Material recovery: Difference between revisions

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{{infobox4
'''Material recovery''' is also known as materials recycling. It is a [[method]] consisting of chemical, thermal, mechanical or biological processing of the waste to regain materials or energy [[product]] for secondary use. It is related to [[environmental]] [[management]]. [[Resource recovery]] reduces amount of solid waste. The biggest environmental improvement comes from reduced energy consumption <ref> Alter H., 1983, p.1</ref>.</p>
|list1=
<ul>
<li>[[Waste stream]]</li>
<li>[[Non recurring cost]]</li>
<li>[[Environmental problem]]</li>
<li>[[Non value added activity]]</li>
<li>[[Closed loop recycling]]</li>
<li>[[Waste management]]</li>
<li>[[Returns of goods, waste and recyclables logistics subsystem]]</li>
<li>[[Life cycle assessment]]</li>
<li>[[Clamshell packaging]]</li>
</ul>
}}
 
 
 
'''Material recovery''' is also known as materials recycling. It is a [[method]] consisting of chemical, thermal, mechanical or biological processing of the waste to regain materials or energy [[product]] for secondary use. It is related to environmental [[management]]. [[Resource recovery]] reduces amount of solid waste. The biggest environmental improvement comes from reduced energy consumption <ref> Alter H., 1983, p.1</ref>.</p>


Material recovery from mixed household waste may cause reductions in [[resource]] consumption and fossil fuel. To this end legislation has been introduced to promote recycling and energy recovery. Potential terminations for separating recyclable and biogenic materials are conducted by '''waste refineries''' <ref>Tonini D., Dorini G & Astrup T.F,2014, p.64-78</ref>.</p>
Material recovery from mixed household waste may cause reductions in [[resource]] consumption and fossil fuel. To this end legislation has been introduced to promote recycling and energy recovery. Potential terminations for separating recyclable and biogenic materials are conducted by '''waste refineries''' <ref>Tonini D., Dorini G & Astrup T.F,2014, p.64-78</ref>.</p>
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* In Situ Vacuum Extractions,
* In Situ Vacuum Extractions,
* Pumping and Recovery,
* Pumping and Recovery,
* Freeze- Crystallization,
* Freeze - Crystallization,
* Chemolisys,
* Chemolisys,
* Thermolysis.
* Thermolysis.
Line 44: Line 27:
* Reduces energy use.
* Reduces energy use.


== Footnotes ==
==Examples of Material recovery==
* '''Mechanical recycling''': Mechanical recycling is the [[process]] of recovering materials from end of life products and reusing them as raw materials for manufacturing new products. This type of recycling involves sorting, shredding and washing of materials before remolding them into new products. Examples of mechanical recycling include glass recycling, paper recycling, plastic recycling, aluminum recycling, and textile recycling.
* '''Biological recycling''': Biological recycling is the process of breaking down organic materials and using them as a source of natural energy or fertilizer. Examples of biological recycling include composting, vermicomposting, anaerobic digestion, and biogas [[production]].
* '''Thermal recycling''': Thermal recycling is the process of recovering heat energy from waste materials. Examples of thermal recycling include energy-from-waste (EfW) technologies such as incineration, pyrolysis, and gasification.
* '''Chemical recycling''': Chemical recycling is the process of breaking down waste materials into their constituent molecules and then converting them into new materials or fuels. Examples of chemical recycling include depolymerization, hydrothermal liquefaction, and supercritical fluid extraction.
 
==Limitations of Material recovery==
Material recovery has the potential to reduce waste and energy consumption, however, it is not without its limitations. These limitations include:
* High [[cost]] of upfront [[investment]] in equipment and facilities - The cost of purchasing, operating and maintaining the necessary equipment and facilities for material recovery can be considerable.
* Lack of infrastructure - In less developed countries, the lack of infrastructure for collection of materials and waste may limit the effectiveness of material recovery.
* Limited markets for recycled materials - In some cases, the recycling of certain materials may be limited by poor markets for the recycled materials.
* Limited capacity and [[technology]] - Due to limited capacity and technology, certain materials may not be suitable for recovery.
* Contamination of materials - The contamination of materials during the recovery process can render them unsuitable for further use.
* Health and safety concerns - In some cases, the recovery process can present a [[risk]] to the health and safety of workers.
 
==Other approaches related to Material recovery==
Material recovery is a method of reclaiming materials or energy products for secondary use through chemical, thermal, mechanical or biological processing of the waste. Other approaches related to material recovery include:
* '''Source reduction''': a method of reducing the amount of waste generated by eliminating, minimizing, or substituting hazardous materials.
* '''Composting''': the decomposition of organic materials to produce a nutrient-rich soil amendment.
* '''Incineration''': the burning of solid waste to reduce its volume.
* '''Recycling''': the process of collecting, sorting, and processing materials to be used again.
* '''Landfilling''': the disposal of solid waste in a secure and environmentally responsible manner.
 
In summary, material recovery is a method used to reclaim materials or energy products for secondary use, and is related to environmental management. Other approaches related to material recovery include source reduction, composting, incineration, recycling, and landfilling.
 
==Footnotes==
<references />  
<references />  


== References ==
{{infobox5|list1={{i5link|a=[[Integrated waste management]]}} &mdash; {{i5link|a=[[Alternative technology]]}} &mdash; {{i5link|a=[[Trade waste]]}} &mdash; {{i5link|a=[[Clean fuel]]}} &mdash; {{i5link|a=[[Recovered material]]}} &mdash; {{i5link|a=[[Conservation of resources]]}} &mdash; {{i5link|a=[[Trade effluent]]}} &mdash; {{i5link|a=[[Functional obsolescence]]}} &mdash; {{i5link|a=[[Primary sector of the economy]]}} }}
 
==References==
* Alter H., (1983) ''[https://books.google.pl/books?id=gsqKQk8slBsC&pg=PA266&lpg=PA266&dq=Materials+Recovery+from+Municipal+Waste:+Unit+Operations+in+Practice,+Marcel+Dekker+INC,+New+York+and+Basel&source=bl&ots=aBHhu_gyzi&sig=ACfU3U132B9rrJxDBvJTIx5F4khMzoFu4Q&hl=pl&sa=X&ved=2ahUKEwif8r7V783hAhUBi8MKHWDSBTgQ6AEwAHoECAgQAQ#v=onepage&q=Materials%20Recovery%20from%20Municipal%20Waste%3A%20Unit%20Operations%20in%20Practice%2C%20Marcel%20Dekker%20INC%2C%20New%20York%20and%20Basel&f=false Materials Recovery from Municipal Waste: Unit Operations in Practice]'', Marcel Dekker INC, New York and Basel
* Alter H., (1983) ''[https://books.google.pl/books?id=gsqKQk8slBsC&pg=PA266&lpg=PA266&dq=Materials+Recovery+from+Municipal+Waste:+Unit+Operations+in+Practice,+Marcel+Dekker+INC,+New+York+and+Basel&source=bl&ots=aBHhu_gyzi&sig=ACfU3U132B9rrJxDBvJTIx5F4khMzoFu4Q&hl=pl&sa=X&ved=2ahUKEwif8r7V783hAhUBi8MKHWDSBTgQ6AEwAHoECAgQAQ#v=onepage&q=Materials%20Recovery%20from%20Municipal%20Waste%3A%20Unit%20Operations%20in%20Practice%2C%20Marcel%20Dekker%20INC%2C%20New%20York%20and%20Basel&f=false Materials Recovery from Municipal Waste: Unit Operations in Practice]'', Marcel Dekker INC, New York and Basel
* Marmolejo L.F., Diaz L.F., Torres P., García M., Burbano M.H., Blanco C., Erazo K., Pereira J.F, (2010) ''[https://www.mdpi.com/2071-1050/2/7/2070/pdf Influence of Handling Practices on Material Recovery from Residential Solid Waste]'', Sustainability, MDPI, Open Access Journal, vol. 2(7),July.
* Marmolejo L.F., Diaz L.F., Torres P., García M., Burbano M.H., Blanco C., Erazo K., Pereira J.F, (2010) ''[https://www.mdpi.com/2071-1050/2/7/2070/pdf Influence of Handling Practices on Material Recovery from Residential Solid Waste]'', Sustainability, MDPI, Open Access Journal, vol. 2(7),July.
* Means J., Smith L., (1994) ''[https://books.google.pl/books?id=qWEB53PvUdoC&pg=PA7&dq=material+recovery&hl=pl&sa=X&ved=0ahUKEwij55D-xb7hAhWww4sKHU15DgwQ6AEIYjAJ#v=onepage&q=material%20recovery&f=false Recycling and Reuse of Material Found on Superfund Sites]'', United States Environmental Protection Agency  
* Means J., Smith L., (1994) ''[https://books.google.pl/books?id=qWEB53PvUdoC&pg=PA7&dq=material+recovery&hl=pl&sa=X&ved=0ahUKEwij55D-xb7hAhWww4sKHU15DgwQ6AEIYjAJ#v=onepage&q=material%20recovery&f=false Recycling and Reuse of Material Found on Superfund Sites]'', United States Environmental Protection Agency  
* Miller G.T., Spoolman S.E, (2012) ''[https://books.google.pl/books?id=TRgYq3s-cf4C&pg=PT312&dq=advantages+recycle&hl=pl&sa=X&ved=0ahUKEwiiqIrczL7hAhXwpYsKHQT5BPAQ6AEIKDAA#v=onepage&q=advantages%20recycle&f=false Cengage Advantage Books: Sustaining the Earth]'' Brooks/Cole, Cengage Learning
* Miller G.T., Spoolman S.E, (2012) ''[https://books.google.pl/books?id=TRgYq3s-cf4C&pg=PT312&dq=advantages+recycle&hl=pl&sa=X&ved=0ahUKEwiiqIrczL7hAhXwpYsKHQT5BPAQ6AEIKDAA#v=onepage&q=advantages%20recycle&f=false Cengage Advantage Books: Sustaining the Earth]'' Brooks/Cole, Cengage Learning

Latest revision as of 00:39, 18 November 2023

Material recovery is also known as materials recycling. It is a method consisting of chemical, thermal, mechanical or biological processing of the waste to regain materials or energy product for secondary use. It is related to environmental management. Resource recovery reduces amount of solid waste. The biggest environmental improvement comes from reduced energy consumption [1].

Material recovery from mixed household waste may cause reductions in resource consumption and fossil fuel. To this end legislation has been introduced to promote recycling and energy recovery. Potential terminations for separating recyclable and biogenic materials are conducted by waste refineries [2].

People have to be aware of sanitary and environmental benefits of the material recovery. It is needed to propagate a reuse of materials and decrease in consumption patterns [3].

Recycling Technologies

There are the following types of recycling technologies [4] :

  • Distillation,
  • Energy recovery,
  • Decanting,
  • Thermal desorption,
  • Solvent extraction,
  • Use a Construction Material,
  • In Situ Vacuum Extractions,
  • Pumping and Recovery,
  • Freeze - Crystallization,
  • Chemolisys,
  • Thermolysis.

Advantages of recycling

Recycling provides the following advantages [5]:

  • Reduces solid waste,
  • Limits greenhouse gas emission,
  • Can save space on garbage dump,
  • Limits water and air pollution,
  • Reduces energy use.

Examples of Material recovery

  • Mechanical recycling: Mechanical recycling is the process of recovering materials from end of life products and reusing them as raw materials for manufacturing new products. This type of recycling involves sorting, shredding and washing of materials before remolding them into new products. Examples of mechanical recycling include glass recycling, paper recycling, plastic recycling, aluminum recycling, and textile recycling.
  • Biological recycling: Biological recycling is the process of breaking down organic materials and using them as a source of natural energy or fertilizer. Examples of biological recycling include composting, vermicomposting, anaerobic digestion, and biogas production.
  • Thermal recycling: Thermal recycling is the process of recovering heat energy from waste materials. Examples of thermal recycling include energy-from-waste (EfW) technologies such as incineration, pyrolysis, and gasification.
  • Chemical recycling: Chemical recycling is the process of breaking down waste materials into their constituent molecules and then converting them into new materials or fuels. Examples of chemical recycling include depolymerization, hydrothermal liquefaction, and supercritical fluid extraction.

Limitations of Material recovery

Material recovery has the potential to reduce waste and energy consumption, however, it is not without its limitations. These limitations include:

  • High cost of upfront investment in equipment and facilities - The cost of purchasing, operating and maintaining the necessary equipment and facilities for material recovery can be considerable.
  • Lack of infrastructure - In less developed countries, the lack of infrastructure for collection of materials and waste may limit the effectiveness of material recovery.
  • Limited markets for recycled materials - In some cases, the recycling of certain materials may be limited by poor markets for the recycled materials.
  • Limited capacity and technology - Due to limited capacity and technology, certain materials may not be suitable for recovery.
  • Contamination of materials - The contamination of materials during the recovery process can render them unsuitable for further use.
  • Health and safety concerns - In some cases, the recovery process can present a risk to the health and safety of workers.

Other approaches related to Material recovery

Material recovery is a method of reclaiming materials or energy products for secondary use through chemical, thermal, mechanical or biological processing of the waste. Other approaches related to material recovery include:

  • Source reduction: a method of reducing the amount of waste generated by eliminating, minimizing, or substituting hazardous materials.
  • Composting: the decomposition of organic materials to produce a nutrient-rich soil amendment.
  • Incineration: the burning of solid waste to reduce its volume.
  • Recycling: the process of collecting, sorting, and processing materials to be used again.
  • Landfilling: the disposal of solid waste in a secure and environmentally responsible manner.

In summary, material recovery is a method used to reclaim materials or energy products for secondary use, and is related to environmental management. Other approaches related to material recovery include source reduction, composting, incineration, recycling, and landfilling.

Footnotes

  1. Alter H., 1983, p.1
  2. Tonini D., Dorini G & Astrup T.F,2014, p.64-78
  3. Marmolejo L.F., Diaz L.F., Torres P., García M., Burbano M.H., Blanco C., Erazo K., Pereira J.F, 2010, p.12
  4. Smoley C.K., 1993 p.11-32
  5. Miller G.T., 2012, p.291


Material recoveryrecommended articles
Integrated waste managementAlternative technologyTrade wasteClean fuelRecovered materialConservation of resourcesTrade effluentFunctional obsolescencePrimary sector of the economy

References

Author: Agnieszka Bednarek