Tuesday 30 September 2008

Man-Made Fibres Congress: Dornbirn , Austria 16-19 th Sept 2008

Introduction

730 delegates, including the great and the good of the world's man-made fibres industry, attended this 47 th annual congress held as ever in the pretty but hard-to-get-to Austrian town of Dornbirn . This year's MMFC clashed, as did the last several, with the EDANA Outlook Conference in Portugal , and so both conferences probably lost a proportion of their potential supporters. Your correspondent and others were poached from Portugal by the attractions of 120 technically-rich papers in three simultaneous sessions structured around the themes of New Fibre Developments, Safety, Sustainability, Sportswear, Nonwovens, Technical Textiles and EU Research projects.

As is often the case, the cramming of so much information into so a short time meant that papers were inevitably concise, some gems had to be missed, and the opportunities for questioning were strictly limited. This summary is biased towards the New Fibre Developments, Nonwovens and Sustainability sessions.

A Cellulosic Future?

Thomas Fahnemann, CEO of Lenzing observed that the recent period of high growth in cellulosics production was being followed by a rude awakening as demand slackened sharply in the last month due to the recessionary effects of high oil price and the credit crunch. However, the high oil price provided an excellent opportunity to promote the benefits of using natural products in a sustainable fashion. Man-made cellulosics, especially those made by Lenzing offered the low carbon footprint that consumers were increasingly demanding. They had:

  • An almost energy neutral process thanks to the “solar powered” polymerisation process, the non fibrous by-products of which provided the power required by the conversion process.
  • The closed-box nature of the modern viscose process which allowed minimal use of chemicals and minimal gaseous and liquid emissions.
  • A CO 2 neutral production route due to the CO 2 credit from tree-farming.
  • An ability to make further investments in environmental protection. These were now good PR and marketable, whereas in the past they simply spoiled the bottom-line.


    So, despite the immediate demand setback, cellulosics would have a great future, further expansions being driven by population growth (7 bn now to 9 bn by 2050) and increasing prosperity as the developing world raised its living standards towards Western levels.

Could the planet sustain a larger population all living at Western standards?

  • The USA accounted for 25% of the CO 2 emissions, and China was now the second largest emitter (18% of total), ahead of the EU.
  • Projecting current trends showed China moving ahead of the USA in 2020 as they continued to expand based on coal-fired power generation.
  • Chinese coal fired power generation was growing at the rate of 1 new station every 2 days, and these plants used old technology and worked at only 23% efficiency – about half the level of current best practise. Steps must be taken to ameliorate the catastrophic effects of this.
  • Western best practise must continue to improve and China must be encouraged to adopt this best practise.
  • The EU was labouring under the high costs of high standards of environmental control while China was making high profits by delaying the adoption of similar standards.
  • The EU should impose import duties restrict the availability of unsustainable imports.
  • The development and adoption of carbon capture and storage technology was urgently needed and the EU were funding several large scale projects.
  • The trade in CO 2 certificates was described as “trading in hot air”. The practise did nothing to reduce CO 2 emissions overall. It simply allowed polluters to continue to pollute thanks to the good practises being adopted elsewhere.
  • A very important issue which needed addressing at a World Trade level was the disadvantage man-made fibres suffered against cotton.
  • Cotton production is a dirty process requiring massive inputs of chemicals and water. The irrigation water alone would add $2-10/kilo if costed at EU domestic water prices, and yet the fibre receives government subsidies while the environmentally superior man-made products are penalised.
  • The use of renewable materials such as wood should be rewarded. Of the 1.7 billion tonnes of wood harvested annually, only 10% goes through pulping operations to extract useful natural raw materials.
  • Plastic recycling should be encouraged so that these oil-based polymers and fibres can be recovered at the rates now achieved by the paper and glass industries.
  • Carbon footprint should be better understood and used as a primary part of any fibres specification – as important in future as tenacity has been in the past. (The group of consumers prepared to pay a premium for low carbon-footprint products is large and growing rapidly.)
  • Polyester fibre has no viable alternative in world textiles. It must continue to grow but the recycling rates must be increased.
  • New natural raw materials for fibres should be sought. Casein was mentioned although this would compete directly with food production.
  • New sources of cellulose should be pressed into service for fibre production – straw and grasses were mentioned.

Finally Mr Fahnemann observed that whilst oil price changed hourly, fibre prices could only be changed with months of notice. Maybe the fibre industry should move towards a price indexing system which allowed similarly fast responses to change in raw material costs.

The Future of the EU Textile Industry


Bill Lakin of Euratex Brussels noted that the end of the textile and apparel quota system in 2005 was intended to usher in a period of free trade, but had failed to do this because a number of emerging countries continued to obstruct progress in the Doha round. Other problems related to the rise in value of the Euro, the fall of the dollar, increasing energy costs and the increasing burden of the REACH legislation. Doha was a double travesty: the dismantling of quotas and the opening up of markets had not been uniformly enforced and non-tariff barriers had increased. Mr Lakin hoped for its failure.

  • EU Textile productivity is nevertheless growing rapidly.
  • Continuous innovation is occurring and not just in technical textiles.
  • The desired transition from commodity products to specialities is occurring.
  • The EU is beginning to benefit from consumer concern related to air and sea freight cost/kilo of textile finishing and making up in the Far East . (Global warming/CO 2 issue)
  • Ditto a reaction against ultra-low cost labour.
  • “Local” trade, this including the Middle East and North Africa would be increasingly favoured.
  • The biggest ever EU research programme – LEAPFROG - intended to fully automate apparel manufacture is progressing and would allow the EU to leapfrog the Far East and its use of low cost labour.



However, the average EU textile company now has only 16 employees and a turnover of about €1.4m. Consolidation was essential to survival.

Overall, the EU Textile industry is in a period of adjustment, has survived the end of quotas but continues to lose jobs. Consolidations and mergers are essential and the industry must promote the value of EU textiles to the consumer and get away from trying to match the low cost of imports. It needs to develop and maintain cutting-edge manufacturing techniques to support the anticipated growth in demand for unique items caused by the need for increasing mass customisation.

Man-Made Fibre Trade


Roger Lee of Tecnon Orbichem reviewed the man-made fibre patterns of trade of the last several years and traced the migration of business from the developed to the developing world:

  • Between 1996 and 2020, world polyester staple production will have grown from 6 million tonnes to 30 million tonnes, Chinese expansion accounts for all of this growth. (Expansion in other Eastern countries simply making up for the decline in the West)
  • The numbers for polyester filament yarn production are similar (7 million to 42 million tonnes all in China )
  • China apart, nylon filament production has been more or less static since 1985 when China was a minor producer. By 2020, China will have 35% of the World production total of 4.3 million tonnes.
  • Acrylic fibres are due to decline from the peak of 2.7 million tonnes in 2005 to 2.3 million tonnes by 2020, despite the Chinese share expanding from 30 to 40%.
  • In 2007 the EU imported 1.3 million tonnes of trousers and T shirts.
  • Of the 0.25 million tonnes of nonwovens imported in 2007 38% were from North America, but Chinese imports are increasing, as are those from Israel , Turkey , the Middle East and North Africa .
  • Cellulosics were not mentioned.



For the future, Mr Lee concluded that while the West will continue to produce man-made fibres, these will support a few key local industries producing products with unique qualities for local markets.

Fibre Innovation in Japan


Akihiro Omatsuzawa of the Japan Chemical Fibres Association provided an overview of recent developments in Japanese fibres.

  • Production had declined by half a million tonnes in the 10 years to 2007, when 200,000 tonnes of cellulosics and 1.1 million tonnes of synthetics were produced annually.
  • Since 2000, cellulosics production had grown by 6.5% p.a. while all other man-made fibres had declined.
  • Usage in the apparel sector had declined most (392 to 244), but home furnishings had also suffered (460 to 404). Industrial textile usage had however grown from 288 to 326 ktonnes/year.
  • Nanofibre developments were now taking center stage:
    • Toray were developing a 44 dtex textile yarn with 1.4million filaments
    • Teijin's Nanofront™ was a high strength 39dtex polyester yarn with 8360 filaments
    • Morphotex™ from Teijin was a nanostructured optical interference fibre.
    • Black Sophista™ from Kuraray was an EVAL/Polyester nanostructured fibre.
    • Mitsubishi Rayon's AHF was an acetate-containing acrylic nanocomposite fibre.
  • Toray's nanoMATRIX technology was targeting the development of nano-scale coatings.
  • Kuraray's Kuralon EC was a conductive PVA fiber using metal nano-particles.



Examples of functional textiles based on these or related technologies were:

  • Ventcool™ - a Mitsubishi Rayon fabric based on triacetate conjugate fibre which is “cubically transformed” by moisture. The result is a fabric which opens up to give improved breathability as it gets moistened by perspiration.
  • Sophista™ - a polyester from Kuraray with ethylene vinyl alcohol content to allow rapid moisture absorbtion and release.
  • Lonwave™ - a polyester from Kuraray with ceramic powder content which radiates far-infrared.
  • Moiscare™ by Toyobo is an acrylate fibre which heats up as it absorbs moisture.
  • Hollow thermal polyester fibres, Aerotop™ from Teijin and Airmint™ from Kuraray, the latter looking like an islands in a sea bico where the islands are air.



Others were relatively well-known high tenacity products such as the para-aramids (Twaron™, Kevlar™ etc), the high MW polyethylenes (Dyneema™), the ultra high strength PVA (Kuralonk-II™), PBO fibres (Zylon™) and the Polyarylates (Vectran™). For high heat resistance the meta-aramids were exemplified by Conex™ and Nomex™, PPS fibres by Torcon™ and Procon™, and Polyimides by Toyobo's P-84™.

Recent and current government-sponsored R&D consortia targets include:

  • Doubling the strength of general use polyester and nylon without doubling the cost. (1 billion yen)
  • Ultra light “smart” fibres using “nano-level compounded process technology” (0.64 billion yen)
  • Use of super-critical CO 2 to dye polypropylene and aramids with aqueous dyes, and to apply chitosan functionality to polyesters. (0.63 billion yen)
  • Thermoplastic cellulose for melt spinning (0.36 billion yen)
  • Synthesising aliphatic polyketones for high performance fibres from CO and ethylene. (0.5 billion yen)
  • Recycling polyester/cotton textiles using melt separation of the cotton for use in composites. (0.6 billion yen)



For the period to 2020, the METI Strategic Technology Roadmap for the Fibre Industry places priority on R&D for Material Security (replacing fossil materials with biomass); Carbon Fibre composites; Construction, IT and Living; and Base Technology, i.e. the technologies required to allow the other 3 priorities to create new markets and meet social needs e.g. “safe and enriching life” and “friendliness to nature and the environment”.

Biopolymers for Textiles


Roy Dolmans of RWTH Aachen described the EU funded Biotext consortium, set up to evaluate the synthesis of blends and copolymers of commercially available biopolymers such as PLA, PHB and some starch-based polymers. He defined biopolymers as biodegradable polymers so as to include biodegradable synthetics, and mentioned that any polymer now commercial would be excluded from the project.

The paper included data on a PHB/PLA blend which had been synthesised, analysed and spun into monofilaments. The PHB was from the bacterial process and cost 10 times the PLA polymer. It was prone to degradation during extrusion and so the work was restricted to blends with less than 20% PHB. Possible applications in medical products or geotextiles were envisaged.

Spunlaid Lyocell Update


Malcolm Hayhurst of Lenzing explained the logic behind the recently announced collaboration with Weyerhaeuser aimed at building a pilot line for the spunlaid lyocell technology.

  • Weyerhaeuser had, and could continue the optimisation of, the Peach™ kraft pulp which worked well in the lyocell process and cost less than dissolving pulp.
  • Their earlier independent work on lyocell spunlaid, followed by the collaboration with Reicofil at Fraunhofer Institute meant they had developed useful expertise and intellectual property.
  • Their pulp and paper technology could contribute to the wet-laying and drying parts of the operation.
  • Reicofil, who had earlier announced a collaboration with Biax Fiberfilm to develop the special spinerettes required by lyocell spunlaid were now working independently and were not contributing to the Lenzing/WH project.
  • Lenzing had their own spinnerette manufacturing technology and would develop the jets themselves.

Work continues on the process with emphasis on improving productivity:

  • Peach™ pulps with alternative molecular weight distribution are being evaluated.
  • The effects of higher extrusion rates and stretching are being evaluated
  • Basis weights from 10 to 200 gsm have been made with dry strengths in the range of 200 to 3500 N/m (EDANA 20.2-89), and wet strengths in the range of 60 -500 N/m
  • Fabric Water Imbibitions (DIN 53814) vary from 70 to 160%, and Total FreeAbsorbency (EDANA 10.4-02) from 300 to 800%
  • Tests against a clean-room wipe specification indicated low lint levels (for the spun-laced continuous microfibers)

For the future, the mothballed “SL1” lyocell plant in Mobile Alabama could provide a low-cost route into a fully commercial scale.

Environmental Assessment of Cellulosics


Martin Patel of Lenzing re-presented the data provided at earlier conferences which compared the impacts of Lenzing's cellulosics with cotton, polyester and PP. This version showed that their new Chinese viscose operation had a higher environmental impact than their other operations in Europe and the USA due to the non-integration of the pulping operation (compared with viscose in EU) and the Chinese use of low-efficiency coal-fired power stations for energy generation.

Current EU viscose was better than current lyocell due to the integrated process, but the “Tencel 2012” process which would use municipal solid waste incineration to provide power would have the lowest impact of all – up to the factory gate. The consumer use phase had not been considered and here the more difficult drying of the absorbent fibres could be expected to change the comparisons with polyester.

In a separate paper by Jim Taylor of Lenzing , the ecological benefits of dyeing and finishing Tencel textiles were enumerated. Tencel dyes darker than cotton and so needs 1/3 rd of the dye to achieve the same shade. It also needs only 40% of the salt, loses less dye in the wash-off stage and gives a dyehouse effluent with half the chemical oxygen demand of a cotton dyehouse.

PCM in Lyocell Fibres


Marcus Krieg of TITK introduced the Smartcell™ clima fibre, an alloy of cellulose and a phase change material made using lyocell technology. Unlike the related viscose-based product produced by Kelheim Fibres using the Outlast™ encapsulated phase change material, the TITK process uses the PCM directly and disperses it in the dope with the aid of an inorganic nanoparticle .

6.7 dtex staple has been produced with good strengths despite high loadings of PCM, the final fibre being 51% cellulose, 36% paraffin wax and 13% inorganic filler. The heat storage capacity is 60 J/gm fibre, and the fibre has a smooth surface, is easy to process, comfortable to wear, and suffers no loss of functionality on washing. 1.7 dtex is being developed this year and this requires re-optimisation of the nanocomposite to prevent higher losses of the paraffin in use. Overall mechanical properties are similar to viscose fibre, i.e. half those of unmodified lyocell fibre.

Lyocell Carpets?


J Männer of Lenzing provided an introduction to carpet technology and markets and made a case for the new 15dtex/150mm Tencel fibre in carpets either alone or blended with wool and synthetics to make comfortable carpets.

  • The high moisture regain of Tencel would improve room climate and hygiene and kill the static propensity of the synthetic. (2 people give off 1.75l of water during the night and a Tencel carpet could absorb 3 litres – and prevent condensation on the windows of a 50 m 3 room.)
  • It inhibits the growth of Staph aureus (by having no free water on the surface), is anti-allergenic and mothproof.
  • It is biodegradable and eco-friendly.



The low abrasion resistance, poor recovery from compression, lack of bulk and very high pile cost compared with BCF nylon were not mentioned.

PLA Update


Eammon Tighe of Natureworks – now a JV between Teijin and Cargill – described how they were continuing to improve their eco-profile by looking for reductions in process greenhouse gas emissions. The lactic acid production from dextrose was the main source of GHG's and had become the target of further development. “PLA5”, the benchmark 2005 process, had been improved by buying renewable energy certificates based on wind-power to give the “PLA6” process which would be in operation until 2009. Then the next generation process “PLA-NG” using “new technology and green power” would kick in. After that, “Long Term” would use new sources of biomass for lactic acid production and green power generation.



  • PLA5 to PLA6 reduced the non-renewable process energy use from 50 to 27 MJ/kg.
  • PLA6 to PLA-NG would reduce it further to 17 MJ/kg.
  • GHG emissions (kg CO 2 /kg polymer) would fall from 2 kg with PLA5 to 0.27 kg for PLA6
  • PLA-NG without wind power would yield 0.75kg, and be a CO 2 absorber with wind-power. (removing 0.67 kg of CO 2 )
  • Water usage by the process was comparable to other synthetics and much less than cotton
  • With regard to the food v bioplastics debate, Ingeo™ PLA polymer uses less than 0.04% of global corn supplies, and bioplastics are tiny users compared with biofuels.
  • Cellulose to PLA processes are being developed.



Current Natureworks output is about 80,000 tonnes/year and 70% of this goes into packaging, the rest fibres. Products made from fibre now include the usual examples of designer apparel, spunbond carrier bags, short-life needled carpets, geotextiles and agritextiles. Interestingly, Mr Tighe said they no longer promoted composting as a disposal route. Recycling is the main option.

A plant expansion will come on stream in 2009.

Dental Care Fibres


Michael Müller of Pedex , since May 2007 a subsidiary of Lenzing Plastics, provided an overview of the wide range of fibres developed to make better toothbrushes:

  • Polymers used include PA 612, PA610, PBT, TPE, PMMA and POM.
  • Most cross-sectional shapes and types of bicomponency are made
  • Fibre diameters are in the range 0.1 to 0.3mm, with sheaths in the 6 to 30 micron range.
  • Spiral Magic Filaments have a square section with a pigment in one corner. When twisted these give a unique glistening appearance and high cleaning efficiency. (Bristle cleaning action is quantified by the University of Ulm .)
  • Whitening filaments are sheath-core with a fluoride donator in the skin layer which also gives the filament a rougher surface and hence better cleaning efficiency than either round or trilobal filaments.
  • Wear indicator filaments have a thin coloured sheath on a white core. The sheath is designed to wear away over 3 months and indicate the need for a brush change.
  • Sensitive structure filaments have a soft gum-feel arising from a foamed sheath polymer on a nylon core.
  • Structure filaments have large lumps of coloured polymer embedded in the surface to provide enhanced cleaning
  • Defined Flagged/Finger filaments are round fibres with a quadrant bicomponency which splits into 4 finer filament as the brush is made. The fine filament ends can be rounded after splitting. Cross section photos suggested the quadrant was in fact the core of a bico fibre with a thin sheath.
  • Rubber-soft filaments are sheath-core bicomponents of PBT and TPE-E, the latter having a high rubbery friction which gives efficient cleaning due to the high wet friction.
  • Rubber-structure filaments appear to be a variety of rubber-soft where the core has shrunk longitudinally and the skin has corrugated under compression. They have a very high surface area which enhances the friction effect.
  • Antibacterial filaments based on Silver Zeolite in the skin are to protect the brush against bacterial growth when stored wet. PBT filaments are also made with 2.5% of Irgaguard B5120. Nanosilver filaments use silver particles in the skin



Fibres are supplied to J&J, P&G and GSK among others.

The Future of Spunmelt Technology


Hans Georg Geus of Reicofil reviewed the evolution of the nonwoven market and the basics of spunmelt technology before revealing some information about their sales:

  • They have delivered 180 Reicofil lines.
  • 17 of these were R1, 39 were R2, 71 were R3 and 36 were R4 systems,
  • Of the R4 lines, 3 had just one spunbond head (S). 9 were SS, 7 were SSS, 7 were SMMS, 5 were SSMMMS and 4 were SMMMS
  • Another 17 lines used just one M (meltblow) head.



Improved meltblowing heads with 35 holes/inch now allowed the production of hygiene fabrics with higher and more uniform hydrohead across the width of the fabric. (820mm -4% and +2% mm H 2 0 now compared with 700mm -9.5% and +6% earlier). Air permeability consistency across the width was similarly improved. Fibre size distributions were also better, 70% of the meltblown filaments being in the 0.1 to 1.0 micron diameter range. These improvements were leading to better filtration performance, or, a halving of basis weight required for a given particle retention level. 50 holes/inch stabilised meltblow heads were now under development.

What did the future hold? In hygiene Mr Geus saw great growth prospects in the emerging economies and increasing usage of renewable raw materials such as PLA and cellulose. There would also be a need to combine different technologies, presumably including HE bonding for the cellulose fibres. In technical products he saw spunbonding being the first nonwoven systems into the emerging economies, leapfrogging rather than replacing card/bond systems. Here again, bonding systems other than thermal would be needed.

Hollow Filament Spunbonds


W. Schilde of STFI described their project to produce nonwovens from hollow filaments of PP, MPP and PET prior to bonding them thermally, hydrodynamically and mechanically.

Spinnerettes with 24 and 90 “double C” and “triple C” slots were used to form the hollow structure in preliminary trials on a fibre line. Hole external diameters of 1mm and 1.2mm were used, the C-slot widths being 0.15, 0.18 and 0.21mm.

For the Reicofil 4 line, a 7360 hole jet with “double C” holes was chosen, these having an external diameter of 1mm and a C-slot width of 0.15mm.



  • Best hollow structure was obtained with 15-25 MFR polymers, used at high throughput and low cooling temperature on the R4 line.
  • Jet configuration, air speed and stretch ratio had minor effects on cross section, but the high air speeds spoilt spinning reliability.
  • Hollow core size could not be increased above about 15% of the total cross section area, PP allowing bigger holes than PET.
  • The circular cores were deformed to ovals by all the bonding methods.
  • The hollow fibre structures had the same strengths as the solid fibre structures.

Assessing Sustainability


Bob Barker of the American Fiber Manufacturers Association observed that most environmental standards don't measure sustainability. He listed the main environmental concer as:

  • Greenhouse gas emissions (i.e. water vapour, CO 2 , Methane, Nitrous oxide, Ozone and halocarbons)
  • Air, water and land pollution
  • Solid waste disposal
  • Water use, water quality, eutrophication and acidification.



These were now being addressed by new standards for the carpet and home furnishings industries.

Finished product use and maintenance proved more important than textile production in an assortment LCA data presented:

  • Cotton fabrics required 85 kwh/kg for washing and drying during their lifetime, whereas 100% polyester needed 20 kwh/kg – unless of course they were hand washed and line dried.
  • 82% of the energy required in the life cycle of a polyester blouse was consumed during use.
  • 80% of the blouse GHG emissions occurred during its useful life.
  • Wool requires seven times the land use, has 3 times the global warming potential, 50 times the photo-oxidant creation potential of cotton, and has 5 times the eutrophication potential the latter being due to ammonia production during the sheep's lifetime. Polyester was best of all on these counts.
  • Textile tablecloths were better for the environment than disposables on all counts but water usage.
  • End-of-life aspects can dramatically affect conclusions. Extending a products life will enhance its sustainability rating, while recycling can offset the impacts of the fibre production process.
  • The carpet recycling plant in Dalton Georgia works with post consumer waste carpets returned in the trucks used to deliver new carpets. The nylon pile is shaved off and recycled by depol-repol via caprolactam.

Sustainability and Nonwovens


Pierre Conrath the Sustainability and Public Affairs Manager of EDANA listed the contributions nonwovens make to improving our environment:

  • Oil sorbents for controlling and cleaning up oil spills.
  • Protective clothing for environmental control personnel
  • Filters for cleaner air and water
  • Crop protection covers
  • Battery Separators (Renewable Energy Storage!)
  • Publication of Environmental Guidelines in the 1990's
  • Life-cycle assessments on diapers and inco products.
  • EDANA Sustainability Reports
  • Environmentally-oriented conferences and committees.



EDANA is now planning a review of sustainability strategy using an external panel of experts and would focus on the design and implementation of good sustainability practices throughout the supply chain. This would involve developing methods to quantify sustainability and its counterpart “Convenience”. Life cycle assessment was key to the former, and would be extended to “cradle to cradle” studies. A new “Right for Hygiene” programme would set the record straight and highlight the benefits arising from hygienic disposables and personal care wipes.

The EU “Sustainable Consumption and Production Plan” proposals would encourage green public procurement, eco-labelling, eco-design, eco-management and eco-auditing schemes. Mr Conrath thought this type of EU legislation would have a global impact as other countries adopted EU policies. The green public procurement initiative would target 50% of all public authority purchases being green by 2010.

Sustainable Polyester Development


Emanuele Pivotto of Sinterama Spa introduced the company and its activities and said they were pledged to minimise their environmental impact, use cleaner production methods and develop earth friendly products, one of which was CoCoNa yarn. This appeared to be a polyester yarn loaded with active carbon from coconut shells. The yarn allowed fabrics made from it to dry in half the time and absorbed body odour so that a garment could be worn for longer without causing offence. RecyPES was a recycled polyester made by depolymerisation and repolymerisation of bottle polymer.

Ecological Aspects of Man-Made Fibres


Robert Kirkwood of Invista listed the objectives of their Apparel Planet Agenda. They wanted to minimise the carbon footprint of synthetics, improve the carbon footprint of natural fibres by improving their performance, and increase the longevity of clothing.

Life Cycle Analysis as covered by the ISO 14040 series of standards was the tool being used to meet their objectives. As used by Marks and Spencer, LCA has shown that for apparel textiles, the consumer-use part of a garment's life dominates its environmental impact, accounting for over 75% of the total life cycle. Polyester trousers for example last 2 years, are washed 92 times and dried in a tumble dryer on average 46 times during their life.

The biggest reductions in impact along the textile supply and use chain are therefore achieveable by:

  • Cool water washing
  • Line drying rather than tumble drying
  • Not ironing
  • Wearing for longer periods between washing
  • Keeping clothes for longer and avoiding fashion items.

Eco-processing of Polyester


Paul Roshan of LEITAT, a technological research centre for textiles in Spain discussed ways of making polyester more hydrophilic or hydrophobic.

The traditional route involves treatment with 2 molar caustic for up to 8 hours at 50 o C, rinsing and neutralising with acetic acid. An alternative bio route involves treating with enzymes at 30 o C for up to eight hours followed by 15 minutes at 60 o C to kill the enzyme before rinsing off. Esterase, the best of the enzymes tested, rendered polyester hydrophilic in less than 1 hour, while lipase (2 nd best) required 4 hours to reach the 2 seconds level in the water drop absorbtion test.

Plasma-enhanced chemical vapour deposition achieved hydrophilicity when acrylic acid or acrylamide precursors were used. The same technique could render a polyester/lyocell woven fabric hydrophobic to a 120 o contact angle in 10 minutes when perfluorohexane was used as the precursor. However in any subsequent wet processing (washing) the lyocell tended to fibrillate and this destroyed the hydrophobicity as new untreated cellulose surface was exposed.

“Made in Green” Polyester


Xavier Valera of Fibras Europeas de Poliester ( Spain ) wondered how a small polyester producer was going to survive when by 2010 87% of the world's synthetic fibres would be produced in China . His answer was to Go Green and get the ecological and social product certificates to prove it. The “Made in Green” scheme by the Aitex Institute of Technology was chosen to help compete against low-quality products that might contain hidden harmful materials, made in countries which do not respect international guidelines regarding contaminants or worker protection.

The certification guarantees:

  • Freedom from harmful substances to Oeko-Tex 100 standard
  • Respect for the environment to ISO 14001 or Oeko Tex 1000.
  • Respect for human rights to International Labour Organisation and United Nations standards as listed in the Code of Conduct and Social Responsibility drawn up by Aitex.



Traceability through the entire production chain is the key.

New Polyester Fibres


T Kobayashi of Teijin Fibres mentioned how the denier of their Tepyrus short-cut polyester for wet-laid nonwovens was being reduced below the normal 0.6 dtex into the nano range. A new 0.07dtex short-cut is allowing the wet-lay process access to the durable synthetic leather market when combined with hydroentanglement bonding. It is also allowing the production of ultra-thin paper for battery separators and stencils for screen printing. Aspect ratio is the key to good formation and values of around 1000/1 L/D are needed. This means the fine fibres need to be cut to 0.6 to 0.8mm length to allow dispersibility

Teijin's ELK™ is high-loft cushion made from a blend of a binder fibre and a matrix fibre. The binder fibre has a polyester elastomer sheath covering an off-centre polyester core. The matrix fibre is a PTT/PET bicomponent with a low modulus and a spiral crimp. The blend is through-air bonded to let the elastic binder polymer concentrate at fibre crossing points. This renders it capable of giving softer cushions than standard polyester fillings. Unlike the PU foam with which it competes, ELK™ is fully recyclable into plastics or combustible without generation of any toxic gases. It also demonstrates better compression durability and breathability than the equivalent PU foam. It has now been adopted for Japan 's bullet-train seating.

Health and Safety of Nanofibres


L.L.Bergson of Bergson and Campbell (USA) said nanotechnology was defined by the EU as the “study of phenomena and fine-tuning of materials at atomic, molecular and macromolecular scales where properties differ significantly from those at larger scale”. In the USA , Nanoscience was defined as “research to discover new behaviours and properties of materials at the nanoscale (1-100nm)” and Nanotechnology as “the way discoveries made at the nanoscale are put to work”.

Current EU regulations cover in principle the potential health, safety and environmental risks of nanomaterials, but they are not explicitly mentioned under REACH regulations. Non governmental organisations are calling for revision of the 1 tpy registration threshold where nanomaterials are concerned and there is at least the potential for nanomaterials to become subject to separate authorisation.

In the USA , the Federal Government argues that existing statutory authorities are adequate to address the oversight of nanotechnology and its applications, but will “adapt or develop additional approaches as necessary”. The US EPA argues that particle size does not affect molecular identity and if the chemical is already listed on the Toxic Substances Control Act Inventory a nano version would not be subject to separate premanufacture notification. However, the EPA regards carbon nanotubes and fullerenes as new chemicals even though they are just forms of carbon.

Meltblown Melamine Nonwovens


Ulf Panzer of Agrolinz Melamine International has been collaborating with TITK Rudolstadt to produce thermoset microfiber nonwovens from a new extrudable HIPE®ESIN MER melamine. AMI is a 100% subsidiary of Borealis AG with 160,000 tonnes/year melamine capacity split between Linz in Austria and Piesteritz in Germany . Melamine thermoset resin is made (like fertilizer) from air and natural gas via ammonia and urea. Its main uses are in mouldings, textile and paper finishes, flame retardant additives and adhesives. The new Hiperesin has a thermoplastic “window” between 90 o C and 140 o C which allows extrusion into fibres and meltblown nonwovens which can then be thermally cross-linked into thermoset products with inherent flame resistance and a decomposition temperature of 400 o C. The cross-linking process requires temperatures above 200 o C for 2-3 minutes, the limitations on oven length limiting the speed of any nonwoven operation. Some slides suggested a catalyst was used in cross-linking, this catalyst being removed in the oven to leave a volatiles-free nonwoven.

The meltblown webs shown were remarkably soft and clearly contained very fine fibres. Applications envisaged were flame-barrier mattress pads, hot gas filtration and heat/sound insulation for engine compartments.

Asked if formaldehyde was released as the decomposition temperature was reached, Mr Panzer did not know. He said the product was similar to Basofil™ flame retardant fibres.

Applications for Meltblown Melamine


Ina Sigmund of STFI has been developing applications for the meltblown melamine nonwovens mentioned above. She found the webs easy to needlepunch provided fine needles were used at low speeds, and easy to hydroentangle. Layered products using the bonded melamine nonwovens for use in protective clothing, filtration, bedding and upholstery were demonstrated. In filtration, performance of the self-bonded microporous meltblown structure when applied to the surface of a needlefelt gave a high contaminant holding capacity, high filtration efficiency and lower pressure drop than the equivalent membranes.

Recycling from Post Consumer Waste


Andreas Bartl of the Vienna University of Technology considered 3 cases of fibre recovery from waste: deriving fibres from tyres, from waste apparel and from the municipal shredder “light fraction”.

Tyre-derived fibre is 50% viscose, 20% polyamide and 30% polyester. It is obtained after grinding and appears to be like fluff pulp with some rubber powder contamination. It can be used to reinforce bitumen for road surfacing where it helps to prevent surface cracking, or as a viscosity modifier in lacquers.

End of life apparel recycling is a publically-funded consortia project with the aims of avoiding landfill and incineration of textiles by use of a low energy automated process to recover fibres for reuse. The apparel which has usually been rejected by charity shops as unsuitable for further wear is ground up, and has any non-fibrous content separated by various means (“magnets, sifters, etc”). The fibrous output is separated into long and short, the latter being used for reinforcement of bitumen, concrete, plaster board and pastes while the former is reused in textiles and nonwovens.

Shredder light fraction contains about 20% of fibres which can be extracted and used like the tyre derived fibres.

It was unclear which of the above were aspirations and which were commercial achievements.

Sanitized Silver


Dominik Zimmermann of Sanitized AG promoted the use of their T25-25 Silver product which unlike the usual TiO 2 /Ag products is effective against athletes foot. It can be applied to textiles along with other fabric finishes and achieves a much higher exhaust rate than competitors (>90%). Treated fabrics are washable and dry-cleanable and are being used to make skin contact sportswear, footwear and functional underwear. In addition to controlling perspiration odour, they are being marketed on a “stay cleaner for longer” basis because they need less washing, and when washed at 30 o C the silver gives improved cleanliness.

Odour control in Sportswear


Dirk Höfer of the Hohenstein Institute has evaluated a variety of antibacterial agents used in sportswear. He listed silver, triclosan, quats, chitosan, polyhexanide and copper compounds. To the usual range of tests for an antimicrobial he added the need to quantify odour control, both subjectively and objectively. He provided snippets of information but only on the silver products:

  • Silver-containing fibres give a log 2-3 reduction in organisms
  • Silver-coated fibres give log 4-5 reductions
  • Silver-finished fibres give log 3.5 to 4 reductions
  • Duration of sporting activity is a key issue: squash is over in 1 hour but cycling can go on for 6 hours or more.
  • Silver-containing fibres are slow-acting and take 4 hours to be effective – so these might be appropriate for cycling
  • Silver-coated fibres are effective in less than 1 hour and would be appropriate for squash.
  • Silver-coated fibres worked well for odour absorbtion.
  • Skin-Silver interactions had been studied to show silver was non-toxic, non-allergenic and non-mutagenic.
  • It had no effect on skin flora.
  • Sweat from skin under silver-coated garments contained only 5300ppb Ag, while the skin surface contained 93ppb and the subcutaneous region 1 ppb.
  • The main message seemed to be if you want to make claims about the effectiveness of antimicrobial textiles, Hohenstein has the technology to validate those claims.



Mr Sun of the China National Textile and Apparel Council said a few words. 45% of the 78.4 million tonnes of fibre produced in 2007 were from China , and China imported 2.2 million tonnes of cotton. Sustainability initiatives were evident, bamboo being used as a raw material for viscose production, and 4 million tonnes of polyester was being recycled. China was also developing more sustainable varieties of cotton by genetic modification.

Nataliya Federova of NC State won the Albrecht Prize for Innovation for her paper on nanofibres from bico nonwovens. She was unable to attend the conference and a colleague presented a summary of her work. Nanofibres were defined as sub-half micron diameter fibres and these could be made from islands-in-a-sea spinning of 360 nylon islands in a PLA sea. The strong filaments were easily hydroentangled and the PLA could be dissolved by hot alkali. Interestingly, if the sea was used to thermally bond the structure, some nanofibres were exposed and the resulting fabric had 3-4 times the strength achieved by hydroentanglement alone.



Calvin Woodings

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