Research on the Role of Art Creation in Ceramic Material Product Design Based on the Perspective of Innovation

He Yueming

doi:10.1051/e3sconf/202125101033

All issues

Volume 251 (2021)

E3S Web Conf., 251 (2021) 01033

References

Open Access

Issue		E3S Web Conf. Volume 251, 2021 2021 International Conference on Tourism, Economy and Environmental Sustainability (TEES 2021)


Article Number		01033
Number of page(s)		9
Section		Analysis of Energy Industry Economy and Consumption Structure Model
DOI		https://doi.org/10.1051/e3sconf/202125101033
Published online		15 April 2021

Haug A. Acquiring Materials knowledge in design education [J]. International Journal of Technology and Design Education, 2018 (2), 1–16. [Google Scholar]
Chang, Hsiang-Tang, Lu, Chien-Han. Simultaneous Evaluations of Material Toxicity and Ease of Disassembly during Electronics Design [J]. Journal of Industrial Ecology, 2014, 18 (4): 478–490. [Google Scholar]
Miyashita L., Ishihara K., Watanabe Y., et al. ZoeMatrope: a system for physical material design [J]. ACM Transactions on Graphics, 2016, 35 (4): 1–11. [Google Scholar]
Dupont T., Leclaire P., Panneton R., et al. A microstructure material design for low frequency sound absorption [J]. Applied Acoustics, 2018, 136:86–93. [Google Scholar]
Khare V., Sonkaria S., Lee G. Y., et al. From 3D to 4D printing - design, material and fabrication for multi-functional multi-Materials [J]. International Journal of Precision Engineering and Manufacturing-Green Technology, 2017, 4 (3): 291–299. [Google Scholar]
Reichmanis E., Katz H., Kloc C., et al. Plastic electronic devices: From Materials design to device applications [J]. Bell Labs Technical Journal, 2014, 10 (3): 87–105. [Google Scholar]
Sakimoto K. K., Kornienko N., Yang P. Cyborgian Material Design for Solar Fuel Production: The Emerging Photosynthetic Biohybrid Systems [J]. Accounts of Chemical Research, 2017, 50 (3): 476–481. [Google Scholar]
Tang Y., Zhang Y., Li W., et al. ChemInform Abstract: Rational Material Design for Ultrafast Rechargeable Lithium-Ion Batteries [J]. Chemical Society Reviews, 2015, 44 (17): 5926–5940. [Google Scholar]
Banh T. T., Lee D. Multi-material topology optimization design for continuum structures with crack patterns [J]. Composite Structures, 2017, 186:193–209. [Google Scholar]
Chen Y., Cheng X., Fu K. Multi-material design of a vehicle body considering crashworthiness safety and social effects [J]. International Journal of Crashworthiness, 2019:1–10. [Google Scholar]
Laura Remón, Siedlecki D., Cabeza-Gil I., et al. Influence of material and haptic design on the mechanical stability of intraocular lenses by means of finite-element modeling [J]. Journal of Biomedical Optics, 2018, 23 (3): 1–10. [Google Scholar]
Liliana C. Tomé, Marrucho I. M. Ionic liquid-based Materials: A platform to design engineered CO2 separation membranes [J]. Chemical Society Reviews, 2016, 45 (10): 2785–2824. [Google Scholar]
Onishi T. Quantum Chemistry in Proton-Conductors. Mechanism Elucidation and Materials Design [J]. Advances in Quantum Chemistry, 2015, 70:31–67. [Google Scholar]
Grujicic M., Snipes J. S., Ramaswami S. Application of the Materials-by-Design Methodology to Redesign a New Grade of the High-Strength Low-Alloy Class of Steels with Improved Mechanical Properties and Processability [J]. Journal of Materials Engineering and Performance, 2015. [Google Scholar]
Heath A. C. G., Kwak M. L. Ensuring the nomenclatural stability of Ixodes anatis Chilton, 1904 with the discovery of lost type material and the designation of a lectotype [J]. New Zealand Entomologist, 2019 (4), 1–2. [Google Scholar]
Li W., Shi H., Zhang J. From Molecules to Materials: Computational Design of N-Containing Porous Aromatic Frameworks for CO2 Capture [J]. ChemPhysChem, 2014, 15 (9): 1772–1778. [Google Scholar]
Souto N., Andrade-Campos A., Thuillier S. Mechanical design of a heterogeneous test for material parameters identification [J]. International Journal of Material Forming, 2016, 10 (3): 353–367. [Google Scholar]
Wang F., Grinberg I., Jiang L., et al. Materials Design of Visible-Light Ferroelectric Photovoltaics from First Principles [J]. Ferroelectrics, 2015, 483 (1): 1–12. [Google Scholar]
Desai S., Dean C. Concurrent material and process selection in a flexible design for manufacture paradigm [J]. International Journal of Advanced Manufacturing Technology, 2018, 97 (8): 764–769. [Google Scholar]
Al-Bahi A. M., Soliman A. Y. A., Hassan M. H. M., et al. Concept design of an illicit material detection system [J]. Journal of Radioanalytical and Nuclear Chemistry, 2014, 299 (1): 351–356. [Google Scholar]
Gorley M., Fursdon M., Kalsey M. Integrating Materials Engineering and Design for Fusion [J]. IEEE Transactions on Plasma Science, 2018, PP(99): 1–6. [Google Scholar]
Demis S., Tapali J. G., Papadakis V. G. Plant Design and Economics of Rice Husk Ash Exploitation as a Pozzolanic Material [J]. Waste and Biomass Valorization, 2015, 6 (5): 843–853. [Google Scholar]
Travitzky N., Bonet A., Dermeik B., et al. Additive Manufacturing of Ceramic-Based Materials [J]. Advanced Engineering Materials, 2014, 16 (6): 729–754. [Google Scholar]
Tiina Härkäsalmi, Lehmonen J., Jukka Itälä, et al. Design-driven integrated development of technical and perceptual qualities in foam-formed cellulose fibre Materials [J]. Cellulose, 2017, 24 (11): 5053–5068. [Google Scholar]
Hamim S. U., Singh R. P. Taguchi-based Design of Experiments in Training POD-RBF Surrogate Model for Inverse Material Modeling using Nanoindentation [J]. Inverse Problems in Science and Engineering, 2016, 25 (3): 363–381. [Google Scholar]
Elhebeary M., Saif M. T. A. Design, Simulation, and Testing of a Novel Bending Stage for Mechanical Characterization of Materials [J]. Experimental Mechanics, 2016, 57 (1): 1–8. [Google Scholar]

Current usage metrics show cumulative count of Article Views (full-text article views including HTML views, PDF and ePub downloads, according to the available data) and Abstracts Views on Vision4Press platform.

Data correspond to usage on the plateform after 2015. The current usage metrics is available 48-96 hours after online publication and is updated daily on week days.

Initial download of the metrics may take a while.

[1] Haug A. Acquiring Materials knowledge in design education [J]. International Journal of Technology and Design Education, 2018 (2), 1–16. [Google Scholar]

[2] Chang, Hsiang-Tang, Lu, Chien-Han. Simultaneous Evaluations of Material Toxicity and Ease of Disassembly during Electronics Design [J]. Journal of Industrial Ecology, 2014, 18 (4): 478–490. [Google Scholar]

[3] Miyashita L., Ishihara K., Watanabe Y., et al. ZoeMatrope: a system for physical material design [J]. ACM Transactions on Graphics, 2016, 35 (4): 1–11. [Google Scholar]

[4] Dupont T., Leclaire P., Panneton R., et al. A microstructure material design for low frequency sound absorption [J]. Applied Acoustics, 2018, 136:86–93. [Google Scholar]

[5] Khare V., Sonkaria S., Lee G. Y., et al. From 3D to 4D printing - design, material and fabrication for multi-functional multi-Materials [J]. International Journal of Precision Engineering and Manufacturing-Green Technology, 2017, 4 (3): 291–299. [Google Scholar]

[6] Reichmanis E., Katz H., Kloc C., et al. Plastic electronic devices: From Materials design to device applications [J]. Bell Labs Technical Journal, 2014, 10 (3): 87–105. [Google Scholar]

[7] Sakimoto K. K., Kornienko N., Yang P. Cyborgian Material Design for Solar Fuel Production: The Emerging Photosynthetic Biohybrid Systems [J]. Accounts of Chemical Research, 2017, 50 (3): 476–481. [Google Scholar]

[8] Tang Y., Zhang Y., Li W., et al. ChemInform Abstract: Rational Material Design for Ultrafast Rechargeable Lithium-Ion Batteries [J]. Chemical Society Reviews, 2015, 44 (17): 5926–5940. [Google Scholar]

[9] Banh T. T., Lee D. Multi-material topology optimization design for continuum structures with crack patterns [J]. Composite Structures, 2017, 186:193–209. [Google Scholar]

[10] Chen Y., Cheng X., Fu K. Multi-material design of a vehicle body considering crashworthiness safety and social effects [J]. International Journal of Crashworthiness, 2019:1–10. [Google Scholar]

[11] Laura Remón, Siedlecki D., Cabeza-Gil I., et al. Influence of material and haptic design on the mechanical stability of intraocular lenses by means of finite-element modeling [J]. Journal of Biomedical Optics, 2018, 23 (3): 1–10. [Google Scholar]

[12] Liliana C. Tomé, Marrucho I. M. Ionic liquid-based Materials: A platform to design engineered CO2 separation membranes [J]. Chemical Society Reviews, 2016, 45 (10): 2785–2824. [Google Scholar]

[13] Onishi T. Quantum Chemistry in Proton-Conductors. Mechanism Elucidation and Materials Design [J]. Advances in Quantum Chemistry, 2015, 70:31–67. [Google Scholar]

[14] Grujicic M., Snipes J. S., Ramaswami S. Application of the Materials-by-Design Methodology to Redesign a New Grade of the High-Strength Low-Alloy Class of Steels with Improved Mechanical Properties and Processability [J]. Journal of Materials Engineering and Performance, 2015. [Google Scholar]

[15] Heath A. C. G., Kwak M. L. Ensuring the nomenclatural stability of Ixodes anatis Chilton, 1904 with the discovery of lost type material and the designation of a lectotype [J]. New Zealand Entomologist, 2019 (4), 1–2. [Google Scholar]

[16] Li W., Shi H., Zhang J. From Molecules to Materials: Computational Design of N-Containing Porous Aromatic Frameworks for CO2 Capture [J]. ChemPhysChem, 2014, 15 (9): 1772–1778. [Google Scholar]

[17] Souto N., Andrade-Campos A., Thuillier S. Mechanical design of a heterogeneous test for material parameters identification [J]. International Journal of Material Forming, 2016, 10 (3): 353–367. [Google Scholar]

[18] Wang F., Grinberg I., Jiang L., et al. Materials Design of Visible-Light Ferroelectric Photovoltaics from First Principles [J]. Ferroelectrics, 2015, 483 (1): 1–12. [Google Scholar]

[19] Desai S., Dean C. Concurrent material and process selection in a flexible design for manufacture paradigm [J]. International Journal of Advanced Manufacturing Technology, 2018, 97 (8): 764–769. [Google Scholar]

[20] Al-Bahi A. M., Soliman A. Y. A., Hassan M. H. M., et al. Concept design of an illicit material detection system [J]. Journal of Radioanalytical and Nuclear Chemistry, 2014, 299 (1): 351–356. [Google Scholar]

[21] Gorley M., Fursdon M., Kalsey M. Integrating Materials Engineering and Design for Fusion [J]. IEEE Transactions on Plasma Science, 2018, PP(99): 1–6. [Google Scholar]

[22] Demis S., Tapali J. G., Papadakis V. G. Plant Design and Economics of Rice Husk Ash Exploitation as a Pozzolanic Material [J]. Waste and Biomass Valorization, 2015, 6 (5): 843–853. [Google Scholar]

[23] Travitzky N., Bonet A., Dermeik B., et al. Additive Manufacturing of Ceramic-Based Materials [J]. Advanced Engineering Materials, 2014, 16 (6): 729–754. [Google Scholar]

[24] Tiina Härkäsalmi, Lehmonen J., Jukka Itälä, et al. Design-driven integrated development of technical and perceptual qualities in foam-formed cellulose fibre Materials [J]. Cellulose, 2017, 24 (11): 5053–5068. [Google Scholar]

[25] Hamim S. U., Singh R. P. Taguchi-based Design of Experiments in Training POD-RBF Surrogate Model for Inverse Material Modeling using Nanoindentation [J]. Inverse Problems in Science and Engineering, 2016, 25 (3): 363–381. [Google Scholar]

[26] Elhebeary M., Saif M. T. A. Design, Simulation, and Testing of a Novel Bending Stage for Mechanical Characterization of Materials [J]. Experimental Mechanics, 2016, 57 (1): 1–8. [Google Scholar]