A Review on Paver Block Preparation Using Waste Plastic Materials

Dheeraj S Deshmukh, Sandeep Petkar,
Journal of Production and Industrial Engineering
Volume 4: Issue 2, September 2023, pp 90-97

Author's Information
Dheeraj S Deshmukh1 
Corresponding Author
1G H Raisoni College of Engineering, Nagpur, Maharashtra, India
dheeraj.deshmukh@raisoni.net

Sandeep Petkar2
2G H Raisoni University, Saikheda, M.P., India
Article -- Peer Reviewed
Published online – 20 September 2023

Open Access article under Creative Commons License

Cite this article – Dheeraj S Deshmukh, Sandeep Petkar, ,“A Review on Paver Block Preparation Using Waste Plastic Materials”, Journal of Production and Industrial Engineering, RAME Publishers, vol. 4, Issue 2, pp. 90-97, 2023.
https://doi.org/10.26706/jpie.4.2.20230903

Abstract:
Day by day plastic use is increasing thereby produces waste. Scholars are working to calculate cement characteristics for mixtures comprising several different unwanted plastic material as combined, grout or fibrous material for concrete makings. Almost all desirable properties for paver block making are discussed in this paper for the noble cause. Critical review is done to reduce use of concrete material with plastic waste in paver block so as to produce it economically and utilize plastic waste in paver blocks. Currently in India 56 lakhs ton of waste plastic is created annually. Since deprivation rate of waste plastic is a sluggish process. Lot of work is done by scholars in this direction for use of unwanted plastic in convenient manner. Plastic waste could be treated in diverse quantities of excavation dirt, grainy amassed and unwanted ironstone. It is observed that paver block could be effectively used, prepared with waste plastic materials has vast application in low load of floor space regions.
Index Terms:
Management, profitability, stock exchange, market share, commercial bank
REFERENCES
  1. Akcaozoglu S, Atis CD, Akcaozoglu K. An investigation on the use of shredded pet waste bottles as aggregate in lightweight concrete. Waste Manage 2010;32:285–90.
    Crossref
  2. Albano C, Camacho N, Hernandez M, Matheus A, Gutierrez A. Influence of content and particle size of pet waste bottles on concrete behaviour at different w/c ratios. Waste Manage (Oxford) 2009;29:2707–16.
    Crossref
  3. Choi YW, Moon DJ, Kim YJ, Lachemi M. Characteristics of mortar and concrete containing fine aggregate manufactured from recycled waste polyethylene terephthalate bottles. Constr Build Mater 2009;23:2829–35.
    Crossref
  4. Choi YW, Moon DJ, Chung JS, Cho SK. Effects of pet waste bottles aggregate on the properties of concrete. Cem Concr Res 2005;35:776–81.
    Crossref
  5. Kim SB, Yi NH, Kim HY, Kim JHJ, Song YC. Material and structural performance evaluation of recycled PET fibre reinforced concrete. Cem Concr Compos 2010;32:232–40.
    Crossref
  6. Marzouk OY, Dheilly RM, Queneudec M. Valorisation of post-consumer plastic waste in cementitious concrete composites. Waste Manage 2007;27:310–8.
    Crossref
  7. Silva DA, Betioli AM, Gleize PJP, Roman HR, Gomez LA, Ribeiro JLD. Degradation of recycled PET fibres in Portland cement-based materials. Cem Concr Res 2005;35:1741–6.
    Crossref
  8. Yesilata B, Isıker Y, Turgut P. Thermal insulation enhancement in concretes by adding pet waste and rubber pieces. Constr Build Mater 2009;23:1878–82.
    Crossref
  9. Kou SC, Lee G, Poon CS, Lai WL. Properties of lightweight aggregate concrete prepared with PVC granules derived from scraped PVC pipes. Waste Manage 2009;29:621–8.
    Crossref
  10. Naik TR, Singh SS, Huber CO, Brodersen BS. Use of post-consumer plastic wastes in cement-based composites. Cem Concr Res 1996;26:1489–92.
    Crossref
  11. Panyakapo P, Panyakapo M. Reuse of thermosetting plastic waste for lightweight concrete. Waste Manage 2008;28:1581–8.
    Crossref
  12. Al-Manaseer AA, Dalal TR. Concrete containing plastic aggregates. Concr Int 1997;19:47–52.
    Crossref
  13. Ismail ZZ, Al-Hashmi EA. Use of plastic waste in concrete mixture as aggregate replacement. Waste Manage 2008;28:2041–7.
    Crossref
  14. Soroushian P, Plasencia JS, Ravanbakhsh S. Assessment of reinforcing effects of recycled plastic and paper in concrete. ACI Mater J 2003;100:203–7.
    Crossref
  15. Kan A, Demirbog˘a R. A novel material for lightweight concrete production. Cem Concr Compos 2009;31:489–95.
    Crossref
  16. Kan A, Demirbog˘a R. A new technique of processing for waste-expanded polystyrene foams as aggregates. J Mater Process Technol 2009;209: 2994–3000.
    Crossref
  17. Asokan P, Osmani M, Price ADF. Improvement of the mechanical properties of glass fibre reinforced plastic waste powder filled concrete. Constr Build Mater 2010;24:448–60.
    Crossref
  18. Hannawi K, Kamali-Bernard S, Prince W. Physical and mechanical properties of mortars containing PET and PC waste aggregates. Waste Manage 2010;30:2312–20.
    Crossref
  19. Fraj AB, Kismi M, Mounanga P. Valorization of coarse rigid polyurethane foam waste in lightweight aggregate concrete. Constr Build Mater 2010;24:1069–77.
    Crossref
  20. Mounanga P, Gbongbon W, Poullain P, Turcry P. Proportioning and characterization of lightweight concrete mixtures made with rigid polyurethane foam wastes. Cem Concr Compos 2008;30:806–14.
    Crossref
  21. Bayasi Z, Zeng J. Properties of polypropylene fiber reinforced concrete. ACI Mater J 1993;90:605–10.
    Crossref
  22. Siddique R, Khatib J, Kaur I. Use of recycled plastic in concrete: a review. Waste Manage 2008;28:1835–52.
    Crossref
  23. Frigione M. Recycling of PET bottles as fine aggregate in concrete. Waste Manage 2010;30:1101–6.
    Crossref
  24. Batayneh M, Marie I, Ibrahim A. Use of selected waste materials in concrete mixes. Waste Manage 2007;27:1870–6.
    Crossref
  25. Saikia N, de Brito J. Mechanical properties and abrasion behaviour of concrete containing shredded pet waste bottle aggregate as a partial substitution of natural aggregate. Cem Concr Compos, submitted for publication.
    Crossref
  26. Remadnia A, Dheilly RM, Laidoudi B, Quéneudec M. Use of animal proteins as foaming agent in cementitious concrete composites manufactured with recycled PET aggregates. Constr Build Mater 2009;23:3118–23.
    Crossref
  27. Saikia N, de Brito J. Waste polyethylene terephthalate as an aggregate in concrete. Mag Concr Res, submitted for publication.
    Crossref
  28. Laukaitis A, Zurauskas R, Keriene J. The effect of foam polystyrene granules on cement composite properties. Cem Concr Compos 2005;27:41–7.
    Crossref
  29. Nasvik J. Plastic aggregate offers colorful alternative to mineral aggregate: color flexibility is offered in a material made from recycled plastic in some colors. Publication #J910701a, the Aberdeen, Group; 1991.
    Crossref
  30. Dweik HS, Ziara MM, Hadidoun HS. Enhancing concrete strength and thermal insulation using thermoset plastic waste. Int J Polym Mater 2008;57:635–56.
    Crossref
  31. Raadal HL, Hanssen OJ. Recycling of plastic in the Drammen region. Assessment of landfill, energy recovery and recycling of plastic packaging waste (in Norwegian). Ostfold Research Foundation, OR45.99, Norway; 1999.
    Crossref
  32. Eriksson E, Olund G. Recycling, energy recovery or landfill? Environmental analysis of producer responsibility for plastic packaging (in Swedish). Gothenburg, Sweden: Department of Technical Environmental Planning, Chalmers University of Technology; 1999.
    Crossref
  33. Nyland CA, Modahl IS, Raadal HL, Hanssen OJ. Application of LCA as a decisionmaking tool for waste management systems: material flow modelling. Int J Life Cycle Assess 2003;2003(8):331–6.
    Crossref
  34. P.M. Solanki, D.S. Deshmukh, V.R. Diware, M.S. Deshmukh, Experimental investigation of thermoelectric generator system, Materials Today: Proceedings, Volume 47, Part 11, 2021, Pages 3012-3017, ISSN 2214-7853,
    Crossref
  35. Sheetal D Deshmukh, Shubham Gabhane and Dheeraj S Deshmukh, “Osmotic dehydration of carrot strips and modelling”, Journal of Physics: Conference Series, Volume 1913, 2021, 1913 012093.
    Crossref
  36. Mahesh.V. Kulkarni, D.S. Deshmukh, S.P Shekhawat, An innovative design approach of hot water storage tank for solar water heating system using artificial neural network, Materials Today: Proceedings, Volume 46, Part 11, 2021, Pages 5400-5405, ISSN 2214-7853,
    Crossref
  37. Patil, P.P. and .Deshmukh, Dr.D.S and .Vaidya,, Dr.A.M and Paul, I.D., Experimental Investigation of New Innovative Flat Plate Collector for Solar Water Heater (May 17, 2019). Proceedings of the Second International Conference on Emerging Trends in Science & Technologies For Engineering Systems (ICETSE-2019),
    Crossref
  38. Shailesh Pimpale, Manish Deshmukh, Rajesh Shelke and Dheeraj Deshmukh, published a research paper titled ” Experimental Investigation on Hip Implant Materials Development through Analytical and Finite Element Analysis: 3D Modelled Computed Tomography”, Biointerface Research in Applied Chemistry, Platinum Open Access Journal (ISSN: 2069-5837, Volume 12, Issue 3, 2022, 4103 – 4125, online available 15 August 2021,
    Crossref
  39. Dr. B. S. Bhaskar, Dr. M. S. Deshmukh, Dr. S.K. Choudhary and Dr. D. S. Deshmukh, published a research paper titled ”Heat Transfer Through Porous Materials (Aluminum Foam) Empirical Optimization of a Heat Exchanger”, International Journal of Mechanical Engineering, ISSN: 0974-5823, Vol. 7 No. 1, Page No. 47 – 55, January, 2022, Copyrights @Kalahari,
    Crossref
  40. Dewansh Bhajane et al 2022 IOP Conf. Ser.: Mater. Sci. Eng. 1259 012022
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