Model geogrids and 3D printing

Dionysios Stathas; J. P. Wang; Hoe I. Ling

doi:10.1016/j.geotexmem.2017.07.006

Model geogrids and 3D printing

Dionysios Stathas, J. P. Wang, Hoe I. Ling

Department of Civil Engineering

Research output: Contribution to journal › Article › peer-review

48 Scopus citations

Abstract

This paper summarizes the technical aspects of using 3D printing to fabricate small model geogrids for geotechnical experiments, with the aim of scaling their geometry and tensile behavior under operational conditions, say up to 5% strain. Specifically, we successfully fabricated model geogrids with one-hundredth of the tensile strength of prototypes, which is desirable for 1:10 model tests under 1-g condition. We also successfully fabricated another one with tensile strength close to one-tenth of prototypes, which is desirable for 1:10 model tests under 10-g condition in centrifuges. Therefore, by using 3D-printed model geogrids with properly scaled dimensions and tensile behavior, it is possible to achieve the two scaling laws simultaneously in reinforced-soil model tests, making the small-scale model tests more representative of field conditions.

Original language	English
Pages (from-to)	688-696
Number of pages	9
Journal	Geotextiles and Geomembranes
Volume	45
Issue number	6
DOIs	https://doi.org/10.1016/j.geotexmem.2017.07.006
State	Published - Dec 2017

Keywords

3D printing
Aperture size
Geogrid
Geosynthetics
Tensile strength

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10.1016/j.geotexmem.2017.07.006

Cite this

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title = "Model geogrids and 3D printing",

abstract = "This paper summarizes the technical aspects of using 3D printing to fabricate small model geogrids for geotechnical experiments, with the aim of scaling their geometry and tensile behavior under operational conditions, say up to 5% strain. Specifically, we successfully fabricated model geogrids with one-hundredth of the tensile strength of prototypes, which is desirable for 1:10 model tests under 1-g condition. We also successfully fabricated another one with tensile strength close to one-tenth of prototypes, which is desirable for 1:10 model tests under 10-g condition in centrifuges. Therefore, by using 3D-printed model geogrids with properly scaled dimensions and tensile behavior, it is possible to achieve the two scaling laws simultaneously in reinforced-soil model tests, making the small-scale model tests more representative of field conditions.",

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T1 - Model geogrids and 3D printing

AU - Stathas, Dionysios

AU - Wang, J. P.

AU - Ling, Hoe I.

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N2 - This paper summarizes the technical aspects of using 3D printing to fabricate small model geogrids for geotechnical experiments, with the aim of scaling their geometry and tensile behavior under operational conditions, say up to 5% strain. Specifically, we successfully fabricated model geogrids with one-hundredth of the tensile strength of prototypes, which is desirable for 1:10 model tests under 1-g condition. We also successfully fabricated another one with tensile strength close to one-tenth of prototypes, which is desirable for 1:10 model tests under 10-g condition in centrifuges. Therefore, by using 3D-printed model geogrids with properly scaled dimensions and tensile behavior, it is possible to achieve the two scaling laws simultaneously in reinforced-soil model tests, making the small-scale model tests more representative of field conditions.

AB - This paper summarizes the technical aspects of using 3D printing to fabricate small model geogrids for geotechnical experiments, with the aim of scaling their geometry and tensile behavior under operational conditions, say up to 5% strain. Specifically, we successfully fabricated model geogrids with one-hundredth of the tensile strength of prototypes, which is desirable for 1:10 model tests under 1-g condition. We also successfully fabricated another one with tensile strength close to one-tenth of prototypes, which is desirable for 1:10 model tests under 10-g condition in centrifuges. Therefore, by using 3D-printed model geogrids with properly scaled dimensions and tensile behavior, it is possible to achieve the two scaling laws simultaneously in reinforced-soil model tests, making the small-scale model tests more representative of field conditions.

KW - 3D printing

KW - Aperture size

KW - Geogrid

KW - Geosynthetics

KW - Tensile strength

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Model geogrids and 3D printing

Abstract

Keywords

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