Geometric quality evaluation of three-dimensional printable concrete using computational fluid dynamics

Weijiu CUI; Haijun SUN; Jiangang ZHOU; Sheng WANG; Xinyu SHI; Yaxin TAO

doi:10.1007/s11709-024-1080-4

Front. Struct. Civ. Eng. ›› 2024, Vol. 18 ›› Issue (7) : 963 -976. DOI: 10.1007/s11709-024-1080-4

RESEARCH ARTICLE

Geometric quality evaluation of three-dimensional printable concrete using computational fluid dynamics

Weijiu CUI ¹^,²^,³
, Haijun SUN ⁴
, Jiangang ZHOU ⁵
, Sheng WANG ⁶
, Xinyu SHI ⁷
, Yaxin TAO ⁸^,⁹^,^†

Author information +

History +

PDF (16987KB)

Abstract

The importance of geometrical control of three dimensional (3D) printable concrete without the support of formwork is widely acknowledged. In this study, a numerical model based on computational fluid dynamics was developed to evaluate the geometrical quality of a 3D printed layer. The numerical results were compared, using image analysis, with physical cross-sectional sawn samples. The influence of printing parameters (printing speed, nozzle height, and nozzle diameter) and the rheological behavior of printed materials (yield stress), on the geometrical quality of one printed layer was investigated. In addition, the yield zone of the printed layer was analyzed, giving insights on the critical factors for geometrical control in 3D concrete printing. Results indicated that the developed model can precisely describe the extrusion process, as well as the cross-sectional quality.

Graphical abstract

Keywords

digital fabrication / 3D concrete printing / geometric quality / computational fluid dynamics / printing parameters / yield stress

Cite this article

Download citation ▾

Weijiu CUI, Haijun SUN, Jiangang ZHOU, Sheng WANG, Xinyu SHI, Yaxin TAO. Geometric quality evaluation of three-dimensional printable concrete using computational fluid dynamics. Front. Struct. Civ. Eng., 2024, 18(7): 963-976 DOI:10.1007/s11709-024-1080-4

登录浏览全文

4963

注册一个新账户忘记密码

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Wangler T, Pileggi R, Gürel S, Flatt R J. A chemical process engineering look at digital concrete processes: Critical step design, inline mixing, and scaleup. Cement and Concrete Research, 2022, 155: 106782

[2]	Mechtcherine V, van Tittelboom K, Kazemian A, Kreiger E, Nematollahi B, Nerella V N, Santhanam M, de Schutter G, van Zijl G, Lowke D, Ivaniuk E, Taubert M, Bos F. A roadmap for quality control of hardening and hardened printed concrete. Cement and Concrete Research, 2022, 157: 106800

[3]	Tao Y, Lesage K, Van Tittelboom K, Yuan Y, de Schutter G. Twin-pipe pumping strategy for stiffening control of 3D printable concrete: From transportation to fabrication. Cement and Concrete Research, 2023, 168: 107137

[4]	Gebhard L, Esposito L, Menna C, Mata-Falcón J. Inter-laboratory study on the influence of 3D concrete printing set-ups on the bond behaviour of various reinforcements. Cement and Concrete Composites, 2022, 133: 104660

[5]	Marchment T, Sanjayan J. Reinforcement method for 3D concrete printing using paste-coated bar penetrations. Automation in Construction, 2021, 127: 103694

[6]	Ma G, Buswell R, Leal da Silva W R, Wang L, Xu J, Jones S Z. Technology readiness: A global snapshot of 3D concrete printing and the frontiers for development. Cement and Concrete Research, 2022, 156: 106774

[7]	Mohan M K, Rahul A V, de Schutter G, Van Tittelboom K. Extrusion-based concrete 3D printing from a material perspective: A state-of-the-art review. Cement and Concrete Composites, 2021, 115: 103855

[8]	Weng Y, Li M, Ruan S, Wong T N, Tan M J, Ow Yeong K L, Qian S. Comparative economic, environmental and productivity assessment of a concrete bathroom unit fabricated through 3D printing and a precast approach. Journal of Cleaner Production, 2020, 261: 121245

[9]	Xiao J, Zou S, Yu Y, Wang Y, Ding T, Zhu Y, Yu J, Li S, Duan Z, Wu Y, Li L. 3D recycled mortar printing: System development, process design, material properties and on-site printing. Journal of Building Engineering, 2020, 32: 101779

[10]	Tao Y, Vantyghem G, Lesage K, Yuan Y, Corte W D, Tittelboom K V, Schutter G D. Adhesion properties of printable polymer-modified concrete for rock tunnel linings. ACI Materials Journal, 2021, 118(6): 61–73

[11]	de Schutter G, Lesage K, Mechtcherine V, Nerella V N, Habert G, Agusti-Juan I. Vision of 3D printing with concrete—Technical, economic and environmental potentials. Cement and Concrete Research, 2018, 112: 25–36

[12]	Buswell R A, Leal de Silva W R, Jones S Z, Dirrenberger J. 3D printing using concrete extrusion: A roadmap for research. Cement and Concrete Research, 2018, 112: 37–49

[13]	Lu B, Weng Y, Li M, Qian Y, Leong K F, Tan M J, Qian S. A systematical review of 3D printable cementitious materials. Construction and Building Materials, 2019, 207: 477–490

[14]	Nair S A O, Panda S, Santhanam M, Sant G, Neithalath N. A critical examination of the influence of material characteristics and extruder geometry on 3D printing of cementitious binders. Cement and Concrete Composites, 2020, 112: 103671

[15]	BhattacherjeeSSanthanamM. Enhancing buildability of 3D printable concrete by spraying of accelerating admixture on surface. In: Proceedings of Second RILEM International Conference on Concrete and Digital Fabrication: Digital Concrete 2020. Eindhoven: Springer, 2020

[16]	Tao Y, Ren Q, Lesage K, van Tittelboom K, Yuan Y, de Schutter G. Shape stability of 3D printable concrete with river and manufactured sand characterized by squeeze flow. Cement and Concrete Composites, 2022, 133: 104674

[17]	Comminal R, Leal da Silva W R, Andersen T J, Stang H, Spangenberg J. Modelling of 3D concrete printing based on computational fluid dynamics. Cement and Concrete Research, 2020, 138: 106256

[18]	Rahul A V, Mohan M K, De Schutter G, van Tittelboom K. 3D printable concrete with natural and recycled coarse aggregates: Rheological, mechanical and shrinkage behaviour. Cement and Concrete Composites, 2022, 125: 104311

[19]	Yuan Q, Li Z, Zhou D, Huang T, Huang H, Jiao D, Shi C. A feasible method for measuring the buildability of fresh 3D printing mortar. Construction and Building Materials, 2019, 227: 116600

[20]	Buswell R, Xu J, de Becker D, Dobrzanski J, Provis J, Kolawole J T, Kinnell P. Geometric quality assurance for 3D concrete printing and hybrid construction manufacturing using a standardised test part for benchmarking capability. Cement and Concrete Research, 2022, 156: 106773

[21]	Roussel N, Spangenberg J, Wallevik J, Wolfs R. Numerical simulations of concrete processing: From standard formative casting to additive manufacturing. Cement and Concrete Research, 2020, 135: 106075

[22]	Perrot A, Pierre A, Nerella V N, Wolfs R J M, Keita E, Nair S A O, Neithalath N, Roussel N, Mechtcherine V. From analytical methods to numerical simulations: A process engineering toolbox for 3D concrete printing. Cement and Concrete Composites, 2021, 122: 104164

[23]	Reinold J, Nerella V N, Mechtcherine V, Meschke G. Extrusion process simulation and layer shape prediction during 3D-concrete-printing using the particle finite element method. Automation in Construction, 2022, 136: 104173

[24]	Wolfs R J M, Bos F P, Salet T A M. Early age mechanical behaviour of 3D printed concrete: Numerical modelling and experimental testing. Cement and Concrete Research, 2018, 106: 103–116

[25]	Vantyghem G, Ooms T, de Corte W. VoxelPrint: A Grasshopper plug-in for voxel-based numerical simulation of concrete printing. Automation in Construction, 2021, 122: 103469

[26]	Ramyar E, Cusatis G. Discrete fresh concrete model for simulation of ordinary, self-consolidating, and printable concrete flow. Journal of Engineering Mechanics, 2022, 148(2): 04021142

[27]	Remond S, Pizette P. A DEM hard-core soft-shell model for the simulation of concrete flow. Cement and Concrete Research, 2014, 58: 169–178

[28]	Chang Z, Zhang H, Liang M, Schlangen E, Šavija B. Numerical simulation of elastic buckling in 3D concrete printing using the lattice model with geometric nonlinearity. Automation in Construction, 2022, 142: 104485

[29]	Wolfs R J M, Salet T A M, Roussel N. Filament geometry control in extrusion-based additive manufacturing of concrete: The good, the bad and the ugly. Cement and Concrete Research, 2021, 150: 106615

[30]	Pan T, Teng H, Liao H, Jiang Y, Qian C, Wang Y. Effect of shaping plate apparatus on mechanical properties of 3D printed cement-based materials: Experimental and numerical studies. Cement and Concrete Research, 2022, 155: 106785

[31]	PanTGuoRJiangYJiX. How do the contact surface forces affect the interlayer bond strength of 3D printed mortar? Cement and Concrete Composites, 2022, 133: 104675

[32]	Hanada T, Kuroda K, Takahashi K. CFD geometrical optimization to improve mixing performance of axial mixer. Chemical Engineering Science, 2016, 144: 144–152

[33]	Jiang S, He Z, Zhou Y, Xiao X, Cao G, Tong Z. Numerical simulation research on suction process of concrete pumping system based on CFD method. Powder Technology, 2022, 409: 117787

[34]	Mollah M T, Comminal R, Serdeczny M P, Šeta B, Spangenberg J. Computational analysis of yield stress buildup and stability of deposited layers in material extrusion additive manufacturing. Additive Manufacturing, 2023, 71: 103605

[35]	Mollah M T, Comminal R, Serdeczny M P, Pedersen D B, Spangenberg J. Stability and deformations of deposited layers in material extrusion additive manufacturing. Additive Manufacturing, 2021, 46: 102193

[36]	Mollah M T, Comminal R, Leal da Silva W R, Šeta B, Spangenberg J. Computational fluid dynamics modelling and experimental analysis of reinforcement bar integration in 3D concrete printing. Cement and Concrete Research, 2023, 173: 107263

[37]	Mollah M T, Comminal R, Serdeczny M P, Pedersen D B, Spangenberg J. Numerical predictions of bottom layer stability in material extrusion additive manufacturing. Journal of the Minerals Metals & Materials Society, 2022, 74(3): 1096–1101

[38]	Spangenberg J, Leal da Silva W R, Comminal R, Mollah M T, Andersen T J, Stang H. Numerical simulation of multi-layer 3D concrete printing. RILEM Technical Letters, 2021, 6: 119–123

[39]

Spangenberg J, Leal da Silva W R. In: Buswell R, Blanco A, Cavalaro S, Kinnell P. Eds. Integrating reinforcement with 3D concrete printing: Experiments and numerical modelling. In: Proceedings of Third RILEM International Conference on Concrete and Digital Fabrication. Cham: Springer International Publishing, 2022, 379–384

[40]	Liu Z, Li M, Weng Y, Qian Y, Wong T N, Tan M J. Modelling and parameter optimization for filament deformation in 3D cementitious material printing using support vector machine. Composites. Part B, Engineering, 2020, 193: 108018

[41]	Liu Z, Li M, Tay Y W D, Weng Y, Wong T N, Tan M J. Rotation nozzle and numerical simulation of mass distribution at corners in 3D cementitious material printing. Additive Manufacturing, 2020, 34: 101190

[42]	He L, Chow W T, Li H. Effects of interlayer notch and shear stress on interlayer strength of 3D printed cement paste. Additive Manufacturing, 2020, 36: 101390

[43]	Mohan M K, Rahul A V, van Tittelboom K, de Schutter G. Rheological and pumping behaviour of 3D printable cementitious materials with varying aggregate content. Cement and Concrete Research, 2021, 139: 106258

[44]	Tao Y, Rahul A V, Mohan M K, van Tittelboom K, Yuan Y, de Schutter G. Blending performance of helical static mixer used for twin-pipe 3D concrete printing. Cement and Concrete Composites, 2022, 134: 104741

[45]	Lloret-Fritschi E, Quadranti E, Scotto F, Fuhrimann L, Demoulin T, Mantellato S, Unteregger L, Burger J, Pileggi R G, Gramazio F, Kohler M, Flatt R J. Additive digital casting: From lab to industry. Materials, 2022, 15(10): 3468

[46]	Shantanu B, Smrati J, Manu S. Criticality of binder-aggregate interaction for buildability of 3D printed concrete containing limestone calcined clay. Cement and Concrete Composites, 2023, 136: 104853

[47]	Roussel N. Rheological requirements for printable concretes. Cement and Concrete Research, 2018, 112: 76–85

[48]	Tao Y, Rahul A V, Lesage K, Yuan Y, van Tittelboom K, de Schutter G. Stiffening control of cement-based materials using accelerators in inline mixing processes: Possibilities and challenges. Cement and Concrete Composites, 2021, 119: 103972

[49]	Hou S, Duan Z, Xiao J, Ye J. A review of 3D printed concrete: Performance requirements, testing measurements and mix design. Construction and Building Materials, 2021, 273: 121745

[50]	Chen Y, Chaves Figueiredo S, Li Z, Chang Z, Jansen K, Çopuroğlu O, Schlangen E. Improving printability of limestone-calcined clay-based cementitious materials by using viscosity-modifying admixture. Cement and Concrete Research, 2020, 132: 106040