1 / 19

ENGI 1313 Mechanics I

ENGI 1313 Mechanics I . Lecture 37: Analysis of Equilibrium Problems with Dry Friction. Lecture 37 Objective. to illustrate the equilibrium analysis of rigid bodies subjected to dry friction force by example. Equilibrium and Frictional Forces. Analysis Steps FBD

oliver
Download Presentation

ENGI 1313 Mechanics I

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. ENGI 1313 Mechanics I Lecture 37: Analysis of Equilibrium Problems with Dry Friction

  2. Lecture 37 Objective • to illustrate the equilibrium analysis of rigid bodies subjected to dry friction force by example

  3. Equilibrium and Frictional Forces • Analysis Steps • FBD • Assume frictional force to be an unknown • Do not assume Fs = sN unless impending motion is stated • Determine the Number of Unknowns • If more unknowns than equations, assume friction force at some or all contact points • Apply Equilibrium Equations • Impending motion or tipping

  4. W W Class of Friction Problems • 1. Equilibrium • Geometry and dimensions are known • Draw FBD • # Unknowns = # Equilibrium Equations • Solve for reaction forces • No motion, if

  5. Class of Friction Problems (cont.) • 2. Impending Motion at All Contact Points • # Unknowns = # Equilibrium Equations + # Friction Equations • Impending Motion • Motion

  6. Class of Friction Problems (cont.) • 2. Impending Motion at All Contact Points • Find the minimum angle () for a 100 N bar to be placed against the wall. • FBD • Unknowns? • 5 • Equations? • 3 Equilibrium Equations • 2 Friction Equations

  7. Class of Friction Problems (cont.) • 3. Impending Motion at Some Contact Points • # Unknowns < # Equilibrium Equations + # Friction Equationsor • # Unknowns < # Equilibrium Equations + # Equations for Tipping • May have to evaluate both scenarios • If so, governing case has minimum requirements

  8. Class of Friction Problems (cont.) • 3. Impending Motion at Some Contact Points • Find horizontal force (P) to cause movement. • FBD • # Unknowns? • 7 • Equations • Find minimum P or

  9. Example 37-01 • A uniform ladder weighs 20 lb. The vertical wall is smooth (no friction). The floor is rough with s = 0.8. Find the minimum force P needed to move (tip or slide) the ladder.

  10. Example 37-01 (cont.) • FBD • # Unknowns? • 4 • Equilibrium Equations? • 3 • Assumptions? • Tipping occurs NB W FA NA

  11. Example 37-01 (cont.) • Analysis W FA NA

  12. Example 37-01 (cont.) • Check Tipping Assumption •  Tipping occurs W FA NA

  13. Example 37-02 • Drum weight is 100 lb, s = 0.5, a = 3 ft and b = 4 ft. Find the smallest magnitude of P that will cause impending motion (tipping or slipping) of the drum.

  14. Example 37-02 (cont.) P • FBD • Assume Slipping Occurs 3 ft 3 4 4 ft W = 100lb Fs x N

  15. Example 37-02 (cont.) P • For Slipping 3 ft 3 4 4 ft W = 100 lb Fs x N

  16. Example 37-02 (cont.) P • Check x •  Slipping 3 ft 3 4 4 ft W = 100 lb O Fs x N

  17. Example 37-02 (cont.) P • Assume Tipping Occurs 3 ft 3 4 4 ft W = 100 lb Fs N

  18. Example 37-02 (cont.) P • Check Fs •  Slipping • Calculate minimum P based on slipping condition 3 ft 3 4 4 ft W = 100 lb Fs N

  19. References • Hibbeler (2007) • http://wps.prenhall.com/esm_hibbeler_engmech_1

More Related