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TECHNICAL PAPER
ReFeReNces heat-cured mortars, Cement and Concrete Research 31(5)
(2001) 795-803.
[1] H. Haroglu, Investigating the structural frame decision
making process, © Hasan Haroglu, 2010. [15] P. Shakor, S. Nejadi, G. Paul, An Investigation into the
Effects of Deposition Orientation of Material on the
[2] P. Shakor, S. Nejadi, G. Paul, S. Malek, Review of Emerging Mechanical Behaviours of the Cementitious Powder and
Additive Manufacturing Technologies in 3D Printing of Gypsum Powder in Inkjet 3 D Printing, Proceedings of the
Cementitious Materials in the Construction Industry, 36 ISARC, IAARC, Banff, Alberta, Canada, 2019, pp. 42-49.
th
Frontiers in Built Environment 4(85) (2019).
[16] P . Feng, X. Meng, J.-F. Chen, L. Ye, Mechanical properties
[3] F. Hamidi, F. Aslani, Additive manufacturing of cementitious of structures 3D printed with cementitious powders,
composites: Materials, methods, potentials, and challenges, Construction and Building Materials 93 (2015) 486-497.
Construction and Building Materials 218 (2019) 582-609.
[17] P. Feng, X. Meng, H. Zhang, Mechanical behavior of FRP
[4] D. Lowke, E. Dini, A. Perrot, D. Weger, C. Gehlen, sheets reinforced 3D elements printed with cementitious
B. Dillenburger, Particle-bed 3D printing in concrete materials, Composite Structures 134 (2015) 331-342.
construction – Possibilities and challenges, Cement and
Concrete Research (2018). [18] 3DSystems, ZP151 Powder Safety Data Sheet, 2013.
[5] P. Shakor, J. Renneberg, S. Nejadi, G. Paul, Optimisation of [19] A200MIXER, A200 hobart mixer speed specification,
different concrete mix designs for 3D Printing by utilising hobartcorp.
6DOF industrial robot, ISARC 2017-Proceedings of the 34 [20] J. Hill, J. Orr, N. Dunne, In vitro study investigating the
th
International Symposium on Automation and Robotics in mechanical properties of acrylic bone cement containing
Construction, 2017. calcium carbonate nanoparticles, Journal of Materials
Science: Materials in Medicine 19(11) (2008) 3327-3333.
[6] P. Shakor, S. Nejadi, G. Paul, A Study into the Effect of
Different Nozzles Shapes and Fibre-Reinforcement in 3D [21] B. Lothenbach, F. Winnefeld, C. Alder, E. Wieland, P. Lunk,
Printed Mortar, Materials 12(10) (2019) 1708. Effect of temperature on the pore solution, microstructure
and hydration products of Portland cement pastes, Cement
[7] S.C. Paul, G.P.A.G. van Zijl, M.J. Tan, I. Gibson, A review and Concrete Research 37(4) (2007) 483-491.
of 3D concrete printing systems and materials properties:
current status and future research prospects, Rapid [22] M.a.a. Abd elaty, Compressive strength prediction of
Prototyping Journal 24(4) (2018) 784-798. Portland cement concrete with age using a new model,
HBRC Journal 10(2) (2014) 145-155.
[8] A.V. Rahul, M. Santhanam, H. Meena, Z. Ghani, 3D printable
concrete: Mixture design and test methods, Cement and [23] M.N. Amin, K. Khan, M.U. Saleem, N. Khurram, M.U.K.
Concrete Composites 97 (2019) 13-23. Niazi, Aging and curing temperature effects on compressive
strength of mortar containing lime stone quarry dust and
[9] P. Shakor, J. Sanjayan, A. Nazari, S. Nejadi, Modified 3D industrial granite sludge, Materials 10(6) (2017) 642.
printed powder to cement-based material and mechanical
properties of cement scaffold used in 3D printing, [24] PortlandCementAssociation, Ettringite Formation and the
Construction and Building Materials 138 (2017) 398-409. Performance of Concrete, concrete information, USA.
[10] P. Shakor, S. Nejadi, G. Paul, J. Sanjayan, A Novel [25] 3DSystems, ZB63 Safety Data Sheet, 2012.
Methodology of Powder-based Cementitious Materials [26] E. Altan, S.T. Erdoğan, Alkali activation of a slag at ambient
in 3D Inkjet Printing for Construction Applications Sixth and elevated temperatures, Cement and Concrete
International Conference on the Durability of Concrete Composites 34(2) (2012) 131-139.
Structures, Whittles Publishing, Leeds, UK, 2018.
[27] C.L. Bellego, B. Gérard, G. Pijaudier-Cabot, Chemo-
[11] P. Shakor, S. Nejadi, G. Paul, J. Sanjayan, A. Nazari, mechanical effects in mortar beams subjected to water
Mechanical Properties of Cement-Based Materials and hydrolysis, Journal of Engineering Mechanics 126(3) (2000)
Effect of Elevated Temperature on Three-Dimensional 266-272.
(3-D) Printed Mortar Specimens in Inkjet 3-D Printing, ACI [28] K. Sagoe-Crentsil, L. Weng, Dissolution processes,
Materials Journal 116(2) (2019) 55-67.
hydrolysis and condensation reactions during geopolymer
[12] R. Yang, C.D. Lawrence, C.J. Lynsdale, J.H. Sharp, Delayed synthesis: Part II. High Si/Al ratio systems, Journal of
ettringite formation in heat-cured Portland cement mortars, Materials Science 42(9) (2007) 3007-3014.
Cement and Concrete Research 29(1) (1999) 17-25.
[29] S. Mandal, B. Basu, Probing the influence of post-
[13] S. Aydın, B. Baradan, Mechanical and microstructural processing on microstructure and in situ compression failure
properties of heat cured alkali-activated slag mortars, with in silico modeling of 3D-printed scaffolds, Journal of
Materials & Design 35 (2012) 374-383. Materials Research 33(14) (2018) 2062-2076.
[14] C. Famy, K.L. Scrivener, A. Atkinson, A.R. Brough, Influence [30] S. Mandal, S. Meininger, U. Gbureck, B. Basu, 3D powder
of the storage conditions on the dimensional changes of printed tetracalcium phosphate scaffold with phytic
The IndIan ConCreTe Journal | SepTember 2019 73
