Browse > Article
http://dx.doi.org/10.7844/kirr.2018.27.1.3

3D Printed Building Technology using Recycling Materials  

Baek, Chul-Seoung (Korea Institute of Limestone and Advanced Materials)
Seo, Jun-Hyung (Korea Institute of Limestone and Advanced Materials)
Cho, Jin-Sang (Korea Institute of Limestone and Advanced Materials)
Ahn, Ji-Whan (Korea Institute of Geoscience and Mineral Resources)
Cho, Kye-Hong (Korea Institute of Limestone and Advanced Materials)
Publication Information
Resources Recycling / v.27, no.1, 2018 , pp. 3-13 More about this Journal
Abstract
3D printing, also known as Additive Manufacturing (AM), is being positioned as a new business model of revolutionizing paradigms of existing industries. Launched in early 2000, 3D printing technology for architecture has also advanced rapidly in association with machinery and electronics technologies mostly in the United States and Europe. However, 3D printing systems for architecture require different mechanical characteristics from those of cement/concrete raw materials used in existing construction methods. Accordingly, in order to increase utilization of raw materials produced in the cement and resource recycling industry, it is necessary to develop materials processing and utilization technology, to secure new property evaluation and testing methods, and to secure database related to environmental stability for a long period which aims to reflect characteristics of an architectural 3D printing technology.
Keywords
Additive manufacturing; 3D Printing; Construction material; Industrial waste; Recycling;
Citations & Related Records
Times Cited By KSCI : 2  (Citation Analysis)
연도 인용수 순위
1 Kim, D. H., 2015 : Status and Direction of Development on the 3D Printing Technology for BRP(Building Rapid Printing), Journal of The korean Association For Spatial Structures, 15(3), pp.61-68.   DOI
2 Ministry of Future Creation Science, 2014 : Strategy Technology Road Map for 3D Printing, 3D Convergence Technology Center.
3 WiPS, 2014 : Patent Trend Analysis in 3D Printing, Polymer Science and Technology, 25(1), pp.51-55.
4 Lee, B. J., 2015 : Patent Trend Analysis in 3D Printing, KIC News, 18(1). pp.45-59.
5 Gridlogics, 2014 : 3D Printing Technology Insight Report : An analysis of patenting activity around 3D-Printing from 1990-Current, Gridlogics Technologies Pvt Ltd, pp.1-44.
6 UK Intellectual Property Office Patent Informatics Team, 2013 : 3D Printing : A patent overview, Intellectual Property Office. www.ipo.gov.uk.
7 Oh, J., 2014 : Applicability to the Construction of 3D Printing Technology, Journal of the Korean Society of Civil Enginners, 62(9), pp.38-44.
8 KR Patent No. 1016200740000, 2015 : 3D Printing Apparatus for Manufacturing Cement Product and Method Thereof.
9 KR Patent No. 1016200740000, 2015 : Concrete composition for 3D Printing, Concrete and Manufacturing Method of the Concrete using it.
10 KR Patent No. 1016487640000, 2016 : Construction 3D printer nozzle capable of discharging different material.
11 KR Patent No. 1016661810000, 2016 : Construction 3D printer nozzle capable of cutting layer.
12 KR Patent No. 1020170008346, 2017 : Manufacturing method of structure with reinforced concrete construction using 3d printer.
13 Sachs, E. et al., 1992 : Three dimensional printing: rapid tooling and prototypes directly from CAD representation, Journal of Engineering for Industry, 114(4), pp.481-488.   DOI
14 Dagalakis, N. G., 1989, Stiffness study of a parallel link robot crane for shipbuilding applications, Journal of Offshore Mechanical and Architectural Engineering, 111(3), pp.183-193.   DOI
15 Albus, J. S., 1993 : The NIST RoboC-rane, Journal of Robotic Systems, 10(5), pp.709-724.   DOI
16 Pegna, J., 1997 : Exploratory investigation of solid freeform construction, Automation in Construction, 5(5), pp.427-437.   DOI
17 Hinzewski, C. Corbel, S. and T. Chartier, 1998 : Stereolithography for the fabrication of ceramic three-dimensional parts, Rapid Prototyping Journal, 4(3), pp.104-111.   DOI
18 Buswell, R. A., 2007 : Freeform Construction: Mega-scale Rapid Manufacturing for construction, Automation in Construction, 16(2), pp.224-231.   DOI
19 Khoshnevis, B. and George, B., 2002 : Automated Construction Using Contour Crafting - Applications on Earth and Beyond, Nist Special Publication Sp, pp.489-494.
20 Williams, R. L. et al., 2004 : Self-contained automated construction deposition system, Automation in Construction, 13(3), pp.393-407.   DOI
21 US Patent No. US 8337736 B2., 2012 : Method for automatically producing a conglomerate structure and apparatus therefor.
22 Kwon, H. K., 2002 : Experimental and Analysis of Contour Crafting (CC) Process using Uncured Ceramic Materials, PhD Thesis, University of Southern California.
23 Hwang, D. and Behrokh, K., 2004 : Concrete wall fabrication by contour crafting, 21st International Association for Automation and Robotics in Construction (IAARC 2004), Jeju, Korea.
24 Lim, S. W. et al., 2011 : Development of a viable concrete printing process, The 28th International Association for Automation and Robotics in Construction (IAARC 2011), Seoul, Korea.
25 Lim, S. W. et al., 2009 : Fabricating Construction Components using layered Manufacturing Technology, Global Innovation in Construction Conference, pp.512-520.
26 Le, T. T., 2012 : Hardened properties of high-performance printing concrete, Cement and Concrete Research, 42(3), pp.558-566.   DOI
27 Le, T. T., 2012 : Mix design and fresh properties for high-performance printing concrete, Materials and Structures, 45(8), pp.1221-1232.   DOI
28 Cesaretti, G. et al., 2014 : Building components for an outpost on the Lunar soil by means of a novel 3D printing technology, Acta Astronautica, 93, pp.430-450.   DOI
29 Feng, L. and Liang, Y., 2014 : Study on the Status Quo and Problems of 3D Printed Buildings in China, Global Journals of Human-Social Science Research, 14(5), pp.7-9.
30 Neudecker, S. et al., 2016 : A new robotic spray technology for generative manufacturing of complex concrete structures without formwork, Procedia CIRP, 43, pp.333-338.   DOI
31 Kim, D. H. and Lee, J. H., 2015 : Status and Direction of Development on the 3D Printing Technology for BRP (Building Rapid Printing)", Journal of the Korean Association for Spatial Structures, 15(3), pp.61-68.   DOI
32 Lim, S. W., 2012 : Developments in construction-scale additive manufacturing processes, Automation in Construction, 21, pp.262-268.   DOI
33 Feng, P. et al., 2015 : Mechanical properties of structures 3D printed with cementitious powders, Construction and Building Materials, 93, pp.486-497.   DOI
34 Wu, P. et al., 2016 : A critical review of the use of 3-D printing in the construction industry, Automation in Construction, 68, pp.21-31.   DOI
35 Gosselin, C. et al., 2016 : Large-scale 3D printing of ultra-high performance concrete - a new processing route for architects and builders, Materials and Design, 100, pp.102-109.   DOI
36 Cravero, F. et al., 2017 : A design tool for resource-efficient fabrication of 3d-graded structural building components using additive manufacturing, Automation in Construction, 82, pp.75-83.   DOI
37 Kang, T. W., 2015 : Technology framework for 3D printing-based architecture, Building construction, 15(4), pp.24-31.
38 Labonnote, N. et al., 2016 : Additive construction: State-of-the-art, challenges and opportunities, Automation in Construction, 72, pp.347-366.   DOI
39 Seo, M. B., 2015 : Analysis of 3D Printing Construction Technology and Case Study, Review of Architecture and Building Science, 60(1), pp.42-46.
40 Choi, B. S., 2015 : New Technology and Changes in the industry context (2) 3D printing, Science and Technology Policy, 26(5), pp.24-31.
41 Achillas, C. et al., 2015 : A methodological framework for the inclusion of modern additive manufacturing into the production portfolio of a focused factory, Journal of manufacturing systems, 37, pp.328-339.   DOI
42 Zocca, A. et al., 2015 : Additive Manufacturing of Ceramics: Issues, Potentialities, and Opportunities, Journal of the American Ceramic Society, 98(7), pp.1983-2001.   DOI
43 Karapatis, N. P. et al., 1998 : Direct rapid tooling: a review of current research, Rapid Prototyping Journal, 4(2), pp.77-89.   DOI