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Bowstring

A bowstring is a strong, flexible cord that connects the two ends of an archery bow, storing potential energy when drawn and releasing it to propel an arrow upon release.^[1] It must withstand high tension, abrasion, and repeated stress while remaining lightweight and elastic to ensure accuracy and safety.^[2] Historically, bowstrings date back to prehistoric times, with the oldest known examples being approximately 7,000-year-old fragments made from animal sinew discovered in Cueva de los Murciélagos, Spain, dating to the early Neolithic period (ca. 5200–4900 BCE).^[3] Another notable early example is a 5,300-year-old unfinished cord made from animal fibers discovered with Ötzi the Iceman, likely intended for a yew bow.^[4] Early materials included natural fibers such as plant-based options like flax, hemp, and linen, as well as animal-derived sinew, gut, and twisted rawhide, which were reverse-twisted or looped for durability in hunting and warfare.^[5] These traditional strings required frequent replacement due to environmental exposure and wear, often waxed or sized for protection.^[6] In modern archery, bowstrings are crafted from synthetic high-modulus polyethylene fibers like Dyneema SK75 or Spectra, offering superior strength, low stretch, and longevity compared to natural materials.^[7] Common constructions include endless-loop and Flemish-twist designs, with protective servings of braided nylon at contact points to prevent fraying from fingers or arrow nocks.^[8] These advancements support both traditional recurve bows and high-performance compound bows, enhancing precision in competitive and recreational shooting.^[9]

Fundamentals

Definition and Function

A bowstring is a thin, high-tensile cord that connects the two ends of a bow's limbs, forming a taut loop under tension to propel an arrow forward upon release.^[1]^[2] This essential component enables the bow to function as a mechanical device for launching projectiles with precision and force.^[10] In its primary role, the bowstring stores potential energy generated by the archer's drawing action, which deforms the bow's limbs; upon release, it rapidly transfers this energy as kinetic force to the arrow through elastic recoil of the system.^[11]^[10] The string's vibration during this process can influence arrow speed and flight stability, potentially causing minor energy losses or oscillations that affect trajectory if not minimized.^[12] As the power transmission medium, the bowstring's performance is governed by basic mechanics where stored energy depends on draw length and tension, conceptually approximated by the elastic potential energy formula:

E \approx \frac{1}{2} k x^2

Here, E represents stored energy, k is the effective stiffness of the bow-string system, and x is the draw displacement, illustrating how greater draw amplifies propulsion without requiring detailed derivation.^[13]^[10] Bowstring design varies by bow type to optimize energy transfer and handling. In recurve bows, the string features a larger top loop to accommodate the curved limb tips, ensuring secure attachment and efficient energy release.^[14] Longbows typically use simpler, uniform loops suited to straight limbs, prioritizing minimal mass for smoother draws.^[15] Compound bows, by contrast, employ shorter, multi-strand strings that interact with cams and cables to let off tension at full draw, allowing higher stored energy with reduced holding effort.^[16]

Physical Properties

Bowstrings require lightweight construction to optimize arrow propulsion, as added mass reduces the kinetic energy transferred from the bow to the arrow. The effect is most pronounced at the string's center, where string mass has a greater impact on velocity than equivalent mass added at the limb tips due to the string's higher acceleration during release.^[17] High tensile strength is essential to endure draw weights typically ranging from 10 to 35 kg without failure; for instance, materials like BCY 452X exhibit a breaking strength of approximately 70 pounds per strand, allowing multi-strand constructions to safely handle tensions far exceeding operational loads.^[18] Abrasion resistance is critical to withstand repeated friction from the arrow nock and contact with bow limbs, with advanced blends such as BCY X-99 and 452Xtra incorporating high-abrasion Vectran fibers to minimize fraying and wear.^[7] Low stretch and controlled elasticity ensure consistent performance, with minimal elongation under load to maintain uniform draw length and maximize energy efficiency. Excessive stretch results in "creep," defined as non-recoverable elongation that alters draw weight, length, and tuning parameters like peep sight rotation.^[19] Materials engineered for minimal creep, such as those blending Dyneema and Vectran, exhibit near-zero permanent deformation at standard bow tensions, preventing the gradual reduction in arrow speed associated with elastic recovery losses.^[7] Resistance to water and environmental factors is vital to avoid performance degradation; bowstrings must limit moisture absorption, which can increase mass, promote slippage, and weaken fibers. Waxing serves as a protective barrier against humidity, while UV exposure accelerates material breakdown, particularly in synthetic fibers, leading to reduced tensile integrity over time.^[20]^[21] Durability varies by material and usage, with high-quality synthetics typically lasting 1,000 to 10,000 shots before requiring replacement due to cumulative wear. Factors like prolonged UV exposure contribute to degradation by breaking down polymer chains, while proper maintenance can extend lifespan toward the upper end of this range.^[22]^[23] The overall impact on archery performance underscores the interplay of these properties, particularly string mass's role in arrow velocity. From principles of energy conservation, the arrow's speed v is proportional to $1 / \sqrt{m_{\text{string}}}, where m_{\text{string}} represents the string's mass; this simple proportionality highlights how lighter strings enhance efficiency by allocating more stored potential energy to the arrow rather than accelerating the string itself.^[24]

Historical Development

Ancient and Traditional Bowstrings

The origins of bowstrings date back to the late Paleolithic era, with evidence of bow-and-arrow technology emerging around 54,000 years ago in Eurasia, based on microscopic analysis of lithic points from Grotte Mandrin in France that indicate use as arrowheads; early strings were likely crafted from available natural materials such as plant fibers or animal sinew to provide the necessary tension and elasticity.^[25] Direct archaeological preservation of bowstrings remains extremely rare due to their organic composition and rapid degradation, but indirect evidence from associated artifacts suggests simple, hand-crafted cords were integral to early hunting tools. Although no bowstrings from this period have been preserved, later Mesolithic sites provide indirect evidence, such as the approximately 11,000-year-old arrow shafts from the Stellmoor site in Germany, which imply contemporaneous strings made from twisted fibers or sinew for compatibility with wooden bows.^[26] The earliest directly preserved bowstrings date to the Neolithic period. In December 2024, archaeologists announced the discovery of two bowstrings made from braided animal sinew, dating to approximately 7,000 years ago (ca. 5200–4900 BCE), in Cueva de los Murciélagos (Cave of the Bats) in Albuñol, Spain; these are the oldest known preserved bowstrings in Europe.^[3] Another early example is a 5,300-year-old unfinished bowstring made from three-ply twisted animal sinew, found with Ötzi the Iceman in the Ötztal Alps.^[4] In ancient Near Eastern cultures around 3000 BCE, bowstrings were typically constructed from plant-based fibers like flax or linen, twisted into durable cords to suit composite bows used in warfare and hunting; Egyptian examples, including those from pharaonic tombs, often employed linen derived from flax for its strength and availability along the Nile.^[27] Mesopotamian archers similarly relied on regionally sourced vegetable fibers to create strings that could withstand the tension of horn-wood-sinew composite bows depicted in reliefs and seals. Among Native American peoples, particularly in northern and western regions, bowstrings were frequently made from animal sinew—tendons from large game like buffalo or elk—valued for their resilience in cold, arid climates where plant fibers might become brittle or absorb moisture.^[28] This material provided superior elasticity and durability, allowing strings to contract and expand with temperature changes without snapping. Medieval European developments saw the refinement of bowstrings for the English longbow, where high-quality Irish linen—derived from flax—was the preferred material in the 14th and 15th centuries, often reverse-twisted to enhance tensile strength and prevent unraveling under repeated draws.^[5] In Asia, traditional Japanese yumi bows utilized layered strings of silk or hemp fibers, braided for precision and balance on asymmetrical designs that emphasized ceremonial and martial accuracy. These materials were selected for their low stretch and ability to maintain consistent tension across the bow's unequal limbs. Traditional construction of ancient and medieval bowstrings involved manual techniques such as reverse-twisting bundles of raw fibers—starting with aligned strands soaked in water or animal glue for pliability—followed by serving the ends with finer threads to form loops that attached securely to the bow's nocks. Braiding methods, including simple three-strand plaits, were also employed in some cultures to distribute stress evenly and add bulk for power. String lengths were meticulously matched to the bow's tiller—the relative draw of the upper and lower limbs—to ensure balanced force and prevent twisting during release, a practice observed in ethnographic accounts of indigenous crafting.^[29] Bowstrings held profound cultural significance as disposable yet essential components in pre-modern societies, often replaced after every major use due to wear from friction and weather exposure. In warfare, they enabled the devastating volleys of English longbowmen at the Battle of Agincourt in 1415, where approximately 5,000 to 7,000 archers contributed to a decisive victory against a larger French force through rapid, high-volume fire. For hunting, reliable strings were critical for survival, as seen in Native American and Mesopotamian traditions where a failed cord could mean the difference between securing game and starvation, underscoring their role in sustaining communities across diverse environments.^[30]

Evolution of Materials and Techniques

In the 19th century, European archery saw the introduction of machine-spun linen and cotton bowstrings, which offered improved uniformity and consistency over traditional hand-twisted plant fibers like flax or hemp. This advancement stemmed from the Industrial Revolution's textile innovations, allowing for more reliable production of strings that maintained tension and resisted fraying under repeated use. By the early 20th century, these materials had become standard in competitive archery, including their adoption in the Olympic Games following the sport's inclusion in 1900, where linen strings provided the necessary strength and elasticity for longbow and early recurve events. The early 20th century marked the experimentation with synthetic materials, as nylon—the first fully synthetic fiber, developed by DuPont in 1935—began influencing archery through initial trials with plastic-based fibers in the 1930s. These early synthetics promised superior weather resistance compared to flax or linen, which were prone to degradation from moisture. The World Wars exacerbated material shortages, spurring innovations such as substituted plant fibers and rudimentary composites to sustain archery practices amid rationing of natural resources like cotton and silk.^[31]^[32] By the mid-20th century, techniques evolved with the standardization of looped-end bowstrings for recurve bows, enabling quicker attachment and consistent brace height that enhanced accuracy in target shooting. Serving methods also advanced, incorporating waxed threads—often nylon or polyester blends—wrapped around critical areas like the nocking point and loops to prevent fraying and abrasion from the bow's friction. A pivotal shift occurred in the 1950s when Dacron, a durable polyester fiber introduced by DuPont, replaced linen in Western archery, offering low stretch and longevity that reduced the need for frequent restringing.^[33]^[34] The invention of the compound bow in 1966 by Holless Wilbur Allen further influenced string design, necessitating lower-stretch materials to accommodate the mechanical cams and pulleys that multiplied draw force while minimizing energy loss. Early compound strings used plastic-coated steel cables, but this quickly evolved to synthetic fibers like Dacron variants to handle the increased tension without excessive creep.^[35]^[36] Regional variations persisted, particularly in traditional archery; for instance, Korean gakgung bows continued employing silk strings into the 1970s, valued for their smooth release and cultural authenticity despite the global shift to synthetics.^[37]

Construction Methods

String Forms and Types

Bowstrings are constructed in several basic forms that determine their structural integrity, attachment method, and suitability for different bow types. The simplest form is the simple twist, consisting of a single bundle of fibers twisted together into a cord and secured with knots at the ends. This primitive design, prone to unraveling under repeated stress, was historically used in early bows where advanced techniques were unavailable.^[38] A more robust variation is the reverse-twisted string, where individual fibers or small bundles are first twisted in one direction (with the lay), then combined and twisted in the opposite direction to create a balanced, interlocking structure. This method enhances strength and elasticity compared to the simple twist, making it suitable for traditional European and North American bows, though it can exhibit higher stretch over time. Reverse-twisted strings offer greater durability for sustained use but require careful tensioning to avoid uneven wear.^[38]^[5] Looped strings represent the predominant modern forms, designed for secure attachment to bow limbs without knots that could weaken the structure. The endless loop is a continuous strand, typically machine-made on a jig, with uniform loops formed during the twisting or braiding process and protected by serving material wrapped around the loop areas; it serves as the standard for contemporary recurve bows due to its consistency and ease of production. In contrast, the Flemish twist is a handmade looped type where the string's ends are spliced back into the main body to integrate the loops, providing a traditional aesthetic and often quieter performance on longbows and recurves. Looped forms facilitate quick replacement and adjustment on the bow, though endless loops may require precise sizing to match limb grooves.^[39]^[38] Specialized configurations adapt these forms for specific bows, such as multi-strand constructions in compound bows, which employ 20 to 36 strands to increase thickness and minimize vibration during high-speed shots. Loop attachment variations include endless loops for fast nock fit on recurves and laid-in loops—where strands are woven directly into the bow tips—for enhanced security on traditional self-bows. Design considerations emphasize strand count, typically 12 to 24 for recurves, which influences overall diameter and ensures proper nock fit without slippage; loop sizes must align with the bow's limb pockets to prevent misalignment under draw.^[40]^[41]

Serving and Reinforcements

Serving refers to the protective wrapping applied to bowstrings to shield vulnerable areas from wear and enhance structural integrity. Its primary purpose is to prevent abrasion caused by the arrow nock, finger tab, or contact with the bow limbs, while also reinforcing string loops to resist slippage and maintain consistent performance.^[42]^[43]^[44] The two principal types are center serving and end serving. Center serving is positioned at the nocking point, typically measuring 7 to 10 inches in length, and utilizes monofilament line or braided thread to create a durable, smooth surface that accommodates the arrow nock and withstands finger pressure. End servings, applied to protect the string loops, are shorter at about 2 to 3 inches and help secure the string ends against fraying and detachment.^[43]^[42] Serving techniques generally involve hand-wrapping the material around the bowstring under controlled tension, often facilitated by a serving jig for uniformity and tightness. Materials commonly include polyester (such as Dacron) thread for standard applications due to its balance of strength and flexibility, while high-wear areas may employ more robust options like Kevlar thread for superior abrasion resistance. The process begins with an overhand knot or tag end weave, proceeds with even wraps in the direction of the string's twist, and concludes with a secure finish, such as a back-serve loop or heat-sealing the ends to form a swollen knot that prevents loosening.^[45]^[42]^[46] Nocking points are integrated into the center serving, typically positioned about 3/8 inch (10 mm) above the square for finger shooters, though the exact height is fine-tuned for the archer's setup to ensure proper arrow flight. These are created using tied thread, whipped servings, or attached locators, ensuring alignment consistency across shots and reducing tuning variability.^[44]^[43] In advanced applications, particularly for compound bows, thicker "puffy" servings can be incorporated to cushion the string and mitigate peep sight rotation from torsional forces. Custom reinforcements may also involve applying heat-shrink tubing over served areas for enhanced protection, improved grip, and tailored fit against environmental wear.^[47]^[48]

Materials

Natural and Traditional Materials

Natural and traditional bowstrings were predominantly crafted from plant-based fibers, which offered accessible and robust options for archers across various cultures, though they often required protective treatments like waxing to mitigate environmental vulnerabilities. Linen, derived from flax plants through a process of retting—where stalks are soaked in water to separate fibers—provided exceptional tensile strength and durability when braided into strands, making it a staple for European archery until the mid-20th century. However, linen's hygroscopic nature led to swelling, stretch, and significant strength loss in wet conditions, which could compromise bow performance during rainy campaigns. Irish linen, prized for its fine quality, was commonly used for English longbows in medieval warfare, where archers relied on its load-bearing capacity for draw weights exceeding 100 pounds.^[5] Hemp fibers, coarser and more elastic than linen, were twisted and braided after water treatment to extract the bast, yielding strings suitable for demanding applications in Asian archery traditions. Hemp's natural resilience and moderate stretch made it ideal for composite bows, where it absorbed shocks effectively without excessive elongation. In ancient China, hemp bowstrings were valued for their strength in military contexts, dating back over 5,000 years, and remained common in regions like Japan for yumi bows in kyudo practice.^[5]^[49] Silk, harvested from silkworm cocoons through labor-intensive sericulture, produced exceptionally smooth and low-stretch strings that minimized energy loss during arrow release, though its high cost limited it to elite or ceremonial use. In Japanese archery, silk contributed to the precision of kyudo strings, often blended with other fibers for enhanced cohesion, while in China, it was employed for recurves, sometimes combined with bamboo elements for hybrid constructions in traditional designs.^[5]^[50]^[51] Animal-based materials complemented plant fibers by providing superior elasticity in certain environments, albeit with challenges related to weight and humidity. Sinew, sourced from dried animal tendons such as those of deer or horses, was beaten into fine fibers and twisted with hide glue for cohesion, resulting in strings with excellent elasticity that could store and release energy efficiently. Favored by Inuit hunters for their harsh, cold climates and Native American archers for short bows, sinew strings shrank in low humidity to increase tension but softened and stretched in moist conditions, necessitating protective coatings like resin.^[5]^[52]^[53] Gut, typically from animals like cattle or buffalo, was cleaned, twisted, and dried to form strong, elastic strings that offered good shock absorption and were less affected by humidity than sinew. Commonly used in European and Asian archery traditions, gut strings provided a balance of durability and flexibility but required careful preparation to prevent rotting.^[5] Rawhide, prepared by curing and stripping animal hides like those from donkeys or deer—soaking, stretching, and twisting them while drying—offered durable strings capable of withstanding high tension over extended use. Though heavier than plant alternatives, which slightly reduced arrow speed, rawhide's robustness made it suitable for African hunter-gatherer bows and medieval Chinese repeating crossbows, where reliability in varied terrains was paramount.^[5]^[54]^[55]

Synthetic and Modern Materials

The development of synthetic materials for bowstrings began in the mid-20th century, revolutionizing archery by providing greater durability, consistency, and performance compared to natural fibers. These engineered polymers addressed limitations such as excessive stretch and environmental degradation, enabling faster arrow speeds and more precise tuning in competitive settings.^[33] One of the earliest synthetic materials adopted for bowstrings was Dacron, a polyester fiber introduced by DuPont in the 1950s specifically for archery applications. With approximately 13% elongation under load and a tensile strength of about 22.5 kg per strand, Dacron offered forgiving stretch that absorbed vibrations, making it ideal for beginners and traditional bows while lasting several seasons with proper care. Its relative ease of handling and resistance to moisture contributed to its widespread use in entry-level and recreational archery.^[7]^[56] In the 1970s, high-performance aramid fibers like Kevlar emerged, providing significantly lower stretch at around 0.8% and higher strength of approximately 31.8 kg per strand, which allowed for faster arrow velocities and tighter groupings in target archery. However, Kevlar's sensitivity to ultraviolet light and tendency to degrade under prolonged exposure limited its longevity in outdoor conditions. To mitigate these issues, Vectran, a liquid crystal polymer developed in the late 1980s, was introduced as a more stable alternative with comparable low stretch and strength properties but improved resistance to UV degradation and creep, enhancing reliability for competitive use.^[57]^[58] The 1980s marked the advent of ultra-high-molecular-weight polyethylene (UHMWPE) fibers, such as Dyneema and Spectra, which exhibit minimal stretch of about 1%, exceptional tensile strength around 45.5 kg per strand, and lightweight, waterproof characteristics that minimize energy loss. These materials became the standard for Olympic and high-level competition due to their ability to maintain brace height and deliver consistent performance across thousands of shots.^[7] Modern bowstrings often employ composite blends to optimize durability, speed, and vibration dampening, such as 8125G, which combines Dyneema with Gore fibers for balanced properties, or mixtures like 67% Dyneema and 33% Vectran in 452Xtra for enhanced abrasion resistance. These composites support strand counts up to 64, reducing oscillations and improving shot stability in precision archery. Recent advancements include higher-grade Dyneema variants like SK99 for even lower creep.^[7]^[59] Post-2000 advancements include specialized coatings, such as nano-enhanced wax formulations, that reduce friction and wear on synthetic fibers, extending string life in high-volume shooting scenarios. While these non-biodegradable synthetics pose environmental challenges through persistent waste, efforts in recycling programs for polyethylene-based materials aim to mitigate impacts by repurposing discarded strings into industrial applications.^[60]

Performance and Maintenance

Tuning and Adjustment

Tuning a bowstring involves precise adjustments to ensure optimal arrow flight, power transfer, and consistency across shots. One key measurement is brace height, defined as the perpendicular distance from the bowstring to the deepest part of the grip. For recurve bows, this typically ranges from 7 to 9 inches (18 to 23 cm), and adjustments are made by adding or removing twists in the string—in increments of 3 to 4 twists—to achieve the quietest shot and maximize energy efficiency.^[61]^[62]^[63] String stretch affects arrow speed consistency, with higher stretch leading to reduced speeds equivalent to a 1-2 pound difference in draw weight. Low-stretch strings minimize this energy loss for better power output during extended use.^[24]^[64] Proper peep sight and nock fit are essential for a consistent draw cycle, with the peep sight tied into the string serving and aligned to match the archer's anchor point for unobstructed sighting. The nock point, where the arrow attaches, should be set 1/4 to 1/2 inch above square to the rest, ensuring secure fit without excessive tension that could cause separation on release. Tiller adjustment balances limb pressure on the string by measuring the distance from string to limb centers—aiming for a positive tiller of 0 to 4 mm in recurves—to promote even tension and straight nock travel.^[61]^[63]^[65] Testing methods verify these adjustments through empirical analysis of arrow performance. Paper tuning involves shooting an unfletched arrow through a sheet of paper from 4 to 6 feet, where tear patterns reveal issues like string torque—a left tear indicates rightward adjustment to the rest or nocking point in 1/16-inch increments. Chronograph testing measures arrow velocity to assess power, with well-tuned compound bows often targeting speeds exceeding 300 feet per second for optimal kinetic energy delivery.^[61]^[66]^[67] Bow-specific considerations refine string performance further. In compound bows, cam synchronization ensures both cams rotate evenly by adding half-twists to the cable of the leading cam until draw stops align, preventing erratic flight. For recurves, tiller tuning emphasizes even string tension across limbs, adjusted via limb bolts while maintaining brace height for balanced draw force.^[68]^[63]

Care, Inspection, and Replacement

Proper maintenance of a bowstring is essential to ensure longevity, safety, and consistent performance in archery. Daily care begins with regular waxing using beeswax for natural strings or synthetic waxes like silicone-based products for modern materials, applied every 100-200 shots or when the string appears dry or fuzzy to prevent fraying and maintain fiber integrity.^[69]^[70] After shooting sessions, store the bow unstrung in a cool, dry place to relieve tension on the limbs and string, avoiding prolonged stress that can accelerate wear.^[71]^[72] Inspection should be conducted routinely, such as after every 500 shots or monthly, focusing on key areas for signs of degradation. Look for fuzzing or broken strands along the string body, separation in the serving (the protective wrapping around critical sections), and slippage in the end loops that secure the string to the bow limbs; using a magnifying glass can reveal micro-abrasions or early wear not visible to the naked eye.^[73]^[72]^[74] Environmental factors play a significant role in string health—avoid exposure to excessive heat or direct sunlight, which can cause material creep and weakening, and store in low-humidity conditions to prevent moisture absorption that leads to stretching or mildew.^[75]^[76] Replacement criteria depend on usage and material, with synthetic bowstrings typically lasting 1-3 years or 3,000-5,000 shots under normal conditions, but requiring earlier substitution for high-use scenarios like tournaments where wear accumulates faster.^[71]^[77]^[78] Key indicators include visible fraying, excessive fuzziness, dry brittleness, or a measurable increase in draw length due to stretch from original specifications.^[73]^[79] Safety is paramount, as frayed or compromised strings can snap during draw, potentially causing a dry-fire that damages the bow or injures the archer; always retire worn strings by cutting them into short pieces for safe disposal to prevent accidental reuse.^[71]^[72]

References

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The meaning of BOWSTRING is a waxed or sized cord joining the ends of a shooting bow.
[2]
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### Types of Bowstrings: Simple, Reverse-Twisted, Looped
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### Flemish Twist Bowstring Construction Summary
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### Summary of Serving a Bow String
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[43]
[PDF] ARCHERY - Scouting America
An attachment to the center serving of a bowstring used to mark the nocking point. The nock locator may be a metal crimp-on, a piece of plastic that shrinks ...
[44]
How To Properly Serve a Bowstring - Bowhunter
Oct 12, 2017 · Weave the lead line, maintain even pressure, and flare/burn the ends to prevent slipping. These steps ensure a durable and consistent serve.
[45]
https://www.bowhunter.com/editorial/how-to-properly-serve-a-bowstring/309295
[46]
Using Heat Shrink Tubing on Bow Strings
Oct 31, 2016 · Heat shrink tubing on bow strings adds comfort and extra grip, and can be used for branding, using a 1/4" piece that shrinks at a 3:1 ratio.Missing: reinforcements | Show results with:reinforcements
[47]
Dongs-Key Thin-walled Heat Shrink Tubing - Archery Webshop
The Dongs-Key private label products are put in our range to serve the archers better and better. Thin-walled Heat Shrink Tubing protects your string.Missing: reinforcements | Show results with:reinforcements
[48]
Perspectives on Structure, Chemistry, and Enzymes for Retting Flax
Two main methods have been historically employed commercially to ret flax for textile-grade fibers, namely, water retting and dew (or field) retting [3, 37]. In ...
[49]
History of Cannabis in Ancient China - Psychology Today
May 10, 2011 · The Chinese also relied on hemp for warfare. Due to its strength and durability, Chinese archers made bowstrings from hemp. Because these hemp ...
[50]
https://www.3riversarchery.com/pure-silk-thread.html
[51]
Gōng xián (弓弦) | Mandarin Mansion Glossary
Mar 31, 2020 · Gōng xián (弓弦) literally means "bowstring". Chinese bowstrings were often made of silk. On war and strength bows, deer rawhide was commonly used.Missing: stretch | Show results with:stretch
[52]
Preparing and Using Sinew - Sensible Survival
Nov 7, 2011 · Sinew is a super material that has no modern equivalent. The only down-side to sinew is that it must be kept dry. If you get it wet it will soften and stretch.
[53]
A Note on Indian Bow Making or the Secrets of Sinew Revealed
Sinew, the shredded fibers of animal tendon, was used for cordage, binding points on arrow shafts, and for backing material for bows.Missing: archaeology | Show results with:archaeology
[54]
Rawhide Bowstring? - PaleoPlanet - Tapatalk
Oct 14, 2007 · Rawhide makes a good, fairly durable bowstring. It's a bit heavier and slower than most of the modern synthetic materials, but worked well ...
[55]
Primitive Bow Making – Part 4 | Sensible Survival
Feb 15, 2009 · Most surviving Native-American bows have strings made of sinew. Twisted rawhide was also used. The Cherokee, I am told, used twisted squirrel ...Missing: scholarly | Show results with:scholarly
[56]
Strings and Strategies - Bow International
Jul 5, 2015 · In the 1970s and early 80s, in high-level target archery, non-stretch Kevlar strings displaced Dacron. These materials had many advantages over ...
[57]
Vectran™ - Kuraray America, Inc.
Impact resistant · Vibration dampening · Cut/slash/abrasion resistant · Retains strength after repeated bending/flexing · Excellent offgassing and outgassing ...
[58]
BCY 8125 Bow String Material - The Footed Shaft
In stock Rating 4.7 34 BCY Formula 8125 string material is made from 100% SK75 Dyneema® fiber. Highest speed and higher durability. The choice of Olympic style recurve shooters ...Missing: composition | Show results with:composition
[59]
https://footedshaft.com/products/bcy-8125-bow-string-material
[60]
[PDF] ARROW TUNING AND MAINTENANCE GUIDE - Easton Archery
Observe how the paper is torn. This tear indicates good arrow flight. The point and fletching enter the same hole. Stiff Arrow. Unfletched shafts ...
[61]
How to Tune a Traditional Bow - Fred Eichler
### Summary of Brace Height Adjustment, Twisting String, and Tuning Methods for Recurves
[62]
How To Tune A Recurve Bow - The Best Guide by Olympic Experts
Line up the string with the limbs and riser as shown, then adjust your pressure button length until the point of the arrow is just slightly to the left of the ...INITIAL SETUP · BOW ALIGNMENT AND SETUP · BASIC RECURVE TUNING
[63]
https://www.onlinearcheryacademy.com/how-to-tune-a-recurve-bow/
[64]
How to Tie in a Peep Sight Properly | Specialty Archery
Jul 25, 2022 · The peep sight needs two reference points for you to line up your bow sight, your target sight, and your peep sight. When you draw the bow, ...
[65]
https://specialtyarch.com/how-to-tie-in-a-peep-sight-properly/
[66]
Bow-Tuning Techniques for Peak Performance - Bowhunter
However, paper-tuning is the foremost choice, since it provides an immediate visual of the arrow's flight pattern. I prefer to paper-tune first without ...Cam Alignment · Leveling The Sight · Recommended
[67]
What archers need to know about cam timing
### Summary of Cam Synchronization for Compound Bows
[68]
https://lancasterarchery.com/blogs/archery-tips/what-archers-need-to-know-about-cam-timing
[69]
How often do you wax bow strings and cables? | Archery Talk Forum
Aug 29, 2023 · Regular Maintenance: As a general rule of thumb, you should wax your bowstring every 100 to 200 shots or every few weeks, depending on how often ...Over waxing your string?? | Archery Talk ForumHow often do you wax your compound bow strings? - Archery TalkMore results from www.archerytalk.com
[70]
Bowstring Maintenance and When to Replace Them - Bowhunter
Jul 19, 2021 · Some bow manufacturers suggest changing out strings every two to three years, but again, it all depends on your shooting routine.
[71]
Compound Bow Maintenance Tips for Archers – OneX Archery Blog
Caring for Your Bowstring. How to Wax Your Bowstring the Right Way ... It is wise to inspect your bowstring often to catch any issues early. ... Measure the axle-to ...Getting Started With The... · Stick To A Routine With... · Troubleshooting Tips For...
[72]
The ins and outs of a quality bowstring - gohunt
Jun 25, 2019 · The ins and outs of a quality bowstring. String selection, how to not over-wax your strings and much more. Dave Barnett's avatar. June 25, 2019 ...
[73]
https://www.gohunt.com/browse/tips-and-tricks/archery/the-ins-and-outs-of-a-quality-bowstring
[74]
https://lancasterarchery.com/blogs/archery-tips/how-to-wax-a-bowstring-and-other-basic-string-maintenance
[75]
What Happens if Your Equipment Gets Wet? - Archery 360
Mar 30, 2023 · Shoving a wet bow and arrows inside a case can lock in moisture and cause serious damage including rust on accessories, stretched strings and cables, and even ...Missing: environmental heat<|control11|><|separator|>
[76]
When Should You Replace a Bowstring? | MeatEater Wired To Hunt
May 10, 2023 · Generally, a quality set of bowstrings can last several thousand shots when properly cared for. But even if you hang up your rig for a few ...Missing: UV | Show results with:UV<|separator|>
[77]
https://www.themeateater.com/wired-to-hunt/whitetail-hunting-gear/when-should-you-replace-a-bowstring
[78]
When Should You Replace Your Bowstring? - Bowhunting.com
Aug 19, 2020 · Bowstrings should be replaced every 2-3 years, or when showing wear, such as fuzzing, fraying, inconsistent shot grouping, or loss of poundage.<|separator|>