[1] [1] WANG Y L,WANG C F,ZHANG F Y. Review on performance requirements and related admixtures of 3D printed concrete［J］. Bulletin of the Chinese Ceramic Society,2021,40(6): 1844-1854 (in Chinese).

[2] [2] LEI B,MA Y,XIONG Y C,et al. Study on preparation method of 3D printing concrete material［J］. Concrete,2018(2): 145-149+153 (in Chinese).

[3] [3] QI S,LI Q Y,CUI X P,et al. Research status and prospect of 3D printed concrete materials［J］. Concrete,2021(1): 36-39 (in Chinese).

[4] [4] JIAO Z K,WANG D M,WANG Q B,et al. Influencing factors and testing methods of printability of 3D printing concrete materials［J］. Bulletin of the Chinese Ceramic Society,2021,40(6): 1821-1831 (in Chinese).

[5] [5] CHANG X D,LI W H,WANG Q. Research progress of 3D printed concrete materials and its performance test［J］. Bulletin of the Chinese Ceramic Society,2019,38(8): 2435-2441 (in Chinese).

[6] [6] HOU S D,XIAO J Z,DUAN Z H,et al. Fresh properties of 3D printed mortar with recycled powder［J］. Construction and Building Materials,2021,309: 125186.

[7] [7] PANDA B,UNLUER C,TAN M J. Investigation of the rheology and strength of geopolymer mixtures for extrusion-based 3D printing［J］. Cement and Concrete Composites,2018,94: 307-314.

[8] [8] CHEN,LI,FIGUEIREDO C,et al. Limestone and calcined clay-based sustainable cementitious materials for 3D concrete printing: a fundamental study of extrudability and early-age strength development［J］. Applied Sciences,2019,9(9): 1809.

[9] [9] LONG W J,TAO J L,LIN C,et al. Rheology and buildability of sustainable cement-based composites containing micro-crystalline cellulose for 3D-printing［J］. Journal of Cleaner Production,2019,239: 118054.

[10] [10] PEI Q,HU S C,DING Y. Research status and application exploration of cement-based materials modified by fly ash in building 3D printing［J］. Coal Technology,2022,41(9): 223-226 (in Chinese).

[11] [11] FAN J,ZOU S Q,YANG Y F,et al. Experimental study on mechanical and drying shrinkage properties of high volume fly ash cement mortar［J］. Concrete,2020(6): 130-133 (in Chinese).

[12] [12] LI W H,CHANG X D,WANG Q,et al. Effect of mineral admixture on properties of 3D printing cement-based materials［J］. Bulletin of the Chinese Ceramic Society,2020,39(10): 3101-3107+3114 (in Chinese).

[13] [13] WU W H,LUO S R,OU X,et al. Effect of mineral admixtures on mechanical anisotropy of 3D printed cement-based materials［J］. Journal of Fuzhou University (Natural Science Edition),2023,51(2): 286-292 (in Chinese).

[14] [14] WANG Y Q,PAN G H,ZHANG J Y. Research on application of attapulgite in building material［J］. Bulletin of the Chinese Ceramic Society,2010,29(6): 1353-1357 (in Chinese).

[15] [15] WU Y R,JIN J,CHEN B Z,et al. Review on the application of palygorskite in building materials［J］. Bulletin of the Chinese Ceramic Society,2018,37(8): 2436-2441 (in Chinese).

[16] [16] PANDA B,RUAN S Q,UNLUER C,et al. Improving the 3D printability of high volume fly ash mixtures via the use of nano attapulgite clay［J］. Composites Part B: Engineering,2019,165: 75-83.

[17] [17] HUANG Y L,YUAN Q,LIU Y Q,et al. Influence of additives on slipform construction performance of semi-fluidity self-compacting concrete［J］. Materials Reports,2019,33(supplement 1): 254-260 (in Chinese).

[18] [18] YU Y,JIA J H,DUAN B,et al. Effects of attapulgite and nano-silica on 3D printability of high strength gypsum plaster［J］. Bulletin of the Chinese Ceramic Society,2021,40(6): 1987-1996 (in Chinese).

[19] [19] ZHOU W,ZHANG Y M,MA L,et al. Influence of printing parameters on 3D printing engineered cementitious composites (3DP-ECC)［J］. Cement and Concrete Composites,2022,130: 104562.

[20] [20] BUSWELL R A,LEAL DE SILVA W R,JONES S Z,et al. 3D printing using concrete extrusion: a roadmap for research［J］. Cement and Concrete Research,2018,112: 37-49.

[21] [21] MA G W,WANG L,JU Y. State-of-the-art of 3D printing technology of cementitious material: an emerging technique for construction［J］. Science China Technological Sciences,2018,61(4): 475-495.

[22] [22] YANG H S,CHE Y J. Recycling of aggregate micro fines as a partial replacement for fly ash in 3D printing cementitious materials［J］. Construction and Building Materials,2022,321: 126372.

[23] [23] MORTADA Y,MOHAMMAD M,MANSOOR B,et al. Development of test methods to evaluate the printability of concrete materials for additive manufacturing［J］. Materials,2022,15(18): 6486.

[24] [24] SONEBI M,ABDALQADER A,FAYYAD T,et al. Optimisation of rheological parameters,induced bleeding,permeability and mechanical properties of supersulfated cement grouts［J］. Construction and Building Materials,2020,262: 120078.

[25] [25] ZHANG Y,ZHANG Y S,LIU G J,et al. Fresh properties of a novel 3D printing concrete ink［J］. Construction and Building Materials,2018,174: 263-271.

[26] [26] YANG H S,CHE Y J,SHI M Y. Influences of calcium carbonate nanoparticles on the workability and strength of 3D printing cementitious materials containing limestone powder［J］. Journal of Building Engineering,2021,44: 102976.

[27] [27] KHALIL N,AOUAD G,EL CHEIKH K,et al. Use of calcium sulfoaluminate cements for setting control of 3D-printing mortars［J］. Construction and Building Materials,2017,157: 382-391.

[28] [28] TANG Z Z,JIA L T,LIN Y Q,et al. Effect of tungsten tailing powder on rheology,hydration and mechanical properties of cement-based 3D printing concrete［J］. Materials Reports,2023: 15 (in Chinese).

[29] [29] BAZ B,AOUAD G,KLEIB J,et al. Durability assessment and microstructural analysis of 3D printed concrete exposed to sulfuric acid environments［J］. Construction and Building Materials,2021,290: 123220.

[30] [30] YE J H,ZHENG Y,YU J T,et al. Research progress on 3D printable fiber reinforced concrete［J］. Journal of the Chinese Ceramic Society,2021,49(11): 2538-2548 (in Chinese).

[31] [31] PANDA B,CHANDRA PAUL S,JEN TAN M. Anisotropic mechanical performance of 3D printed fiber reinforced sustainable construction material［J］. Materials Letters,2017,209: 146-149.

[32] [32] CHE Y J,YANG H S. Hydration products,pore structure,and compressive strength of extrusion-based 3D printed cement pastes containing nano calcium carbonate［J］. Case Studies in Construction Materials,2022,17: e01590.

[33] [33] WANG L,LI D L,YE K H,et al. Quantification,optimization and standardization of 3D printability of cementitious composites［J］. Bulletin of the Chinese Ceramic Society,2021,40(6): 1814-1820 (in Chinese).

[34] [34] MA G W,LI Z J,WANG L. Printable properties of cementitious material containing copper tailings for extrusion based 3D printing［J］. Construction and Building Materials,2018,162: 613-627.

[35] [35] VARELA H,BARLUENGA G,PALOMAR I. Influence of nanoclays on flowability and rheology of SCC pastes［J］. Construction and Building Materials,2020,243: 118285.

[36] [36] YAN J,YU X T,LIU X L,et al. Effect of nano attapulgite on properties of recycled aggregate concrete［J］. Science Technology and Engineering,2023,23(23): 10059-10066 (in Chinese).

[37] [37] LIU J. Effecting research of air-entraining agent and attapulgite on thixotropy performance of fresh concrete［J］. China Concrete and Cement Products,2016(4): 5-9 (in Chinese).

[38] [38] YAN J,LU C,BAI Y Q,et al. Study on the influence of calcined nano-attapulgite on splitting and bending strength of recycled concrete［J］. Journal of Jiangsu University of Science and Technology (Natural Science Edition),2023,37(4): 111-118 (in Chinese).

[39] [39] YAN J,LIU X L,WANG X T,et al. Influence of nano-attapulgite on compressive strength and microstructure of recycled aggregate concrete［J］. Cement and Concrete Composites,2022,134: 104788.

[40] [40] CHEN M X,LI L B,WANG J A,et al. Rheological parameters and building time of 3D printing sulphoaluminate cement paste modified by retarder and diatomite［J］. Construction and Building Materials,2020,234: 117391.

[41] [41] RAHUL A V,SANTHANAM M,MEENA H,et al. 3D printable concrete: mixture design and test methods［J］. Cement and Concrete Composites,2019,97: 13-23.

[42] [42] YUAN Q,ZHOU D J,KHAYAT K H,et al. On the measurement of evolution of structural build-up of cement paste with time by static yield stress test vs small amplitude oscillatory shear test［J］. Cement and Concrete Research,2017,99: 183-189.

[43] [43] JIN Y,XU J B,SUN D T,et al. Effect of nano-silica on structural deformation,rheological and mechanical properties of 3D printed white Portland cement-based materials［J］. Bulletin of the Chinese Ceramic Society,2021,40(6): 1855-1862 (in Chinese).

[44] [44] ROUSSEL N. A thixotropy model for fresh fluid concretes: theory,validation and applications［J］. Cement and Concrete Research,2006,36(10): 1797-1806.

[45] [45] PERROT A,PIERRE A,VITALONI S,et al. Prediction of lateral form pressure exerted by concrete at low casting rates［J］. Materials and Structures,2015,48(7): 2315-2322.

[46] [46] QIAN Y,KAWASHIMA S. Use of creep recovery protocol to measure static yield stress and structural rebuilding of fresh cement pastes［J］. Cement and Concrete Research,2016,90: 73-79.

[47] [47] QUANJI Z J,LOMBOY G R,WANG K J. Influence of nano-sized highly purified magnesium alumino silicate clay on thixotropic behavior of fresh cement pastes［J］. Construction and Building Materials,2014,69: 295-300.

[48] [48] YAO H,XIE Z L,LI Z M,et al. The relationship between the rheological behavior and interlayer bonding properties of 3D printing cementitious materials with the addition of attapulgite［J］. Construction and Building Materials,2022,316: 125809.

[49] [49] PANDA B,PAUL S C,HUI L J,et al. Additive manufacturing of geopolymer for sustainable built environment［J］. Journal of Cleaner Production,2017,167: 281-288.

[50] [50] MA G,R A,XIE P P,et al. 3D-printable aerogel-incorporated concrete: anisotropy influence on physical,mechanical,and thermal insulation properties［J］. Construction and Building Materials,2022,323: 126551.

[51] [51] YE J H,CUI C,YU J T,et al. Fresh and anisotropic-mechanical properties of 3D printable ultra-high ductile concrete with crumb rubber［J］. Composites Part B: Engineering,2021,211: 108639.

[52] [52] HOU S D,XIAO J Z,DUAN Z H. Preparation of 3D printable concrete with small coarse aggregate and its printability and mechanical properties［J］. Journal of Building Materials,2022,25(7): 730-736 (in Chinese).

[53] [53] LI Z M,YUAN Q,ZUO S H,et al. A review on interlayer bonding of 3D printing cement-based materials［J］. China Building Materials Science & Technology,2021,30(3): 18-22 (in Chinese).

[54] [54] PAN T H,JIANG Y Q,HE H,et al. Effect of structural build-up on interlayer bond strength of 3D printed cement mortars［J］. Materials,2021,14(2): 236.