Abstract
Fibre reinforcement is an effective method of soil improvement that presents an alternative solution to other more common methods of ground reinforcement, such as mechanical stabilization by geosynthetics (geogrids, geotextiles, geocomposites, etc.). Research activities in this area are being carried out, but the main disadvantage of currently used fibres is their uniform cross-section and usually smooth surface given by available production methods. This study presents an alternative way of fabrication of synthetic fibres – utilization of fused deposition modelling (3D printing). With the rapid development in commercially available 3D printing techniques, it is now possible to refine the shape and dimensions of the 3D printed objects to a tenth of a millimetre. The review of the basic index and mechanical properties of fibre-reinforced soils is presented in the first part of the paper. The second part is devoted to the description of the production process of fibres including the suitability analysis of materials used for 3D printing. Finally, the initial testing programme of fibre-reinforced non-cohesive soil is presented. The preformed laboratory test confirmed that the inclusion of 3D printed fibres led to a significant increase in shear strength. Examination of samples after tests did not reveal breakage of fibres, thus the fibres pull-out was the governing failure mode.
Highlights
Fibre reinforcement of construction materials is a well-known technology [1,2,3,4,5]
This study presents an alternative way of fabrication of synthetic fibres – utilization of fused deposition modelling (3D printing)
This paper presents an alternative way of fabrication of synthetic fibres – utilization of fused deposition modelling (3D printing)
Summary
Fibre reinforcement of construction materials is a well-known technology [1,2,3,4,5]. The wheat straw or other organic fibres were added to soil/clay to increase the strength parameters of bricks [6]. The influence of fibres on the mechanical behaviour of soils has been studied by many researchers. Gray and Ohashi [4] analysed the influence of different types of fibres (natural/synthetics/metal) on the shear strength of non-cohesive soils using the shear box apparatus. This study involves the limit equilibrium model to quantify the strength increase of the fibre-soil composite. Drained triaxial compression tests of fibre-soil composite with polyamide, steel and polypropylene fibres were conducted by Michalowski and Čermák [8]. Different fibre concentrations varying between 0.5% to 2% were used. As much as 70% increase in peak strength was achieved at fibre concentration of 2%. Wei [9] utilized wheat and rice straw, jute and polypropylene
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
