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Printability, Engineering Properties and Environmental Implications of 3D-Printed Cementitious Mortars Incorporating Hydrated Lime, Tile Powder and Accelerator (2025-12)

10.1080/19648189.2025.2594585

 Öztürk Ece,  Ince Ceren,  Borgianni Yuri,  Nicolaides Demetris,  Ball Richard
Journal Article - European Journal of Environmental and Civil Engineering, pp. 1-34

Abstract

3D printing offers transformative potential in construction, yet optimising the performance of cementitious materials before and after extrusion remains a critical challenge. This study presents a performance-based mix design framework targeting extrudability, buildability, and layer stability, while evaluating the individual and combined effects of cement (C), hydrated lime (L), recycled tile powder (T), and chemical accelerators (A). Results reveal that their synergy significantly enhances rheology, yield stress, and print stability, while maintaining sufficient flowability. A specifically optimised mix, CLTA, achieved a 40% reduction in shrinkage, improved interlayer bonding, and markedly increased mechanical strength, modulus of toughness, and failure strain, key for energy absorption in printed structures. Environmentally, CLTA reduced raw material demand and improved eco-strength and cost-efficiency by up to 20%, promoting circularity and resource efficiency. The findings provide a robust pathway for designing high-performance, sustainable 3D-printed mortars, integrating engineering functionality with ecological resilience, paving the way for broader adoption of additive manufacturing in construction.

54 References

  1. Bai Gang, Wang Li, Ma Guowei, Sanjayan Jay et al. (2021-03)
    3D Printing Eco-Friendly Concrete Containing Under-Utilised and Waste Solids as Aggregates
  2. Bao Ta, Yeakleang Muy, Abdelouhab Sandra, Courard Luc (2024-10)
    Testing Mortars for 3D Printing:
    Correlation with Rheological Behavior
  3. Barbosa Marcella, Anjos Marcos, Cabral Kleber, Souza Dias Leonardo (2022-05)
    Development of Composites for 3D Printing with Reduced Cement Consumption
  4. Bayat Hamid, Kashani Alireza (2023-09)
    Analysis of Rheological Properties and Printability of a 3D Printing Mortar Containing Silica-Fume, Hydrated Lime, and Blast-Furnace-Slag
  5. Chang Ze, Chen Yu, Schlangen Erik, Šavija Branko (2023-09)
    A Review of Methods on Buildability Quantification of Extrusion-Based 3D Concrete Printing:
    From Analytical Modelling to Numerical Simulation
  6. Chen Yu, He Shan, Gan Yidong, Çopuroğlu Oğuzhan et al. (2021-11)
    A Review of Printing-Strategies, Sustainable Cementitious Materials and Characterization Methods in the Context of Extrusion-Based 3D Concrete Printing
  7. Cho Eunsan, Gwon Seongwoo, Cha Soowon, Shin Myoungsu (2025-04)
    Impact of Accelerator on Rheological Properties of Cement Composites with Cellulose Microfibers:
    3D Printing Perspective
  8. Colyn Markus, Zijl Gideon, Babafemi Adewumi (2024-02)
    Fresh and Strength Properties of 3D Printable Concrete Mixtures Utilising a High Volume of Sustainable Alternative Binders
  9. Cui Hongzhi, Li Yuanhong, Cao Xiangpeng, Huang Mingyang et al. (2022-03)
    Experimental Study of 3D Concrete Printing-Configurations Based on the Buildability Evaluation
  10. Dams Barrie, Shepherd Paul, Ball Richard (2023-11)
    Development and Performance Evaluation of Fibrous Pseudoplastic Quaternary Cement Systems for Aerial Additive Manufacturing
  11. Dey Dhrutiman, Srinivas Dodda, Panda Biranchi, Suraneni Prannoy et al. (2022-02)
    Use of Industrial Waste-Materials for 3D Printing of Sustainable Concrete:
    A Review
  12. Fasihi Ali, Libre Nicolas (2024-01)
    From Pumping to Deposition:
    A Comprehensive Review of Test-Methods for Characterizing Concrete-Printability
  13. Gu Yucun, Khayat Kamal (2024-05)
    Extrudability Window and Off-Line Test-Methods to Predict Buildability of 3D Printing Concrete
  14. Hou Shaodan, Duan Zhenhua, Xiao Jianzhuang, Ye Jun (2020-12)
    A Review of 3D Printed Concrete:
    Performance-Requirements, Testing Measurements and Mix-Design
  15. Hou Shaodan, Xiao Jianzhuang, Duan Zhenhua, Ma Guowei (2021-10)
    Fresh Properties of 3D Printed Mortar with Recycled Powder
  16. İlcan Hüseyin, Şahin Oğuzhan, Kul Anil, Yıldırım Gürkan et al. (2022-03)
    Rheological Properties and Compressive Strength of Construction and Demolition Waste-Based Geopolymer Mortars for 3D Printing
  17. Jayathilakage Roshan, Rajeev Pathmanathan, Sanjayan Jay (2022-08)
    Rheometry for Concrete 3D Printing:
    A Review and an Experimental Comparison
  18. Jin Yuan, Jiang Chengzhi, Gan Xingyu, Sun Zhaoyang et al. (2025-07)
    Enhancing the Printability of 3D Printed White Cementitious Materials with Accelerators:
    Evolution of Early-Age Hydration and Rheology
  19. Khan Shoukat, Koç Muammer (2023-03)
    Buildability-Analysis of 3D Concrete Printing Process:
    A Parametric Study Using Design of Experiment-Approach
  20. Kristombu Baduge Shanaka, Navaratnam Satheeskumar, Zidan Yousef, McCormack Tom et al. (2021-01)
    Improving Performance of Additive Manufactured Concrete:
    A Review on Material Mix-Design, Processing, Inter-Layer Bonding, and Reinforcing-Methods
  21. Li Jiannan, Singh Amardeep, Zhao Yasong, Sun Jingting et al. (2024-11)
    Enhancing Thermo-Mechanical and Moisture Properties of 3D Printed Concrete Through Recycled Ultra-Fine Waste-Glass-Powder
  22. Liu Qiong, Cheng Shengbo, Sun Chang, Chen Kailun et al. (2023-11)
    Steel-Cable Bonding in Fresh Mortar and 3D Printed Beam Flexural Behavior
  23. 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
  24. Long Wujian, Tao Jie-Lin, Lin Can, Gu Yucun et al. (2019-08)
    Rheology and Buildability of Sustainable Cement-Based Composites Containing Micro-Crystalline Cellulose for 3D Printing
  25. Ma Guowei, Li Zhijian, Wang Li (2017-12)
    Printable Properties of Cementitious Material Containing Copper-Tailings for Extrusion-Based 3D Printing
  26. Ma Guowei, Sun Junbo, Wang Li, Aslani Farhad et al. (2018-09)
    Electromagnetic and Microwave-Absorbing Properties of Cementitious Composite for 3D Printing Containing Waste Copper Solids
  27. Mai (née Dressler) Inka, Freund Niklas, Lowke Dirk (2020-01)
    The Effect of Accelerator Dosage on Fresh Concrete Properties and on Inter-Layer Strength in Shotcrete 3D Printing
  28. Moeini Mohammad, Hosseinpoor Masoud, Yahia Ammar (2022-04)
    3D Printing of Cement-Based Materials with Adapted Buildability
  29. Mohan Manu, Rahul Attupurathu, Tittelboom Kim, Schutter Geert (2020-10)
    Rheological and Pumping Behavior of 3D Printable Cementitious Materials with Varying Aggregate Content
  30. Nodehi Mehrab, Ozbakkaloglu Togay, Gholampour Aliakbar (2022-04)
    Effect of Supplementary Cementitious Materials on Properties of 3D Printed Conventional and Alkali-Activated Concrete:
    A Review
  31. Panda Biranchi, Mohamed Nisar, Paul Suvash, Bhagath Singh Gangapatnam et al. (2019-07)
    The Effect of Material Fresh Properties and Process Parameters on Buildability and Inter-Layer Adhesion of 3D Printed Concrete
  32. Papachristoforou Michail, Mitsopoulos Vasilios, Stefanidou Maria (2018-10)
    Evaluation of Workability Parameters in 3D Printing Concrete
  33. Qian Hao, Hua Sudong, Yue Hongfei, Feng Guiyang et al. (2022-09)
    Utilization of Recycled Construction-Powder in 3D Concrete Printable Materials through Particle-Packing-Optimization
  34. Rangel Carolina, Guimarães Ana, Salet Theo, Lucas Sandra (2024-03)
    3D Printing Lightweight Mortars with Cork to Improve Thermal Efficiency in Buildings
  35. Robayo-Salazar Rafael, Vargas Armando, Martínez Fabio, Gutiérrez Ruby (2024-02)
    Utilization of Powders and Fine Aggregates from the Recycling of Construction and Demolition Waste in the 3D Printing of Portland-Based Cementitious Materials
  36. Roussel Nicolas (2018-05)
    Rheological Requirements for Printable Concretes
  37. Şahin Oğuzhan, İlcan Hüseyin, Ateşli Anıl, Kul Anil et al. (2021-05)
    Construction and Demolition Waste-Based Geopolymers Suited for Use in 3D Additive Manufacturing
  38. Shahib Al Bari M., Ekaputri Januarti (2024-09)
    The Effect of Fiber on the Green Strength and Buildability of High-Strength 3D Printing Concrete
  39. Soltan Daniel, Li Victor (2018-03)
    A Self-Reinforced Cementitious Composite for Building-Scale 3D Printing
  40. Sonebi Mohammed, Dedenis Marie, Abdalqader Ahmed, Perrot Arnaud (2021-11)
    Effect of Red Mud, Nano-Clay, and Natural Fiber on Fresh and Rheological Properties of Three-Dimensional Concrete Printing
  41. Souza Marcelo, Ferreira Igor, Moraes Elisângela, Senff Luciano et al. (2020-09)
    3D Printed Concrete for Large-Scale Buildings:
    An Overview of Rheology, Printing Parameters, Chemical Admixtures, Reinforcements, and Economic and Environmental Prospects
  42. Suntharalingam Thadshajini, Nagaratnam Brabha, Poologanathan Keerthan, Hackney Phil et al. (2019-12)
    Effect of Polypropylene-Fibers on the Workability Parameters of Extrudable Cementitious Materials
  43. Suryanto Benny, Higgins J., Aitken M., Tambusay Asdam et al. (2023-10)
    Developments in Portland Cement/GGBS Binders for 3D Printing Applications:
    Material-Calibration and Structural Testing
  44. Taqa Ala, Mohsen Mohamed, Aburumman Mervat, Naji Khalid et al. (2024-05)
    Nano-Fly-Ash and Clay for 3D Printing Concrete Buildings:
    A Fundamental Study of Rheological, Mechanical and Microstructural Properties
  45. Tay Yi, Qian Ye, Tan Ming (2019-05)
    Printability-Region for 3D Concrete Printing Using Slump- and Slump-Flow-Test
  46. Teixeira João, Schaefer Cecília, Maia Lino, Rangel Bárbara et al. (2022-03)
    Influence of Supplementary Cementitious Materials on Fresh Properties of 3D Printable Materials
  47. Tripathi Avinaya, Nair Sooraj, Neithalath Narayanan (2022-01)
    A Comprehensive Analysis of Buildability of 3D Printed Concrete and the Use of Bi-Linear Stress-Strain Criterion-Based Failure Curves Towards Their Prediction
  48. Villiers Wibke, Mwongo Mwiti, Babafemi Adewumi, Zijl Gideon (2024-06)
    Quantifying Recycled Construction and Demolition Waste for Use in 3D Printed Concrete
  49. Wangler Timothy, Pileggi Rafael, Gürel Şeyma, Flatt Robert (2022-03)
    A Chemical Process Engineering Look at Digital Concrete Processes:
    Critical Step Design, In-Line Mixing, and Scale-Up
  50. Yalçınkaya Çağlar (2022-03)
    Influence of Hydroxypropyl Methylcellulose Dosage on the Mechanical Properties of 3D Printable Mortars with and without Fiber-Reinforcement
  51. Yang Huashan, Che Yujun, Shi Mengyuan (2021-07)
    Influences of Calcium-Carbonate-Nano-Particles on the Workability and Strength of 3D Printing Cementitious Materials Containing Limestone-Powder
  52. Zhang Chao, Hou Zeyu, Chen Chun, Zhang Yamei et al. (2019-09)
    Design of 3D Printable Concrete Based on the Relationship Between Flowability of Cement-Paste and Optimum Aggregate-Content
  53. Zhang Chao, Nerella Venkatesh, Krishna Anurag, Wang Shen et al. (2021-06)
    Mix-Design Concepts for 3D Printable Concrete:
    A Review
  54. Zhang Hanghua, Xiao Jianzhuang, Duan Zhenhua, Zou Shuai et al. (2022-06)
    Effects of Printing Paths and Recycled Fines on Drying Shrinkage of 3D Printed Mortar

0 Citations

BibTeX 
@article{oztu_ince_borg_nico.2025.PEPaEIo3PCMIHLTPaA,
  author            = "Ece Öztürk and Ceren Ince and Yuri Borgianni and Demetris Nicolaides and Richard J. Ball",
  title             = "Printability, Engineering Properties and Environmental Implications of 3D-Printed Cementitious Mortars Incorporating Hydrated Lime, Tile Powder and Accelerator",
  doi               = "10.1080/19648189.2025.2594585",
  year              = "2025",
  journal           = "European Journal of Environmental and Civil Engineering",
  pages             = "1--34",
}
Formatted Citation

E. Öztürk, C. Ince, Y. Borgianni, D. Nicolaides and R. J. Ball, “Printability, Engineering Properties and Environmental Implications of 3D-Printed Cementitious Mortars Incorporating Hydrated Lime, Tile Powder and Accelerator”, European Journal of Environmental and Civil Engineering, pp. 1–34, 2025, doi: 10.1080/19648189.2025.2594585.

Öztürk, Ece, Ceren Ince, Yuri Borgianni, Demetris Nicolaides, and Richard J. Ball. “Printability, Engineering Properties and Environmental Implications of 3D-Printed Cementitious Mortars Incorporating Hydrated Lime, Tile Powder and Accelerator”. European Journal of Environmental and Civil Engineering, 2025, 1–34. https://doi.org/10.1080/19648189.2025.2594585.