Abstract
In response to issues such as insufficient innovation in jewelry design, research is committed to applying 3D printing digital technology to jewelry design. This can provide more flexible and efficient design and manufacturing methods, thereby driving innovation and development in the jewelry industry. Firstly, in the study, 3D printing technology was used to obtain the two-dimensional slice images required for jewelry design, in order to better understand and adjust design details. Then, based on the obtained images, a new jewelry design method was explored to achieve more personalized and unique jewelry works. Finally, the performance of the design method was validated using a dataset. These results confirm that the accuracy, recall, average error, and average peak signal-to-noise ratio of the experimental method in image information extraction are 92.18%, 88.93%, 4.93%, and 89.71dB, respectively, which are superior to the comparative method. This confirms that the design method studied has better application value in jewelry design. The research aims to provide more flexible and efficient design and manufacturing methods for jewelry design, and promote innovation and development in the jewelry industry.
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The datasets generated during and/or analyzed during the current study are available from the corresponding author on reasonable request.
References
Kale, S.A.: Smart Integrated Approach for Future E-commerce Jewelry Business Using 3D Printing, vol. 6, pp. 83–90. E-Commerce for future & Trends (2019). 1
Zheng, H., Chang, J.: Cad method and model in teaching of creative design for jewelry. Comput.-Aided Des. Appl. 19(S1), 47–58 (2022)
Topaiboul, S., Saingam, A., Toonkum, P.: Preliminary study of unmodified wax printing using FDM 3D-printer for jewelry. Eng. Appl. Sci. Res. 48(6), 704–711 (2021)
Rahimi, M.H., Shayganmanesh, M., Noorossana, R., Pazhuheian, F.: Modelling and optimization of laser engraving qualitative characteristics of Al-SiC composite using response surface methodology and artificial neural networks. Opt. Laser Technol. 112(3), 65–76 (2019)
Ilhamuddin, M., Nururly, S., Rusminah, R., Hilmiati, H.: The consumer perception on quality of the pearl jewelry crafts products Mataram. Jmm Unram-Master of Management Journal. 10(1), 32–40 (2021)
Simge, A.: Luxury perception of low- and Middle-Income Generation Z and their luxury consumption motivations. Int. J. Social Political Economic Res. 7(4), 939–959 (2020)
Ali, A., Soni, M., Javaid, M., Haleem, A.: A comparative analysis of different rapid prototyping techniques for making intricately shaped structure. J. Industrial Integr. Manage. 5(03), 393–407 (2020)
Singh, A.K., Nayak, A., Kumar, N., Singh, R.P., Jain, P.K.: Fabrication of personalized lithophane via additive manufacturing. Sustainable Oper. Computers. 3(2), 17–21 (2022)
Durna, A., Fries, J., Hrabovsky, L., Sliva, A., Zarnovsky, J.: Research and development of laser engraving and material cutting machine from 3D printer. Manage. Syst. Prod. Eng. 1(28), 47–52 (2020)
Voynich, E., Kaukina, O.: The design of jewelry with transformation element. J. Eng. Appl. Sci. 14(3), 780–784 (2019)
Supsomboon, S.: Simulation for jewelry production process improvement using line balancing: A case study. Manage. Syst. Prod. Eng. 3(27), 127–137 (2019)
Jin, C., Li, J.: Application of VR technology in jewelry display. Math. Probl. Eng. 2021(6), 1–9 (2021)
Gandhi, P., Bhole, K.: Characterization of Bulk Lithography process for fabrication of three-dimensional microstructures. J. Micro Nano-Manuf. 1(4), 41002–41002 (2013)
Bhole, K.S., Kale, B.: Techniques to minimise stair-step effect in micro-stereolithography process: A review. Adv. Mater. Process. Technol. 8(4), 3615–3634 (2022)
Guan, Y., Sun, X., Jin, L., Guo, X.L., Zhang, Z.M., Shui, G.Y., Ma, L.B.: Development of 3D printing entity slicing software. China Foundry. 18(6), 587–592 (2021)
Jinghua, X.U., Xinhua, R.E.N., Qianyong, C., Zhang, S., Tan, J.: A slicing optimization method of Manifold Model for 3D Printing based on dual inclinations probability. J. Mech. Eng. 55(13), 129–143 (2019)
Shi, K., Cai, C., Wu, Z.: Slicing and support structure generation for 3D printing directly on B-rep models. Visual Comput. Ind. Biomed. Art. 2(1), 1–10 (2019)
Ke, X.A., Xu, L.B., Paul Maropoulos, D., Liu, X.: Stress-oriented 3D printing path optimization based on image processing algorithms for reinforced load-bearing parts. CIRP Ann. 70(1), 195–198 (2021)
Fehér, E., Domokos, G., Krauskopf, B.: Tracking the critical points of curves evolving under planar curvature flows. J. Comput. Dynamics. 8(4), 447–494 (2021)
Hübner, P., Weinmann, M., Wursthorn, S.: Automatic voxel-based 3D indoor reconstruction and room partitioning from triangle meshes. ISPRS J. Photogrammetry Remote Sens. 181(9), 254–278 (2021)
Islam, A., Othman, F., Sakib, N., et al.: Prevention of shoulder-surfing attack using shifting Condition with the Digraph Substitution rules Artificial Intelligence and Applications. 1(1): 58–68. (2023)
Gil Docampo, M., Peña Villasenín, S., Ortiz Sanz, J.: An accessible, agile and low-cost workflow for 3D virtual analysis and automatic vector tracing of engravings: Atlantic rock art analysis. Archaeol. Prospection. 27(2), 153–168 (2020)
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Ma, T., Ma, W. & Liu, W. The application of carving technique based on 3D printing digitalization technology in jewelry design. Int J Interact Des Manuf (2024). https://doi.org/10.1007/s12008-023-01730-w
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DOI: https://doi.org/10.1007/s12008-023-01730-w