1 / 24

Balls and Air

Balls and Air. Introductory Question. You give a left (clockwise) spin to a football. Which way does it deflect? Left Right It does not deflect. 3 Questions about Balls and Air. Why do balls experience air resistance? Why do some balls have fuzz or dimples?

aldis
Télécharger la présentation

Balls and Air

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Balls and Air

  2. Introductory Question • You give a left (clockwise) spin to a football. Which way does it deflect? • Left • Right • It does not deflect

  3. 3 Questions about Balls and Air • Why do balls experience air resistance? • Why do some balls have fuzz or dimples? • Why do spinning balls curve in flight?

  4. Question 1 • Why do balls experience air resistance? • Can air use viscous forces to slow balls? • Can air pressure also cause air resistance?

  5. Bending the Flow in a Hose • Since water accelerates toward lower pressure, • water flow needs a pressure imbalance to bend • The flow naturally develops a pressure gradient • higher pressure & lower speedon the outside of the bend • lower pressure & higher speedon the inside of the bend

  6. Speeding the Flow in a Nozzle • Since water must speed through a narrow nozzle • it needs a pressure imbalance to push it forward • The flow naturally develops a pressure gradient • lower pressure & higher speedas the neck narrows

  7. Viscous Forces and Viscosity • Viscous forces • oppose relative motion within a fluid • and are similar to sliding friction: they waste energy • Fluids are characterized by viscosities • the measure of the strength of the viscous forces • related to chemical interactions with the fluids

  8. Water Flow Isn’t Always Smooth • We’ve been examining laminar flow • in which viscosity dominates flow • and nearby regions of water remain nearby • Now we’ll also consider turbulent flow • in which inertia dominates flow • and nearby regions of water become separated

  9. Reynolds Number • The flow type depends on the Reynolds number • Below ~2000 viscosity wins, so flow is laminar • Above ~2000 inertia wins, so flow is turbulent

  10. Aerodynamic Forces: Drag • Air resistance is also known as “drag” • When a ball moves through air, drag forces arise • The air pushes the ball downstream • and the ball pushes the air upstream • Drag forces transfer momentum • air transfers downstream momentum to ball • ball transfers upstream momentum to air

  11. Aerodynamic Forces: Lift • When a ball deflects passing air, lift forces arise • the air pushes the ball to one side • and the ball pushes the air to the other side • Lift forces transfer momentum • air transfers sideways momentum to ball • ball transfers sideways momentum to air

  12. Types of Drag & Lift • Surface friction causes viscous drag • Turbulence causes pressure drag

  13. Perfect Flow Around a Ball • Air bends away from ball’s front • high pressure, slow flow • Air bends toward ball’s sides • low pressure, fast flow • Air bends away from ball’s back • high pressure, slow flow • Pressures balance perfectly, so only viscous drag

  14. The Onset of Turbulence • Air flowing into the rising pressure behind ball • accelerates backward (decelerates) • and it loses speed and kinetic energy • Air flowing near the ball’s surface • experiences viscous drag, • accelerates backward even more, • and rapidly loses speed and kinetic energy • If this surface flow stops, turbulence ensues

  15. Imperfect Flow & a Slow Ball • Pressure rises in front • Pressure drops on side • Flow detaches just beyond sides • Big wake forms behind ball • Wake pressure is nearly ambient • Ball experiences imbalancedpressure & big pressure drag

  16. Question 2 • Why do some balls have fuzz or dimples?

  17. Boundary Layer • Flow near the surface forms a “boundary layer” • At low Reynolds number (<100,000) • the boundary layer is laminar • closest layer is slowed relentlessly by viscous drag • At high Reynolds number (>100,000) • boundary layer itself is turbulent • tumbling continually renews closest layer’s energy • boundary layer penetrates deeper into rising pressure

  18. Imperfect Flow & a Fast Ball • Pressure rises in front • Pressure drops on side • Flow detaches near back of ball • Small wake forms behind ball • Wake pressure is nearly ambient • Ball experiences imbalancedpressure & small pressure drag

  19. Tripping the Boundary Layer • To reduce pressure drag, some balls have fuzz • Fuzz “trips” the boundary layer • and initiates turbulence, • which delays flow separation at the back of the ball • and shrinks the turbulent wake • Examples: Tennis balls and Golf balls

  20. Question 3 • Why do spinning balls curve in flight?

  21. Spinning Balls, Magnus Force • Turning surface pushes/pulls on the air flow • Air on one side undergoes long bend toward ball • Air on other side undergoes shorter bend away • Pressures are unbalanced • The overall air flow is deflected • Ball pushes air to one side • Air pushes ball to other side • Ball feels Magnus lift force

  22. Spinning Balls, Wake Force • Turning surface alters point of flow separation • Flow separation is delayed on one side • and hastened on the other side • so wake is asymmetric • The overall air flow is deflected • Ball pushes air to one side • Air pushes ball to other side • Ball feels Wake lift force

  23. Introductory Question • You give a left (clockwise) spin to a football. Which way does it deflect? • Left • Right • It does not deflect

  24. Summary about Balls and Air • The air pressures around these objects are not uniform and result in drag and lift • Balls experience mostly pressure drag • Spinning balls experience Magnus and Wake Deflection lift forces

More Related