ARCHIVES
Research Article
Investigation on Utilization of Medical Waste Ash in Concrete
Sandeep Kumar Verma1
Vipin Kumar2
1Department of Chemical Engineering, Hindustan College of Science &Technology, Farah, Mathura, Uttar Pradesh, India. 2Department of Biotechnology, Hindustan College of Science & Technology, Farah, Mathura, Uttar Pradesh, India.
Published Online: March-April 2024
Pages: 242-245
Cite this article
↗ https://www.doi.org/10.59256/ijire.20240502031
References
1. Al-Rawas AA, Hago AW, Taha R and Al-Kharousi K, “Use of incinerator ash as a replacement for cement and sand in cement mortars.”
Volume 40, Issue 9, Pages 1261–1266, 2005.
2. Altin S, Altin A, Elevli B and Cerit O, “Determination of hospital waste composition and disposal methods: a case study.” Polish
Journal of Environmental Studies Vol. 12, No. , 251-255, 2003.
3. Al-Mutairi N, Terro M and Al-Khaleefi AL, “Effect of recycling hospital ash on the compressive properties of concrete: statistical
assessment and predicting model. Building and Environment” Volume 39, Issue 5, Pages 557–566, 2004.
4. Azni I and Katayon S, “Characteristics of slag produced from incinerated hospital waste.” Volume 93, Issue 2, Pages 201–208, 2002.
5. Azni I, Katayon S, Ratnasamy M and Johari MMNM, “Stabilization and utilization of hospital waste as road and asphalt aggregate.”
Volume 7, Issue 1, pp 33-37, 2005.
6. Clozel-Leloup B, Bodenan F and Piantone P (1999). Bottom ash from municipal solid waste incineration: mineralogy and distribution
of metals, in: Mehu J, Keck G, Navarro A (ed) STAB & ENV 99.
7. Anastasiadou K, Christopoulos K, Mousios E and Gidarakos E, “Solidification/stabilization of fly and bottom ash from medical waste
incineration facility.” Volumes 207–208, Pages 165–170, 2012
8. Cobo M, Galvez A, Conesa JA and de Correa CM, “ Characterization of fly ash from a hazardous waste incinerator in Medellin,
Colombia “, Volume 168, Issues 2–3, Pages 1223–1232, 2009
9. Filipponi P, Polettini A, Pomi R and Sirini P, “Physical and mechanical properties of cement based products containing incineration
bottom ash.”, Volume 23, Issue 2, Pages 145–156,2003
10. Genazzini C, Giaccio G, Ronco A and Zerbino R, “Cement-based materials as containment systems for ash from hospital waste
incineration.”, Volume 25, Issue 6, Pages 649–654, 2005.
11. Gidarakos E, Petrantonaki M, Anastasiadou K and Schramm KW, “Characterization and hazard evaluation of bottom ash produced
from incinerated hospital waste.” Volume 172, Issues 2–3, Pages 935–942, 2009.
12. Sabiha-Javied, Tufail M and Khalid S, “Heavy metal pollution from medical waste incineration.” Volume 90, Issue 1, Pages 77–81,
2008.
13. Santarsiero A and Ottaviani M, “Evaluation of heavy metals in slags from medical waste incinerator.” Volume 51, Issues 1–2, Pages
166- 169, 1995.
14. Kaur H and Rajor Anita. “Influence of incinerated biomedical waste ash on the properties of concrete.” Volume 226, page 428-441,
2019.
15. Ramesh BM, Vongole RM, Nagraj Y, Naganna SR, Sreedhara BM, Mailar G, … & Yaseen ZM. (2021). Valorization of incinerator
bottom ash for the production of resource-efficient eco-friendly concrete: performance and toxicological characterization. Architect
Struct Construct. 1:65–78. https://doi.org/10.1007/s44150-021-00006-9
16. Mazumder EA, Prasad MLV (2022) Characterisation of eco-friendly self-compacting geopolymer concrete for fire endurance
properties. J Build Pathol Rehabil 7(1):1–10. https://doi.org/10.1007/s41024-022-00236-4.
17. Etli S (2023) Evaluation of the effect of silica fume on the fresh, mechanical and durability properties of self-compacting concrete
produced by using waste rubber as fine aggregate. J Cleaner Prod. 384:135590. https://doi.org/10.1016/j.jclepro.2022.135590.
Volume 40, Issue 9, Pages 1261–1266, 2005.
2. Altin S, Altin A, Elevli B and Cerit O, “Determination of hospital waste composition and disposal methods: a case study.” Polish
Journal of Environmental Studies Vol. 12, No. , 251-255, 2003.
3. Al-Mutairi N, Terro M and Al-Khaleefi AL, “Effect of recycling hospital ash on the compressive properties of concrete: statistical
assessment and predicting model. Building and Environment” Volume 39, Issue 5, Pages 557–566, 2004.
4. Azni I and Katayon S, “Characteristics of slag produced from incinerated hospital waste.” Volume 93, Issue 2, Pages 201–208, 2002.
5. Azni I, Katayon S, Ratnasamy M and Johari MMNM, “Stabilization and utilization of hospital waste as road and asphalt aggregate.”
Volume 7, Issue 1, pp 33-37, 2005.
6. Clozel-Leloup B, Bodenan F and Piantone P (1999). Bottom ash from municipal solid waste incineration: mineralogy and distribution
of metals, in: Mehu J, Keck G, Navarro A (ed) STAB & ENV 99.
7. Anastasiadou K, Christopoulos K, Mousios E and Gidarakos E, “Solidification/stabilization of fly and bottom ash from medical waste
incineration facility.” Volumes 207–208, Pages 165–170, 2012
8. Cobo M, Galvez A, Conesa JA and de Correa CM, “ Characterization of fly ash from a hazardous waste incinerator in Medellin,
Colombia “, Volume 168, Issues 2–3, Pages 1223–1232, 2009
9. Filipponi P, Polettini A, Pomi R and Sirini P, “Physical and mechanical properties of cement based products containing incineration
bottom ash.”, Volume 23, Issue 2, Pages 145–156,2003
10. Genazzini C, Giaccio G, Ronco A and Zerbino R, “Cement-based materials as containment systems for ash from hospital waste
incineration.”, Volume 25, Issue 6, Pages 649–654, 2005.
11. Gidarakos E, Petrantonaki M, Anastasiadou K and Schramm KW, “Characterization and hazard evaluation of bottom ash produced
from incinerated hospital waste.” Volume 172, Issues 2–3, Pages 935–942, 2009.
12. Sabiha-Javied, Tufail M and Khalid S, “Heavy metal pollution from medical waste incineration.” Volume 90, Issue 1, Pages 77–81,
2008.
13. Santarsiero A and Ottaviani M, “Evaluation of heavy metals in slags from medical waste incinerator.” Volume 51, Issues 1–2, Pages
166- 169, 1995.
14. Kaur H and Rajor Anita. “Influence of incinerated biomedical waste ash on the properties of concrete.” Volume 226, page 428-441,
2019.
15. Ramesh BM, Vongole RM, Nagraj Y, Naganna SR, Sreedhara BM, Mailar G, … & Yaseen ZM. (2021). Valorization of incinerator
bottom ash for the production of resource-efficient eco-friendly concrete: performance and toxicological characterization. Architect
Struct Construct. 1:65–78. https://doi.org/10.1007/s44150-021-00006-9
16. Mazumder EA, Prasad MLV (2022) Characterisation of eco-friendly self-compacting geopolymer concrete for fire endurance
properties. J Build Pathol Rehabil 7(1):1–10. https://doi.org/10.1007/s41024-022-00236-4.
17. Etli S (2023) Evaluation of the effect of silica fume on the fresh, mechanical and durability properties of self-compacting concrete
produced by using waste rubber as fine aggregate. J Cleaner Prod. 384:135590. https://doi.org/10.1016/j.jclepro.2022.135590.
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