Digital and experimental synergies to design high-heeled shoes

Milazzo, M.; Spezzaneve, Andrea; Persichetti, A.; Tomasi, M. De; Peselli, V.; Messina, Angelo; Gambineri, Francesca; Aringhieri, Giacomo; Roccella, S.

doi:10.1007/s00170-020-05675-2

Cited by 7 publications

(4 citation statements)

References 71 publications

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“…A design that has not been translated into a product and the value of that design has not been realized are impossible if pupils do not grasp the manufacturing process. Students from all directions study professional basic courses together in the freshman year, such as design aesthetics, design composition, design expression techniques, the history of world arts and crafts, the history of Chinese arts and crafts, and other basic courses [ 13 – 15 ]; in the sophomore year, we implement discipline subdivision and choose discipline direction, such as curriculum of ceramics, wood carving, leather design, furniture design, and other disciplines [ 16 – 18 ].…”

Section: Diversification Of “Art and Engineering” Practice Research W...mentioning

confidence: 99%

Cultural Confidence on “Art & Engineering” Construction of Product Design under “New Liberal Arts”

2022

Computational Intelligence and Neuroscience

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A master’s degree program in “new liberal arts” is a great opportunity to strengthen cooperation between art colleges and universities, to promote the construction of product design and digital molding majors, and to promote teaching and research on the “integration” of the theoretical foundations of engineering intelligent manufacturing. To take advantage of cooperative universities’ advantageous disciplines and professional platforms, we should construct new art and emerging interdisciplinary majors, as well as promote the construction and exploration of joint training of doctors and masters in relevant disciplines in the interdisciplinary direction of art and engineering. The foregoing approaches are intended to create a new “art and engineering” model for the establishment of a product design speciality at our university. In order to meet the requirements of “Art & Engineering” advocated by the national new engineering construction, art disciplines have their own inherent rules and characteristics. We should actively create disciplinary and professional characteristics, help universities cooperate with each other in high-quality development, and share and win together, in order to continuously achieve new academic results.

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Section: Diversification Of “Art and Engineering” Practice Research W...mentioning

confidence: 99%

Cultural Confidence on “Art & Engineering” Construction of Product Design under “New Liberal Arts”

2022

Computational Intelligence and Neuroscience

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“…Reducing these values represents the biggest challenge of mass customization [ 52 ], and the technologies integrated within the proposed methodology significantly contribute to these objectives. Additive manufacturing allow the rapid manufacturing of unique models at low cost [ 74 ] and, in that sense, FDM technologies and multi-material possibilities are productive scenarios of great potential [ 75 ], although still with limitations derived from the process and the materials [ 76 ]. Probably, the applications in the field of medicine represent the clearest example to understand the importance and potential of customization [ 56 , 77 ], but it is not the only one.…”

Section: Initial Considerations and Main Synergies Of The Technolomentioning

confidence: 99%

Integration of Additive Manufacturing, Parametric Design, and Optimization of Parts Obtained by Fused Deposition Modeling (FDM). A Methodological Approach

2020

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The use of current computer tools in both manufacturing and design stages breaks with the traditional conception of productive process, including successive stages of projection, representation, and manufacturing. Designs can be programmed as problems to be solved by using computational tools based on complex algorithms to optimize and produce more effective solutions. Additive manufacturing technologies enhance these possibilities by providing great geometric freedom to the materialization phase. This work presents a design methodology for the optimization of parts produced by additive manufacturing and explores the synergies between additive manufacturing, parametric design, and optimization processes to guide their integration into the proposed methodology. By using Grasshopper, a visual programming application, a continuous data flow for parts optimization is defined. Parametric design tools support the structural optimization of the general geometry, the infill, and the shell structure to obtain lightweight designs. Thus, the final shapes are obtained as a result of the optimization process which starts from basic geometries, not from an initial design. The infill does not correspond to pre-established patterns, and its elements are sized in a non-uniform manner throughout the piece to respond to different local loads. Mass customization and Fused Deposition Modeling (FDM) systems represent contexts of special potential for this methodology.

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“…Thus, any product affected by ergonomic aspects can benefit from this type of approach. Commercial applications [ 9 , 10 , 11 , 12 ] in markets such as fashion or customized purchases are examples of this potential, but applications in the field of medicine can be of special relevance. More specifically, application of the proposed methodology to the case study developed in this work is considered of interest to channel the response to very different problems studied in the field of biomechanics, which could benefit from design strategies that incorporate some degree of customization [ 13 , 14 , 15 ].…”

Section: Introductionmentioning

confidence: 99%

Optimization Methodology for Additive Manufacturing of Customized Parts by Fused Deposition Modeling (FDM). Application to a Shoe Heel

2020

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Additive manufacturing technologies offer important new manufacturing possibilities, but its potential is so big that only with the support of other technologies can it really be exploited. In that sense, parametric design and design optimization tools appear as two appropriate complements for additive manufacturing. Synergies existing between these three technologies allow for integrated approaches to the design of customized and optimized products. While additive manufacturing makes it possible to materialize overly complex geometries, parametric design allows designs to be adapted to custom characteristics and optimization helps to choose the best solution according to the objectives. This work represents an application development of a previous work published in Polymers which exposed the general structure, operation and opportunities of a methodology that integrates these three technologies by using visual programming with Grasshopper. In this work, the different stages of the methodology and the way in which each one modifies the final design are exposed in detail, applying it to a case study: the design of a shoe heel for FDM—an interesting example both from the perspectives of ergonomic and mass customization. Programming, operation and results are exposed in detail showing the complexity, usefulness and potential of the methodology, with the aim of helping other researchers to develop proposals in this line.

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Digital and experimental synergies to design high-heeled shoes

Cited by 7 publications

References 71 publications

Cultural Confidence on “Art & Engineering” Construction of Product Design under “New Liberal Arts”

Cultural Confidence on “Art & Engineering” Construction of Product Design under “New Liberal Arts”

Integration of Additive Manufacturing, Parametric Design, and Optimization of Parts Obtained by Fused Deposition Modeling (FDM). A Methodological Approach

Optimization Methodology for Additive Manufacturing of Customized Parts by Fused Deposition Modeling (FDM). Application to a Shoe Heel

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