lift, at 3 m cell depth, is
A = 117,468/3 = 39,155 m²
The actual sizing of a landfill would include a number of additional factors, such as additional area requirements for access roads and auxiliary facilities, reduction in landfill volume as biological decomposition takes place and increas in compaction as additional lifts are added.
Biological Reactions in Landfills Four stage process
1. Aerobic Phase
2. Acid Phase
3. Methanogenesis, unsteady
4. Methanogenesis, steady
INTEGRATED SOLID WASTE MANAGEMENT
Selection and application of suitable techniques, technologies and management programs to achieve specific waste management objectives and goals.
3 R’s in waste management Reduce Recycle Reuse
Why reduction and recycling?
To reduce the waste to burry To reduce the pollution by reusing the resources. To reduce the rate of consumption of resources
The waste has three values
* The bulk value
*The food value or nutrition value
*The energy value