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http://dx.doi.org/10.7464/ksct.2020.26.2.109

Food 3D Printing Technology and Food Materials of 3D Printing  

Kim, Min-Jeong (Division of Biotechnology, The Catholic University of Korea)
Kim, Mi-Kyung (Biopolymer TGR Co., Ltd.)
You, Young-Sun (Division of Biotechnology, The Catholic University of Korea)
Publication Information
Clean Technology / v.26, no.2, 2020 , pp. 109-115 More about this Journal
Abstract
Over the last 3 years, the global food 3D printing market has grown at an average annual rate of 31.5% and has shown an industry size that reached about U$ 9.46 billion. Food 3D printing technology has the advantage of being utilizable in diverse ranges because it enables free design of existing foods so that foods can be produced according to individuals' tastes and purposes. Many countries around the world are producing food 3D printers to release trial products such as foods employing the advantages of food 3D printing. They are also attempting to apply food 3D printing in various fields such as combat rations, space rations, restaurants, liquid foods, foods for the elderly, diets for patients, and baby foods. Whereas the 3D printing market, which has a high growth potential and is expected to continue to expand in size, is highly likely to become a blue ocean, not only is food 3D printing technology small in South Korea, but also the overall ratio of 3D printing utilization and the scale of the relevant industry are small. This is attributable to the fact that South Korea has problems such as insufficient institutionalization compared to developed countries and delays in the development of standardized domestic materials. Therefore, this paper is intended to inform the necessity of food 3D printing and describe food 3D printing technology and food 3D materials in order to obtain the additional effect of vitalizing the South Korean food 3D printing market.
Keywords
Food 3D printing; Food processing; Food material; Customized food; 3D printing technology;
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1 Kim, C. T., Meang, J. S., Shin, W. S., Shim, I. C., Oh, S. I., Jo, Y. H., Kim, J. H., and Kim, C. J., "Food 3D-Printing Technology and It Application in the Food Industry," Food Eng. Prog, 21(1), 12-21 (2017).   DOI
2 Kim, S. H., "Technology Opportunities in 3D Printing," Korean Ind. Chem. News, 18(1), 11-26 (2015).
3 Park, H. J., and Kim, H. W., "Global Food 3D Printing Technology and Industry Trends and Future Prospect," World Agr., 202, 147-168 (2017).
4 Lee, H. G., "3D Printing Technology and The Industry of Future Food," Food Preservation and Processing Industry, 16(2), 24-28 (2017).
5 https://reprap.org/wiki/Fused_filament_fabrication (accessed Jan. 2020).
6 http://www.irobotnews.com/news/articleView.html?idxno=8696 (accessed Jan. 2020).
7 https://www.mdpi.com/1996-1944/10/11/1313 (accessed Jan. 2020).
8 https://www.konicaminolta.com.au/products/3d-printers/selective-laser-sintering-printers/prox-sls-6100 (accessed Jan. 2020).
9 Yoon, H. S., Lee, M. H., Jin, X. Y., Kim, S. J., Lee, S. Y., Kim, Y. B., You, Y. S., and Rhee, J. K., "3D Printing Technology and Its Applications in the Future Food Industry: a Review," Food Science and Industry, 49(4), 64-69 (2016).
10 Liu, Z., Zhang, M., Bhandari, B., and Wang, Y., "3D Printing: Printing Precision and Application in Food Sector," Trends Food Sci. Tech., 69(A), 83-94 (2017).   DOI
11 https://xyzist.com/advanced-pages/digging-into-3d-print-basic/3d-printing-technologies/3dp-powder-bed-and-inkjet-head-3d-printing/ (accessed Jan. 2020).
12 https://ko.3dsystems.com/3d-printers/projet-cjp-660pro (accessed Jan. 2020).
13 Bhandari, B. R., and Howes, T., "Implication of Glass Transition for the Drying and Stability of Dried Foods.," J. Food Engineering, 40, 71-79 (1999).   DOI
14 Bhandari, B. R., and Roos, Y. H., "Dissolution of Sucrose Crystals in the Anhydrous Sorbitol Melt," Carbohyd. Res., 338(4), 361-367 (2003).   DOI
15 Severini, C., Derossi, A., Ricci, I., Caporizzi, R., and Fiore, A., "Printing a Blend of Fruit and Vegetables. New Advances on Critical Variables and Shelf Life of 3D Edible Objects," J. Food Eng., 22(2), 89-100 (2018).
16 Haque, M. K., and Roos, Y. H., "Differences in the Physical State and Thermal Behavior of Spray-Dried and Freeze-Dried Lactose and Lactose/Protein Mixtures," Innovative Food Sci. Emerging Technol., 7(1-2), 63-73 (2006).
17 Roos, Y. H., "Glass Transition Temperature and Its Relevance in Food Processing," Annu. Rev. Food Sci. Technol., 1, 469-496 (2010).   DOI
18 Slade, L., and Levine, H., "Water and Glass Transition-Dependence of the Glass Transition on Composition and Chemical Structure: Special Implication for Flour Functionality in Cookie Baking," Water in Foods, 22, 143-188 (1994).   DOI
19 https://www.naturalmachines.com/store (accessed Jan. 2020).
20 https://www.pinterest.co.kr/pin/544372673701607597/?nic=1 (accessed Jan. 2020).
21 https://3dprinting.com/food/3d-systems-partners-csm-bakery-solutions-food-printing/ (accessed Jan. 2020).
22 https://3dprintingindustry.com/news/3d-systems-makes-sweet-3d-printer-deal-csm-bakery-solutions-120283/ (accessed Jan. 2020).
23 Lee, D. H., "A Study on Revitalization for Developing Cuisine Products of 3D Food Printing: Focused on Chocolate Product", J. of the Table & Food Coordinate, 12(1), 111-126 (2017).   DOI
24 https://www.sedaily.com/NewsVIew/1KUX4HRN77 (accessed Jan. 2020).
25 http://foodink.io/london/ (accessed Jan. 2020).
26 https://www.bbc.com/news/business-35631265 (accessed Jan. 2020).
27 http://www.hellot.net/new_hellot/magazine/magazine_read.html?code=201&idx=41097&public_date=2018-06 (accessed Jan. 2020).
28 https://www.eater.com/2016/2/2/10894458/us-army-3d-printers-food-nutrition (accessed Jan. 2020).
29 http://www.viva100.com/main/view.php?key=20160726010007426 (accessed Jan. 2020).
30 http://www.foodbank.co.kr/news/articleView.html?idxno=55690 (accessed Jan. 2020).