Bowling ball


A bowling ball is a hard spherical ball used to knock down bowling pins in the sport of bowling.
Balls used in ten-pin bowling typically have holes for two fingers and the thumb. Balls used in five-pin bowling, candlepin bowling, duckpin bowling, and kegel have no holes, and are small enough to be held in the palm of the hand.

Ten-pin balls

Specifications

The USBC and World Bowling promulgate bowling ball specifications. USBC specifications include physical requirements for weight, diameter, surface hardness, surface roughness, hole drilling limitations, balance, plug limitations, and exterior markings, as well as requirements for dynamic performance characteristics such as radius of gyration, RG differential, and coefficient of friction.

Coverstock technology

Bowling balls were made of lignum vitae until the 1905 introduction of rubber balls. Polyester balls were introduced in 1959 and, despite developing less hook-generating lane friction than rubber balls, by the 1970s plastic dominated over rubber balls which then became obsolete with the early-1980s development of polyurethane balls. Urethane balls developed more friction with the newly-developed polyurethane lane finishes of the day, sparking the evolution of coverstock technology to pursue ever-stronger hooks with correspondingly higher entry angles.
The early 1990s brought development of reactive resin balls by introducing additives in urethane surface materials to create microscopic oil-absorbing pores that increase the "tackiness" that enhances traction. In the "particle-enhanced" balls developed in the late 1990s, microscopic particles embedded in reactive coverstocks reach through oil lane coatings to provide even greater traction. Ball manufacturers developed closely guarded proprietary blends including ground-up material such as glass, ceramic or rubber, to enhance friction.
Within the reactive category are solid reactive coverstocks, pearl reactive coverstocks, hybrid reactive coverstocks, and particle coverstocks.
Hook potential has increased so much that dry lane conditions or certain spare shots sometimes cause bowlers to use plastic or urethane balls, to purposely avoid the larger hook provided by reactive technology.

Layout and grip

A ball's drilling layout refers to how and where holes are drilled, in relation to the ball's locator pin and mass bias marker. Layout is determined with reference to each bowler's positive axis point. "Pin down" layouts place the pin between the finger holes and the thumb hole, while "pin up" layouts place the pin further from thumb hole than the finger holes. Bowling ball motion is influenced by how far the pin and the mass bias are from the PAP, the distances determining track flare. Track flare—the sequence of oil rings showing migration of the ball's axis on successive revolutions through the oil pattern—is popularly thought to influence entry angle, but Freeman & Hatfield discount its contribution to ball motion.
Holes may be drilled for a conventional grip, a fingertip grip, or less standard grips such as the Sarge Easter grip. Many bowlers using the so-called "two-handed delivery" do not insert their thumbs, thus allowing their fingers to impart even more torque than the fingertip grip.
Finger inserts and thumb slugs are custom-fit urethane tubes inserted into the drilled holes, generally for balls with a fingertip grip. Finger inserts enhance the torque provided by the fingers after the thumb exits the ball.

Ball motion

Ball motion is commonly broken down into sequential skid, hook, and roll phases. As the ball travels down the lane in the skid and hook phases, frictional contact with the lane causes the ball's forward speed to continually decrease, but to continually increase its rev rate. Especially as the ball encounters greater friction in the last ≈20 feet of the lane, the ball's axis rotation causes the ball to hook away from its original direction. Concurrently, lane friction continually decreases the angle of axis rotation until it exactly matches the direction of the ball's forward motion, and rev rate increases until it exactly matches the ball's forward speed: full traction is achieved and the ball enters the roll phase in which forward speed continues to decrease.
Release ratio denotes the ratio of the ball's forward speed to its rev rate at time of release. This ratio continually decreases throughout the ball's travel until it reaches exactly 1.0 when full traction is achieved upon entering the roll phase. A too-high release ratio causes the ball to reach the pins while still in the hook phase, and a too-low release ratio causes the ball to enter the roll phase before reaching the pins. Ball speed and rev rate are said to be matched if the ball enters the roll phase immediately before impacting the pins, maximizing power imparted to the pins yet helping to provide an entry angle that minimizes ball deflection.

Effect of delivery characteristics on ball motion

Various characteristics of ball delivery affect a ball's motion throughout its skid, hook and roll phases. The particular way in which energy is imparted to a ball—with varying proportions of that energy divided among ball speed, axis control and rev rate—determines the ball's motion. The following discussion considers delivery characteristics separately, with the understanding that ball motion is determined by a complex interaction of a variety of factors.
Greater ball speeds give the ball less time to hook, thus reducing observed hook though imparting more kinetic energy to the pins; conversely, slower speeds allow more time for greater hook though reducing kinetic energy.
Greater rev rates cause the ball to experience more frictional lane contact per revolution and thus greater and earlier hook ; conversely, smaller rev rates cause less frictional engagement and allow the ball to hook less and later.
Analysis of the influence of axis rotation is more complex: There is a degree of axis rotation—generally 25° to 35° and varying with ball speed and rev rate—that may be considered optimal in that hook is maximized; however, this optimum axis rotation also causes minimal length. Specifically, Freeman & Hatfield report optimal axis rotation to be arcsin where ω is rev rate, r is ball radius, and v is ball speed. Below and above optimal axis rotation, more length and less hook are encountered, with greater-than-optimal axis rotation causing a sharper hook.
Greater degrees of initial axis tilt cause the ball to rotate on smaller-circumference "tracks", thus reducing the amount of frictional contact to provide greater length and less hook; conversely, smaller degrees of axis tilt involve larger-circumference tracks with more frictional contact per revolution, thus providing less length and more hook.
Loft—the distance past the foul line at which the ball first contacts the lane—determines the effective length of the lane as experienced by the ball: greater loft distances effectively shorten the lane and provide greater length, while smaller loft distances engage the lane earlier and cause an earlier hook.

Effect of coverstock, core and layout on ball motion

Various characteristics of ball core structure and coverstock composition affect a ball's motion throughout its skid, hook and roll phases. Such motion is largely governed by the lane's frictional interaction with the ball, which exhibits both chemical friction characteristics and physical friction characteristics. Also, the ball's internal structure—especially the density, shape and orientation of its core —substantially affect ball motion.
A "dull" ball surface, having spikes and pores, provides greater friction in the oil-covered front end of the lane but reduced frictional contact in the dry back end of the lane, and thus enables an earlier hook. In contrast, a "gloss" ball surface tends to glide atop oil on the front end but establishes greater frictional contact in the dry back end, thus promoting a sharper hook downlane. Accordingly, because different lane conditions and bowler styles favor different hook profiles, there is no single "best" surface.
A 2005-2008 USBC Ball Motion Study found that the ball design factors that most contributed to ball motion were the microscopic "spikes" and pores on the ball's surface, the respective coefficients of friction between ball and lane in the oiled and dry parts of the lane, and the ball's oil absorption rate, followed in dominance by certain characteristics of the ball's core. Freeman and Hatfield explain that in most circumstances it is chemical friction—controlled by the manufacturer's proprietary coverstock formulation governing its "stickiness"—that primarily determines ball motion. Further, surface finish—modifiable by sandpaper, polish and the like—is also a material factor.
Though manufacturer literature often specifies track flare—exhibited by successive tracks of oil in a "bowtie" pattern and caused by RG differential—the USBC ball motion study showed flare's influence to be small, assuming that a minimal threshold of flare exists to present a "dry" surface for successive ball revolutions. Similarly, though manufacturer literature often describes specific core shapes, differently-shaped cores can make exactly the same contribution to ball motion if they have the same overall RG characteristics.
"Weak" layouts hook sooner but have milder backend reaction, while "strong" layouts enable greater skid lengths and more angular backend reaction.
Manufacturers commonly cite specifications relating to a bowling ball's core, include radius of gyration, differential of RG, and intermediate differential.
Analytically, the United States Bowling Congress defines RG as "the distance from the axis of rotation at which the total mass of a body
might be concentrated without changing its moment of inertia". In practice, a higher RG indicates that a ball's mass is distributed more toward its cover—making it "cover heavy"—which tends to make the ball enter the roll phase later. Conversely, a lower RG indicates the ball's mass is distributed more towards its center—making it "center heavy"—which tends to make it enter the roll phase sooner.
Differential of RG is the difference between maximum and minimum RGs measured with respect to different axes. Differential indicates the ball's track flare potential, and contributes to how sharply a ball can hook. A higher differential indicates greater track flare potential—more angular motion from the break point to the pocket—and a lower differential indicates lower flare potential and a smoother arc to the hook.
The lesser-used intermediate differential rating quantifies the degree to which a bowling ball core is symmetrical or asymmetrical. Analytically, ID is defined by the USBC as the "difference in radius of gyration between the Y and Z axes". In practice, a higher ID indicates greater asymmetry, which causes more area to be created at the break point to cause the ball to respond more quickly to friction than symmetrical balls.
Informally, a low-differential ball has been likened to one whose core is a spherical object ; a high-differential ball has been likened to a tall drinking glass ; and a high-mass-bias ball has been likened to a tall drinking mug with a handle on the side.
Higher-friction surfaces cause balls to hook earlier, and lower-friction surfaces cause balls to skid longer before reacting.
Reactive cover stocks finishes include matte, shiny, pearl, and hybrid.

Effect of lane characteristics on ball motion

The phenomenon of lane transition occurs when balls remove oil from the lane as they pass, and deposit some of that oil on originally dry parts of the lane. The process of oil removal, commonly called breakdown, forms dry paths that subsequently cause balls to experience increased friction and to hook sooner. Conversely, the process of oil deposition, commonly called carry down, occurs when balls form oil tracks in formerly dry areas, tracks that subsequently cause balls to experience less friction and delayed hook. Balls tend to "roll out" in response to breakdown, and, conversely, tend to skid longer in response to carry down—both resulting in light hits. Breakdown is influenced by the oil absorption characteristics and rev rates of the balls that were previously rolled, and carry down is mitigated by modern balls having substantial track flare.
Lane materials with softer surfaces such as wood engage the ball with more friction and thus provide more hook potential, while harder surfaces like synthetic compositions provide less friction and thus provide less hook potential.
The lanes' physical topography—hills and valleys that diverge from an ideal planar surface—can substantially and unpredictably affect ball motion, even if the lane is within permissible tolerances.
Higher-viscosity lane oils engage balls with more friction and thus cause slower speeds and shorter length but provide more hook potential and reduced lane transition; conversely, lane oils of lower viscosity are more slippery and thus support greater speeds and length but offer less hook potential and allow faster lane transition. Various factors influence an oil's native viscosity, including temperature and humidity. Also, high humidity increases friction that reduces skid distance so the ball tends to hook sooner.

Manufacturers

The USBC maintains a list, said to be updated weekly, of about 100 bowling ball manufacturers and their approved bowling balls.

Duckpin bowling balls

balls are regulated to be from in diameter and to weigh between and . They lack finger holes. Though duckpin balls are slightly larger than candlepin balls, they have less than 60% the diameter of ten-pin balls, to match the smaller size of duckpins. Duckpin balls are sometimes used for scaled-down ten-pin bowling lanes installed in arcades and other amusement facilities.

Five-pin bowling balls

The basic specifications of five-pin balls are the same a duckpin balls: diameters from, weights from to ; the balls have no finger holes.

Candlepin bowling balls

Candlepin bowling balls have a weight of between and, and a diameter of —much smaller than the balls in ten-pin bowling, and even smaller than the balls in duckpin bowling. Candlepin balls deflect significantly upon impact, being even lighter than the candlepins themselves.

Publications

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