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3D Printable Lightweight Foamed Concrete and Comparison with Classical Foamed Concrete in Terms of Fresh State Properties and Mechanical Strength (2020-04)

10.1016/j.conbuildmat.2020.119271

 Falliano Devid,  de Domenico Dario,  Ricciardi Giuseppe, Gugliandolo Ernesto
Journal Article - Construction and Building Materials, Vol. 254

Abstract

This paper presents a novel type of foamed concrete that is termed ‘‘3D-printable lightweight foamed concrete” (3DP-LWFC). Unlike classical lightweight foamed concrete (C-LWFC), this novel material is able to keep its shape at the fresh state due to enhanced consistency and viscosity. This peculiarity lends itself to being implemented in automated extrusion production process and 3D printing applications without the use of formwork, which is particularly convenient in the building industry. These unique fresh state properties of 3DP-LWFC are demonstrated through a specific extrusion test conceived and used in this experimental campaign, and highlighted by comparison with results related to C-LWFC. Despite the remarkably different behavior of the novel material at the fresh state, the mechanical strength of 3DP-LWFC is even slightly higher than C-LWFC. This is demonstrated through a wide experimental campaign focused on the compressive and flexural strength of 3DP-LWFC, which includes different dry densities, curing conditions, cement types, water/cement ratios. Additionally, the effect of the mixing conditions on the mechanical strength of 3DP-LWFC, in particular the rotational speed of the mixer during the preparation of the paste, is also analyzed and discussed. It is found that the increase of mixing intensity from 1200 rpm to 3000 rpm resulted in a considerable increase of mechanical strength values of 3DP-LWFC, up to more than 70% for the compressive strength and up to around 100% for the flexural strength.

12 References

  1. Asprone Domenico, Auricchio Ferdinando, Menna Costantino, Mercuri Valentina (2018-03)
    3D Printing of Reinforced Concrete Elements:
    Technology and Design Approach
  2. Buchli Jonas, Giftthaler Markus, Kumar Nitish, Lussi Manuel et al. (2018-07)
    Digital In-Situ Fabrication:
    Challenges and Opportunities for Robotic In-Situ Fabrication in Architecture, Construction, and Beyond
  3. Buswell Richard, Silva Wilson, Jones Scott, Dirrenberger Justin (2018-06)
    3D Printing Using Concrete-Extrusion:
    A Roadmap for Research
  4. Falliano Devid, Gugliandolo Ernesto, Domenico Dario, Ricciardi Giuseppe (2018-09)
    Experimental Investigation on the Mechanical Strength and Thermal Conductivity of Extrudable Foamed Concrete and Preliminary Views on Its Potential Application in 3D Printed Multilayer Insulating Panels
  5. Falliano Devid, Sciarrone Antonino, Domenico Dario, Maugeri Natale et al. (2019-10)
    Fiber-Reinforced Lightweight Foamed Concrete Panels Suitable for 3D Printing Applications
  6. Marchon Delphine, Kawashima Shiho, Bessaies-Bey Hela, Mantellato Sara et al. (2018-05)
    Hydration- and Rheology-Control of Concrete for Digital Fabrication:
    Potential Admixtures and Cement-Chemistry
  7. Markin Slava, Nerella Venkatesh, Schröfl Christof, Guseynova Gyunay et al. (2019-07)
    Material-Design and Performance-Evaluation of Foam-Concrete for Digital Fabrication
  8. Reiter Lex, Wangler Timothy, Roussel Nicolas, Flatt Robert (2018-06)
    The Role of Early-Age Structural Build-Up in Digital Fabrication with Concrete
  9. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  10. Schutter Geert, Lesage Karel, Mechtcherine Viktor, Nerella Venkatesh et al. (2018-08)
    Vision of 3D Printing with Concrete:
    Technical, Economic and Environmental Potentials
  11. Wangler Timothy, Lloret-Fritschi Ena, Reiter Lex, Hack Norman et al. (2016-10)
    Digital Concrete:
    Opportunities and Challenges
  12. Wangler Timothy, Roussel Nicolas, Bos Freek, Salet Theo et al. (2019-06)
    Digital Concrete:
    A Review

59 Citations

  1. Ding Yao, Liu Yifan, Yang Bo, Liu Jiepeng et al. (2026-01)
    Application of Artificial Intelligence Technology in 3D Concrete Printing Quality Inspection and Control:
    A State-of-the-Art Review
  2. Geng Renyu, Jiang Jinming, Du Pengcong, Zhang Huiliang et al. (2025-11)
    Multiscale Thermal Optimization of 3D-Printed Walls:
    Integrating Structure, Material, and Process with Fire-Thermal Synergy
  3. Wang Huai, Li Xiulin, Gong Hao, Xu Jingjie et al. (2025-10)
    Thermal and Mechanical Properties of 3D-Printed Fiber-Reinforced Lightweight Concrete Based on Air Entrainment and Hollow Glass Microspheres
  4. Daungwilailuk Totsawat, Pheinsusom Phoonsak, Pansuk Withit (2025-09)
    Behavior of 3D Printed Concrete Walls Exposed to High Temperatures
  5. Falliano Devid, Restuccia Luciana, Tulliani Jean-Marc, Ferro Giuseppe (2025-07)
    Biochar to Enhance Curing and Rheology of Mortars without Formwork
  6. Liu Qiong, Singh Amardeep, Wang Qiming, Qifeng Lyu (2025-05)
    3D-Printed Application in Concretes
  7. Mishra Sanjeet, Snehal K., Das B., Chandrasekaran Rajasekaran et al. (2025-05)
    From Printing to Performance:
    A Review on 3D Concrete Printing Processes, Materials, and Life Cycle Assessment
  8. Liu Qiang, Jiang Quan, Zhao Herui, Yu Yang et al. (2025-02)
    Porous Diatomite Promotes Lightweight and Low-Carbon Concrete 3D Printing:
    An Exploratory Study
  9. Elango K., Saravanakumar R., Vivek D., Yuvaraj S. et al. (2025-01)
    A Critical Review of Fresh, Hardened and Durability Properties of 3D Printing Concrete
  10. Hassan Amer, Alomayri Thamer, Noaman Mohammed, Zhang Chunwei (2025-01)
    3D Printed Concrete for Sustainable Construction:
    A Review of Mechanical Properties and Environmental Impact
  11. Tarhan Yeşim, Tarhan İsmail, Şahin Remzi (2024-12)
    Comprehensive Review of Binder Matrices in 3D Printing Construction:
    Rheological Perspectives
  12. Aminpour Nima, Memari Ali (2024-12)
    Analysis of Anisotropic Behavior in 3D Concrete Printing for Mechanical Property Evaluation
  13. 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
  14. Wang Qingwei, Han Song, Yang Junhao, Li Ziang et al. (2024-11)
    Optimizing Printing and Rheological Parameters for 3D Printing with Cementitious Materials
  15. Zhao Herui, Jiang Quan, Xia Yong, Liu Jian et al. (2024-11)
    Microbial-Induced Carbonate Reinforcement for 3D Printed Concrete:
    Testing in Printable and Mechanical Strength
  16. Chamatete Kunda, Yalçınkaya Çağlar (2024-10)
    Numerical Assessment of Thermal Bridging Effects in 3D Printed Foam-Concrete Walls
  17. Parmigiani Silvia, Falliano Devid, Moro Sandro, Ferro Giuseppe et al. (2024-09)
    Preliminary Study on Multi-Functional Building Components Utilizing Variable Density Foamed Concrete via 3D Printing
  18. Zhao Hongyu, Wang Yufei, Liu Xianda, Wang Xiangyu et al. (2024-08)
    Review on Solid Wastes Incorporated Cementitious Material Using 3D Concrete Printing-Technology
  19. Jiang Shangjin, Wang Yuntao, Hua Sudong, Yue Hongfei et al. (2024-08)
    Preparation and Performance Characterization of Low-Density 3D Printed Expanded Perlite-Foam-Concrete
  20. Hasani Alireza, Dorafshan Sattar (2024-06)
    Transforming Construction?:
    Evaluation of the State of Structural 3D Concrete Printing in Research and Practice
  21. Parmigiani Silvia, Falliano Devid, Moro Sandro, Ferro Giuseppe et al. (2024-06)
    3D Printed Multi-Functional Foamed Concrete Building Components:
    Material-Properties, Component Design, and 3D Printing Application
  22. Boddepalli Uday, Gandhi Indu, Panda Biranchi (2024-05)
    Synergistic Effect of Fly-Ash and Polyvinyl-Alcohol-Fibers in Improving Stability, Rheology, and Mechanical Properties of 3D Printable Foam-Concrete
  23. Gappmeier Peter, Reichenbach Sara, Kromoser Benjamin (2024-03)
    Advances in Formwork Automation, Structure and Materials in Concrete Construction
  24. Azimi Zahir, Mousavi Moein, Bengar Habib, Javadi Akbar (2023-12)
    Study on the Post-Fire Mechanical Properties of Lightweight 3D Printed Concrete Containing Expanded Perlite as Partial Replacement of Natural Sand
  25. Rudziewicz Magdalena, Maroszek Marcin, Góra Mateusz, Dziura Paweł et al. (2023-09)
    Feasibility Review of Aerated Materials Application in 3D Concrete Printing
  26. Federowicz Karol, Techman Mateusz, Skibicki Szymon, Chougan Mehdi et al. (2023-08)
    Development of 3D Printed Heavyweight Concrete Containing Magnetite-Aggregate
  27. Mousavi Seyed, Dehestani Mehdi (2023-07)
    On the Possibility of Using Waste-Disposable-Gloves as Recycled Fibers in Sustainable 3D Concrete Printing Using Different Additives
  28. Tu Haidong, Wei Zhenyun, Bahrami Alireza, Kahla Nabil et al. (2023-06)
    Recent Advancements and Future Trends in 3D Printing Concrete Using Waste-Materials
  29. Xu Zhuoyue, Zhang Dawang, Li Hui, Yin Le et al. (2023-06)
    Effects of Additives on the Mechanical Properties, Rheology, and Printing Properties of PCC-Based 3DPMs
  30. Xu Zhuoyue, Zhang Dawang, Li Hui, Jin Haoyu et al. (2023-06)
    Mix-Design and 3D Printing Correlation-Performance of PCC-Based 3DPM
  31. Bhushan Jindal Bharat, Jangra Parveen (2023-05)
    3D Printed Concrete:
    A Comprehensive Review of Raw Material’s Properties, Synthesis, Performance, and Potential Field Applications
  32. Gao Yanan, Hua Sudong, Yue Hongfei (2023-04)
    Study on Preparation and Rheological Properties of 3D Printed Pre-Foaming Concrete
  33. Razzaghian Ghadikolaee Mehrdad, Cerro-Prada Elena, Pan Zhu, Korayem Asghar (2023-04)
    Nanomaterials as Promising Additives for High-Performance 3D Printed Concrete:
    A Critical Review
  34. Cruz Gil, Dizon John, Farzadnia Nima, Zhou Hongyu et al. (2023-04)
    Performance, Applications, and Sustainability of 3D Printed Cement and Other Geomaterials
  35. Raphael Benny, Senthilnathan Shanmugaraj, Patel Abhishek, Bhat Saqib (2023-01)
    A Review of Concrete 3D Printed Structural Members
  36. Ma Zongfang, Wan Weipeng, Song Lin, Liu Chao et al. (2022-11)
    An Approach of Path-Optimization Algorithm for 3D Concrete Printing Based on Graph-Theory
  37. Liu Chao, Chen Yuning, Zhang Zedi, Niu Geng et al. (2022-10)
    Study of the Influence of Sand on Rheological Properties, Bubble Features and Buildability of Fresh Foamed Concrete for 3D Printing
  38. Mousavi Seyed, Dehestani Mehdi (2022-08)
    Influence of Latex and Vinyl Disposable Gloves as Recycled Fibers in 3D Printing Sustainable Mortars
  39. Pasupathy Kirubajiny, Ramakrishnan Sayanthan, Sanjayan Jay (2022-07)
    Enhancing the Properties of Foam-Concrete 3D Printing Using Porous Aggregates
  40. Ahmed Ghafur, Askandar Nasih, Jumaa Ghazi (2022-07)
    A Review of Large-Scale 3DCP:
    Material-Characteristics, Mix-Design, Printing-Process, and Reinforcement-Strategies
  41. Liu Chao, Chen Yuning, Xiong Yuanliang, Jia Lutao et al. (2022-06)
    Influence of Hydroxypropyl-Methylcellulose and Silica-Fume on Buildability of 3D Printing Foam-Concrete:
    From Water State and Flocculation Point of View
  42. Falliano Devid, Restuccia Luciana, Ferro Giuseppe (2022-06)
    Biochar Addition for 3DCP:
    A Preliminary Study
  43. Ivaniuk Egor, Ivanova Irina, Sokolov Dmitrii, Tošić Zlata et al. (2022-02)
    Application-Driven Material-Design of Printable Strain-Hardening Cementitious Composites
  44. Liu Chao, Xiong Yuanliang, Chen Yuning, Jia Lutao et al. (2022-01)
    Effect of Sulphoaluminate Cement on Fresh and Hardened Properties of 3D Printing Foamed Concrete
  45. Cho Seung, Rooyen Algurnon, Kearsley Elsabe, Zijl Gideon (2021-12)
    Foam Stability of 3D Printable Foamed Concrete
  46. Volpe Stelladriana, Sangiorgio Valentino, Petrella Andrea, Coppola Armando et al. (2021-08)
    Building Envelope Prefabricated with 3D Printing Technology
  47. Guimarães Ana, Delgado João, Lucas Sandra (2021-07)
    Advanced Manufacturing in Civil Engineering
  48. Rehman Atta, Kim Jung-Hoon (2021-07)
    3D Concrete Printing:
    A Systematic Review of Rheology, Mix Designs, Mechanical, Microstructural, and Durability Characteristics
  49. Liu Chao, Wang Xianggang, Chen Yuning, Zhang Chao et al. (2021-06)
    Influence of Hydroxypropyl-Methylcellulose and Silica-Fume on Stability, Rheological Properties, and Printability of 3D Printing Foam-Concrete
  50. Zhang Chao, Nerella Venkatesh, Krishna Anurag, Wang Shen et al. (2021-06)
    Mix-Design Concepts for 3D Printable Concrete:
    A Review
  51. Markin Slava, Krause Martin, Otto Jens, Schröfl Christof et al. (2021-06)
    3D Printing with Foam-Concrete:
    From Material Design and Testing to Application and Sustainability
  52. Salman Nazar, Ma Guowei, Ijaz Nauman, Wang Li (2021-04)
    Importance and Potential of Cellulosic Materials and Derivatives in Extrusion-Based 3D Concrete Printing:
    Prospects and Challenges
  53. Cho Seung, Kruger Jacques, Rooyen Algurnon, Zijl Gideon (2021-03)
    Rheology and Application of Buoyant Foam-Concrete for Digital Fabrication
  54. Suntharalingam Thadshajini, Gatheeshgar Perampalam, Upasiri Irindu, Poologanathan Keerthan et al. (2021-02)
    Numerical Study of Fire and Energy Performance of Innovative Lightweight 3D Printed Concrete Wall-Configurations in Modular Building System
  55. Pessoa Ana Sofia, Guimarães Ana, Lucas Sandra, Simões Nuno (2021-02)
    3D Printing in the Construction Industry:
    A Systematic Review of the Thermal Performance in Buildings
  56. Daungwilailuk Totsawat, Pheinsusom Phoonsak, Pansuk Withit (2021-01)
    Uniaxial Load Testing of Large-Scale 3D Printed Concrete Wall and Finite-Element-Model-Analysis
  57. Mohan Manu, Rahul Attupurathu, Schutter Geert, Tittelboom Kim (2020-10)
    Extrusion-Based Concrete 3D Printing from a Material Perspective:
    A State of the Art Review
  58. Li Zhijian, Wang Li, Ma Guowei, Sanjayan Jay et al. (2020-07)
    Strength and Ductility Enhancement of 3D Printing Structure Reinforced by Embedding Continuous Micro-Cables
  59. Falliano Devid, Crupi Giuseppe, Domenico Dario, Ricciardi Giuseppe et al. (2020-07)
    Investigation on the Rheological Behavior of Lightweight Foamed Concrete for 3D Printing Applications

BibTeX 
@article{fall_dome_ricc_gugl.2020.3PLFCaCwCFCiToFSPaMS,
  author            = "Devid Falliano and Dario de Domenico and Giuseppe Ricciardi and Ernesto Gugliandolo",
  title             = "3D Printable Lightweight Foamed Concrete and Comparison with Classical Foamed Concrete in Terms of Fresh State Properties and Mechanical Strength",
  doi               = "10.1016/j.conbuildmat.2020.119271",
  year              = "2020",
  journal           = "Construction and Building Materials",
  volume            = "254",
}
Formatted Citation

D. Falliano, D. de Domenico, G. Ricciardi and E. Gugliandolo, “3D Printable Lightweight Foamed Concrete and Comparison with Classical Foamed Concrete in Terms of Fresh State Properties and Mechanical Strength”, Construction and Building Materials, vol. 254, 2020, doi: 10.1016/j.conbuildmat.2020.119271.

Falliano, Devid, Dario de Domenico, Giuseppe Ricciardi, and Ernesto Gugliandolo. “3D Printable Lightweight Foamed Concrete and Comparison with Classical Foamed Concrete in Terms of Fresh State Properties and Mechanical Strength”. Construction and Building Materials 254 (2020). https://doi.org/10.1016/j.conbuildmat.2020.119271.