Presentation is loading. Please wait.

Presentation is loading. Please wait.

CE 201 - Statics Lecture 7. EQUILIBRIUM OF A PARTICLE CONDITION FOR THE EQUILIBRIUM OF A PARTICLE A particle is in EQUILIBRIUM if: 1. it is at rest, OR.

Published byFrancine Gibson Modified over 8 years ago

Similar presentations

Presentation on theme: "CE 201 - Statics Lecture 7. EQUILIBRIUM OF A PARTICLE CONDITION FOR THE EQUILIBRIUM OF A PARTICLE A particle is in EQUILIBRIUM if: 1. it is at rest, OR."— Presentation transcript:

1 CE 201 - Statics Lecture 7

2 EQUILIBRIUM OF A PARTICLE CONDITION FOR THE EQUILIBRIUM OF A PARTICLE A particle is in EQUILIBRIUM if: 1. it is at rest, OR 2. it is moving with constant velocity The term "EQUILIBRIUM" is often used to describe a particle at rest. For a particle to be in EQUILIBRIUM, Newton's First Law of Motion must be satisfied.

3 Newton's First Law of Motion "IF THE RESULTANT FORCE ACTING ON A PARTICLE IS ZERO, THEN THE PARTICLE IS IN EQUILIBRIUM".  F = 0

4 Newton's Second Law of Motion F = m × a Applying the condition for equilibrium  F = m × a then, m × a = 0 since m ≠ o then, a = 0 this means that the particle acceleration is equal to zero, therefore the particle is moving at constant velocity.

5 THE FREE-BODY DIAGRAM To apply the equilibrium equation (  F = 0), all known and unknown forces must be included in the equation. The equilibrium equation will best be applied when a free-body diagram of the particle is drawn. What is a free-body diagram?

6 Example Suppose that we have a ball supported on a surface with force F is applied. How can we draw a free-body diagram of the ball? 1. Isolate the ball from all surroundings 2. Indicate all known and unknown forces acting on the ball. F = 50 N 30  F = 50 N 30  W R

7 In this case, we have the following forces acting on the particle: F = 50 N Ball weight, W = ? Surface reaction, R = ? F = 50 N 30  F = 50 N 30  W R

8 Example Draw a free-body diagram of the following system: Tips Label known forces: should be labeled with their magnitude and direction Label unknown forces: should be labeled using letters Assume +ve magnitude of unknown forces. If magnitude of an unknown force was obtained –ve, then the direction of the force is opposite to the direction assumed. Apply equilibrium equation F  F  W R1 R2

9 Connections Two types of connections will be discussed: 1. Springs 2. Cables and Pulleys

10 Springs If a spring is subjected to a force, the length of the spring will change in direct proportion to the force acting on it (if it is a linear elastic spring).

11 Example In this case, the following equation can be used: F = k  s F = acting force k = spring constant or stiffness s = deformed distance measured from its unloaded position (elongated or compressed) If ( s ) is +ve, then ( F ) pulls on the spring, while if ( s ) is –ve, then ( F ) pushes on the spring. s = L – L 0 L0L0 L s (-ve) -F +F L0L0 s (+ve) L

12 Cables and Pulleys All cables are assumed to have negligible weight and can not be stretched Cables can support only tension or pulling forces  T T

13

14

Download ppt "CE 201 - Statics Lecture 7. EQUILIBRIUM OF A PARTICLE CONDITION FOR THE EQUILIBRIUM OF A PARTICLE A particle is in EQUILIBRIUM if: 1. it is at rest, OR."

Similar presentations

Statics of Particles MET 2214 Ok. Lets get started.

Statics of Particles MET 2214 Ok. Lets get started.
Newton’s Laws (II) Free-body diagrams Normal Force

Newton’s Laws (II) Free-body diagrams Normal Force
Force Force is a push or pull on an object The object is called the System Force on a system in motion causes change in velocity = acceleration Force is.

Force Force is a push or pull on an object The object is called the System Force on a system in motion causes change in velocity = acceleration Force is.
Forces Force is the cause of acceleration. It is defined as a push or a pull.

Forces Force is the cause of acceleration. It is defined as a push or a pull.
Newton’s Laws of Motion (Applications)

Newton’s Laws of Motion (Applications)
Translational Equilibrium Physics Montwood High School R. Casao.

Translational Equilibrium Physics Montwood High School R. Casao.
Problem 8.150 Block A of mass 12 kg and block B of mass 6 kg are connected by a cable that passes over pulley C which can rotate freely. Knowing that the.

Problem Block A of mass 12 kg and block B of mass 6 kg are connected by a cable that passes over pulley C which can rotate freely. Knowing that the.
PHYS 218 sec. 517-520 Review Chap. 4 Newton’s laws of motion.

PHYS 218 sec Review Chap. 4 Newton’s laws of motion.
1 Equilibrium of Concurrent, Coplanar Force Systems EF 202 - Week 5.

1 Equilibrium of Concurrent, Coplanar Force Systems EF Week 5.
Newton’s Laws of Motion

Newton’s Laws of Motion
Equilibrium Equilibrium refers to a condition in which an object is at rest originally at rest (static equilibrium) or has a constant velocity if originaly.

Equilibrium Equilibrium refers to a condition in which an object is at rest originally at rest (static equilibrium) or has a constant velocity if originaly.
Introduction Mechanics: deals with the responses of the bodies to the action of forces. Objectives: To give students an introduction to engineering mechanics.

Introduction Mechanics: deals with the responses of the bodies to the action of forces. Objectives: To give students an introduction to engineering mechanics.
Copyright © 2010 Pearson Education South Asia Pte Ltd

Copyright © 2010 Pearson Education South Asia Pte Ltd
King Fahd University of Petroleum & Minerals Mechanical Engineering Dynamics ME 201 BY Dr. Meyassar N. Al-Haddad Lecture # 11.

King Fahd University of Petroleum & Minerals Mechanical Engineering Dynamics ME 201 BY Dr. Meyassar N. Al-Haddad Lecture # 11.
Force Types 1 Definition of Force Drawing the Force Dimensions and Units of Force Tension Elastic Force Gravity Normal Force Friction Drag Pulleys.

Force Types 1 Definition of Force Drawing the Force Dimensions and Units of Force Tension Elastic Force Gravity Normal Force Friction Drag Pulleys.
ENGR 215 ~ Dynamics Sections 13.1 – 13.3. Newton’s Three Laws of Motion First Law –a particle originally at rest, or moving in a straight line with constant.

ENGR 215 ~ Dynamics Sections 13.1 – Newton’s Three Laws of Motion First Law –a particle originally at rest, or moving in a straight line with constant.
Chapter 5 The Laws of Motion. Forces Usually think of a force as a push or pull Usually think of a force as a push or pull Vector quantity Vector quantity.

Chapter 5 The Laws of Motion. Forces Usually think of a force as a push or pull Usually think of a force as a push or pull Vector quantity Vector quantity.
Weight is a force that is defined from the gravitational attraction between two masses. The gravitational force causes the less massive object to accelerate.

Weight is a force that is defined from the gravitational attraction between two masses. The gravitational force causes the less massive object to accelerate.
Applications of Newton’s Laws

Applications of Newton’s Laws
5. The Laws of Motion 5.1 The Concept of Force5.2 Newton’s First Law and Inertial Frames5.3 Mass5.4 Newton’s Second Law5.5 The Force of Gravity and Weight5.6.

5. The Laws of Motion 5.1 The Concept of Force5.2 Newton’s First Law and Inertial Frames5.3 Mass5.4 Newton’s Second Law5.5 The Force of Gravity and Weight5.6.

Similar presentations

Ads by Google