Abstract:
Synthetic fibre blended fabric offcuts generated from textile industry are considered as waste
and currently incinerated in cement kilns. Utilisation of textile waste in development of cement
based product was focused in this study. Behaviour of fabric pieces in cement matrix indicates
its reinforcing effect with proper bonding characteristics while changing its failure pattern from
brittle mode to more ductile pattern. Experimental investigation was carried out to identify the
optimum size of shredded fabric pieces and its content which can be incorporated into cement
matrix to achieve the highest flexural strength of the fabric-cement composite. Optimum fabric
content was found to be 26% by volume and most suitable size range of shredded fabric pieces
was identified as 0 to 10 mm. Superplasticiser was used to improve the workability of mixture
at low w/c ratios and viscosity modifier was used to improve the homogeneity. Paving block
was developed with the use of shredded form of polyester spandex fabric, manufactured sand,
cement and admixtures. Developed block complies with the requirements specified for paving
blocks in SLS 1425 and BS EN 1338 standards. Fiber reinforced paving block has a
compressive strength of 18 MPa and tensile splitting strength of 5.4 MPa. Under compression
type load, the block is initially subjected to elastic deformation and then plastic deformation.
Failure pattern changing point from elastic deformation region to plastic deformation region
was considered as failure point of that block to estimate its compressive strength. The
developed paving block has an abrasion resistance of 17 mm and a skid resistance of 80 USRV.
Elasticity effect of polyester spandex fabric leads to improve the shock absorption
characteristics of fibre reinforced paving block. The shock absorption capability of this paving
block was measured using a test apparatus that was fabricated in accordance with the BS EN
14808 standard, which specifies the determination of shock absorption characteristics of sports
surfaces. The shock absorption capability of this block is 21%, which meets the requirement
specified in the BS EN 15330-1 standard for tennis court surfaces. Incorporation of fabric
pieces into cement matrix leads to create a porous structure while improving water infiltration
capability. Permeability of the paving block was measured in terms of its infiltrated water
volume at constant time intervals under constant pressure head. This paving block has a water
percolation capability of 200 litres/m2 per hour, which means it can absorb up to 100 litres of
water per square meter in 30 minutes under a pressure head of 1.1 bar. This helps to reduce
surface runoff of rainwater. Deterioration of fabric fibres in an alkaline environment was
evaluated as per ISO 8336 standard while subjecting fibre reinforced paving blocks to 50
numbers of soak–dry cycles and soak-dry performance criteria was estimated as 0.8 which
satisfies the ISO 8336 standard requirement. Developed paving block satisfies the requirements
specified for paving blocks in SLS and BS EN standards. The novel paving block has improved
shock absorption and water infiltration characteristics, as well as satisfactory durability. It is
suitable for outdoor sports surfaces, as it provides better foot comfort and slip resistance.