DIACHENKO, Semen ;BALABANOV, Sergey ;SYCHOV, Maxim ;LITOSOV, German ;KIRYANOV, Nikita . IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS. Articles in Press, [S.l.], v. 0, n.0, p. , june 2024. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/sl/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/>. Date accessed: 25 oct. 2024. doi:http://dx.doi.org/.
Diachenko, S., Balabanov, S., Sychov, M., Litosov, G., & Kiryanov, N. (0). IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS. Articles in Press, 0(0), . doi:http://dx.doi.org/
@article{., author = {Semen Diachenko and Sergey Balabanov and Maxim Sychov and German Litosov and Nikita Kiryanov}, title = {IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS}, journal = {Articles in Press}, volume = {0}, number = {0}, year = {0}, keywords = {3D printing, selective laser sintering, polyamide, glass, triply periodic minimal surface, energy absorption, dampers; }, abstract = {This study investigated the energy-absorbing properties of cellular materials with the geometry of triply minimal energy surfaces (TPMS) and the likes of them: D, G, IWP*, N, P, Q, PJ - surfaces made of glass-filled polyamide by selective laser sintering, at a constant isosurface level t=0. As a result of the study, a 3D printing SLS mode with an energy density E=157 J/cm3 was selected; the mechanical properties of glass-filled polyamide in this mode were determined, in particular the compressive strength limit σc= 61 MPa; the physical and mechanical properties of TPMS under their compression were determined depending on the geometry: the highest specific strength limit 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 - a sample with the geometry N. The adequacy of applying the Gibson-Ashby law for manufactured cellular materials with TPMS geometry has been proven. The study proposes to consider TPMS from polyamide as energy-absorbing elements of structures.}, issn = {0039-2480}, pages = {}, doi = {}, url = {https://www.sv-jme.eu/sl/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. IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS. Articles in Press. [Online] 0:0
%A Diachenko, Semen %A Balabanov, Sergey %A Sychov, Maxim %A Litosov, German %A Kiryanov, Nikita %D 0 %T IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS %B 0 %9 3D printing, selective laser sintering, polyamide, glass, triply periodic minimal surface, energy absorption, dampers; %! IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS %K 3D printing, selective laser sintering, polyamide, glass, triply periodic minimal surface, energy absorption, dampers; %X This study investigated the energy-absorbing properties of cellular materials with the geometry of triply minimal energy surfaces (TPMS) and the likes of them: D, G, IWP*, N, P, Q, PJ - surfaces made of glass-filled polyamide by selective laser sintering, at a constant isosurface level t=0. As a result of the study, a 3D printing SLS mode with an energy density E=157 J/cm3 was selected; the mechanical properties of glass-filled polyamide in this mode were determined, in particular the compressive strength limit σc= 61 MPa; the physical and mechanical properties of TPMS under their compression were determined depending on the geometry: the highest specific strength limit 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 - a sample with the geometry N. The adequacy of applying the Gibson-Ashby law for manufactured cellular materials with TPMS geometry has been proven. The study proposes to consider TPMS from polyamide as energy-absorbing elements of structures. %U https://www.sv-jme.eu/sl/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 %& %P 1 %J Articles in Press %V 0 %N 0 %@ 0039-2480 %8 2024-06-19 %7 2024-06-19
Diachenko, Semen, Sergey Balabanov, Maxim Sychov, German Litosov, & Nikita Kiryanov. "IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS." Articles in Press [Online], 0.0 (0): . Web. 25 Oct. 2024
TY - JOUR AU - Diachenko, Semen AU - Balabanov, Sergey AU - Sychov, Maxim AU - Litosov, German AU - Kiryanov, Nikita PY - 0 TI - IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS JF - Articles in Press DO - KW - 3D printing, selective laser sintering, polyamide, glass, triply periodic minimal surface, energy absorption, dampers; N2 - This study investigated the energy-absorbing properties of cellular materials with the geometry of triply minimal energy surfaces (TPMS) and the likes of them: D, G, IWP*, N, P, Q, PJ - surfaces made of glass-filled polyamide by selective laser sintering, at a constant isosurface level t=0. As a result of the study, a 3D printing SLS mode with an energy density E=157 J/cm3 was selected; the mechanical properties of glass-filled polyamide in this mode were determined, in particular the compressive strength limit σc= 61 MPa; the physical and mechanical properties of TPMS under their compression were determined depending on the geometry: the highest specific strength limit 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 - a sample with the geometry N. The adequacy of applying the Gibson-Ashby law for manufactured cellular materials with TPMS geometry has been proven. The study proposes to consider TPMS from polyamide as energy-absorbing elements of structures. UR - https://www.sv-jme.eu/sl/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/
@article{{}{.}, author = {Diachenko, S., Balabanov, S., Sychov, M., Litosov, G., Kiryanov, N.}, title = {IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS}, journal = {Articles in Press}, volume = {0}, number = {0}, year = {0}, doi = {}, url = {https://www.sv-jme.eu/sl/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 AU - Balabanov, Sergey AU - Sychov, Maxim AU - Litosov, German AU - Kiryanov, Nikita PY - 2024/06/19 TI - IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS JF - Articles in Press; Vol 0, No 0 (0): Articles in Press DO - KW - 3D printing, selective laser sintering, polyamide, glass, triply periodic minimal surface, energy absorption, dampers, N2 - This study investigated the energy-absorbing properties of cellular materials with the geometry of triply minimal energy surfaces (TPMS) and the likes of them: D, G, IWP*, N, P, Q, PJ - surfaces made of glass-filled polyamide by selective laser sintering, at a constant isosurface level t=0. As a result of the study, a 3D printing SLS mode with an energy density E=157 J/cm3 was selected; the mechanical properties of glass-filled polyamide in this mode were determined, in particular the compressive strength limit σc= 61 MPa; the physical and mechanical properties of TPMS under their compression were determined depending on the geometry: the highest specific strength limit 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 - a sample with the geometry N. The adequacy of applying the Gibson-Ashby law for manufactured cellular materials with TPMS geometry has been proven. The study proposes to consider TPMS from polyamide as energy-absorbing elements of structures. UR - https://www.sv-jme.eu/sl/article/impact-of-the-geometry-of-cellular-structure-of-glass-filled-polyamide-material-on-the-energy-absorbing-properties-of-design-elements/
Diachenko, Semen, Balabanov, Sergey, Sychov, Maxim , Litosov, German , AND Kiryanov, Nikita . "IMPACT OF THE GEOMETRY OF CELLULAR STRUCTURE OF GLASS-FILLED POLYAMIDE MATERIAL ON THE ENERGY-ABSORBING PROPERTIES OF DESIGN ELEMENTS" Articles in Press [Online], Volume 0 Number 0 (19 June 2024)
Articles in Press
This study investigated the energy-absorbing properties of cellular materials with the geometry of triply minimal energy surfaces (TPMS) and the likes of them: D, G, IWP*, N, P, Q, PJ - surfaces made of glass-filled polyamide by selective laser sintering, at a constant isosurface level t=0. As a result of the study, a 3D printing SLS mode with an energy density E=157 J/cm3 was selected; the mechanical properties of glass-filled polyamide in this mode were determined, in particular the compressive strength limit σc= 61 MPa; the physical and mechanical properties of TPMS under their compression were determined depending on the geometry: the highest specific strength limit 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 - a sample with the geometry N. The adequacy of applying the Gibson-Ashby law for manufactured cellular materials with TPMS geometry has been proven. The study proposes to consider TPMS from polyamide as energy-absorbing elements of structures.