Internal erosion is a common incident associated with nearly half of all dam dysfunctions and failures. This phenomenon occurs when soil particles are washed out of the soil mass by seepage by way of a preferential pathway. When the seepage is strong enough, the flow can wash out coarse particles and form an elongated void referred to as a ‘pipe’. Although many analytical assessment methods have been proposed, laboratory testing using representative soil samples remains the most reliable approach. Experimental studies on the stability of piping and erosion rate commonly use pre-formed or pre-drilled straight holes, which do not adequately represent realistic piping scenarios. This paper presents a novel, validated approach using three-dimensional (3D) printing soluble filament to form pipes within reconstituted soil specimens. 3D printing technology helps to form the pipe at any size and shape, while the soluble filament dissolves in water without inducing significant mechanical disturbance to the surrounding soil. Transparent hydrogels were used to observe the dissolution process of 3D-printed pipe walls, and the approach was further verified using cohesive soils. Test results confirmed that the formation of pipes using 3D soluble filament has negligible impacts on soil pipe stability.
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Research Article|
June 30 2026
Soluble filament 3D printing: a game-changer for experimental studies on piping stability
P. To
;
*College of Science and Engineering,
James Cook University
, Townsville, Australia
Corresponding author: P. To peter.to@jcu.edu.au
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P. Magsalin
P. Magsalin
†College of Science and Engineering,
James Cook University
, Townsville, Australia
Search for other works by this author on:
Corresponding author: P. To peter.to@jcu.edu.au
Publisher: Emerald Publishing
Received:
January 05 2026
Accepted:
May 29 2026
Online ISSN: 2045-2543
© 2026 Emerald Publishing Limited
2026
Emerald Publishing Limited
Licensed re-use rights only
Geotechnique Letters 1–6.
Article history
Received:
January 05 2026
Accepted:
May 29 2026
Citation
To P, Magsalin P (2026;), "Soluble filament 3D printing: a game-changer for experimental studies on piping stability". Geotechnique Letters, Vol. ahead-of-print No. ahead-of-print. https://doi.org/10.1680/jgele.26.00005
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