1. FASH 15 textiles manufactured regenerated fibers

2. produced from naturally occurring polymers these polymers do not occur naturally as fibers— processing is needed starting material is cellulose & protein—majority used in apparel, interiors and technical products are cellulosic: rayon lyocell acetate

3. cellulosic regenerated fibers—rayon the first—many regeneration processes were developed commercial production of viscose rayon began in 1910 in the US—sold a ‘artificial silk’ until rayon was adopted in 1924 produced as a filament until discovered that scraps could be used as staple fibers…now filament tow Cupra rayon—cuprammonium Viscose rayon—regular rayon (weaker than HWM) High-wet-modulus (HWM) rayon— aka HP (high performance), polynosic, or modal

4. cellulosic regenerated fibers—rayon production: wet spinning most common method purified cellulose is chemically converted to a viscose solution forced through spinnerets into a bath returned to solid 100% cellulose filaments HWM process maximizes chain length & fibril structure

5. cellulosic regenerated fibers—rayon physical structure: regular viscose characterized by striations (lengthwise lines) cross section—serrated or indented circular shape (HWM & cupra are more circular) serrated shape is an advantage in dyeing— increases fiber’s surface area filament—40-5000 denier staple & tow—1.5-15 denier micro rayon fibers also available

6. cellulosic regenerated fibers—rayon properties—aesthetics: made to resemble cotton, linen, wool & silk can be engineered with characteristics similar to other fibers in a blend has an attractive, soft, fluid drape sizing may be added to increase body and hand Cupra has more silklike hand & luster, can be found in smaller deniers

7. cellulosic regenerated fibers—rayon properties—durability: regular rayon is a weak fiber—loses about 50% of strength when wet will stretch slightly before breaking—lowest elastic recovery of any fiber, will not return to shape weakness comes from amorphous areas HWM is more crystalline & oriented so relatively strong cupra not as strong as HWM, stronger than viscose

8. cellulosic regenerated fibers—rayon environmental concerns/sustainability: significant processing is involved to produce useable fiber clear cutting may be an issue processing wood pulp uses large quantities of acid & other chemical (water & air pollutioni) cupra rayon no longer produced in US—could not meet minimum air & water quality reqs more susatinable alternatives include lyocell & rayon from managed forests biodegradable—current landfill practices?

9. cellulosic regenerated fibers—rayon uses: mostly used in woven fabrics—especially apparel and interior drapery & upholstery also used in nonwoven fabrics for absorbency technical wipes medical supplies—bandages, diapers, sanitary napkins & tampons Cuprammonium rayon used in dialysis machines to filter waster products from blood

10. cellulosic regenerated fibers—rayon types & kinds: only way to determine specific type of rayon is by the trade name HWM solution-dyed modified cross-section intermediate- & high- tenacity optically brightened high absorbency hollow microfibers Visil —contains silica, flame-retardant

11. cellulosic regenerated fibers—lyocell created in part (1990s) due to environmental concern of rayon production production: wet-spun: polymer dissolved in liquid and spun in a weak bath of amine oxide—low toxicity, low skin irritation; solvent recovered, purified & recycled physical structure: more rounded cross section & smoother longitudinal appearance than rayon

12. cellulosic regenerated fibers— lyocell properties aesthetics: luster, length & diameter can be changed depending upon end use processed to produce a range of surface effects offers unusual combinations of strength, opacity, absorbency durability: performs more like cotton than rayon strongest of cellulosic fibers unique combination of soft hand & good durability, produces comfortable, long-lasting textiles for apparel & interiors

13. cellulosic regenerated fibers— lyocell properties comfort: soft, smooth fiber with few static problems ideal for apparel that contacts skin thermal retention is poor appearance retention: resiliency is moderate—wrinkles but not as severely as rayon shrinks, but not progressively may have problems with fuzziness or piling care either gently machine-washable or dry cleaned sensitive to acids; resistant to mild alkalis sensitive to mildew & some insects

14. cellulosic regenerated fibers—lyocell environmental concerns/sustainability: produced from wood pulp—managed forests/fast-growing eucalyptus trees recovers & reprocesses 99.5% of solvent bath chemicals significantly less hazardous to environment than those used for viscose rayon biodegradable—not recycled makes extensive use of water, dyes & finishing chemicals dry cleaning solvents present additional environmental hazards

15. cellulosic regenerated fibers—lyocell uses: professional business wear leotards hosiery casual wear upholstery window-treatment fabrics filters printers’ blankets specialty papers medical dressings used in blends with wool, cotton & other MF used in conveyer belts for strength & softness

16. cellulosic regenerated fibers—lyocell types & kinds: because it is relatively new, fewer modification available—more modifications expected

17. cellulosic regenerated fibers—acetate originated in Europe as varnish for airplane wings in 1924 became 2 nd MF to be produced in US could not be dyed with existing dyes—disperse dyes created specifically for acetate/triacetate— certain of these change color when exposed to atmospheric pollutants 1 st thermoplastic (heat sensitive) fiber—melt under hot iron—consumers unaccustomed to this

18. cellulosic regenerated fibers—acetate production: 1.purified cellulose from wood pulp or cotton linters 2.mixed with glacial acetic acid; acetic anhydride & a catalyst 3.aged 20 hours—partial hydrolysis occurs 4.precipitated as acid-resin flakes 5.flakes dissolved in acetone 6.solution is filtered 7.spinning solution extruded in column of warm air; solvent recovered 8.filaments stretched and wound onto beams, cones or bobbins ready for use

19. cellulosic regenerated fibers—acetate production:

20. cellulosic regenerated fibers—acetate physical structure: available as staple or filament—filament more silk-like lobular or flower petal shaped cross section— varied according to use; flat filaments give glitter

21. cellulosic regenerated fibers— acetate properties: aesthetics: widely used in satins, brocades & taffetas—luster, body, & drape more important than durability or ease of care durability: weak fiber—loses some strength when wet has no other compensating factors poor resistance to abrasion—may be blended with nylon to increase strength

22. cellulosic regenerated fibers— acetate properties: comfort: smooth & slick—great for linings subject to static buildup extremely soft with no allergenic potential poor thermal retention appearance retention: not very resilient—wrinkle during use wrinkles from washing extremely difficult to remove weaker when wet—shrinks with high heat areas of stress do not recover well

23. cellulosic regenerated fibers— acetate properties: care: dry cleaned unless care label says differently resistant to weak acids & alkalis can be bleached soluble in acetone cannot be heat set at high enough temp thermoplastic & feels sticky at low ironing temperature better sunlight resistance than silk or nylon resistant to moths, mildew & bacteria

24. cellulosic regenerated fibers—acetate environmental concerns/sustainability: produced from cellulose & requires significant processing—wood pulp concerns dry-spun so solvent easier to recover & reuse less likely to degrade than rayon not recycled usually dyed with disperse dyes—require special chemical carriers dry cleaning solvents an issue

25. cellulosic regenerated fibers—acetate uses: lining fabrics—must be carefully selected based on durability of garment drapery—sunlight resistance and assortment of colors formalwear—moire taffeta, satin & brocade bedspreads, quilts, home sewing fabrics, ribbons, cigarette filters, personal hygiene products, fiberfill & filters http://www.youtube.com/watch?v=Goq1Yr1HiQE

26. cellulosic regenerated fibers—acetate types & kinds: solution-dyed flame-retardant sunlight resistant fiberfill textured filament modified cross section antibacterial thick-and-thin slublike filament

27. cellulosic regenerated fibers—bamboo fiber from woody bamboo grass—China promoted as sustainable fiber—crowds out weeds & few insect pests thus grown with no chemicals two types: bast (stems) & regenerated from pulp (like rayon)—most common soft hand, silky texture, durable, good breathability, wicks well & dyes well

28. cellulosic regenerated fibers—seaweed fiber marine plant fiber produced using process similar to lyocell— seaweed added to lyocell spinning solution manufacturers claim minerals & vitamins absorbed through skin of wearer soft, breathable, comfortable next to skin SeaCell: active & pure —silver as antimicrobial agent for bras, underwear, sportswear, workwear, carpets, bedding, towels, craft yarn, nonwovens & hygiene products

29. other regenerated fibers Alginate fibers —short fibers used for wound dressing; protect while allow healing to occur Chitosan —exoskeletons of crustaceans; medical applications Azlon —most often made from soybean waste from tofu manufacturing; durable, soft hand, wonderful drape, good colorfastness, excellent absorbency, good comfort & thermal retention Silk Latte & Milkofil —made from casein (protein in milk); soft hand & take dye well, not as durable as soy fiber

30. manufactured regenerated fibers participation activity: …dig through the box of interior fabric samples—find one with some content that we have discussed today …on a sheet of paper, discuss the following topics according to the fabric sample you have selected: How was this fiber generated? What are the pros of using this fiber/fabric in an interior? What are the cons of using this fiber/fabric in an interior? What sustainability issues are associated with this fiber/fabric? …be sure to attach the fabric sample with your written discussion