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FEA Analysis of Golf Ball and Driver Stress Distributions

Explore stress distributions, natural frequencies, and sweet spot effects in golf equipment using ABAQUS Finite Element Analysis. Learn about internal stresses, frequency measurements, and stress propagation in golf balls and drivers. Discover the impact of material properties on distance and ball deformation. Investigate the geometry and loading conditions of the golf ball and club for insightful results. Gain insights into optimizing club design for enhanced performance. Delve into the complexities of golf equipment dynamics for improved gameplay.

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FEA Analysis of Golf Ball and Driver Stress Distributions

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  1. FEA of a Golf Driver and Golf Ball • Solid Mechanics - ES 240 • Adrian Podpirka • ABAQUS Project

  2. Outline of Work • Introduction to Golf • Goal of Research • Theory • Modeling • Results • Discussion • Analysis • Conclusion • Citations

  3. Golf • Invented in Scotland around 1450s. • Requires hitting a small ball roughly 200-500 yards into a small hole. • Different clubs are used depending on distance and arc required. • During the first shot, the golfer tries to hit it down course as far as possible

  4. Goals of Project • To determine stress distributions in a golf ball and in a driver. • To determine natural frequency of the golf ball and driver. • Attempt to determine percentage of sweet spot and effect of driving distance. • Learn ABAQUS

  5. FEA & Golf • Only recently has FEA been used to design clubs. • Programs are being made specifically to cater to the golf industry. • Used to analyze swings, slicing, tendency to hook, etc.

  6. Theories • Golf Ball • Internal Stresses in the golf ball will arise due to sudden impact and different properties of the two materials • Ball will deform as drastically as seen in the picture to the right. • Frequency Measurement • A closer natural frequency between the ball and the club will lead to an increase in distance. • Stress Propagation • Sweet spot occurs symmetrically from propagating waves. • Allows for wave dispersion before coming in contact with the club face edge.

  7. Young’s Modulus E (GNm^-2) Poisson’s Ration Density (kg m^-3) Note Butadien Rubber .0392 .45 1150 Inner Core of Golf Ball Iononer Resin .294 .40 950 Outer Core of Golf Ball Ti-6Al-4V 118 .34 4507 Standard Driver Head Material Carbon Fiber 17.2 .31 1545 Standard Shaft Material Materials • Golf Ball • Driver Head • Driver Shaft T. Iwatsubo et al B. Wang et al

  8. Geometry of Equipment • Golf Ball • Golf Club - Wood Driver 40 cm 44 cm Shaft length - 1.05 m Height - 40 mm Width - 90 mm Depth - 65 mm

  9. Golf Ball • loaded linearly ramping to 15000 N. • Golf Ball • Sweep meshed with 1600 elements • Modeled a 44 cm diameter area and partitioned off middle section. • Traction load placed in between 7 & 9 • Boundary Condition placed directly opposite • Results • Internal stresses develop as a result of mismatch of materials on the order of 40 kN. • Golf ball is seen to deform. This is analogous to the picture shown before.

  10. Golf Ball Results

  11. Natural Frequency • The closer the frequency between club and ball, the better energy transfer and therefore, farther distance. • We will test the difference between hollow and solid clubs • Golf Ball • Meshed with 124 elements • Circular edge boundary conditions • Driver • Meshed with roughly 169 & 171 elements • Pinned at top

  12. The hollow bodied club face has a lower frequency then the solid body, closer matching that of the balls.

  13. 2D Stress Distribution • Assume traction loading on face of of driver. • Large deformation occurs in shaft of carbon fiber. • Stress waves still occurs in driver face but much less then with coupled shaft.

  14. Stress

  15. 3D Stress Note: The full 3D club could not be meshed because of element assignment errors in ABAQUS. The Natural frequency of the club could not be found.

  16. Analysis • Full Analysis of all data and values will be given in the paper. • The golf balls deformed as theory and practice indicated. • By tuning golf balls to different clubs, better distances can be obtained. This would require changing either the parameters on the ball or club. • Since ABAQUS was not able to mesh the merged structure, I had to forgo on the natural frequency aspect of the 3D driver.

  17. Recommendations • Many of the articles could not be located since Harvard did not have a subscription to them. • Many parameters • Using different material parameters in order to optimize values. • Dynamically loading and setting contact parameters

  18. Citations • Wang et al. “Modal Properties of Golf Club Wood Driver in Different Boundary Conditions” • Hocknell et al. “Hollow Club Hear Modal Characteristics: Determination and Impact Applications” • Hocknell et al. “Experimental Analysis of Impacts with Large Elastic Deformation: I. Linear Motion” • Iwatsubo et al. “Numerical Analysis of Golf Club Head and Ball” • Penner, A. “The Physics of Golf: The Convex Face of a Driver” • Newman et al. “The Dynamic Flexing of a Golf Club Shaft During a Typical Swing” • Arakawa et al. “Dynamic Contact Behavior of a Golf Ball during an Oblique Impact” • H. Kolsky. Stress Waves in Solids. Dover Publications Inc. • Axe et al. “The vibrational mode structure of a golf ball”

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