Acknowledgement
본연구는 한국건설기술연구원 구조연구본부 목적형 R&R "국민 안전과 건전한 인프라 환경을 위한 지속가능한 인프라구조 기술 연구(과제번호: 20240156)"의 시드과제 "순환자원활용 건설 3D 프린팅 기반 저비용 변단면 거푸집 기술 개발"의 일환으로 수행된 연구임.
References
- Ahn, H. J., Lee, D. Y., Ji, W. J., Lee, W. J., and Cho, H. H. (2020), Development of Method for Manufacturing Freeform EPS Forms Using Sloped-LOM Type 3D Printer, Journal of the Korea Institute of Building Construction, 20(2), 171-181 (in Korean).
- ASTM Standard C39. (2012), Standard Test Method for Compressive Strength of Cylindrical Concrete Specimens, ASTM Standard International.
- Chang, Z., Liang, M., Chen, Y., Schlangen, E., and Savija, B. (2023), Does early age creep influence buildability of 3D printed concrete? Insights from numerical simulations, Additive Manufacturing, 77, 103788.
- Jha, K. N. (2012), Formwork for Concrete Structures, Tata Mc Graw Hill Education Private Limited.
- KCI-CT115, (2021), Standard Method of Making Compressive Strength Specimens of Underwater Additive Layering Concrete, Standards of the Korean Concrete Society (in Korean).
- Khan, M. S., Sanchez, F., and Zhou, H. (2020), 3-D printing of concrete: Beyond horizons, Cement and Concrete Research, 133, 106070.
- KS F 2405. (2022), Test method for compressive strength of concrete, Korea Standards Association (in Korean).
- KS L 5111. (2022), Flow table use in tests of hydraulic cement. Korea Standards Association (in Korean).
- Lee, D. K. (2017), 3D Printing Technology for Building Construction, Journal of Korean Association for Spatial Structures, 17(4), 16-19 (in Korean).
- Lee, H. J., Kim, J. H. J., Moon, J. H., Kim, W. W., and Seo, E. A. (2019), Evaluation of the Mechanical Properties of a 3D-Printed Mortar, Materials, 12(24), 4104.
- Lee, H. J., Kim, W. W., Seo, E. A., and Moon, J. H. (2020), Effect of Shrinkage Characteristics of Cement-Based Composites by Extrusion and Lamination Process of Construction 3D Printing, Journal of the Korea Institute for Structural Maintenance and Inspection, 24(6), 113-118 (in Korean).
- Lee, H. J., Moon, H. J., and Kim, J. J. (2012), An Experimental Study on Pumpability Characteristics of High Strength Concrete Mixed Polymix, Journal of the Korea Concrete Institute, 24(5), 509-516 (in Korean). https://doi.org/10.4334/JKCI.2012.24.5.509
- Lee, J. Y., and Lee, T. S. (2020), Using In Situ Resources and 3D Printing for Space Exploration Habitat Construction, Journal of Civil and Environmental Engineering Research, 40(3), 337-343 (in Korean).
- Liu, H., Liu, C., Wu, Y., Bai, G., He, C., Yao, Y., Zhang, R., and Wang, Y. (2022), 3D printing concrete with recycled coarse aggregates: The influence of pore structure on interlayer adhesion, Cement and Concrete Composites, 134, 104742.
- Mazhoud, B., Perrot, A., Picandet, V., Rangeard, D., and Courteille, E. (2019), Underwater 3D printing of cement-based mortar: Construction and Building Materials, 214, 458-467. https://doi.org/10.1016/j.conbuildmat.2019.04.134
- Muthukrishnan, S., Ramakrishnan, S., and Sanjayan, J. (2021), Technologies for improving buildability in 3D concrete printing, Cement and Concrete Composites, 122, 104144.
- Seo, E. A., Kim, W. W., Kim, S. W., Kwon, H. K., and Lee, H. J. (2023a), Mechanical properties of 3D printed concrete with coarse aggregates and polypropylene fiber in the air and underwater environment, Construction and Building Materials, 378, 131184.
- Seo, E. A., Lee, H. J., and Yang, K. H. (2023b), Strength Characteristics of 3D Printed Composite Materials According to Lamination Patterns, Journal of the Korea Institute for Structural Maintenance and Inspection, 25(6), 193-198 (in Korean).
- Seo, E. A., Yang, K. H., and Lee, H. J. (2022), Experimental Study for Evaluating Early Age Shrinkage of Mortar for 3D Printing, Journal of the Korea Institute for Structural Maintenance and Inspection, 26(2), 76-83 (in Korean).
- Wang, L., Ye, K., Wan, Q., Li, Z., and Ma, G. (2023), Inclined 3D concrete printing: Build-up prediction and early-age performance optimization, Additive Manufacturing, 71, 103595.
- Wangler, T., Roussel, N., Bos, F. P., Salet, T. A. M., and Flatt, R. J. (2019), Digital Concrete: A Review, Cement and Concrete Research, 123, 105780.
- Wolfs, R. J. M., Bos, F. P., and Salet, T. A. M. (2018), Early age mechanical behaviour of 3D printed concrete: Numerical modelling and experimental testing, Cement and Concrete Research, 106, 103-116. https://doi.org/10.1016/j.cemconres.2018.02.001
- Wolfs, R., Bos, D., and Salet, T. (2023), Lessons learned of project Milestone: The first 3D printed concrete house in the Netherlands, Materials Today Proceedings, 1-6.
- Won, H. J. (2021), Strength characteristics of 3D printed concrete according to the stacking direction, Journal of the Korea AcademiaIndustrial Cooperation Society, 22(2), 632-637 (in Korean). https://doi.org/10.5762/KAIS.2021.22.12.632
- Woo, S. J., Yang, J. M., Lee, H. J., and Kwon, H. K. (2021), Comparison of Properties of 3D-Printed Mortar in Air vs. Underwater, Materials, 14(19), 5888.
- Zhang, J., and Khoshnevis, B. (2013), Optimal machine operation planning for construction by Contour Crafting, Automation in Construction, 29, 50-67. https://doi.org/10.1016/j.autcon.2012.08.006
- Zhu, B., Pan, J., Nematollahi, B., Zhou, Z., Zhang, Y., and Sanjayan, J. (2019), Development of 3D printable engineered cementitious composites with ultra-high tensile ductility for digital construction, Materials & Design, 181, 108088.
- Zou, M., Liu, C., Zhang, K., Li, W., Cao, Q., Zhang, L., Gu, T., Zhang, G., and Liu, L. (2023), Evaluation and control of printability and rheological properties of 3D-printed rubberized concrete, Journal of Building Engineering, 80, 107988.