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Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege

Engineering 36. Chp 6: Frames. Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege.edu. Introduction: MultiPiece Structures. For the equilibrium of structures made of several connected parts, the internal forces as well the external forces are considered.

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Bruce Mayer, PE Licensed Electrical & Mechanical Engineer BMayer@ChabotCollege

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  1. Engineering 36 Chp6:Frames Bruce Mayer, PE Licensed Electrical & Mechanical EngineerBMayer@ChabotCollege.edu

  2. Introduction: MultiPiece Structures • For the equilibrium of structures made of several connected parts, the internal forces as well the external forces are considered. • In the interaction between connected parts, Newton’s 3rd Law states that the forces of action and reaction between bodies in contact have the same magnitude, same line of action, and opposite sense. • Three categories of engineering structures are considered: • Frames: contain at least one multi-force member, i.e., a member acted upon by 3 or more forces. • Trusses: formed from two-force members, i.e., straight members with end point connections • Machines: structures containing moving parts designed to transmit and modify forces.

  3. Analysis of Frames • Framesand machines are structures with at least one multiforce member. Frames are designed to support loads and are usually stationary. Machines contain moving parts and are designed to transmit & modify forces. • A free body diagram of the complete frame is used to determine the external forces acting on the frame. • Internal forces are determined by dismembering the frame and creating free-body diagrams for each component. • Forces on two force members have known lines of action but unknown magnitude and sense. • Forces on multiforce members have unknown magnitude and line of action. They must be represented with two unknown components. • Forces between connected components are equal, have the same line of action, and opposite sense.

  4. Not Fully Rigid Frames • Some frames may collapse if removed from their supports. Such frames can NOT be treated as rigid bodies. • A free-body diagram of the complete frame indicates four unknown force components which can not be determined from the three equilibrium conditions. • The frame must be considered as two distinct, but related, rigid bodies. • With equal and opposite reactions at the contact point between members, the two free-body diagrams indicate 6 unknown force components. • Equilibrium requirements for the two rigid bodies yield 6 independent equations.

  5. Example: Pin & Roller Frame • SOLUTION PLAN • Create a free-body diagram for the complete frame and solve for the support reactions. (won’t collapse) • Define a free-body diagram for member BCD. The force exerted by the link DE has a known line of action but unknown magnitude (2-frc member); determined by summing moments about C. • With the force on the link DE known, the sum of forces in the x and y directions may be used to find the force components at C. • With member ACE as a free-body, check the solution by summing moments about A • Members ACE and BCD are connected by a pin at C and by the link DE. For the loading shown, determine the force(s) in link DE and the components of the force exerted by the Pin at C on member BCD.

  6. Example: Pin & Roller Frame • SOLUTION • Create a free-body diagram for the COMPLETE FRAME and solve for the support reactions. • Note

  7. Example: Pin & Roller Frame • Define a free-body diagram for member BCD. The force exerted by the 2-force link DE has a known line of action but unknown magnitude. It is determined by summing moments about C. (DE in Compression) • Use the Sum of forces in the x and y directions to find the force components at C.

  8. Example: Pin & Roller Frame • With member ACE as a free-body, check the solution by summing moments about A • 

  9. Example: Pin & Pin Frame • For the Frame Shown Below Find • The RCNs at points A & C • The SHEAR FORCES acting on the PINS at A & C • Draw FBDs noting that the forces at B are Equal & Opp • FBD for AB

  10. Example: Pin & Pin Frame • FBD for Member BC • For AB take ΣMB = 0

  11. Example: Pin & Pin Frame • For AB take ΣFy = 0 • Recall FAy = 75 lbs • For AB take ΣFx = 0 • Will use Later: FBx = FAx

  12. Example: Pin & Pin Frame • For BC take ΣMC = 0 • For BC take ΣFx = 0

  13. Example: Pin & Pin Frame • For BC take ΣFy = 0 • Recall from Before: FAx = FBx, and FBx = 86.6 lbs • Thus

  14. Example: Pin & Pin Frame • Now Find SHEAR FORCE on Pins atA & C • The Forces at A & C • Find the Shear Force Magnitude by • In this Case • Thus the connecting pins must resist a shear force of 115 lbs

  15. WhiteBoard Work Let’s WorkThis NiceProblem 30cm • Find the Forces Acting on Each of the Members, and on the Frame at Pts A & D

  16. Engineering 36 Appendix Bruce Mayer, PE Registered Electrical & Mechanical EngineerBMayer@ChabotCollege.edu

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