Footwear recycling gets a kick-start

Supplementary content information

shoe components and fragments on a table

Shows shoe components and fragments resulting from different stages of the recycling process

A newly developed recycling process could make landfill sites filled with old shoes a thing of the past.

The world’s first comprehensive system for separating and recovering useful materials from old footwear has been successfully trialled.

It is able to granulate and segregate leather, plastic foams and rubber so that they can be re-used in products ranging from rubber playground surfacing to new shoes!

The system was developed and tested at Loughborough University’s Innovative Manufacturing and Construction Research Centre (IMCRC), whose ten year research programme was funded by the EPSRC.

You can find out more about the research in an audio slideshow below:

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Footwear is incredibly difficult to recycle as it can contain up to forty different types of material, many of which are stitched or glued together, says Professor Shahin Rahimifard, who led the project. In our process, the first, manual step is to pre-sort shoes into broad types, such as trainers, and to recover metals, such as eyelets. Next the shoes are automatically shredded and granulated, with the granules automatically separated into four waste streams: leather, foams, rubber and other material.

The shoes are turned into 3-4mm fragments using a granulator. Low-cost air-based technologies developed by the project then separate the materials by exploiting their different sizes and weights: an air-cascade separator first removes lighter textile particles and other fine leather and foam residues by blowing them away from heavier granules; then a series of vibrating air-tables separate rubber from foam and leather by stratifying the granulated materials, with lighter granules ending up on top of heavier ones.

For each recovered material stream, there are a variety of applications. For example:

  • Recovered leather fibres can be reformed to produce bonded leather sheets.
  • Reclaimed rubber can be used as a running track or playground surfacing product.
  • For some types of footwear rubbers, finely ground rubber can be put back into new shoe soles - achieving so-called ‘closed loop’ recycling.
  • Recycled foams can be used in underlay material for laminate floors and carpets.
  • A key use for mixed textiles and other lighter residues could be as insulation material for buildings.

The Loughborough team is now talking to a recycling company interested in incorporating the process into its operations. In parallel, with EPSRC funding, collaboration is also under way with major footwear manufacturers to explore how shoes could be designed differently in future to make them easier to recycle.

The team has already developed a computerised tool that advises footwear designers on materials selection and helps them explore whether particular combinations of materials would make recycling harder or easier. The more similar two materials are in density, the harder it is to separate granules made of them, driving up the cost of recycling.

"Our ultimate goal is to build on all our EPSRC-funded work and develop follow-up lines of research that stimulate industry interest, and for our future projects to become self-funding," says Professor Rahimifard. "But we believe we’ve already helped footwear recycling perhaps take the first step towards becoming as economically feasible as glass, plastic or paper recycling."

The breakthrough could lead to enormous environmental benefits – currently 95 per cent of the 20 billion pairs of shoes produced globally each year end up in landfill sites. To date the only way of avoiding the landfilling of unwanted shoes has been to deposit them in ‘shoe banks’ for second-hand use.

For more information on this project, visit The Centre for Sustainable Manufacturing and Reuse/Recycling Technologies website.

Notes for Editors

Innovative Manufacturing and Construction Research Centre (IMCRC)

The 10 year IMCRC research programme ran from October 2001 to September 2011. In total, over 200 projects were undertaken within the programme.

The development of the footwear recycling process was part of the two-year IMCRC project ‘Minimisation of End-of-Life Waste in the Footwear Industry’ carried out by Loughborough University’s Centre for Sustainable Manufacturing and Reuse/Recycling Technologies, known as the Centre for SMART. Professor Shahin Rahimifard is the Director of the Centre.

Bonded leather (also known as reconstituted leather) is made by rolling waste leather to form sheets. It can look and feel like real leather, but is typically a lot cheaper.

Engineering and Physical Sciences Research Council

EPSRC is the UK’s main agency for funding research in engineering and the physical sciences. EPSRC invests around £800 million a year in research and postgraduate training, to help the nation handle the next generation of technological change. The areas covered range from information technology to structural engineering, and mathematics to materials science. This research forms the basis for future economic development in the UK and improvements for everyone’s health, lifestyle and culture. EPSRC works alongside other Research Councils with responsibility for other areas of research. The Research Councils work collectively on issues of common concern via UK Research and Innovation.

Reference: PN 71-13