Skip to content

Use of Municipal Solid-Waste Incineration-Ash in 3D Printable Concrete (2020-06)

10.1016/j.psep.2020.06.018

 Rehman Atta, Lee Sang-Min,  Kim Jung-Hoon
Journal Article - Process Safety and Environmental Protection, Vol. 142, pp. 219-228

Abstract

Concrete 3D printing is an application of 3D printing technology for the construction of concrete structural and non-structural elements. It is a rapid method of construction without the use of formwork, with minimum labor involvement and reduced material wastage. Curved walls and complex structures can be constructed by modifying the print path and controlling the rheological properties of concrete. The fusion of this technology with waste materials is necessary to reduce the problems associated with the recycling of wastes and to minimize CO2 emissions associated with the production of cement. In this study, two different municipal solid waste (MSW) incineration ashes (fly ash and bottom ash) were used to develop a concrete having rheological and hardened requirements of concrete used in 3D printing. Waste incinerator ashes were added as a substitute of ordinary Portland cement in concrete mix proportions. Flow table test and Gilmore needle test were used to measure the flow and setting time of concrete, respectively. Yield stress was measured by shear vane test. The buildability of ash containing printable concrete was simulated by comparing the vertical stresses due to the printing of concrete layers with the increase in the strength of the first stacked layer. Workability, open time, and buildability of the mix proportions were related to yield stress. The effect of adding waste incinerator ash upon the compressive strength was measured. The bond strength between layers at different printing time gaps was evaluated using bi-surface direct shear test. Experimental results showed that setting time promoting effect and initial yield stress enhancement by incinerated fly ash allows for a rapid construction speed with concrete 3D printing. This study concludes that incinerated fly ash can be successfully recycled in 3D printable concrete due to its favorable effects on rheology which are favorable for printing concrete.

13 References

  1. Bong Shin, Nematollahi Behzad, Nazari Ali, Xia Ming et al. (2018-09)
    Fresh and Hardened Properties of 3D Printable Geopolymer Cured in Ambient Temperature
  2. Bos Freek, Wolfs Robert, Ahmed Zeeshan, Salet Theo (2016-08)
    Additive Manufacturing of Concrete in Construction:
    Potentials and Challenges of 3D Concrete Printing
  3. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  4. Gosselin Clément, Duballet Romain, Roux Philippe, Gaudillière-Jami Nadja et al. (2016-03)
    Large-Scale 3D Printing of Ultra-High-Performance Concrete:
    A New Processing Route for Architects and Builders
  5. Jeon Kwang-Hyun, Park Min-Beom, Kang Min-Kyung, Kim Jung-Hoon (2013-11)
    Development of an Automated Freeform Construction System and Its Construction Materials
  6. Kazemian Ali, Yuan Xiao, Cochran Evan, Khoshnevis Behrokh (2017-04)
    Cementitious Materials for Construction-Scale 3D Printing:
    Laboratory Testing of Fresh Printing Mixture
  7. Le Thanh, Austin Simon, Lim Sungwoo, Buswell Richard et al. (2012-01)
    Mix-Design and Fresh Properties for High-Performance Printing Concrete
  8. Perrot Arnaud, Rangeard Damien, Pierre Alexandre (2015-02)
    Structural Build-Up of Cement-Based Materials Used for 3D Printing-Extrusion-Techniques
  9. Putten Jolien, Deprez Maxim, Cnudde Veerle, Schutter Geert et al. (2019-09)
    Microstructural Characterization of 3D Printed Cementitious Materials
  10. Rahul Attupurathu, Santhanam Manu, Meena Hitesh, Ghani Zimam (2018-12)
    3D Printable Concrete:
    Mixture-Design and Test-Methods
  11. Sakin Mehmet, Kiroglu Yusuf (2017-10)
    3D Printing of Buildings:
    Construction of the Sustainable Houses of the Future by BIM
  12. Soltan Daniel, Li Victor (2018-03)
    A Self-Reinforced Cementitious Composite for Building-Scale 3D Printing
  13. Tay Yi, Panda Biranchi, Paul Suvash, Mohamed Nisar et al. (2017-05)
    3D Printing Trends in Building and Construction Industry:
    A Review

36 Citations

  1. Teixeira João, Jesus Manuel, Rangel Bárbara, Alves Jorge et al. (2026-01)
    Evaluation of Printing Performance of Cementitious Pastes with Alternative Powders
  2. Tushar Fazlul, Hasan Mehedi, Hasan Kamrul, Mawa Jannatul et al. (2026-01)
    Factors Affecting Flowability and Rheological Behavior of 3D Printed Concrete:
    A Comprehensive Review
  3. Taborda-Llano Isabella, Hoyos-Montilla Ary, Asensio Eloy, Guerrero Ana et al. (2025-12)
    Influence of the Construction Process Parameters on the Mechanical Performance and Durability of 3D Printed Concrete:
    A Systematic Review
  4. Solaiappan Kamesh, Foruzanmehr M. (2025-11)
    A Rheological Test Method for Determining the Printability Zone of Cementitious 3D Printers
  5. Zhang Jiao-Long, Yuan Yong, Fatoyinbo Imoleayo, Zhou Lujie et al. (2025-11)
    3D-Printable Mortars Incorporating Municipal Solid Waste Incineration Bottom Ash:
    Linking Hydration to Extrudability and Mechanical Performance
  6. Jamifar Vahid, Eskandari‐Naddaf Hamid, Dehestani Mehdi (2025-10)
    Optimizing Electric Arc Furnace Dust Utilization in 3D Printed Reinforced Cement Paste Using D‐Optimal Design of Experiments and Gray Wolf Optimization
  7. Yuan Yong, Fatoyinbo Imoleayo, Sheng Ruiyi, Wang Qiling et al. (2025-02)
    Advancing the Applicability of Recycled Municipal Solid Waste Incineration Bottom Ash as a Cement Substitute in Printable Concrete:
    Emphasis on Rheological and Microstructural Properties
  8. Schossler Rodrigo, Ullah Shafi, Alajlan Zaid, Yu Xiong (2025-01)
    Data-Driven Analysis in 3D Concrete Printing:
    Predicting and Optimizing Construction Mixtures
  9. Irshidat Mohammad, Cabibihan John-John, Fadli Fodil, Ramahi Siraj et al. (2024-12)
    Waste Materials Utilization in 3D Printable Concrete for Sustainable Construction Applications:
    A Review
  10. Khan Mirza, Ahmed Aayzaz, Ali Tariq, Qureshi Muhammad et al. (2024-12)
    Comprehensive Review of 3D Printed Concrete, Life Cycle Assessment, AI and ML Models:
    Materials, Engineered Properties and Techniques for Additive Manufacturing
  11. Habibi Alireza, Buswell Richard, Osmani Mohamed, Aziminezhad Mohamadmahdi (2024-11)
    Sustainability Principles in 3D Concrete Printing:
    Analysing Trends, Classifying Strategies, and Future Directions
  12. Li L., Fang Z., Chu S., Kwan Albert (2024-11)
    Improving Mechanical Properties of 3D Printed Mortar by Exploiting Synergistic Effects of Fly-Ash-Microsphere and Nano-Silica
  13. Murali Gunasekaran, Leong Sing (2024-11)
    Waste-Driven Construction:
    A State of the Art Review on the Integration of Waste in 3D Printed Concrete in Recent Researches for Sustainable Development
  14. Samrani Phebe, Cao Yifang, Fimbres-Weihs Gustavo, Sanjaya Eric et al. (2024-09)
    Effect of Fly-Ash and Ground Waste Glass as Cement Replacement in Concrete 3D Printing for Sustainable Construction
  15. Gao Jianhao, Wang Chaofeng, Li Jiaqi, Chu S. (2024-09)
    Data-Driven Rheological-Model for 3D Printable Concrete
  16. Zhao Hongyu, Wang Yufei, Liu Xianda, Wang Xiangyu et al. (2024-08)
    Review on Solid Wastes Incorporated Cementitious Material Using 3D Concrete Printing-Technology
  17. Butkutė Karolina, Vaitkevičius Vitoldas, Adomaitytė Fausta (2024-07)
    Eco-Friendly 3D Printed Concrete Made with Waste and Organic Artificial Aggregates
  18. Aslani Farhad, Zhang Yifan (2024-06)
    Sustainable 3D Printed Concrete Structures Using High-Quality Secondary Raw Materials
  19. Bong Shin, Du Hongjian (2024-06)
    Sustainable Additive Manufacturing of Concrete with Low-Carbon Materials
  20. González-Fonteboa Belén, Seara-Paz Sindy, Caneda-Martínez Laura (2024-06)
    3D Printing Concrete with Byproducts
  21. Birru Bizu, Rehman Atta, Kim Jung-Hoon (2024-06)
    Comparative Analysis of Structural Build-Up in One-Component Stiff and Two-Component Shotcrete-Accelerated Set-on-Demand Mixtures for 3D Concrete Printing
  22. Capêto Ana, Jesus Manuel, Uribe Braian, Guimarães Ana et al. (2024-05)
    Building a Greener Future:
    Advancing Concrete Production Sustainability and the Thermal Properties of 3D Printed Mortars
  23. Ding Tao, Shen Kaige, Cai Chen, Xiao Jianzhuang et al. (2024-02)
    3D Printed Concrete with Sewage Sludge Ash:
    Fresh and Hardened Properties
  24. Rehman Atta, Kim Ik-Gyeom, Kim Jung-Hoon (2024-01)
    Towards Full Automation in 3D Concrete Printing Construction:
    Development of an Automated and In-Line Test-Method for In-Situ Assessment of Structural Build-Up and Quality of Concrete
  25. Ungureanu Dragoș, Onuțu Cătălin, Țăranu Nicolae, Vornicu Nicoleta et al. (2023-11)
    Microstructure and Mechanical Properties of Cost-Efficient 3D Printed Concrete Reinforced with Polypropylene Fibers
  26. Rehman Atta, Perrot Arnaud, Birru Bizu, Kim Jung-Hoon (2023-09)
    Recommendations for Quality-Control in Industrial 3D Concrete Printing Construction with Mono-Component Concrete:
    A Critical Evaluation of Ten Test-Methods and the Introduction of the Performance-Index
  27. Bhushan Jindal Bharat, Jangra Parveen (2023-05)
    3D Printed Concrete:
    A Comprehensive Review of Raw Material’s Properties, Synthesis, Performance, and Potential Field Applications
  28. Fonseca Mariana, Matos Ana (2023-03)
    3D Construction Printing Standing for Sustainability and Circularity:
    Material-Level Opportunities
  29. Basha Shaik, Rehman Atta, Aziz Md, Kim Jung-Hoon (2023-02)
    Cement Composites with Carbon-Based Nanomaterials for 3D Concrete Printing Applications:
    A Review
  30. Zhang Chao, Jia Zijian, Luo Zhe, Deng Zhicong et al. (2022-11)
    Printability and Pore-Structure of 3D Printing Low-Carbon Concrete Using Recycled Clay-Brick-Powder with Various Particle-Features
  31. Daher Jana, Kleib Joelle, Benzerzour Mahfoud, Abriak Nor-Edine et al. (2022-09)
    Recycling of Flash-Calcined Dredged Sediment for Concrete 3D Printing
  32. Khosravani Mohammad, Haghighi Azadeh (2022-08)
    Large-Scale Automated Additive Construction:
    Overview, Robotic Solutions, Sustainability, and Future Prospect
  33. Nodehi Mehrab, Aguayo Federico, Nodehi Shahab, Gholampour Aliakbar et al. (2022-07)
    Durability Properties of 3D Printed Concrete
  34. Ma Guowei, A Ruhan, Xie Panpan, Pan Zhu et al. (2022-01)
    3D Printable Aerogel-Incorporated Concrete:
    Anisotropy Influence on Physical, Mechanical, and Thermal Insulation Properties
  35. Guimarães Ana, Delgado João, Lucas Sandra (2021-07)
    Advanced Manufacturing in Civil Engineering
  36. Rehman Atta, Kim Jung-Hoon (2021-07)
    3D Concrete Printing:
    A Systematic Review of Rheology, Mix Designs, Mechanical, Microstructural, and Durability Characteristics

BibTeX 
@article{rehm_lee_kim.2020.UoMSWIAi3PC,
  author            = "Atta Ur Rehman and Sang-Min Lee and Jung-Hoon Kim",
  title             = "Use of Municipal Solid-Waste Incineration-Ash in 3D Printable Concrete",
  doi               = "10.1016/j.psep.2020.06.018",
  year              = "2020",
  journal           = "Process Safety and Environmental Protection",
  volume            = "142",
  pages             = "219--228",
}
Formatted Citation

A. U. Rehman, S.-M. Lee and J.-H. Kim, “Use of Municipal Solid-Waste Incineration-Ash in 3D Printable Concrete”, Process Safety and Environmental Protection, vol. 142, pp. 219–228, 2020, doi: 10.1016/j.psep.2020.06.018.

Rehman, Atta Ur, Sang-Min Lee, and Jung-Hoon Kim. “Use of Municipal Solid-Waste Incineration-Ash in 3D Printable Concrete”. Process Safety and Environmental Protection 142 (2020): 219–28. https://doi.org/10.1016/j.psep.2020.06.018.