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Basic Techniques of Energy Recovery from Waste
Energy can be recovered from the organic fraction of waste (biodegradable as well as non-biodegradable) through thermal, thermo-chemical and biochemical methods.
A brief description of the commonly applied technologies for energy generation from waste is as follows
Anaerobic Digestion/Biomethanation
In this process, the organic fraction of the waste is segregated and fed into a closed container (biogas digester). In the digester, the segregated waste undergoes biodegradation in presence of methanogenic bacteria and under anaerobic conditions, producing methane-rich biogas and effluent. The biogas can be used either for cooking/heating applications, or for generating motive power or electricity through dual-fuel or gas engines, low-pressure gas turbines, or steam turbines. The sludge from anaerobic digestion, after stabilization, can be used as a soil conditioner. It can even be sold as manure depending upon its composition, which is determined mainly by the composition of the input waste.
Combustion/Incineration
In this process, wastes are directly burned in presence of excess air (oxygen) at high temperatures (about 800°C), liberating heat energy, inert gases, and ash. Combustion results in transfer of 65%–80% of heat content of the organic matter to hot air, steam, and hot water. The steam generated, in turn, can be used in steam turbines to generate power.
Pyrolysis/Gasification
Pyrolysis is a process of chemical decomposition of organic matter brought about by heat. In this process, the organic material is heated in absence of air until the molecules thermally break down to become a gas comprising smaller molecules (known collectively as syngas).
Gasification can also take place as a result of partial combustion of organic matter in presence of a restricted quantity of oxygen or air. The gas so produced is known as producer gas. The gases produced by pyrolysis mainly comprise carbon monoxide (25%), hydrogen and hydrocarbons (15%), and carbon dioxide and nitrogen (60%). The next step is to ‘clean’ the syngas or producer gas. Thereafter, the gas is burned in internal combustion (IC) engine generator sets or turbines to produce electricity.
Landfill Gas recovery
The waste dumped in a landfill becomes subjected, over a period of time, to anaerobic conditions. As a result, its organic fraction slowly volatilizes and decomposes, leading to production of ‘landfill gas’, which contains a high percentage of methane (about 50%). It can be used as a source of energy either for direct heating/cooking applications or to generate power through IC engines or turbines.
Analysis of Key Aspects of Waste to Energy Technologies
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Criteria |
Incineration |
Anaerobic Digestion |
Gasification/Pyrolysis |
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A |
Feedstock |
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Industrial |
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Liquid |
Not suitable |
Suitable |
Not suitable |
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Solid |
Suitable |
Not suitable |
Suitable |
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Urban |
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Liquid |
Not suitable |
Suitable |
Not suitable |
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Solid |
Suitable |
Suitable |
Suitable |
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Farm |
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Poultry |
Suitable |
Suitable |
Suitable |
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Cattle |
Suitable |
Suitable |
Suitable |
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B |
Technology features |
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Technology status |
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Industrial |
Proven |
Proven |
Emerging |
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Urban |
Proven |
Proven |
Emerging |
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Farm |
Proven |
Proven |
Proven |
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Energy efficiency |
85-90% (Based on calorific value) |
50-60% (Based on volatiles) |
90-95% (Based on calorific value) |
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C |
Operating conditions |
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System configuration |
Complex |
Simple |
Complex |
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Process Flexibility |
Low |
Good |
Low |
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Modular |
Yes |
Yes |
Yes |
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D |
Capital, O & M costs |
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Relative capital cost |
Very high |
Medium-high |
Very High |
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O & M |
High |
Low |
Limited |
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Commercial viability |
Less viable than others owing to costly downstream air pollution control |
Readily viable |
Varies considerably |
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Captive power requirements |
Significant (25-30%) |
Low (5%) |
Variable (5-20%) |
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Area requirements |
Elaborate |
Compact |
Compact |
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E |
Environmental impacts |
Can be minimized, but requires expensive technology investments |
Minimum |
Can be controlled to a significant extent |
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F |
Socio-economic impacts |
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Public acceptability |
Not fully satisfactory |
Satisfactory |
Satisfactory |
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Waste disposal |
Complete, except for ash to landfill. |
Complete except for sludge stabilization |
Complete, except for ash |
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Source: MNRE (http://mnre.gov.in/nmp/technology-we.pdf), with additional research from EAI
Technology Options for Energy Recovery from Waste
Technological Routes for the Recovery of Energy from MSW
Technological Routes for Energy Recovery from Sewage
Technological Routes for Energy Recovery from Fecal Sludge