Aluminium recycling is the process in which secondary commercial aluminium is created from scrap or other forms of end-of-life or otherwise unusable aluminium.[1] It involves re-melting the metal, which is cheaper and more energy-efficient than the production of virgin aluminium by electrolysis of alumina (Al2O3) refined from raw bauxite by use of the Bayer and Hall–Héroult processes.

An aluminium recycling symbol.
The European Committee for Standardization logo for aluminium recycling.

Recycling scrap aluminium requires only 5% of the energy used to make new aluminium from the raw ore.[2] In 2022, the United States produced 3.86 metric tons of secondary aluminium for every metric ton of primary aluminium produced. Over the same time period, secondary aluminium accounted for 34% of the total new supply of aluminium including imports.[3] Used beverage containers are the largest component of processed aluminium scrap, and most of it is manufactured back into aluminium cans.[4]

Recycling process

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Collection & sorting

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The first step in aluminium recycling is the collection and sorting of aluminium scrap from various sources.[5] Scrap aluminium comes primarily from either manufacturing scrap or end-of-life aluminium products such as vehicles, building materials, and consumer products.[5] Manufacturing scrap includes shreds, shavings, cuttings, and other leftover aluminium from manufacturing processes. Post-consumer scrap consists of obsolete or discarded aluminium products. Aluminium cans,[6] in particular, are a major source of recyclable aluminium scrap. Once collected, aluminium scrap is sorted based on alloy type, grade, impurity levels, and other factors.[6] Sorting may be done manually or using technologies like eddy current separators, air classifiers, and density separators.[7] The scrap is sorted into categories like wrought alloy scrap, casting alloy scrap, used beverage cans, automobile scrap, and mixed scrap. Proper sorting is essential for producing high-quality recycled aluminium.

Pre-treatment

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After sorting, the scrap may undergo pre-treatment processes to prepare it for melting.[8] These can include baling, shredding, crushing, granulating, decoating, and demagnetizing.[9] Shredding and crushing reduce the particle size of the scrap and liberate it from other materials, while granulating produces fine particles ideal for melting.[10] Thermal decoating removes coatings like paint and plastic from aluminium surfaces.[7] Demagnetizing removes iron particles clinging to the aluminium scrap. Pre-treatment improves the density of the scrap charge and removes contaminants, resulting in faster melting, cleaner metal, reduced dross formation, and lower energy consumption.[11]

Melting

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Once pre-treated, the aluminium scrap undergoes melting and liquid metal treatment to produce refined aluminium alloy suitable for casting or reprocessing.[11] Different furnace types are used based on the type of scrap, desired metal quality, and economics. Smaller scrap is typically processed in rotary or reverberatory gas-fired furnaces, while large individual pieces of scrap can be charged directly into reverb furnaces through side wells.[10] Electric induction furnaces are also used. As the scrap melts, fluxes are added to bind and absorb impurities which are scraped off the top as dross. Chlorine gas may also be injected to remove impurities through flotation. The melt can then undergo refining processes like flux injection to further reduce hydrogen and impurities. Degassing removes dissolved hydrogen while chemical filtration removes solid impurities and inclusions. The final result is molten aluminium alloy ready for casting.[12]

Casting

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The molten recycled aluminium is cast into solid forms such as ingots, sows, or directly into sheets or extrusion billets. Direct-chill casting is commonly used to solidify the liquid aluminium into large cylindrical billets for extrusion or rolling.[7] The direct chill method sprays water onto the hot metal as it exits the mold, quickly chilling it into a solid billet form.[13] For ingots, book molds are often used, producing slabbed ingots suitable for remelting or rolling.[14] Continuous casting directly shapes the aluminium into rolling slabs without an intermediate ingot casting step. Twin-belt or twin-roll strip casting produces alloy strips 6-7mm thick directly from the melt for subsequent rolling. The casting method depends on the subsequent processing and use of the recycled aluminium alloy.[15]

History

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Model promoting aluminium recycling at Douglas Aircraft Company in 1942

Although aluminium in its pure form has been produced as early as 1825,[16] secondary aluminium production, or recycling, rose in volume with the introduction of industrially viable primary aluminium processes, namely the combination of the Bayer and Hall-Héroult processes. The Hall-Héroult process for aluminium production from alumina was invented in 1886 by Charles Hall and Paul Héroult.[17] Carl Josef Bayer created a multi-step process to convert raw Bauxite into alumina in 1888.[18] As aluminium production rose with the use of these two processes, aluminium recycling grew too. In 1904, the first two aluminium can recycling plants were built in the United States; one recycling plant was built in Chicago, Illinois and the other was built in Cleveland, Ohio.[19] Aluminium recycling increased most significantly in volume when metal resources were strained during WWI, as the U.S. government campaigned for civilians to donate old products such as aluminium pots, pans, boats, vehicles, and toys to recycle for the construction of aluminium airframes.[19]

Advantages

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Aluminium is an infinitely recyclable material, and it takes up to 95 percent less energy to recycle it than to produce primary aluminium, which also limits emissions, including greenhouse gases. Today, about 75 percent of all aluminium produced in history, nearly a billion tons, is still in use.[20]

Hydraulic press and baled cans prepared for transport

The recycling of aluminium generally produces significant cost savings over the production of new aluminium, even when the cost of collection, separation and recycling are taken into account.[21] Over the long term, even larger national savings are made when the reduction in the capital costs associated with landfills, mines, and international shipping of raw aluminium are considered.

Energy savings

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Recycling aluminium uses about 5% of the energy required to create aluminium from bauxite;[22] the amount of energy required to convert aluminium oxide into aluminium can be vividly seen when the process is reversed during the combustion of thermite or ammonium perchlorate composite propellant.

Aluminium die extrusion is a specific way of getting reusable material from aluminium scraps but does not require a large energy output of a melting process. In 2003, half of the products manufactured with aluminium were sourced from recycled aluminium material.[23]

Environmental savings

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The benefit with respect to emissions of carbon dioxide depends in part on the type of energy used. Electrolysis can be done using electricity from non-fossil-fuel sources, such as nuclear, geothermal, hydroelectric, or solar. Aluminium production is attracted to sources of cheap electricity. Canada, Brazil, Norway, and Venezuela have 61 to 99% hydroelectric power and are major aluminium producers. However the anodes widely used in the Hall–Héroult process are made of carbon and are consumed during aluminium production, generating large quantities of carbon dioxide, regardless of electricity source.[24] Efforts are underway to eliminate the need for carbon anodes.[25] The use of recycled aluminium also decreases the need for mining and refining bauxite.

The vast amount of aluminium used means that even small percentage losses are large expenses, so the flow of material is well monitored and accounted for financial reasons. Efficient production and recycling benefits the environment as well.[26]

Impact

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Environmental

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Because many countries continue to rely on coal-generated electricity for aluminium production, the aluminium industry contributes to 2% of global greenhouse gas emissions, around 1.1 billion tons of carbon dioxide.[27] Many countries now seek to decarbonize aluminium not only as it is the second most used metal in the world, but also because it would heavily address the total greenhouse gas emissions in an effort to slow climate change.[28]

As one of the most recyclable –and recycled– materials in use today, aluminium can be virtually infinitely recycled. Since recycled aluminium takes 5% of the energy used to make new aluminium, around 75% of aluminium manufactured continues to be in use today.[29] According to the Aluminium Association, in industrial markets such as automotive and building, aluminium is recycled at rates of up to 90%.

Since 1991, greenhouse gas emissions from aluminium cans have dropped about 40%, similar to energy demand levels. This can be attributed to a reduction in the carbon intensity of primary aluminium production, improving the efficacy of manufacturing operations, and lighter cans.[30] While primary aluminium only accounts for 26.6% of the can, it makes up the major source of the can's carbon footprint. For example, as of 2020, 86% of China's aluminium production relies mostly on coal-generated electricity. On the other hand, Canada sources roughly 90% of its primary aluminium production using hydroelectric power, considering it to be the most sustainable in the world.[28]

Aluminium and its applications are wide and numerous–from defense construction and electrical transmission to playing a key role in emission-reducing goods (electric vehicles and solar panels). As such, countries have begun to decarbonize aluminium to combat global climate change.

Economic

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Aluminium recycling has several economic benefits when done properly. In fact, the Environmental Protection Agency considers recycling a "critical" part of the United States economy, contributing to tax revenue, wages, and job creation.[31] By facilitating scrap handling and improving its efficiency – from "end of life" scrap to repurposing scrap throughout the production stage ("in-house" scrap) – aluminium recycling helps in achieving the goals of a circular economy.[32] This type of economy focuses on minimizing the extraction of natural resources, leading to a reduction of consumer and industrial waste. A few examples of countries that have adopted the shift to a circular economy include the European Union, Finland, France, Slovenia, Italy, Germany, and the Netherlands.[33]

A recent study conducted within the United States has highlighted some ways that aluminium recycling has proven to have economic benefits, including:

  • Job creation: Contributing to more than 100,000 jobs in the reprocessing to the United States economy.
  • Economic activity: Bring about $1.6 billion in material sales
  • Wage increases: Increasing the wages of waste management and the recycling industry from $2.1 billion to $5 billion.
  • Energy conservation: Save enough energy to power 1.5 million homes per year.
  • Waste management: Maintain more than 1 million tons of waste out of landfills every year.

As countries take note of the various economic and environmental benefits of aluminium recycling, increased efforts are expected to improve the efficacy of this process.

Recycling rates

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According to 2020 data from the International Aluminium Institute, the global recycling efficiency rate is 76%. Around 75% of the almost 1.5 billion tonnes of aluminium ever produced is still in productive use today.[34]

Brazil recycles 98.2% of its aluminium can production, equivalent to 14.7 billion beverage cans per year,[35] ranking first in the world, more than Japan's 82.5% recovery rate. Brazil has topped the aluminium can recycling charts eight years in a row.[36]

Europe

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Recycling rate for aluminium beverage cans
Country 2021[37]
  Austria 71%
  Belgium 94%
  Bulgaria 83%
  Croatia 80%
  Cyprus 28%
  Czech Republic 51%
  Denmark 84%
  Estonia 89%
  Finland 97%
  France 48%
  Germany 99%
  Greece 60%
  Hungary 42%
  Iceland 91%
  Ireland 62%
  Italy 90%
  Latvia 49%
  Lithuania 87%
  Luxembourg 82%
  Malta 50%
  Netherlands 82%
  Norway 92%
  Poland 79%
  Portugal 36%
  Romania 35%
  Slovakia 58%
  Slovenia 64%
  Spain 67%
  Sweden 90%
   Switzerland 92%
  United Kingdom 82%
  Europe 76.1%

Challenges

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Aside from recycled aluminium beverage cans, the majority of recycled aluminium comes in a mixture of different alloys. Those alloys generally have high percentages of silicon (Si) and require additional refinement during the shredding, sorting, and refining process to reduce impurities. Due to the levels of impurities found after refinement, the applications of recycled aluminium alloys are limited to castings and extrusions. The aerospace industry often restrict impurity levels of Si and Fe in alloys to a 0.40% maximum. Controlling the appearance of these elements is increasingly difficult the more often the metal has been recycled and require higher cost operations for the alloys to meet performance requirements.[38]

Byproducts

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White dross, a residue from primary aluminium production and secondary recycling operations, usually classified as waste,[39] still contains useful quantities of aluminium which can be extracted industrially.[40] The process produces aluminium billets, together with a highly complex waste material. This waste is difficult to manage. It reacts with water, releasing a mixture of gases (including, among others, hydrogen, acetylene, and ammonia) which spontaneously ignites on contact with air;[41] contact with damp air results in the release of copious quantities of ammonia gas. Despite these difficulties, however, the waste has found use as a filler in asphalt and concrete.[42]

See also

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References

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  1. ^ Wallace, G. (2011-01-01), Lumley, Roger (ed.), "4 - Production of secondary aluminium", Fundamentals of Aluminium Metallurgy, Woodhead Publishing Series in Metals and Surface Engineering, Woodhead Publishing, pp. 70–82, doi:10.1533/9780857090256.1.70, ISBN 978-1-84569-654-2, retrieved 2023-11-06
  2. ^ "The price of virtue". The Economist. ISSN 0013-0613. Retrieved 2023-11-06.
  3. ^ "Aluminum Statistics and Information | U.S. Geological Survey". www.usgs.gov. Retrieved 2023-11-06.
  4. ^ "Land, Waste, and Cleanup Topics". United States Environmental Protection Agency.
  5. ^ a b Falde, Nathan (2018-08-16). "How is Aluminum Recycled? Step by Step | Greentumble". Retrieved 2023-11-06.
  6. ^ a b "Aluminum Recycling". American Chemical Society. Retrieved 2023-11-06.
  7. ^ a b c Capuzzi, Stefano; Timelli, Giulio (April 2018). "Preparation and Melting of Scrap in Aluminum Recycling: A Review". Metals. 8 (4): 249. doi:10.3390/met8040249. ISSN 2075-4701.
  8. ^ Provider, Aluminum Machinery Total Solution. "Seven things your competitors know about aluminum scrap pretreatment process". Brightstar Aluminum Machinery. Retrieved 2023-11-06.
  9. ^ Vallejo-Olivares, Alicia; Høgåsen, Solveig; Kvithyld, Anne; Tranell, Gabriella (2022-12-01). "Thermal De-coating Pre-treatment for Loose or Compacted Aluminum Scrap and Consequences for Salt-Flux Recycling". Journal of Sustainable Metallurgy. 8 (4): 1485–1497. Bibcode:2022JSusM...8.1485V. doi:10.1007/s40831-022-00612-x. hdl:11250/3029143. ISSN 2199-3831.
  10. ^ a b "Effective recovery & quality improvement of aluminium scrap • STEINERT". steinertglobal.com. Retrieved 2023-11-06.
  11. ^ a b "Aluminium Recycling – Processes". The International Aluminium Institute. Retrieved 2023-11-06.
  12. ^ Yang, Yongxiang; Xiao, Yanping; Zhou, Bo; Reuter, Markus A. "Aluminium Recycling: Scrap Melting and Process Simulation". ResearchGate.
  13. ^ "Aluminum Recycling and Secondary Processing". Light Metal Age Magazine. 2021-08-17. Retrieved 2023-11-06.
  14. ^ dolincasting (2021-08-17). "Aluminum Casting Techniques and Processes". Dolin Aluminum Casting. Retrieved 2023-11-06.
  15. ^ Fiore, S.; Zanetti, M. C.; Ruffino, B. (2005-09-01). "Waste characterization and recycle in an aluminium foundry". Resources, Conservation and Recycling. 45 (1): 48–59. Bibcode:2005RCR....45...48F. doi:10.1016/j.resconrec.2005.01.006. ISSN 0921-3449.
  16. ^ Kvande, Halvor (2008-08-01). "Two hundred years of aluminum ... or is it aluminium?". JOM. 60 (8): 23–24. Bibcode:2008JOM....60h..23K. doi:10.1007/s11837-008-0102-3. ISSN 1543-1851. S2CID 135517326.
  17. ^ Reverdy, Michel; Potocnik, Vinko (2020). "History of Inventions and Innovations for Aluminum Production". TMS 2020 149th Annual Meeting & Exhibition Supplemental Proceedings. The Minerals, Metals & Materials Series. Cham: Springer International Publishing. pp. 1895–1910. doi:10.1007/978-3-030-36296-6_175. ISBN 978-3-030-36296-6. S2CID 213788259.
  18. ^ Habashi, Fathi. "Bayer's process process for Alumina Production: A Historical Perspective" (PDF). Bull. Hist. Chem.
  19. ^ a b Byers, Ann (2017-12-15). Reuse It: The History of Modern Recycling. Cavendish Square Publishing, LLC. ISBN 978-1-5026-3127-5.
  20. ^ Bertram; Ramkumar; Rechberger; Rombach; Bayliss; Martchek; Müller; Liu (October 2017). "A regionally-linked, dynamic material flow modelling tool for rolled, extruded and cast aluminium products". Resources, Conservation and Recycling. 125: 48–69. Bibcode:2017RCR...125...48B. doi:10.1016/j.resconrec.2017.05.014. Retrieved October 17, 2024.
  21. ^ "International Aluminum Institute" (PDF). Archived from the original (PDF) on 2022-04-23. Retrieved 2010-02-09.
  22. ^ "Sustainability – Recycling | Aluminum Association". www.aluminum.org. Retrieved 2023-11-06.
  23. ^ "Manufacturing with Die Casting: An Eco-Friendly Option". NADCA Design. 2017-01-21. Archived from the original on 2022-10-07. Retrieved 2017-03-08.
  24. ^ Khaji, Khalil; Al Qassemi, Mohammed (2016). "The Role of Anode Manufacturing Processes in Net Carbon Consumption". Metals. 6 (6): 128. doi:10.3390/met6060128.
  25. ^ Clemence, Christopher (April 2, 2019). "Leaders Emerge In The Aluminium Industry's Race To Zero Carbon". Aluminium Insider.
  26. ^ "Aluminium organisation: Environmental issues". Archived from the original on 2010-10-06. Retrieved 2010-11-28.
  27. ^ "Why addressing the aluminium industry's carbon footprint is key". World Economic Forum. 2020-11-30. Retrieved 2023-11-06.
  28. ^ a b Reinsch, William Alan; Benson, Emily (2022-02-25). "Decarbonizing Aluminum: Rolling Out a More Sustainable Sector". Center for Strategic and International Studies.
  29. ^ "Sustainability – Recycling". www.aluminum.org. Retrieved 2023-11-06.
  30. ^ "Aluminum Can Life Cycle Assessment Report Overview" (PDF). 2021.
  31. ^ "Recycling Economic Information (REI) Report". EPA United States Environmental Protection Agency. August 4, 2023. Retrieved November 6, 2023.
  32. ^ Rajeev, Vikram (2021-08-10). "Economic Benefits and Circular Economy Leads to Rising Popularity of Aluminum Recycling in APAC". Frost & Sullivan. Retrieved 2023-11-06.
  33. ^ "Which country is leading the circular economy shift?". www.ellenmacarthurfoundation.org. 2021-06-28. Retrieved 2023-11-06.
  34. ^ "Aluminium Recycling Factsheet". International Aluminium Institute. October 2022. Retrieved 14 September 2022.
  35. ^ "In 2009, Brazil was, once again, the leading country worldwide in the collection of aluminium beverage cans, with a recycling rate of 98.2%". Alu - Aluminium for future generations. 2010. Retrieved 2013-03-26.
  36. ^ "Brazil's unemployed catadores keep recycling rates high while earning much-needed cash. - Free Online Library". Thefreelibrary.com. 2010-03-22. Retrieved 2012-11-15.
  37. ^ "Aluminium beverage can recycling in 2021 at a new record level of 76%". metalpackagingeurope.org. Retrieved 15 May 2024.
  38. ^ Das, Subodh K (2006). "Emerging Trends in Aluminum Recycling: Reasons and Responses" (PDF). Light Metals 2006. TMS (The Minerals, Metals & Materials Society).
  39. ^ "Residues from aluminium dross recycling in cement" (PDF). Archived from the original (PDF) on 2018-08-26. Retrieved 2018-06-07.
  40. ^ Hwang, J.Y., Huang, X., Xu, Z. (2006), Recovery of Metals from Aluminum Dross and Salt cake, Journal of Minerals & Materials Characterization & Engineering. Vol. 5, No. 1, pp 47-62
  41. ^ "Why are dross & saltcake a concern?". Archived from the original on 2018-06-12. Retrieved 2012-01-13.
  42. ^ Dunster, A.M., Moulinier, F., Abbott, B., Conroy, A., Adams, K., Widyatmoko, D.(2005). Added value of using new industrial waste streams as secondary aggregates in both concrete and asphalt. DTI/WRAP Aggregates Research Programme STBF 13/15C. The Waste and Resources Action Programme
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