The characteristics of a sail are due to design, construction and the attributes of the fibers, which are woven together to make the sail cloth. The following sections discuss the attributes of fibers assuming a good design and careful construction. According to Mahr, there are six key factors in evaluating a fiber for suitability in weaving a sail-cloth: •
Initial modulus – The ability to resist stretching. Higher resistance is better for upwind sails. •
Breaking strength – Measured as a force per cross sectional area of fiber. Higher is better for sails. •
Creep – Describes the long term stretch of a fiber or fabric. A material with creep may have a superior modulus, but lose its shape over time. •
Resistance to ultraviolet light – Strength loss from exposure to the Sun’s UV rays measured by a standardized exposure test. •
Flex strength – Strength lost due to bending, folding, or flogging, which is frequently measured with an industry standard 50 fold test. •
Cost-effectiveness –Both the initial cost and its durability of the material define its cost-effectiveness over time. There is no perfect solution since in most cases the increase of one attribute generally results in the decreased attractiveness of another. Reduced stretch generally also reduces the flexibility causing a trade-off of performance for durability. Solving both problems generally sends the price out of range for most sailors.
Nylon Nylon is used in
spinnakers because of its light weight, high tensile strength, superior abrasion resistance and flexibility. However, it has a low modulus allowing too much stretch to be suitable for upwind sails. Nylon is more susceptible to UV and chemical degradation than polyesters and its physical properties can change due to moisture absorption.
Polyester (PET) Polyethylene terephthalate, the most common type of
polyester, is the most common fiber used in sailcloth; it is also commonly referred to by the brand name Dacron. PET has excellent resiliency, high abrasion resistance, high UV resistance, high flex strength and low cost. Low absorbency allows the fiber to dry quickly. PET has been replaced by stronger fibers for most serious racing applications, but remains the most popular sail cloth due to lower price and high durability. Dacron is the brand name of Dupont’s Type 52 high modulus fiber made specifically for sailcloth. Allied Signal has produced a fiber called 1W70 polyester that has a 27% higher tenacity than Dacron. Other trade names include Terylene, Tetoron, Trevira and Diolen.
PEN fiber (Pentex) PEN (
Polyethylene naphthalate), commonly known by Honeywell's trade name "Pentex", is another kind of polyester fiber, which stretches only 40% as much as standard PET fibers, but about twice as much as Kevlar 29. Because it only shrinks about a third as much as a good PET, PEN can not be woven as tightly; thus, woven PEN must be impregnated with resin making sails prone to damage from improper use and handling. PEN is better suited for making laminated sailcloth, where the fibers are laid straight for strength and are bonded to sheets of film for stability (e.g.,
PET film often called by one of its trade names Mylar), or as a
taffeta outer layer of a laminate, protecting a PET film. PEN laminates are an economical alternative for higher performance sail.
Kevlar Kevlar, an
aramid fiber, has become the predominant fiber for racing sails, since it was introduced by DuPont in 1971. It is stronger, has a higher strength to weight ratio than steel, and has a modulus that is five times greater than PET, and about twice as high as PEN. There are two popular types of Kevlar: Type 29 and Type 49, the latter having a 50% higher initial modulus than Type 29 but a lower flex loss.
DuPont has developed higher modulus Types 129, 149 and 159, but these have seen little use in sails, since generally as the modulus increases the flex strength decreases. DuPont has recently introduced Kevlar Edge, a fiber developed specifically for sails with 25% higher flex strength and a higher modulus than Kevlar 49. Kevlar, along with other aramid fibers, have poor UV resistance (Kevlar loses strength roughly twice as quickly in sunlight as PET) and rapid loss of strength with flexing, folding and flogging. Minimal flogging and careful handling can greatly extend the life of a Kevlar sail.
Technora Technora is an aramid, which is produced in
Japan by
Teijin, has a slightly lower modulus strength than Kevlar 29 but a slightly higher resistance to flex fatigue. The fiber’s lower UV resistance is enhanced by dyeing the naturally gold fiber black. Technora is most often used as bias support (X-ply) in laminate sailcloth.
Twaron Twaron is an aramid, which is produced in The Netherlands by Teijin, is chemically and physically similar to DuPont’s Kevlar. Twaron HM (High modulus) has similar stretch properties to Kevlar 49, greater tensile strength and better UV resistance. Twaron SM is similar to Kevlar 29. Like Kevlar, the fiber is a bright gold color.
Spectra Spectra is an
ultra-high-molecular-weight polyethylene (UHMWPE) made by
Honeywell, which offers superior UV resistance (on par with PET), very high initial modulus numbers (second only to high modulus Carbon Fiber), superior breaking strength, and high flex strength. However, it also exhibits permanent and continuous elongation under a sustained load (AKA: creep). This results in a change in shape as the sail ages. Because of this Spectra is only used in spinnakers on high performance boats where the sails are replaced regularly.
Dyneema Equivalent to Spectra,
Dyneema is an extremely strong fiber produced by the
Dutch company
DSM. It is often used by European sailcloth manufacturers, is available in a wider variety of yarn sizes than Spectra, and is growing in popularity. Dyneema DSK78 set a new standard combining the typical high strength to weight ratio, excellent low stretch, abrasion, and UV resistance but added three times better creep performance compared to Dyneema SK75 and nearly two times better than Dyneema SK90.
Certran Hoechst
Celanese produces Certran
polyethylene similar to Spectra, with about one half the modulus rating of Spectra. It has similar properties to Spectra including superior resistance to flex fatigue and UV degradation but also exhibits creep.
Zylon (PBO) PBO (Poly (p-phenylene-2, 6-benzobisoxazole)) is liquid crystal polymer developed by Japan-based Toyobo under the trade name
Zylon. It is a gold fiber with an initial modulus that is significantly higher than other high modulus yarns, including aramids. Among PBO's desirable properties are high thermal stability, low creep, high chemical resistance, high cut and abrasion resistance, and excellent resistance to stretch after repeated folding. PBO is also quite flexible and has a soft feel. But PBOs have poor resistance to both UV and visible light.
Vectran Vectran is a polyester-based high performance LCP (
liquid crystal polymer) produced by Ticona. It is naturally gold in color and has a modulus similar to Kevlar 29, but has less strength loss with flex. This is a benefit in endurance applications and for cruising sails where durability is key. Additional advantages of Vectran fiber has a 0.02% creep at 30% of max load after 10 000 hours, high chemical and abrasion resistance and high tensile strength. The UV endurance is inferior to PET and PEN, but the degradation levels off after roughly 400 hours of exposure, while the Aramids and Spectra continue to degrade.
Carbon fiber Carbon fiber is a high modulus synthetic fiber made from carbon atoms. It is virtually unaffected by UV exposure and provides exceptionally low stretch. Variants can balance along a continuum from brittle with no-stretch to extreme durability/flexibility with only slightly more stretch than aramid sails. ==Weaving==