Durability of Green Rubberized 3D Printed Lightweight Cement Composites Reinforced with Micro-Attapulgite and Micro-Steel-Fibers (2024-05)¶
Bodur Burak, Mecit Işık Muhammet, Benli Ahmet, Bayrak Barış, Öz Ali, Bayraktar Oguzhan, , Aydın Abdulkadir
Journal Article - Journal of Building Engineering, Vol. 90, No. 109447
Abstract
The increasing amount of tires manufactured annually worldwide has made waste tire management a major environmental concern. The goal of this work is to investigate the potential applications of waste tire aggregates (WTA) in a novel class of affordable, recycled composite materials. This study assesses the material behavior of rubberized 3D printed lightweight cement composites (3DLC) reinforced with raw micro attapulgite (ATP) and micro steel fibers (MSF) using WTA as a 100 % replacement for fine aggregate manufactured through 3D printing. The paper takes advantage of 3D concrete printing's advantages and addresses the environmental issues associated with waste tires. The extrudability and buildability properties of 3DLC are determined in the fresh state. Physical and thermal properties of 3DLC were determined. Mechanical properties of 3DLC including compressive, flexural, shear strength and flexural toughness were assessed. 3D printed samples were exposed to high temperature and sulfate (MgSO4), and their durability properties were determined. The microstructures of the mixes was analyzed. The CO2 emissions and costs of the blends were also assessed. The outcomes revealed that, the 3DLC mixture with 10 % ATP and 2 % MSF showed the greatest compressive strength performance, with increases of 17.82 and 29.51 % at 28 and 90 days, respectively relative to the mixture without ATP. Regardless of MSF level, at 28 and 90 days, all mixes with 10%ATP content showed the largest flexural strengths. The 3DLC mixture with 10 % ATP and 2 % MSF had the highest measured thermal conductivity. The blends with 20 % ATP and 0 % MSF showed the lowest thermal conductivity. The mixture containing 10 % ATP and 2 % MSF demonstrated the greatest high temperature performance, demonstrating strength enhancement of 21.85, 6.72 and 3.36 % at 200,400 and 600°C respectively. Replacing cement with 10 and 20%ATP greatly increased the sulfate resistance of 3DLC mixtures and the mixture with 20%ATP and 2%MSF exhibited the best sulfate performance. The lowest CO2 emission and cost were determined for the mixture containing 20%ATP and 0%MSF (A20S0).
¶
28 References
- Bhattacherjee Shantanu, Basavaraj Anusha, Rahul Attupurathu, Santhanam Manu et al. (2021-06)
Sustainable Materials for 3D Concrete Printing - Carvalho Ivo, Melo Abcael, Melo Carlos, Brito Mateus et al. (2023-12)
Evaluation of the Effect of Rubber-Waste-Particles on the Rheological and Mechanical Properties of Cementitious Materials for 3D Printing - Chen Yu, Figueiredo Stefan, Li Zhenming, Chang Ze et al. (2020-03)
Improving Printability of Limestone-Calcined-Clay-Based Cementitious Materials by Using Viscosity-Modifying Admixture - Chen Mingxu, Yang Lei, Zheng Yan, Li Laibo et al. (2021-01)
Rheological Behaviors and Structure Build-Up of 3D Printed Polypropylene- and Polyvinyl-Alcohol-Fiber-Reinforced Calcium-Sulphoaluminate-Cement Composites - Kaszyńska Maria, Skibicki Szymon, Hoffmann Marcin (2020-12)
3D Concrete Printing for Sustainable Construction - Kruger Jacques, Zeranka Stephan, Zijl Gideon (2019-07)
An Ab-Inito Approach for Thixotropy Characterisation of Nano-Particle-Infused 3D Printable Concrete - Liu Xiongfei, Li Qi, Li Jixiang (2022-04)
Shrinkage and Mechanical Properties Optimization of Spray-Based 3D Printed Concrete by PVA-Fiber - Liu Junli, Setunge Sujeeva, Tran Jonathan (2022-07)
3D Concrete Printing with Cement-Coated Recycled Crumb Rubber:
Compressive and Microstructural Properties - 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 - 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 - Moeini Mohammad, Hosseinpoor Masoud, Yahia Ammar (2022-04)
3D Printing of Cement-Based Materials with Adapted Buildability - Roussel Nicolas (2018-05)
Rheological Requirements for Printable Concretes - Sambucci Matteo, Biblioteca Ilario, Valente Marco (2023-01)
Life Cycle Assessment (LCA) of 3D Concrete Printing and Casting Processes for Cementitious Materials Incorporating Ground Waste Tire Rubber - Sambucci Matteo, Valente Marco (2021-06)
Influence of Waste-Tire-Rubber-Particles-Size on the Microstructural, Mechanical, and Acoustic Insulation Properties of 3D Printable Cement Mortars - Schutter Geert, Lesage Karel, Mechtcherine Viktor, Nerella Venkatesh et al. (2018-08)
Vision of 3D Printing with Concrete:
Technical, Economic and Environmental Potentials - Singh Amardeep, Liu Qiong, Xiao Jianzhuang, Lyu Qifeng (2022-02)
Mechanical and Macrostructural Properties of 3D Printed Concrete Dosed with Steel-Fibers under Different Loading-Direction - Sun Junbo, Aslani Farhad, Lu Jenny, Wang Lining et al. (2021-06)
Fiber-Reinforced Lightweight Engineered Cementitious Composites for 3D Concrete Printing - Sun Xiaoyan, Zhou Jiawei, Wang Qun, Shi Jiangpeng et al. (2021-11)
PVA-Fiber-Reinforced High-Strength Cementitious Composite for 3D Printing:
Mechanical Properties and Durability - Valente Marco, Sibai Abbas, Sambucci Matteo (2019-09)
Extrusion-Based Additive Manufacturing of Concrete Products:
Revolutionizing and Remodeling the Construction Industry - Weng Yiwei, Li Mingyang, Liu Zhixin, Lao Wenxin et al. (2018-12)
Printability and Fire Performance of a Developed 3D Printable Fiber-Reinforced Cementitious Composites under Elevated Temperatures - Xiao Jianzhuang, Han Nv, Zhang Lihai, Zou Shuai (2021-05)
Mechanical and Microstructural Evolution of 3D Printed Concrete with Polyethylene-Fiber and Recycled Sand at Elevated Temperatures - Xiao Jianzhuang, Zou Shuai, Ding Tao, Duan Zhenhua et al. (2021-08)
Fiber-Reinforced Mortar with 100% Recycled Fine Aggregates:
A Cleaner Perspective on 3D Printing - Yalçınkaya Çağlar (2022-03)
Influence of Hydroxypropyl Methylcellulose Dosage on the Mechanical Properties of 3D Printable Mortars with and without Fiber-Reinforcement - Yang Yekai, Wu Chengqing, Liu Zhongxian, Wang Hailiang et al. (2021-10)
Mechanical Anisotropy of Ultra-High-Performance Fiber-Reinforced Concrete for 3D Printing - Yao Xiaofei, Lyu Xin, Sun Junbo, Wang Bolin et al. (2023-03)
AI-Based Performance Prediction for 3D Printed Concrete Considering Anisotropy and Steam-Curing Condition - Ye Junhong, Cui Can, Yu Jiangtao, Yu Kequan et al. (2021-01)
Fresh and Anisotropic-Mechanical Properties of 3D Printable Ultra-High-Ductile Concrete with Crumb-Rubber - Zhang Yu, Zhang Yunsheng, She Wei, Yang Lin et al. (2019-01)
Rheological and Hardened Properties of the High-Thixotropy 3D Printing Concrete - Zhou Yiyi, Jiang Dan, Sharma Rahul, Xie Yi et al. (2022-11)
Enhancement of 3D Printed Cementitious Composite by Short Fibers:
A Review
8 Citations
- Sun Yuhang, Li Chuang, Liu Xiongfei, Wang Li et al. (2025-11)
Enhancing Sulfate Resistance of Spray-Based 3D Printed Recycled Tunnel Slag Concrete Through Polypropylene Fiber Optimization - Varghese Renny, Rangel Bárbara, Maia Lino (2025-10)
Strength, Structure, and Sustainability in 3D-Printed Concrete Using Different Types of Fiber Reinforcements - Liu Shijie, Liu Tong, Alqurashi Muwaffaq, Abdou Elabbasy Ahmed et al. (2025-09)
Advancing 3D-Printed Fiber-Reinforced Concrete for Sustainable Construction:
A Comparative Optimization Based Study of Hybrid Machine Intelligence Models for Predicting Mechanical Strength and CO₂ Emissions - Bajwa Asad, Samarasinghe Don, Flemmer Claire, Bao Ding (2025-06)
A Systematic Literature Review on the Thermal Behaviour of Building Elements Constructed Through 3D Concrete Printing (3DCP) - Mishra Sanjeet, Upadhyay Bikash, Das B. (2025-06)
Exploring the Role of Metakaolin in Binary and Ternary Blended 3D Printable Mortars:
Deep Insights into Printability - Raza Ali, Junjie Zhang, Fan Jiahui, Umar Muhammad et al. (2025-05)
Comprehensive Study on the Microstructural and Mechanical Performance of 3D-Printed Engineered Cementitious Composites with Yellow River Sand Integration - Mim Nusrat, Shaikh Faiz, Sarker Prabir (2025-03)
Sustainable 3D Printed Concrete Incorporating Alternative Fine Aggregates:
A Review - Venugopal Reddy P., Nakkeeran G., Roy Dipankar, Alaneme George (2024-11)
Evaluating the Use of Recycled Fine Aggregates in 3D Printing:
A Systematic Review
BibTeX
@article{bodu_meci_benl_bayr.2024.DoGR3PLCCRwMAaMSF,
author = "Burak Bodur and Muhammet Ahmet Mecit Işık and Ahmet Benli and Barış Bayrak and Ali Öz and Oguzhan Yavuz Bayraktar and Gökhan Kaplan and Abdulkadir Cüneyt Aydın",
title = "Durability of Green Rubberized 3D Printed Lightweight Cement Composites Reinforced with Micro-Attapulgite and Micro-Steel-Fibers: Printability and Environmental Perspective",
doi = "10.1016/j.jobe.2024.109447",
year = "2024",
journal = "Journal of Building Engineering",
volume = "90",
pages = "109447",
}
Formatted Citation
B. Bodur, “Durability of Green Rubberized 3D Printed Lightweight Cement Composites Reinforced with Micro-Attapulgite and Micro-Steel-Fibers: Printability and Environmental Perspective”, Journal of Building Engineering, vol. 90, p. 109447, 2024, doi: 10.1016/j.jobe.2024.109447.
Bodur, Burak, Muhammet Ahmet Mecit Işık, Ahmet Benli, Barış Bayrak, Ali Öz, Oguzhan Yavuz Bayraktar, Gökhan Kaplan, and Abdulkadir Cüneyt Aydın. “Durability of Green Rubberized 3D Printed Lightweight Cement Composites Reinforced with Micro-Attapulgite and Micro-Steel-Fibers: Printability and Environmental Perspective”. Journal of Building Engineering 90 (2024): 109447. https://doi.org/10.1016/j.jobe.2024.109447.