Fact-checked by Grok 2 weeks ago

Compound bow

A compound bow is a modern archery bow equipped with a levering system of cams and pulleys mounted on the limbs, which provides a mechanical advantage by reducing the holding weight at full draw while maintaining high arrow velocity and energy transfer.^[1] Invented in 1966 by American engineer Holless Wilbur Allen following an unsuccessful hunting trip that highlighted the limitations of traditional bows, the compound bow revolutionized archery by combining the power of recurve designs with ergonomic efficiency.^[1] This innovation allows archers to exert peak draw weights—typically ranging from 40 to 70 pounds—during the initial pull but hold the string with only 10-20% of that force, enabling steadier aiming and longer shots without excessive fatigue.^[2] The compound bow's design features rigid limbs made from advanced composites like fiberglass and carbon fiber, connected by a string and cable system that rotates the cams as the bow is drawn, optimizing energy storage and release.^[3] This mechanism not only amplifies arrow speed—often exceeding 300 feet per second—but also enhances accuracy through reduced hand shock and vibration compared to longbows or recurves.^[4] Key advantages include superior precision for target shooting and ethical harvesting in hunting, where let-off percentages (up to 80-90%) allow for precise shot placement at distances up to 50 yards or more.^[5] Since its patent in 1969, the compound bow has dominated modern archery, with ongoing advancements in cam profiles and materials improving efficiency and customization. Regulatory standards, such as minimum draw weights of 35-50 pounds for hunting in many states, underscore its role in ethical wildlife management and Olympic-style competitions.^[6]

History and Development

Invention and Early Patents

The compound bow was invented by Holless Wilbur Allen, an inventor from Billings, Missouri, who sought to improve upon traditional recurve bows by incorporating mechanical leverage to enhance energy storage and reduce the effort required to hold the bow at full draw. Allen's design utilized off-center pulleys or eccentric cams attached to the bow's limbs, which multiplied the draw force during the initial pull while allowing the holding weight to drop significantly at the end of the draw cycle, typically by 70-80 percent. This innovation addressed the limitations of conventional bows, where the full draw weight had to be maintained throughout aiming, often leading to fatigue and inaccuracy in hunting scenarios. Allen developed his concept in the early 1960s through experimentation with modified recurve bows and pulley systems, culminating in a functional prototype by 1966 using a pinewood riser, oak and fiberglass limbs, and wooden eccentric discs.^[7]^[8]^[9] On June 23, 1966, Allen filed for a patent titled "Archery Bow with Draw Force Multiplying Attachments," which was granted by the U.S. Patent and Trademark Office on December 30, 1969, as U.S. Patent No. 3,486,495. The patent described a system where cables connected to the eccentric pulleys wound in a way that stored more potential energy in the limbs compared to a standard bow of equivalent draw length, while the let-off mechanism enabled easier aiming without sacrificing arrow velocity. Early prototypes were tested in the mid-1960s, with Allen producing limited handmade versions for personal use and small-scale sales starting around 1967, though major manufacturers initially dismissed the design as overly complex. These initial bows achieved arrow speeds up to 20 percent faster than traditional recurves of similar draw weight, validating Allen's leverage-based approach.^[7]^[8]^[9] Following the patent grant, Allen licensed the technology to select companies, but legal challenges emerged as competitors questioned the patent's validity and scope. Notable disputes arose in the 1970s, including a 1977 lawsuit by Precision Shooting Equipment against Allen Archery, Inc., where Bear Archery intervened as a licensee to contest the patent's enforceability, leading to prolonged litigation over royalty calculations and design infringements. These battles, culminating in settlements and court rulings through the early 1980s, ultimately affirmed the patent's strength and facilitated broader licensing agreements, such as those with PSE and Jennings Archery, enabling commercial production starting in 1967 and paving the way for widespread adoption among hunters and archers.^[10]^[11]^[8] Allen was posthumously inducted into the Archery Hall of Fame in 2010 as the "Father of the Compound Bow".^[8]

Modern Advancements and Manufacturers

In the 1980s and 1990s, compound bow technology evolved significantly with the introduction of advanced cam systems aimed at improving draw smoothness and minimizing vibration. Mathews Archery pioneered the single-cam system around 1995, which simplified tuning and reduced cable wear compared to earlier dual-cam designs, allowing for a more consistent draw cycle.^[12] Shortly thereafter, Darton Archery developed the first hybrid cam in the late 1990s, combining elements of single and dual cams to balance synchronization and power delivery while further decreasing lateral nock travel and vibration.^[12] By the early 2000s, Bowtech introduced binary cams in 2005, a modified twin-cam variant that interconnects the cams via cables for enhanced timing and reduced torque, contributing to smoother draws and quieter shots.^[13] Major manufacturers have driven these innovations, with Hoyt, Mathews, PSE, and Bowtech leading the market through flagship models emphasizing performance and reliability. Hoyt's Carbon RX-9, released in recent years, incorporates advanced carbon risers for reduced weight and enhanced stability, achieving speeds up to 350 fps.^[14] Mathews' Vertix series, launched in 2019, features 3D Damping Technology that reduces vibration by 20% compared to prior models, delivering quieter shots and less hand shock for improved accuracy.^[15] PSE's Mach 33 DS, named Outdoor Life's 2025 Bow of the Year, utilizes the FDS Cam System for even power distribution and up to 10 fps speed gains, paired with a carbon riser for a lightweight yet durable build.^[16] Bowtech's Virtue model employs binary cam technology refined over decades, offering adjustable draw lengths and minimal vibration for versatile hunting applications.^[17] These companies collectively hold significant market share, with Mathews and Hoyt dominating in both hunting and target archery segments.^[18] The integration of carbon fiber and advanced alloys began in the 1990s, transforming compound bow construction for superior strength-to-weight ratios and longevity. Hoyt introduced the ProForce Carbon Plus riser in 1992, one of the earliest uses of carbon fiber to lighten the bow frame while maintaining rigidity against high draw weights.^[19] PSE followed with full carbon fiber risers by 1998, reducing overall bow weight by up to 20% compared to aluminum predecessors without sacrificing durability.^[20] Magnesium and high-strength aluminum alloys also emerged in the era, as seen in various 1990s models, providing corrosion resistance and impact absorption for field use.^[21] These materials have since become standard, enabling modern bows to weigh as little as 3.5 pounds while enduring repeated high-energy shots. As of 2025, compound bow trends emphasize smart integration and sustainability to enhance user experience and environmental impact. Mathews' Shot Sense module, compatible with recent models, connects to a mobile app for real-time shot analytics, including draw length, speed, and vibration data to aid training and tuning.^[22] Integrated rangefinders in bow sights, such as the Garmin Xero A1i, provide instant yardage and ballistic adjustments directly on the bow setup, streamlining aiming for bowhunters.^[23] Additionally, manufacturers are adopting eco-friendly materials like recycled carbon composites and bio-based resins, aligning with growing demand for sustainable archery gear that reduces manufacturing carbon footprints without compromising performance.^[24]

Design and Mechanics

Core Components

The riser serves as the central handle and structural core of a compound bow, providing a rigid platform to which the upper and lower limbs attach at each end. It typically consists of a vertical frame with a forward-facing cutout known as the sight window, which facilitates unobstructed aiming and arrow passage. Constructed from lightweight alloys such as aluminum or magnesium for durability and reduced weight, the riser also includes integrated mounting points, including threaded holes like the Berger hole for attaching stabilizers to counterbalance the bow's vibration.^[25]^[26] The limbs form the flexible upper and lower arms extending from the riser's limb pockets, designed to bend under tension to store potential energy that propels the arrow upon release. In compound bows, these limbs are often configured in parallel or slightly deflexed orientations to optimize energy transfer and minimize recoil, with the upper limb typically shorter than the lower for ergonomic balance during aiming. They connect to the riser via adjustable pockets that allow for draw weight modifications, ensuring the bow's performance can be tuned to the archer's needs.^[25]^[27] The sight window, located above the handle on the riser's medial side, features an arrow shelf or rest area that supports the arrow's nock during the draw and shot, preventing contact with the bow's body for cleaner arrow flight. An arrow rest, often a drop-away or containment style, mounts within this window to cradle the arrow shaft securely, while the adjacent rest mount provides precise adjustability for alignment. This setup, combined with the window's geometry, enhances accuracy by allowing the archer to align the peep sight with the bow sight through the cutout.^[26]^[27] The grip is an ergonomic, contoured section integrated into the rear of the riser, designed for comfortable hand placement to minimize torque during the shot and promote consistent form. Often wrapped in low-friction materials like rubber or laminate for better control, it positions the archer's hand close to the bow's centerline to reduce side-to-side movement. Surrounding the grip are various threaded mounting points and dovetail slots for attaching accessories such as quivers, slings, and additional stabilizers, enabling customization without compromising the bow's structural integrity. These elements integrate with the cam systems at the limb tips to form a cohesive unit, though the core components provide the static foundation.^[25]^[26]

Cam and Pulley Systems

The cam and pulley systems are the defining mechanical features of compound bows, distinguishing them from traditional bows by incorporating eccentric cams mounted at the tips of the limbs. These cams, typically elliptical or oval in shape, rotate as the bow is drawn, altering the effective length of the cables and strings to create a mechanical advantage that amplifies the archer's input force for greater energy storage in the limbs.^[7] The original design for this system was patented in 1969 by Holless Wilbur Allen, who described the eccentric attachments as force-multiplying levers that transform the draw motion into efficient limb deflection.^[7] Several types of cam systems have evolved to optimize performance, balance, and ease of maintenance. Single cam systems feature one eccentric cam, usually on the bottom limb, paired with a round idler pulley on the top limb; this asymmetric setup simplifies tuning and reduces noise but may produce slightly slower arrow speeds due to less precise synchronization.^[28] Dual cam (or twin cam) systems employ two identical eccentric cams, one at each limb tip, connected by split-yoke cables for synchronized rotation, which promotes straight nock travel and higher speeds but demands regular maintenance to prevent timing issues.^[13] Binary cam systems use two cams linked by interlocked control cables that self-correct during the draw, minimizing synchronization needs while achieving high efficiency and speed.^[29] Hybrid cam systems combine elements of the others, with an eccentric power cam on the bottom and a smaller control cam or idler on top, offering a compromise between speed and tuning simplicity.^[28] The primary role of these cams lies in their varying radii, which enable the system to achieve peak draw weight early in the cycle—often within the first few inches—before progressively reducing the holding force through a decreasing gear ratio as the cams rotate. This mechanical advantage, derived from the pulley-like action and eccentric geometry, allows the limbs to store significantly more potential energy than a straight-pull bow of equivalent draw weight, with the inner cam radius (typically around 0.75 inches) interacting with the outer radius (about 1.8 inches) to multiply force by ratios up to 2.4:1.^[29] By changing cable lengths dynamically, the cams ensure efficient energy transfer to the arrow upon release, enhancing velocity without requiring the archer to exert constant peak effort.^[13] Tuning these systems is essential for consistent performance and accuracy. Cam lean, where a cam tilts away from perpendicular during the draw due to cable torque, can be corrected using adjustable yoke cables in twin or hybrid setups or by adding shims in binary designs to maintain level nock travel.^[28] Synchronization ensures both cams rotate evenly, particularly in dual and binary systems, preventing uneven limb stress and arrow flight issues; this is achieved by adjusting cable lengths or tensions.^[13] Draw stops, integrated into the cams as pegs or modules, limit rotation at full draw to provide a solid back wall, with their positioning influencing the feel and stability of the hold.^[29]

Draw Cycle and Let-Off Mechanism

The draw cycle of a compound bow involves a series of phases that optimize energy storage and ease of use. In the initial pull phase, the archer encounters high resistance as the bowstring is drawn back, flexing the limbs and beginning to store potential energy through the mechanical advantage of the cams and cables.^[30] As the draw advances into the transition phase, the cams rotate further, building to the peak draw weight before the force curve begins to decline, marking the onset of the let-off.^[30] At full draw, the bow reaches the valley phase, characterized by a sharp reduction in holding weight that allows the archer to maintain position with minimal effort.^[30] This let-off typically ranges from 65% to 80%, depending on the bow's cam design, and is calculated using the formula:

\left( \frac{\text{peak draw weight} - \text{holding weight}}{\text{peak draw weight}} \right) \times 100

The let-off percentage quantifies the mechanical relaxation at the end of the draw, where the holding weight represents the minimum force required after the peak.^[31]^[5] The cycle concludes at the backwall, a solid mechanical stop—often provided by draw stops or cable contact—that prevents over-drawing and ensures repeatable draw length for consistent aiming.^[30] The let-off mechanism enhances aiming by drastically lowering the force needed to hold at full draw, which reduces muscular fatigue and permits extended hold times for improved shot precision, particularly beneficial in hunting or target scenarios.^[5] Different cam types can subtly influence the smoothness and timing of this cycle, affecting the overall feel during the transition and valley.^[30] In terms of energy dynamics, the cam geometry allows compound bows to store significantly more total potential energy in the limbs than recurve bows of equivalent peak draw weight—often around 40% more—due to the nonlinear force-draw curve that maintains high limb tension through much of the draw.^[30] Both types exhibit high storage efficiency (>90% of input work to stored energy), but compounds achieve superior dynamic efficiency of 80-85%, transferring a greater portion of stored energy to the arrow's kinetic energy compared to recurves (typically 65-71%).^[32]^[33] This contributes to greater overall performance while minimizing archer exertion.^[32]

Construction and Materials

Frame and Limbs

The frame of a compound bow, commonly referred to as the riser, serves as the central structural component that connects the limbs, cams, and other elements, providing stability and support during the draw and release. Risers are predominantly constructed from machined aluminum alloys, such as aircraft-grade 6061, valued for their high strength-to-weight ratio and cost-effectiveness in production.^[34] Magnesium alloys are also employed in some designs to further reduce overall weight while maintaining rigidity, making them suitable for hunting bows where portability is key.^[35] For premium models, carbon fiber composites are increasingly used, offering superior vibration dampening and torsional stability compared to metals, which enhances shot comfort and accuracy.^[36] The limbs, which store and release the bow's energy, are typically built using laminated construction techniques involving multiple layers of fiberglass bonded around a core material. Fiberglass provides durability and flexibility, while foam cores—often made from lightweight polymers—help optimize energy transfer and reduce mass without compromising performance.^[3] Advanced iterations incorporate carbon nanotube reinforcements within the laminate structure, enabling higher energy storage capacity and greater resilience to stress, all while keeping limb weight minimal to avoid fatigue during extended use.^[37] Manufacturing processes for these components emphasize precision to ensure reliability and efficiency. Risers are primarily produced via CNC machining, which allows for intricate shaping from aluminum or magnesium billets, achieving tight tolerances essential for consistent performance.^[38] Limbs undergo compression molding, where layered materials are pressed under heat and pressure in custom molds to form the curved profiles, with particular attention to aligning fibers parallel in compound designs to minimize torque and vibration upon release.^[39]^[40] These material and construction choices contribute significantly to the lightweight nature of modern compound bows, with many complete assemblies weighing under 4 pounds, improving maneuverability in the field compared to traditional bows that often exceed this due to less advanced materials.^[41]^[42] The riser's pockets securely attach the limbs to the cams, facilitating the bow's unique mechanical advantages.

String and Cable Assembly

The strings and cables in a compound bow are critical tension elements that facilitate the draw cycle and arrow propulsion, typically constructed from ultra-high-molecular-weight polyethylene (UHMWPE) fibers such as Dyneema or Spectra for their exceptional tensile strength-to-weight ratio and minimal stretch under load. These materials provide durability against abrasion and environmental factors like UV exposure, with serving—a protective wrapping of monofilament or braided material—applied at the nock point and cam contact areas to ensure precise arrow fit and prevent wear. For instance, modern strings often use 8125-grade Dyneema, which offers over 20% higher breaking strength compared to earlier polyethylene variants, allowing for thinner diameters that reduce drag. In a typical compound bow setup, the assembly includes a single main string that connects the cams and directly propels the arrow upon release, paired with one or more buss cables that link the cams to the bow's limbs to control their rotation and let-off. Dual-cam bows additionally incorporate control cables (or harness cables) to synchronize the cams' timing, preventing peep rotation and ensuring even draw length across the power stroke. This configuration allows for adjustable draw lengths by twisting the cables, with buss cables typically shorter and under higher tension to manage peak draw weight. Installation involves precise serving for accessories like peep sights, which are integrated into the main string for aiming alignment, and D-loops—a short serving loop at the nock—that connects the release aid without direct finger pressure on the string. Regular waxing with beeswax or synthetic compounds protects against fraying and maintains low friction, while controlled twist rates (e.g., 1-2 twists per inch) in the string bundle fine-tune draw length without altering brace height. Professional installation is recommended to avoid torque on the cams, often requiring a bow press to slacken the assembly safely. Maintenance is essential due to progressive creep—gradual elongation under repeated stress—that can degrade accuracy and safety; strings and cables should be inspected for fuzzing or separation after every 50-100 shots and replaced every 1-2 years or 1,000-2,000 shots, depending on shooting frequency and conditions. Failure to do so risks catastrophic breakage, as evidenced by tensile tests showing up to 10% strength loss after 500 cycles in high-draw-weight setups. Replacement kits from manufacturers ensure compatibility, with pre-stretched strings minimizing initial settling time.

Performance Specifications

Draw Weight and Length

Draw weight in a compound bow refers to the peak force, measured in pounds (lbs), that the archer must exert to draw the bow to its full position. According to the Archery Manufacturers Organization (AMO) standards, now maintained by the Archery Trade Association (ATA), draw weight is standardized by measuring the peak force at a 28-inch draw length, which corresponds to a true draw length from the pivot point plus 1.75 inches.^[43] This measurement ensures consistency across manufacturers, with adjustable compound bows typically offering a range of 40-70 lbs to accommodate various user strengths and applications.^[44] To adjust draw weight, archers loosen the limb locking screws and use an Allen wrench to turn the limb bolts—clockwise to increase weight and counterclockwise to decrease it—ensuring both upper and lower limbs are adjusted evenly for balance. Each full turn typically alters the weight by 1-2 lbs, though exact changes vary by model and should be verified with a bow scale; manufacturers like Hoyt recommend not exceeding 8-10 turns from the maximum setting to avoid damaging the limbs.^[45] Draw length is the distance, in inches, from the nocking point on the string to the bow's pivot point (deepest part of the grip) at full draw, plus 1.75 inches per AMO standards to standardize measurements.^[43] This specification allows for adjustments typically ranging from 24 to 31 inches on modern compound bows, enabling customization to the archer's physical build. To measure personal draw length, an archer stands in shooting stance, draws an arrow marked at the pivot point, and calculates the distance from nock to mark plus 1.75 inches.^[46] Adjustment of draw length is achieved by swapping or repositioning cam modules, which control the string and cable paths. On systems like Mission Archery's FastFit cam, this involves loosening a set screw with an Allen wrench, sliding the module to the desired position (often marked in half-inch increments), and retightening, a process that can be completed in under 30 seconds without a bow press.^[47] Rotating modules on other cams, such as those on Hoyt bows, similarly shifts the draw length by altering cam timing. Properly fitting draw weight and length to the archer is essential for accuracy, comfort, and injury prevention, with an average adult draw length of 28 inches serving as a common benchmark. Mismatches can lead to inconsistent shots or strain, while a well-fitted setup—ideally at 75% of the archer's maximum strength for draw weight—enhances control and performance.^[49] These adjustments also influence the let-off mechanism, affecting the holding weight at full draw.

Speed, Energy, and Efficiency Metrics

The International Bowhunters Organization (IBO) speed rating standardizes compound bow performance by measuring arrow velocity under controlled conditions: a 30-inch draw length, 70 pounds peak draw weight, and a 350-grain arrow, with modern high-end models achieving up to 350 feet per second (fps).^[50]^[51] This metric highlights the bow's potential speed but decreases in real-world setups with shorter draws or heavier arrows. Kinetic energy (KE) quantifies the arrow's impact potential, calculated using the formula:

KE = \frac{\text{arrow mass in grains} \times \text{velocity}^2}{450{,}240}

where KE is in foot-pounds (ft-lbs); for hunting applications, typical compound bow setups deliver 60-100 ft-lbs, sufficient for ethical big-game harvest with proper shot placement.^[52]^[53] Efficiency in compound bows refers to the percentage of stored draw energy transferred to the arrow, typically 80-90% in modern designs, with losses primarily from vibration, friction, and incomplete energy release.^[54] This high transfer rate is achieved through rigid limb construction and cam systems that minimize energy dissipation. Arrow weight significantly influences these metrics, as lighter arrows (e.g., 300-350 grains) maximize speed for flatter trajectories, while heavier ones (400-500 grains) enhance penetration via greater momentum, often at the cost of 20-50 fps in velocity.^[55] Draw weight, as established in bow specifications, scales these outputs proportionally but remains a foundational variable.^[50]

Comparison to Other Bows

Technical Advantages

Compound bows offer several mechanical advantages over traditional recurves and longbows due to their cam and pulley systems, which optimize energy transfer and shooter interface. The cams enable the limbs to store approximately one-third more energy at full draw compared to recurves of equivalent draw weight, primarily through a more efficient force-draw curve that maintains higher tension throughout the draw cycle.^[56] This results in greater potential energy retention, with hybrid cam designs achieving up to 81% efficiency in converting stored energy to arrow kinetic energy, surpassing the typical 70-80% of straight-limb bows.^[57] Fixed draw stops on the cams ensure a consistent full-draw position, minimizing variations in draw length that can occur in traditional bows due to shooter fatigue or form inconsistencies. This mechanical consistency reduces arrow speed deviation across multiple shots, leading to tighter groupings at extended ranges, as the bow reaches peak energy release at a precise, repeatable point.^[58] The let-off effect, facilitated by these cams, further aids in maintaining this precision without excessive holding effort.^[28] Modular cam systems and limb bolts provide extensive adjustability, allowing users to fine-tune draw length, draw weight, and let-off percentage—often in increments as small as 1/4 inch or 2 pounds—without requiring a complete bow rebuild or specialized tools. Unlike fixed-geometry traditional bows, which demand custom fabrication for alterations, this modularity enables personalization to fit individual anthropometrics while preserving structural integrity.^[59] Parallel limb configurations, combined with integrated dampeners, significantly reduce post-shot vibrations and hand shock by directing recoil forces axially rather than laterally into the grip. This design can decrease vibration transmission compared to non-parallel setups, enhancing overall bow stability and reducing torque that could affect aim.^[40] Dampeners, often made from viscoelastic materials, absorb residual limb oscillations, further minimizing noise and felt recoil for a smoother shooting experience.^[60]

Technical Disadvantages

Compound bows feature multiple moving parts, including cams and cables, which introduce greater mechanical complexity compared to simpler recurve or longbow designs. This complexity makes them more susceptible to misalignment or failure if not properly tuned, as the interconnected components can shift under stress or wear, leading to inconsistent performance or even breakage.^[61] Due to their reliance on metal risers, cams, and pulley systems, compound bows are generally heavier and bulkier than traditional recurves, with typical masses ranging from 3 to 4.5 pounds, reducing portability in field scenarios where lightweight recurves often weigh 2 to 3 pounds.^[51] Maintenance requirements are more demanding than for longbows, necessitating periodic cam timing adjustments to ensure synchronized rotation and regular string and cable replacements every 1-3 years depending on usage, as these elements degrade from stretching and friction.^[61]^[62] Undampened compound bows can generate noise from cable slap and vibrations during the shot, potentially alerting game more than the quieter release of simpler bow types, although modern suppressors mitigate this to some extent.

Practical Advantages

One of the primary practical advantages of the compound bow is its let-off mechanism, which significantly reduces the holding weight at full draw, enabling archers to maintain a steady aim for extended periods without excessive fatigue. For instance, a 70-pound draw weight bow with an 80% let-off requires only about 14 pounds to hold, allowing precise aiming for 10-20 seconds or more, which is particularly beneficial for shots up to 50 yards where minor adjustments can determine accuracy.^[63]^[64] Compound bows offer exceptional versatility through their adjustable features, accommodating users from beginners to advanced archers across various settings. Draw weights can often be tuned from as low as 14 pounds up to 70 pounds, and draw lengths from 16 to 31 inches, making them suitable for indoor target practice or outdoor field archery while allowing progression as skills develop.^[65] In hunting scenarios, compound bows deliver higher kinetic energy to arrows compared to traditional bows, facilitating ethical kills on larger game at ranges of 30-40 yards by ensuring sufficient penetration and flatter trajectories for vital zone placement.^[66]^[67] The forgiving nature of the compound bow's draw cycle enhances training efficiency for novice archers, as the let-off and consistent pulley system reduce the physical demands of holding and releasing, enabling quicker development of proper form and muscle memory with less initial strain.^[63]

Practical Disadvantages

Compound bows generally carry a higher upfront cost compared to traditional recurves, with quality models ranging from $500 to $2,000, while basic recurves can be obtained for $100 to $300. ^[68] ^[69] This price differential stems from the advanced materials, cam systems, and manufacturing precision required for compounds, often necessitating additional expenditures for initial setup and accessories. ^[63] Furthermore, ongoing costs include professional tuning services, which typically range from $20 to $100 per session depending on the shop and complexity, adding to the long-term ownership expenses. ^[70] In field scenarios, the bulkier design of compound bows can pose challenges for navigation in tight spaces, such as dense brush or elevated hunting platforms, due to their typical axle-to-axle length of 30 to 35 inches. ^[71] ^[72] This dimension provides stability for accurate shots but makes the bow less maneuverable than slimmer traditional options, potentially complicating quick draws or movements in confined environments. ^[71] Compound bows exhibit greater sensitivity to environmental conditions like humidity, where moisture can cause cables and strings to stretch, altering draw length and requiring frequent adjustments to maintain performance. ^[73] ^[74] Unlike more robust traditional bows, which tolerate weather variations with minimal intervention, compounds demand protective measures such as waxing and dry storage to mitigate these effects. ^[75] Historically, compound bows have been excluded from Olympic archery events and many World Archery Federation competitions, which are limited to recurve bows; however, a mixed team compound event will debut at the 2028 Summer Olympics.^[76] Users often face a steeper learning curve for maintenance and repairs with compound bows, as DIY tuning involves specialized tools and knowledge of cam synchronization, though many issues necessitate professional service for optimal results. ^[77] ^[78] This complexity can lead to downtime if adjustments are mishandled, contrasting with the simpler upkeep of traditional bows and underscoring the value of archery shop expertise. ^[70]

Arrows and Accessories

Compatible Arrows

Compound bows require arrows specifically engineered to handle high draw weights, speeds, and let-off characteristics, ensuring optimal energy transfer and flight stability. Primary arrow construction favors carbon shafts due to their lightweight nature, high straightness tolerances (often ±0.001 inches), and resistance to bending under stress, making them ideal for the powerful propulsion of compound bows.^[79] Aluminum shafts serve as reliable backups, offering durability and affordability, though they are heavier and more prone to denting compared to carbon.^[80] Fletching typically consists of plastic vanes, which provide enhanced stability and helical orientation for spin-induced accuracy, outperforming feathers in wind resistance and ease of tuning for compound setups.^[81] Spine rating, a measure of arrow stiffness defined as the deflection in inches multiplied by 1000 when a 1.94-pound weight is hung from the center of a 29-inch shaft, is crucial for compound bows to prevent excessive flexing that could disrupt arrow flight.^[82] For high draw weights (50-70 pounds), stiffer spines in the 300-400 range are recommended to maintain rigidity during release, as softer spines may paradox or veer off course under the bow's let-off dynamics.^[83] Selection relies on manufacturer charts, such as Easton's group system, which factors in draw length, peak weight, and point mass to match the arrow to the bow's specifications, ensuring consistent grouping and minimal oscillation.^[84] Arrow weight tuning balances speed, kinetic energy, and penetration, with a common guideline of 5-6 grains per pound of draw weight for total arrow mass (including point, shaft, fletching, and nock) to achieve efficient energy transfer without excessive vibration.^[85] For instance, a 60-pound compound bow pairs well with arrows totaling 300-360 grains, promoting flat trajectories while mitigating bow wear from lighter setups below 5 grains per pound.^[86] Hunting configurations incorporate broadheads (100-125 grains) to optimize momentum on impact, whereas target shooting uses field points of similar weight for consistent spine dynamics and easier tuning.^[87] Nocks and inserts complete the arrow assembly, with brass inserts preferred at the front end for their durability, weight adjustability (often 20-50 grains), and secure threading that withstands repeated impacts without fracturing.^[88] These inserts enhance front-of-center (FOC) balance, typically 10-15% for compounds, aiding stability during flight. Nocks at the rear must ensure compatibility with cam-over-travel, featuring large grooves to accommodate the string's rotational path and D-loop release, preventing slippage or premature detachment that could cause erratic nock travel.^[89] Press-fit or lighted nocks, often in high-impact polymers, snap securely onto the string for an audible "click," supporting the bow's high-speed release without interference.^[90]

Essential and Optional Accessories

Essential accessories for a compound bow include the release aid, arrow rest, and stabilizer, which are critical for achieving consistent accuracy and safe operation. The release aid is a mechanical device that attaches to the bowstring and allows the archer to draw and release the string with minimal hand involvement, significantly reducing finger torque that can cause arrow misalignment during the shot.^[91]^[92] Arrow rests support the arrow on the bow's shelf or riser and are often drop-away designs that retract upon release to provide a clean arrow flight path, minimizing contact with fletching and enhancing precision.^[93]^[91] Stabilizers, typically mounted to the riser's front or rear accessory ports, counterbalance the bow's weight and absorb post-shot vibrations, improving stability and reducing hand fatigue during extended use.^[91]^[92] Sighting systems are also fundamental for targeting, with multi-pin sights featuring multiple fiber-optic pins calibrated for different distances (e.g., 20 to 60 yards) to allow quick ranging, while single-pin sliders use a movable pin for adjustable yardage settings.^[93]^[91] Peep sights, small apertures tied into the bowstring, align the archer's eye with the front sight for consistent aiming reference, often positioned at full draw to reinforce the anchor point.^[93]^[92] Optional accessories further customize the setup for comfort and performance. Quivers, available in bow-mounted (attached to the riser for quick access) or hip styles, securely hold arrows and help maintain the bow's balance when loaded.^[91]^[93] Dampeners, such as rubber silencers or string loops, mitigate noise and vibration from the shot, promoting quieter operation and reduced bow jump.^[93]^[91] Slings attach to the stabilizer or riser to secure the bow to the archer's body, preventing drops and allowing a relaxed grip.^[91]^[92] Safety gear complements these items, including arm guards that shield the forearm from string slap during release, and finger tabs that protect digits when shooting without a release aid—though the latter are less commonly used with modern compound setups.^[92]^[91]

Usage and Applications

Target Archery

In target archery, compound bows are utilized in both competitive and recreational settings under governing bodies such as the World Archery Federation (WA) and the National Field Archery Association (NFAA). In WA competitions, compound archers in the open division are permitted unlimited sights, including multiple pins or single adjustable pins without magnification restrictions, distinguishing them from recurve classes that limit sighting aids. Scoring follows a 10-ring system on a five-color target, where the innermost gold ring awards 10 points, emphasizing precision in grouping arrows tightly. Olympic archery has traditionally featured only recurve bows at 70 meters; however, starting with the 2028 Los Angeles Games, a compound mixed team event will be included at 50 meters.^[76] Compound divisions in other international WA events typically shoot qualification rounds at 50 meters using an 80 cm target face with an 8 cm 10-ring, though some NFAA outdoor target rounds incorporate distances up to 70 meters to test accuracy under varied conditions.^[94]^[95]^[96] Techniques in compound target archery prioritize consistent form and release mechanics over raw power, leveraging the bow's let-off to maintain steady aiming without fatigue. A key method involves back tension releases, which activate through rhomboid muscle engagement in the shooter's back, promoting an unanticipated shot that reduces target panic and enhances accuracy by minimizing hand torque. Indoor setups, such as the popular Vegas round under NFAA rules, are shot at 18 meters (20 yards) on a 40 cm five-spot target, allowing archers to focus on rapid, repetitive shooting in controlled environments like leagues or tournaments. This emphasis on form ensures reliable arrow flight, where the compound's consistent draw cycle contributes to tight groupings at competition distances.^[97]^[98]^[99] In competition, compound bows offer advantages through highly adjustable sights that allow precise windage and elevation tweaks, enabling archers to compensate for environmental factors like crosswinds during qualification or matchplay rounds. The bow's mechanical efficiency provides consistent arrow speeds, facilitating predictable trajectories and superior grouping compared to traditional bows, which aids in achieving high scores in set formats. Training regimens commonly include drills for anchor point consistency, such as blind draws where archers establish and repeat the contact points—typically the release hand against the jaw, string to the nose or lip, and peep sight alignment—without visual feedback to build muscle memory. These practices are integral to preparation for events like the WA World Archery Championships, where compound divisions feature individual, team, and mixed formats testing endurance and precision over multiple ends.^[100]^[101]^[102]

Hunting and Field Use

Compound bows are widely utilized in hunting due to their power and precision, but ethical use emphasizes ensuring humane kills through adequate equipment and shot placement. A minimum draw weight of 40 pounds is commonly recommended and often legally required for hunting deer to achieve sufficient kinetic energy for deep penetration into vital organs.^[103] Broadheads, typically fixed-blade or mechanical designs with at least two sharpened cutting edges, are essential for creating effective wound channels that promote quick, ethical harvests by maximizing blood loss and minimizing suffering.^[104] Hunting regulations for compound bows vary significantly by jurisdiction to balance safety, wildlife management, and fair chase principles. In the United States, most states permit compound bows during dedicated archery seasons, but some impose restrictions such as prohibiting them in primitive weapon or muzzleloader seasons to preserve traditional methods.^[105] Blaze orange requirements are mandated in numerous states for all hunters, including those using compound bows, during concurrent firearm seasons to enhance visibility and prevent accidents; for instance, at least 400 square inches of fluorescent orange above the waist is required in states like Oklahoma.^[106] Field adaptations enhance the practicality of compound bows in dynamic hunting environments. Lightweight models, often weighing under 4 pounds with compact axle-to-axle lengths of 29 to 33 inches, facilitate easy carrying and maneuvering in rugged terrain or elevated positions.^[65] These bows are particularly suited for tree stand hunting, where shorter brace heights and quiet operation allow for unobstructed draws from confined spaces.^[107] Additionally, applying scent-free synthetic wax to bowstrings helps mitigate human odor retention, reducing the risk of detection by game animals with acute senses.^[108] Success in compound bow hunting hinges on targeted practice and specialized tools to address real-world challenges. Hunters must regularly practice shooting at odd angles, such as those encountered from tree stands, to account for trajectory adjustments on uphill or downhill shots.^[109] Integrated angle-compensating rangefinders are crucial for accurate ranging in typical hunting distances of 20 to 40 yards, providing horizontal distance calculations that ensure precise pin placement and effective shots.^[110]

References

[1]
[PDF] The Modern Compound Bow - Deep Blue Repositories
These Asiatic bows consisted of wood, horn, and sinew, and the portions touching the string were rigid and did not flex upon drawing. These static-recurve bow ...
[2]
[PDF] INDEX - ARCHERY - UA Cooperative Extension
Compound bows have several advantages over recurve bows of similar draw ... Secure your bow somehow to where you can work on it with both hands. Use a ...
[3]
Cams | Science Behind the Sport | West Virginia University
The elasticity of the bow limbs combined with the mechanical advantage of the cams amplifies the force that propels the arrow.
[4]
Archer's Compound Bow--smart use of Nonlinearity
This study clearly demonstrates from physics principles the two widely known and important advantages of the compound bow over earlier types- improved precision ...
[5]
Exploring Michigan 4-H Shooting Sports: Archery
Feb 28, 2017 · Bow type and style is a personal preference. The advantage to using a compound bow is the draw weight is reduced at full draw, making it easier ...
[6]
[PDF] 4-H Archery Project Book | Extension Sheboygan County
Mar 15, 2024 · COMPOSITE BOW: A bow made of more than one substance. COMPOUND BOW: A bow developed in recent years that use a system of cams, pulleys, and ...<|control11|><|separator|>
[7]
Archery — Texas Parks & Wildlife Department
Compound Bow- this is truly a modern bow and has become the most popular bow in use today. The mechanics of the wheels and cables reduce the amount of effort ...Missing: definition | Show results with:definition
[8]
US3486495A - Archery bow with draw force multiplying attachments
Additionally, it is an aim of this invention to provide limbs which are adjustable with respect to the handle section of the bow in order to permit relaxing of ...
[9]
Inductee - Hollis Wilbur Allen - Archery Hall of Fame and Museum
Allen filed for a patent on his new bow on June 23, 1966. It was granted in 1969. By 1977, there were 100 different models of compound bows available, only 50 ...
[10]
The history of compound bows - Bow International
Oct 14, 2022 · On 30 December 1969 the US Patent Office published patent no. 3,486,495 for an archery bow with draw force multiplying attachments. An inventor ...
[11]
Allen Archery, Inc., Plaintiff-appellee, v. Precision Shooting ...
The disputes between Allen and Precision center on their differing interpretations of the licensing agreement. The agreement basically gives Precision a license ...Missing: Oneida commercial 1978 Bear
[12]
IN RE ALLEN COMPOUND BOW PATENT LITIGATION, (JPML 1978)
Again, Allen Archery claims infringement upon its compound bow patent, alleges breach of a patent license agreement, and seeks a judicial determination that the ...
[13]
Understanding compound bows - KAIT
Apr 1, 2009 · Around 1995, Mathews Archery introduced the single-cam and shortly thereafter Darton Archery introduced the first hybrid cam. Today there are ...
[14]
Compound Bow Cam & Limb Technologies - Hunter's Friend
BINARY CAMS` Introduced by Bowtech Archery as a new concept for 2005, the Binary Cam is a modified 3-groove twin-cam system that slaves the top and bottom cams ...Missing: advancements 1980s 2000s
[15]
Hoyt Archery | For the Most Serious Archers and Bowhunters
### Summary of Current Flagship Compound Bows and Recent Advancements
[16]
Field Test: 2019 Mathews Vertix Compound Bow Review - GearJunkie
Feb 14, 2019 · The Vertix boasts Mathews' noise- and vibration-killing 3D Damping Technology. The rig also has Crosscentric Cam Technology, which promises a smooth draw, ...
[17]
The Best Compound Bows of 2025, Tested and Reviewed
Jun 25, 2025 · The PSE Mach 33 DS is the best compound bow of 2025. It has a smooth draw, a comfortable back wall, little vibration after the shot, steady aim, repeatable ...Missing: models | Show results with:models
[18]
https://www.60xcustomstrings.com/blog/the-10-best-compound-bow-manufacturers/
[19]
http://www.archeryhistory.com/compounds/90.php
[20]
Bows 1990-1999 - Archery History *
Bows 1990-1999 - Click Photos to Zoom ; Hoyt ProForce (1992) ProForce Carbon Plus and Medali, Guzzetta Enterprises TLC4 (1992) (physical weight-7 pounds), Hoyt ...Missing: fiber advanced alloys
[21]
Who made the first carbon bow? | Archery Talk Forum
Feb 13, 2014 · I had the PSE in carbon fiber riser compound bow in 1998, 12 years prior. And it sounds like maybe Diamond had one prior to that.Vintage bows vs modern bows, how much have we advance?Origins | Archery Talk ForumMore results from www.archerytalk.comMissing: alloys history 1990s
[22]
History of the Compound Bow - Archery 360
Nov 12, 2020 · Holless Wilbur Allen, a 2010 inductee to the Archery Hall of Fame and Museum, applied in 1966 for a patent for the first compound bow. It ...Missing: Oneida 1978
[23]
SHOT SENSE™ – Mathews Archery
The Shot Sense module will track and record your shot analytics, providing advanced feedback in real time through the Mathews Shot Sense app.
[24]
3 Best Rangefinder Bow Sights: The Must-Have Bow Optics of 2025
QUICK LIST: Best Rangefinder Bow Sight in 2025. Burris Oracle 2 - Best Overall; Garmin Xero A1 Bow Sight - Best Smart Sight for Bow; Garmin Xero A1i Pro - Best ...
[25]
Growth Roadmap for Archery Equipment and Accessories Market ...
Rating 4.8 (1,980) Jun 6, 2025 · ... bows and accessories tailored to individual needs. Sustainable Materials: Increasing adoption of eco-friendly materials in manufacturing.
[26]
A Guide to Parts of a Compound Bow | Field & Stream
Feb 28, 2023 · The parts of a compound bow include: Riser, Arrow Shelf, Grip, Limb Pockets, Limbs, Cam, Axles, Cam Modules, Limb or Cable Stops, Bowstring, D- ...
[27]
Anatomy of a Compound Bow - Bowhunting.com
A compound bow includes cam systems, string and cables, limbs, a riser, and a grip. The riser is the foundation of the bow.Missing: core | Show results with:core
[28]
Learn parts of a compound bow [Interactive Diagram] - N1 Outdoors
Aug 1, 2021 · Compound bow parts include cams, limbs, riser, sight mounts, cable guard, rest mounts, arrow shelf, stabilizer mount, axle, string splitter, ...
[29]
Cam systems explained - Bow International
Dec 16, 2022 · The cams on a compound allow the archer to comfortably draw and hold a heavier draw weight, they maximise the bow's energy and efficiently store and deliver it.
[30]
Understanding Compound Bows - Bowhunting.com
Some bows have a hard back-wall in the letoff valley while others are softer. The feel of the back wall is related to the shape of the harness track in the area ...Missing: phases initial transition
[31]
Equipment Definitions - Pope and Young Club
The let-off force is the lowest force reached following the peak force during a single uninterrupted draw cycle. In all cases, both the highest and lowest force ...Missing: explanation | Show results with:explanation
[32]
What is compound bow let-off?
### Summary of Let-Off Mechanism in Compound Bows
[33]
https://www.isjos.org/pdfs/ISJOS_v17_p3.pdf
[34]
[PDF] Work, Energy, and Efficiency of a Recurve Bow
The average recurve bow efficiency was found to range from 65% to 71%, with efficiency decreasing with increasing draw distance.
[35]
Compound bow components - find out about technology and ...
The eccentric system is engineered to maximize the amount of stored energy the bow can produce while minimizing the amount of effort you need to draw and hold ...
[36]
Check out all products from Topoint Archery | DutchBowStore.com
Complete and very affordable compound set by Topoint Archery. The riser is made of an aluminum/magnesium alloy for rigidity and weight ...
[37]
Carbon vs. Aluminum: which bow riser should you choose? | Uukha
Oct 15, 2025 · Less vibrations: carbon absorbs more vibration than aluminum, offering greater shooting comfort. Working with carbon requires a more complex ...Missing: compound magnesium alloys composites
[38]
Gordon Glass™ Archery Bow Limbs - Avient
Whether it's traditional recurve, compound, or crossbow limbs, our engineering team will work with you to develop a limb that meets your specific requirements.
[39]
Win & Win Shadow 32 Review - Bowhunter
Nov 15, 2013 · Shadow limbs measure 12.5 inches long and are also made of carbon infused with nano materials, which consist of carbon nanotubes and graphite ...
[40]
Compound Bow CNC Machining - Elimold
Elimold offers CNC machining for compound bow parts like risers, cams, and arms, using 3-5 axis milling and turning, with high precision and custom ...
[41]
Method for manufacturing a compression molded archery bow limb
The purpose of the present invention is to provide an archery bow limb for a compound bow that has all the advantages of similarly employed prior art bow limbs ...
[42]
https://www.kokomolantern.com/blog/i/84971436/which-better-traditional-recurve-or-compound
[43]
Best Compound Bows of 2025, Expert Tested - Field & Stream
Jul 3, 2025 · After weeks of testing and hundreds of arrows sent downrange, our expert picks the best new flagship bows of the year.Missing: major | Show results with:major
[44]
Which is better: traditional, recurve, or compound? - Kokomo Lantern
Dec 15, 2024 · The main advantage of the compound bow is the weight reduction ability they have, compared to traditional and recurve bows.
[45]
[PDF] AMO Standards - Outlab
In accordance with the AMO Bow Weight Standard, the manufacturer has the option to mark his bow with actual draw weight at 28” (26¼” DLPP) draw or to use the ...
[46]
https://www.uukha.com/en/news/draw-length-what-is-it-and-how-is-it-measured
[47]
Hoyt - Frequently Asked Questions
### Summary: Adjusting Draw Weight on Hoyt Compound Bows
[48]
Draw Length in Archery: definition, measurement and AMO standard
The official draw length is the AMO one, and to find out what it is, simply add 1.75" to the measurement you found earlier. For example, you measured 74.5 cm ...
[49]
Cam Adjustment | Mission Archery By Mathews
Draw lengths can be changed in under 30 seconds with the simple use of an allen wrench. Loosen, slide and retighten. It's that easy.
[50]
ADJUSTING THE DRAW LENGTH ON THE HBX AND ... - YouTube
Jun 16, 2021 · Here we give you step-by-step instructions on how to adjust your draw length for your Hoyt bow that uses the HBX or HBX Pro Cam System.
[51]
Compound Bow Fitment Guide - draw length - Hunter's Friend
A good rule-of-thumb is to choose a draw weight that requires about 75% of your "maximum" strength. If your bow is too heavy to draw back (overbowed), and you ...
[52]
The Truth Behind Compound Bow Speed Ratings
Jun 22, 2020 · The IBO standard is similar, measured with a 30-inch draw length and an arrow weighing 5 grains per pound of draw weight; otherwise, exactly equivalent to ATA ...
[53]
Compound Bow Specifications and Jargon - Hunter's Friend
The higher the draw weight (force) - the more power the bow stores and the faster the arrow will shoot. The longer the draw cycle (distance) the more power the ...
[54]
KINETIC ENERGY CALCULATOR - Easton Archery
To calculate your arrow's kinetic energy you need to know two variables: 1) your total finished arrow weight in grains, and 2) the velocity of your arrow. ...
[55]
How Much Kinetic Energy For Bowhunting?
The formula for doing so is: KE = (m*v2)/450,800. The m in this formula represents mass (weight), the v represents velocity (speed), and the outcome of the ...
[56]
How Compound Bows Work
Apr 11, 2017 · The draw cycle of a compound bow is not linear: as you pull the string back, the effort required peaks part of the way along, and then lets ...Missing: phases | Show results with:phases
[57]
3 Rules of Thumb to Follow for Consistent Arrow Speed - Bowhunter
Jun 2, 2015 · If you round those numbers up, you get 8-12 fps, with a middle ground of 10 fps, which is the generally accepted rule of thumb. Just remember ...
[58]
[PDF] Alternative design for the compound archery bow / - DSpace@MIT
May 5, 1992 · approximately 1/3 more energy than the recurve of the ... Although the compound bow has great advantages in performance over the recurve.
[59]
[PDF] Kinematic Analysis of Cam Profiles Used in Compound Bows
Since most bows are 80% efficient, there is a considerable effort for improving the compound bow's efficiency. There have been many advances in compound bow ...
[60]
Bow-Tuning Techniques for Peak Performance - Bowhunter
A better way is to use a draw board to synchronize the cams' stops. This allows for an up-close and meticulous evaluation (while the bow is at full draw) of the ...Cam Alignment · Leveling The Sight · Recommended
[61]
Dialing in Your Draw Length - Archery 360
May 4, 2021 · On a compound bow, the draw length is measured from the nocking point to the deepest part of the grip, and then add 1 3/4 inch.
[62]
Compound Bow Stabilizers, Archery Parts & Accessories
Free delivery over $199 10-day returnsIncrease shooting accuracy with a balanced bow to help lessen bow movement after shots with top quality Stabilizers. Shop brands like Apache and Vibracheck!Missing: reduction | Show results with:reduction
[63]
[PDF] Laporte County 4-H Shooting Sports Archery - Purdue Extension
Still later, mechanical advantages were added as compound bows were developed and their limbs were fitted with eccentric wheels, cams or even cammed limb tips ...<|control11|><|separator|>
[64]
https://wildernessawareness.org/articles/how-to-make-a-bow-and-arrow-part-4/
[65]
Compound vs Recurve Bow: What's the Big Difference? - Huntwise
Sep 19, 2024 · Recurve bows are much simpler in design featuring a curved limb structure that stores energy more efficiently than straight-limbed long bows.
[66]
How to Make a Bow and Arrow Part 4 » Wilderness Awareness School
Aug 4, 2020 · Compound bows have up to an 80% let off. Let off is a mechanical advantage that allows you to hold less weight at full draw. For a 60 lb. bow ...
[67]
The Best Beginner Compound Bows of 2025 | Field & Stream
Beyond the obvious cost savings, the main advantage of a youth compound bow or a beginner model for a teen or adult is enhanced adjustability. ... From our Expert.
[68]
Why Use a Compound Bow For Hunting | Hunter-ed.com™
Jun 18, 2024 · Through an intricately designed system of pulleys and cables that store a release of energy, the compound bow provides archers with a powerful ...
[69]
Is it Ethical to Take Long-Distance Bowhunting Shots?
At 100 yards, your arrow will be flying closer to 250 fps, which drops your kinetic energy (what most are familiar with) from 66 ft-lbs. to just 52 ft-lbs ...
[70]
https://archerytrade.org/an-inside-look-at-service-prices-nationwide/
[71]
https://www.bowhunting.com/bowhunt101/axle-to-axle-length-shorter-or-longer-which-is-the-best/
[72]
An Inside Look at Service Prices Nationwide - ATA
Bowstring installations range from $20 to $30, and tuning from $20 to $25. They also charge $60 for an hour of service if you need multiple services, and $99 ...
[73]
Axle to Axle Length - Shorter or Longer, Which Is The Best?
Aug 4, 2021 · Shorter axle to axle bows tend to be more beneficial in hunting scenarios due to the weight and maneuverability. Whether you're a spot and stalk ...
[74]
Axle to axle and brace height // GOHUNT. The Hunting Company
Aug 29, 2019 · Shorter axle-to-axle bows tend to be faster and are utilized better in hunting situations like in a treestand or ground blind. That's simply ...
[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: maintenance humidity
[76]
String/Cable Stretch in Heat and Humidity, or Other? - Archery Talk
Jul 22, 2013 · Heat will kill your string/cable life. Not sure which materials are the least affected by heat and humidity. I will not leave my bow in a closed ...The effects of high humidity on strings and cables? - Archery TalkString stretch and hot weather? | Archery Talk ForumMore results from www.archerytalk.comMissing: maintenance | Show results with:maintenance
[77]
Top Compound Bow Maintenance Tips for 2025 – OneX Archery Blog
Before you put your bow away, a fresh coat of wax on the string and cables can create a protective barrier against dust and humidity. For storage longer than ...
[78]
The Best Way to Tune Your Bow (Paper, Walk-Back, French, Bare ...
Jun 13, 2022 · Paper tuning is a great tuning method overall, no matter a person's experience level. If you're a beginner, though, I'd highly suggest having someone ...
[79]
https://eastonarchery.com/wp-content/uploads/2023/11/Easton-Target-2024.pdf
[80]
[PDF] Easton-Target-2024.pdf
The Easton X10 and X10 Protour are made of carbon fiber bonded to a 7075 alloy core, with straightness of ± .001" and weight tolerance of ± 0.5 grains. X10 ...
[81]
[PDF] carbon & metal fused... the world's most deadly arrow - Easton Archery
The arrow has a micro diameter carbon core, a full metal jacket, a 6mm to 4mm tapered profile, and a 4mm nock end for better penetration and accuracy.
[82]
Sonic 6.0™ - Easton Archery
The Sonic 6.0 is a 6mm high-performance hunting arrow with helical fletching, 6mm H nocks, and 100% carbon-fiber construction, available in six spines.Missing: aluminum | Show results with:aluminum
[83]
FAQs - Easton Archery - Archery Questions Answered
STATIC spine is measured by the amount of flex in the arrow when an 880-gram (1.94 lbs.) weight is suspended from the center of the arrow. The arrow must be 29″ ...Missing: compound | Show results with:compound
[84]
Target & Hunting Arrow Selector - Easton Archery
Having the proper arrow spine is key to optimizing the grouping of your arrows and for the best possible accuracy. Use our arrow selector.Missing: construction fletching
[85]
Group I - Easton Archery
Determine arrow length, peak bow weight, draw length, and ATA velocity. Calculate bow weight, then use the chart to find the suggested arrow group and shaft ...Missing: formula | Show results with:formula
[86]
Arrow Speed Calculator - Ashby Bowhunting Foundation
Arrow Speed Calculator. This calculator is based on average efficiency gains as arrow weight is increased from 5 grains per pound (IBO).
[87]
Finding The Perfect Arrow - Bowhunting.com
... 5 grains per pound. Though an arrow of this weight is very quick, bows firing them take a beating from the increased vibration they produce. Accessory ...
[88]
Do Your Arrows Match Your Bow's Power Curve? (And Why
That's why bow manufacturers post a strict minimum arrow weight: 5 grains per pound of draw weight. Go lighter than that, and you risk damaging your bow.
[89]
The Secret to Maximizing Bowhunting Arrow Penetration
Aug 3, 2018 · The Axis shaft and the modifiable brass insert configuration combines to deliver the ideal blend of arrow diameter, arrow weight and FOC weight ...
[90]
https://www.bowhunter.com/editorial/untunable-bow-nock-travel-could-be-your-problem/382681
[91]
Untunable Bow? Nock Travel Could Be Your Problem - Bowhunter
Vertical nock travel (up or down as the string zips forward) arises from poor cam-timing, the result of poor cam design or the stretch of one harness versus ...Missing: insert brass
[92]
The Best Compound Bow Accessories of 2025, Expert Tested
Aug 27, 2025 · However, there are a few additional accessories you may want to consider, including a stabilizer, a sling, and a kisser button. Stabilizers ...
[93]
Beginner's Compound Bowhunting Setup | Specialty Archery
Nov 1, 2022 · Hunting Compound Bow Accessories You Should Have · Bow Scope · Arrow Rest · Arrow Stabilizer · Arrow Quiver · Arrows · Peep Sight · Verifiers · Tips.
[94]
What Bow Accessories to Purchase | Bow Sights | Arrow Rests
An arrow rest is the most important accessory you can put on your compound bow when it comes to accuracy. There are not only several different rest ...
[95]
Compound | World Archery
Individual matches last for 15 arrows, mixed team matches last for 16 arrows and team matches last for 24 arrows. World Archery also recognises compound bows ...
[96]
Chapter 11 - Athletes Equipment - Rulebook | World Archery
The maximum diameter of arrow shafts shall not exceed 9.3mm (arrow wraps shall not be considered as part of this limitation but may not extend further than 22cm ...
[97]
NFAA Shooting Styles & Equipment Rules
Target Crossbows may not exceed a draw weight of 95 pounds as published by the manufacturer. The maximum bolt/arrow speed shall be 300 fps plus or minus 3%. 16.
[98]
Back to a Back Tension - Bow International
Feb 12, 2015 · The advantage of using a back tension release is that, logically enough, it encourages the archer to use back tension in their shot process; ...
[99]
Rules | The Vegas Shoot
Peak compound bow draw weight shall not exceed 80 lbs. Maximum arrow shaft diameter ... All divisions will follow NFAA Shooting Styles and Equipment Rules.<|separator|>
[100]
The Basics of Indoor Bow Building - National Field Archery Association
Jan 4, 2019 · Building an indoor bow is easier than other setups. A typical setup includes a compound bow, sight, arrow rest, and stabilizers. Bows are often ...
[101]
Understanding Different Types of Sights for Compound Bows
Mar 9, 2023 · Single pin sights allow you to confidently shoot at exact distances instead of having to accommodate for shooting at incremental ranges. Some ...
[102]
10 training exercises that will make your archery practice more efficient
Aug 30, 2020 · These are some simple examples of drills that anyone can integrate into a single visit to the range – or as part of a larger training programme – to help ...
[103]
5 Tips for Compound Archers - Archery 360
Oct 3, 2025 · An anchor point shouldn't be a single contact point. The best anchor points include a hand bone touching a face bone, the bowstring touching ...
[104]
MINIMUM DRAW WEIGHT TO KILL A WHITETAIL - Easton Archery
Lots of opinions. Even the lawmakers in some states have one, as they put regulations around minimum draw weights for hunting – usually 40 pounds. And while ...
[105]
Broadhead Safety - Hunter Ed
Broadhead Safety · A responsible bowhunter will use razor-sharp broadheads and only take shots that allow a clear, close shot to the vital area of the game ...
[106]
https://hunter-ed.com/blog/blaze-orange-regulations-every-state/
[107]
Blaze Orange Regulations for Every State | Hunter-ed.com™
Dec 4, 2023 · All hunters must wear an outer garment above the waist with at least 144 square inches of hunter orange above the waist or a hunter orange hat during firearm ...Missing: compound | Show results with:compound
[108]
Alpha AX-2 | Our Premier Aluminum Hunting Bow - Hoyt Archery
$$5.99 delivery 30-day returnsPerfect for treestands, ground blinds or those who prefer a more compact rig. Starting at compact 29 inches axle to axle, these are the most compact premier ...
[109]
Pro Hunt'R™ Scent Free Synthetic Bow String Wax - LOC OutdoorZ
In stockOur Scent Free Bow String Wax is formulated for today's high performance Compound, Crossbows , and Traditional bows. Premium blended synthetic wax.
[110]
Shooting angles in bowhunting // GOHUNT. The Hunting Company
Aug 25, 2021 · We know that when aiming at a steep up or downhill shot, we need to be aiming for the horizontal yardage, not the line of sight yardage.Missing: success factors odd 20-40
[111]
Rangefinder for Bowhunting - Angle Compensation - Dialed In Hunter
The angle compensating rangefinder is a must in bowhunting. This is a short breakdown of how they work and why you need one.