Waste-to-Energy
Incineration Anaerobic Digestion Gasification Ethanol Fuel Pyrolysis Oil Plasma Arc Mechanical Biological Refuse Derived Fuel

Incineration is a waste treatment technology that involves the combustion of organic materials and/or substances.^[1] Incineration and other high temperature waste treatment systems are described as "thermal treatment". Incineration of waste materials converts the waste into incinerator bottom ash, flue gases, particulates, and heat, which can in turn be used to generate electric power. The flue gases are cleaned of pollutants before they are dispersed in the atmosphere.

Incineration with energy recovery is one of several waste-to-energy (WtE) technologies such as gasification, Plasma arc gasification, pyrolysis and anaerobic digestion. Incineration may also be implemented without energy and materials recovery.

In several countries there are still expert and local community concerns about the environmental impact of incinerators (see The argument against incineration).

In some countries, incinerators built just a few decades ago often did not include a materials separation to remove hazardous, bulky or recyclable materials before combustion. These facilities tended to risk the health of the plant workers and the local environment due to inadequate levels of gas cleaning and combustion process control. Most of these facilities did not generate electricity.

Incinerators reduce the volume of the original waste by 95-96 %, depending upon composition and degree of recovery of materials such as metals from the ash for recycling.^[2] This means that while incineration does not completely replace landfilling, it reduces the necessary volume for disposal significantly.

Incineration has particularly strong benefits for the treatment of certain waste types in niche areas such as clinical wastes and certain hazardous wastes where pathogens and toxins can be destroyed by high temperatures. Examples include chemical multi-product plants with diverse toxic or very toxic wastewater streams, which cannot be routed to a conventional wastewater treatment plant.

Waste combustion is particularly popular in countries such as Japan where land is a scarce resource. Denmark and Sweden have been leaders in using the energy generated from incineration for more than a century, in localised combined heat and power facilities supporting district heating schemes.^[3] In 2005, waste incineration produced 4.8 % of the electricity consumption and 13.7 % of the total domestic heat consumption in Denmark.^[4] A number of other European Countries rely heavily on incineration for handling municipal waste, in particular Luxemburg, The Netherlands, Germany and France. ^[2]

For more information see the following links:

• Incineration Technology


• Incineration Pollution and Emissions


• Incineration Pros & Cons

Incinaration Gallery

Control room of a typical moving grate incinerator overseeing two boiler lines SYSAV incineration plant in Malmö, Sweden capable of handling 25 tonnes per hour household waste. To the left of the stack, a new identical oven line is under construction (March 2007).

Spittelau incineration plant in Vienna. Municipal solid waste in the furnace of a moving grate incinerator capable of handling 15 tons of waste per hour. The holes in the grate elements supplying the primary combustion air are visible.

Decomissioned Kwai Chung Incineration Plant from 1978 An example of a low capacity, mobile incinerator.