The Impact of the Geometry of Cellular Structure Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements

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DIACHENKO, Semen V. ;BALABANOV, Sergey V. ;SYCHOV, Maxim M. ;LITOSOV, German E. ;KIRYANOV, Nikita V. .
The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements. 
Articles in Press, [S.l.], v. 0, n.0, p. 607-619, june 2024. 
ISSN 0039-2480.
Available at: <https://www.sv-jme.eu/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/>. Date accessed: 22 nov. 2024. 
doi:http://dx.doi.org/10.5545/sv-jme.2024.975.
Diachenko, S., Balabanov, S., Sychov, M., Litosov, G., & Kiryanov, N.
(0).
The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements.
Articles in Press, 0(0), 607-619.
doi:http://dx.doi.org/10.5545/sv-jme.2024.975
@article{sv-jmesv-jme.2024.975,
	author = {Semen V.  Diachenko and Sergey V.  Balabanov and Maxim M.  Sychov and German E.  Litosov and Nikita V.  Kiryanov},
	title = {The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements},
	journal = {Articles in Press},
	volume = {0},
	number = {0},
	year = {0},
	keywords = {additive technologies; selective laser sintering; polyamide; glass; triply periodic minimal surface; energy absorption; dampers; },
	abstract = {Energy-absorbing properties of cellular materials with D, G, IWP*, N, P, Q, PJ triply minimal energy surface geometries were investigated. Materials were made of glass-filled polyamide by selective laser sintering. Mechanical properties of cellular structures were determined depending on the geometry: the highest specific compressive strength σsp.max >8 MPa∙cm3/g is possessed by samples with the geometry IWP* and PJ; the highest specific energy absorption Asp = 14.5 MJ/m3 is in the sample with the geometry N. A mass-strength criterion for cellular structures is proposed. The maximal values of mass-strength criterion are from samples with geometries N, IWP* and PJ; 4.16 MPa2/g, 3.51 MPa2/g, and 2.88 MPa2/g. The adequacy of applying the Gibson-Ashby equation for fabricated cellular materials with triply periodic minimal surfaces (TPMS) geometry has been proven.},
	issn = {0039-2480},	pages = {607-619},	doi = {10.5545/sv-jme.2024.975},
	url = {https://www.sv-jme.eu/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/}
}
Diachenko, S.,Balabanov, S.,Sychov, M.,Litosov, G.,Kiryanov, N.
0 June 0. The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements. Articles in Press. [Online] 0:0
%A Diachenko, Semen V. 
%A Balabanov, Sergey V. 
%A Sychov, Maxim M. 
%A Litosov, German E. 
%A Kiryanov, Nikita V. 
%D 0
%T The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements
%B 0
%9 additive technologies; selective laser sintering; polyamide; glass; triply periodic minimal surface; energy absorption; dampers; 
%! The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements
%K additive technologies; selective laser sintering; polyamide; glass; triply periodic minimal surface; energy absorption; dampers; 
%X Energy-absorbing properties of cellular materials with D, G, IWP*, N, P, Q, PJ triply minimal energy surface geometries were investigated. Materials were made of glass-filled polyamide by selective laser sintering. Mechanical properties of cellular structures were determined depending on the geometry: the highest specific compressive strength σsp.max >8 MPa∙cm3/g is possessed by samples with the geometry IWP* and PJ; the highest specific energy absorption Asp = 14.5 MJ/m3 is in the sample with the geometry N. A mass-strength criterion for cellular structures is proposed. The maximal values of mass-strength criterion are from samples with geometries N, IWP* and PJ; 4.16 MPa2/g, 3.51 MPa2/g, and 2.88 MPa2/g. The adequacy of applying the Gibson-Ashby equation for fabricated cellular materials with triply periodic minimal surfaces (TPMS) geometry has been proven.
%U https://www.sv-jme.eu/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/
%0 Journal Article
%R 10.5545/sv-jme.2024.975
%& 607
%P 13
%J Articles in Press
%V 0
%N 0
%@ 0039-2480
%8 2024-06-19
%7 2024-06-19
Diachenko, Semen V., Sergey V.  Balabanov, Maxim M.  Sychov, German E.  Litosov, & Nikita V.  Kiryanov.
"The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements." Articles in Press [Online], 0.0 (0): 607-619. Web.  22 Nov. 2024
TY  - JOUR
AU  - Diachenko, Semen V. 
AU  - Balabanov, Sergey V. 
AU  - Sychov, Maxim M. 
AU  - Litosov, German E. 
AU  - Kiryanov, Nikita V. 
PY  - 0
TI  - The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements
JF  - Articles in Press
DO  - 10.5545/sv-jme.2024.975
KW  - additive technologies; selective laser sintering; polyamide; glass; triply periodic minimal surface; energy absorption; dampers; 
N2  - Energy-absorbing properties of cellular materials with D, G, IWP*, N, P, Q, PJ triply minimal energy surface geometries were investigated. Materials were made of glass-filled polyamide by selective laser sintering. Mechanical properties of cellular structures were determined depending on the geometry: the highest specific compressive strength σsp.max >8 MPa∙cm3/g is possessed by samples with the geometry IWP* and PJ; the highest specific energy absorption Asp = 14.5 MJ/m3 is in the sample with the geometry N. A mass-strength criterion for cellular structures is proposed. The maximal values of mass-strength criterion are from samples with geometries N, IWP* and PJ; 4.16 MPa2/g, 3.51 MPa2/g, and 2.88 MPa2/g. The adequacy of applying the Gibson-Ashby equation for fabricated cellular materials with triply periodic minimal surfaces (TPMS) geometry has been proven.
UR  - https://www.sv-jme.eu/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/
@article{{sv-jme}{sv-jme.2024.975},
	author = {Diachenko, S., Balabanov, S., Sychov, M., Litosov, G., Kiryanov, N.},
	title = {The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements},
	journal = {Articles in Press},
	volume = {0},
	number = {0},
	year = {0},
	doi = {10.5545/sv-jme.2024.975},
	url = {https://www.sv-jme.eu/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/}
}
TY  - JOUR
AU  - Diachenko, Semen V. 
AU  - Balabanov, Sergey V. 
AU  - Sychov, Maxim M. 
AU  - Litosov, German E. 
AU  - Kiryanov, Nikita V. 
PY  - 2024/06/19
TI  - The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements
JF  - Articles in Press; Vol 0, No 0 (0): Articles in Press
DO  - 10.5545/sv-jme.2024.975
KW  - additive technologies, selective laser sintering, polyamide, glass, triply periodic minimal surface, energy absorption, dampers, 
N2  - Energy-absorbing properties of cellular materials with D, G, IWP*, N, P, Q, PJ triply minimal energy surface geometries were investigated. Materials were made of glass-filled polyamide by selective laser sintering. Mechanical properties of cellular structures were determined depending on the geometry: the highest specific compressive strength σsp.max >8 MPa∙cm3/g is possessed by samples with the geometry IWP* and PJ; the highest specific energy absorption Asp = 14.5 MJ/m3 is in the sample with the geometry N. A mass-strength criterion for cellular structures is proposed. The maximal values of mass-strength criterion are from samples with geometries N, IWP* and PJ; 4.16 MPa2/g, 3.51 MPa2/g, and 2.88 MPa2/g. The adequacy of applying the Gibson-Ashby equation for fabricated cellular materials with triply periodic minimal surfaces (TPMS) geometry has been proven.
UR  - https://www.sv-jme.eu/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/
Diachenko, Semen V., Balabanov, Sergey V., Sychov, Maxim M., Litosov, German E., AND Kiryanov, Nikita V..
"The Impact of the Geometry of Cellular Structure  Made of Glass-Filled Polyamide on the Energy-Absorbing Properties of Design Elements" Articles in Press [Online], Volume 0 Number 0 (19 June 2024)

Authors

Affiliations

  • Saint Petersburg State Institute of Technology, Russia 1
  • Russian Academy of Sciences, Institute of Silicate Chemistry, Russia 2

Paper's information

Articles in Press
© The Authors 2024. CC BY 4.0 Int.

https://doi.org/10.5545/sv-jme.2024.975

Energy-absorbing properties of cellular materials with D, G, IWP*, N, P, Q, PJ triply minimal energy surface geometries were investigated. Materials were made of glass-filled polyamide by selective laser sintering. Mechanical properties of cellular structures were determined depending on the geometry: the highest specific compressive strength σsp.max >8 MPa∙cm3/g is possessed by samples with the geometry IWP* and PJ; the highest specific energy absorption Asp = 14.5 MJ/m3 is in the sample with the geometry N. A mass-strength criterion for cellular structures is proposed. The maximal values of mass-strength criterion are from samples with geometries N, IWP* and PJ; 4.16 MPa2/g, 3.51 MPa2/g, and 2.88 MPa2/g. The adequacy of applying the Gibson-Ashby equation for fabricated cellular materials with triply periodic minimal surfaces (TPMS) geometry has been proven.

additive technologies; selective laser sintering; polyamide; glass; triply periodic minimal surface; energy absorption; dampers;