Presentation is loading. Please wait.

Presentation is loading. Please wait.

Summer School 2007B. Rossetto1 4. Forces  Definition A force is defined by a vector and an application point: 1 - the modulus F = is the strength (newton)

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Summer School 2007B. Rossetto1 4. Forces  Definition A force is defined by a vector and an application point: 1 - the modulus F = is the strength (newton)"— Presentation transcript:

1 Summer School 2007B. Rossetto1 4. Forces  Definition A force is defined by a vector and an application point: 1 - the modulus F = is the strength (newton) 2 - the support D must be attached to the point to which the force is applied 3 - the arrow gives the direction of action D P D’ Consequence: do not have the same effect if they are not applied to the same point P of a rigid body. They differ by their torque. P’ The moment/P characterizes the ability to make the body turn around P Definition of the torque of with respect to P:

2 Summer School 2007B. Rossetto2 4. Forces  Torque of a couple D P D’ P’ O H H’ 1 – Definition. A couple is a set of two equal and opposite forces 2 – Torque of a couple/0: (O between P and P’ ) Proof : from the definition

3 Summer School 2007B. Rossetto3 4. Kinematics  First law of Newton (inertia principle) Define a system (particle, set of particles, solid)

4 Summer School 2007B. Rossetto4 4. Statics  Point or particle equilibrium 1 - Identify all the applied forces to the point 2 - Use the fundamental theorem derived from Newyon 1 st law No translation: Exemple : equilibrium of some point P : x y T1T1 T2T2 P  Knowing P,  and , we deduce T 1 and T 2 (other way : triangle relationship)

5 Summer School 2007B. Rossetto5 4. Statics  Solid Equilibrium 1 - Define a system and identify all the applied forces 2 - Apply the fundamental theorems : No translation: No rotation with respect to O: Note that these topics requires some knowledge about solid concepts, like center of mass (cf. chap. 8)

6 Summer School 2007B. Rossetto6 4. Statics  Solid Equilibrium r1r1 To the center of the first wheel: In this example, it is necessary to define the system to apply the theorems The same equations can be written for the second wheel. Finally, we find: T=W/2 r2r2

7 Summer School 2007B. Rossetto7 4. Statics  Solid Equilibrium Example: ladder equilibrium. W:weight, supposed applied in G L: length, : angle : sliding friction characterization   G B A ( static >  dynamic ) Finally:

Download ppt "Summer School 2007B. Rossetto1 4. Forces  Definition A force is defined by a vector and an application point: 1 - the modulus F = is the strength (newton)"

Similar presentations

Mechanics of Rigid Body. C

Mechanics of Rigid Body. C
Two-Dimensional Rotational Dynamics W09D2. Young and Freedman: 1

Two-Dimensional Rotational Dynamics W09D2. Young and Freedman: 1
Chapter 9 Rotational Dynamics.

Chapter 9 Rotational Dynamics.
Summer School 2007B. Rossetto1 5. Kinematics  Piecewise constant velocity t0t0 tntn titi t i+1 x(t) x(t i ) h t x i = v(t i ). h Distance runned during.

Summer School 2007B. Rossetto1 5. Kinematics  Piecewise constant velocity t0t0 tntn titi t i+1 x(t) x(t i ) h t x i = v(t i ). h Distance runned during.
Rotational Equilibrium and Rotational Dynamics

Rotational Equilibrium and Rotational Dynamics
Chapter 9 Rotational Dynamics.

Chapter 9 Rotational Dynamics.
Dynamics of Rotational Motion

Dynamics of Rotational Motion
Chapter 8 Rotational Equilibrium and Rotational Dynamics.

Chapter 8 Rotational Equilibrium and Rotational Dynamics.
Chapter 8 Rotational Equilibrium and Rotational Dynamics.

Chapter 8 Rotational Equilibrium and Rotational Dynamics.
Dynamics of a Rigid Body

Dynamics of a Rigid Body
Rotational Motion – Part II

Rotational Motion – Part II
Summary Lecture 12 Rotational Motion 10.8Torque 10.9Newton 2 for rotation 10.10 Work and Power 11.2Rolling motion Rotational Motion 10.8Torque 10.9Newton.

Summary Lecture 12 Rotational Motion 10.8Torque 10.9Newton 2 for rotation Work and Power 11.2Rolling motion Rotational Motion 10.8Torque 10.9Newton.
Chapter 12: Rolling, Torque and Angular Momentum.

Chapter 12: Rolling, Torque and Angular Momentum.
Chapter 10: Rotation. Rotational Variables Radian Measure Angular Displacement Angular Velocity Angular Acceleration.

Chapter 10: Rotation. Rotational Variables Radian Measure Angular Displacement Angular Velocity Angular Acceleration.
Physics 111: Elementary Mechanics – Lecture 11 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.

Physics 111: Elementary Mechanics – Lecture 11 Carsten Denker NJIT Physics Department Center for Solar–Terrestrial Research.
Summer School 2007B. Rossetto1 8. Dynamics of a rigid body  Theorems r CM : location of the center of mass referred to an inertial frame /Oxyz v CM :

Summer School 2007B. Rossetto1 8. Dynamics of a rigid body  Theorems r CM : location of the center of mass referred to an inertial frame /Oxyz v CM :
Ch. 7: Dynamics.

Ch. 7: Dynamics.
Phy 211: General Physics I Chapter 10: Rotation Lecture Notes.

Phy 211: General Physics I Chapter 10: Rotation Lecture Notes.
Chapter Eight Rotational Dynamics Rotational Dynamics.

Chapter Eight Rotational Dynamics Rotational Dynamics.
Chapter 11 Rolling, Torque, and Angular Momentum In this chapter we will cover the following topics: -Rolling of circular objects and its relationship.

Chapter 11 Rolling, Torque, and Angular Momentum In this chapter we will cover the following topics: -Rolling of circular objects and its relationship.

Similar presentations

Ads by Google