3D Food Printing in Museum Makerspaces: Creative Reinterpretation of Heritage
Abstract
In recent years, studies into the production of food have broadened to include design and design methods. At the same time 3D food printing (3DFP) is emerging as a viable technology for the production of consumer quality edible products. While advances in 3DFP are witnessed weekly, its use in the context of museums has yet to be explored in depth. In this paper we propose that the museum can be used as a laboratory for engaging audiences in new/creative food production and resultant reinterpretations of heritage through their makerspaces. We explore how a traditional cuisine could be used to inspire younger generations to explore STEM (Science, Technology, Engineering and Mathematics) and, vice versa, how technology enthusiasts could be motivated to explore culinary heritage by preparing food with digital fabricators. This paper reports on the initial research undertaken with the Slovenian diasporic group in Australia. Our results from the in-depth interviews demonstrated that making traditional desserts present a challenge for younger generation. Thus it was decided that a potica cake would be chosen as a test case for engagement with heritage through creative 3DFP. Non-edible 3D printed visual prototypes of a jelly cake with a secret message were also trialled. Our research output offers a suitable case study for the central premise that the museum can be used as a laboratory for engaging audiences in creative food production.
References
[1] ifooddesign – International Food Design Society. (3 August 2016). Available: http://ifooddesign.org/sample-page/.
[2] Scuola Politecnica di Design – SPD – Postgraduate Design School. (3 August 2016). Food Design and
Innovation. Available: http://www.scuoladesign.com/master/food-design/.
[3] Design Group Italia. (3 August 2016). Food Lab. Available: http://www.designgroupitalia.com/en/smart-labs/food-lab/4/.
[4] J. I. Lipton, M. Cutler, F. Nigl, D. Cohen, and H. Lipson, Additive manufacturing for the food industry,
Trends in Food Science & Technology, 43, 114–123, (2015), 10.1016/j.tifs.2015.02.004.
[5] H. Lipson, and M. Kurman, Fabricated: The new world of 3D printing, John Wiley & Sons, (2013).
[6] PERFORMANCE – PERsonalized FOod using Rapid MAnufacturing for the Nutrition of elderly ConsumErs. (5 August 2016). Available: http://www.performance-fp7.eu/.
[7] Food Ink. (5 August 2016). Available: http://foodink.io/.
[8] R. A. Khot, R. Pennings, and F. F. Mueller, EdiPulse: Supporting Physical Activity with Chocolate Printed Messages, presented at the Proceedings of the 33rd Annual ACM Conference Extended Abstracts on Human Factors in Computing Systems, Seoul, Republic of Korea, (2015).
[9] A. Freeman, S. Adams Becker, M. Cummins, E. McKelroy, C. Giesinger, and B. Yuhnke, NMC Horizon Report: 2016 Museum Edition, The New Media Consortium, Austin, Texas2016.
[10] NEW INC. (5 August 2016). Available: http://www.newinc.org/.
[11] Australian Centre for the Moving Image (ACMI). (5 August 2016). ACMI X. Available: https://www.acmi.net.au/acmi-x/.
[12] P. Bray, Eat the collection, in Photo of the Day blog, ed: The Powerhouse Museum, 2013, 4 July 2016.
Available: http://www.powerhousemuseum.com/imageservices/2013/07/eat-the-collection/.
[13] E. Sala, J. Dandy, and M. Rapley, Real Italians and wogs: The discursive construction of Italian identity among first generation Italian immigrants in Western Australia, Journal of Community & Applied Social Psychology, 20, 110–124, (2010).
[14] S. Talja, Analyzing qualitative interview data: The discourse analytic method, Library & Information Science Research, 21, 459–477, (1999), 10.1016/S0740-8188(99)00024-9.
[15] Embassy of the Republic of Slovenia in Canberra. (5 August 2016). Slovenian Community. Available: http://canberra.embassy.si/index.php?id=1570&L=1.
[16] Museum Victoria, Museums Australia (Victoria). (7 September 2016). Victorian Collections. Available: https://victoriancollections.net.au/.
[17] Victorian Collections. (7 September 2016). Colour drawing - Neva Roeder-Bole, colour drawing, Carnation variation, Grade 2. Available: https://victoriancollections.net.au/items/52f58df32162ef1e60d71df5.
[18] J. I. Lipton, D. Arnold, F. Nigl, N. Lopez, D. L. Cohen, N. Noren, and H. Lipson, Multi-Material Food Printing with Complex Internal Structure Suitable for Conventional Post-Processing, 21st Solid Freeform Fabrication Symposium (SFF’10), (2010).
[19] Stratasys. (9 August 2016). Objet500 and Objet350 Connex3. Available: http://www.stratasys.com/3d-printers/production-series/connex3-systems.
[20] D. Prindle, Forget plastic — this 3D printer retrofit makes it possible to print fudge, jelly, and more,
in Digital Trends, 2015, 5 August 2016. Available: http://www.digitaltrends.com/cool-tech/bocusini3d-food-printer-retrofit-kickstarter/.
[21] F. You, X. Wu, and X. Chen, 3D Printing of Porous Alginate/gelatin Hydrogel Scaffolds and Their Mechanical Property Characterization, International Journal of Polymeric Materials and Polymeric Biomaterials, (2016), (Accepted Manuscript).
[22] R. Lozano, L. Stevens, B. C. Thompson, K. J. Gilmore, R. Gorkin Iii, E. M. Stewart, et al., 3D printing of layered brain-like structures using peptide modified gellan gum substrates, Biomaterials, 67, 264–273, (2015), 10.1016/j.biomaterials.2015.07.022, 10.
[23] D. L. Taylor, and M. in het Panhuis, Self-Healing Hydrogels, Advanced Materials, (2016), 10.1002/adma.201601613.
[24] M. Wehner, R. L. Truby, D. J. Fitzgerald, B. Mosadegh, G. M. Whitesides, J. A. Lewis, et al., An integrated design and fabrication strategy for entirely soft, autonomous robots, Nature, 536, 451–455, (2016), 10.1038/nature19100, 08/25/print.
[25] Q. Ge, A. H. Sakhaei, H. Lee, C. K. Dunn, N. X. Fang, and M. L. Dunn, Multimaterial 4D Printing with Tailorable Shape Memory Polymers, Scientific Reports, 6, 31110, (2016), 10.1038/srep31110, 08/08/online.