Presentation is loading. Please wait.

Presentation is loading. Please wait.

Problem 10.110 c 240 mm b x B A z y Collars A and B are connected by the wire AB and can slide freely on the rods shown. Knowing that the length of the.

Published byJonathan Manning Modified over 8 years ago

Similar presentations

Presentation on theme: "Problem 10.110 c 240 mm b x B A z y Collars A and B are connected by the wire AB and can slide freely on the rods shown. Knowing that the length of the."— Presentation transcript:

1 Problem 10.110 c 240 mm b x B A z y Collars A and B are connected by the wire AB and can slide freely on the rods shown. Knowing that the length of the wire is 440 mm and that the weight W of collar A is 90 N, determine the magnitude of the force P required to maintain equilibrium of the system when (a) c = 80 mm, (b) c = 280 mm. P W

2 c 240 mm b x B A z y 1. Apply the principle of virtual work. If a system of connected rigid bodies is in equilibrium, the total virtual work of the external forces applied to the system is zero for any virtual displacement of the system. 1a. Define a virtual displacement. By using a single variable, define a virtual displacement of all the forces that do work. P W Solving Problems on Your Own Collars A and B are connected by the wire AB and can slide freely on the rods shown. Knowing that the length of the wire is 440 mm and that the weight W of collar A is 90 N, determine the magnitude of the force P required to maintain equilibrium of the system when (a) c = 80 mm, (b) c = 280 mm. Problem 10.110

3 c 240 mm b x B A z y 1b. Express the total virtual work done by the forces and couples during the virtual displacement.  U = F.  r and  U = M  where  U is the virtual work, F is a force undergoing a virtual displacement  r, and M is a couple undergoing a virtual rotation . 1c. Set the virtual work to zero and solve for the variable. P W Solving Problems on Your Own Collars A and B are connected by the wire AB and can slide freely on the rods shown. Knowing that the length of the wire is 440 mm and that the weight W of collar A is 90 N, determine the magnitude of the force P required to maintain equilibrium of the system when (a) c = 80 mm, (b) c = 280 mm. Problem 10.110

4 Problem 10.110 Solution Define a virtual displacement. c 240 mm b x B A z y Since AB = 440 mm we have ( 440 mm) 2 = ( 240 mm ) 2 + b 2 + c 2 b 2 = ( 440 ) 2 _ ( 240 ) 2 _ c 2 = 136 x 10 3 _ c 2 Differentiate: 2 b  b = _ 2 c  c  b = _  c = _ c b c cc c 136 x 10 3 _ c 2 P W

5 Express the total virtual work done by the forces. Set the virtual work to zero and solve for the variable. Virtual work:  U = 0: P  c + W  b = 0 P  c = W For W = 90 N: P = 90 c cc c 136 x 10 3 _ c 2 c c 240 mm b x B A z y P W Problem 10.110 Solution

6 c 240 mm b x B A z y P W P = 90 c 136 x 10 3 _ c 2 (a) When c = 80 mm: P = 90 ; P = 20 N (b) When c = 280 mm: P = 90 ; P = 105 N 80 136 x 10 3 _ 80 2 280 136 x 10 3 _ 280 2 Problem 10.110 Solution

Download ppt "Problem 10.110 c 240 mm b x B A z y Collars A and B are connected by the wire AB and can slide freely on the rods shown. Knowing that the length of the."

Similar presentations

Method of Virtual Work.

Method of Virtual Work.
Mechanics of Rigid Body. C

Mechanics of Rigid Body. C
ENGR-1100 Introduction to Engineering Analysis

ENGR-1100 Introduction to Engineering Analysis
PLANAR KINETICS OF A RIGID BODY: CONSERVATION OF ENERGY

PLANAR KINETICS OF A RIGID BODY: CONSERVATION OF ENERGY
Chapters 17, 18 Review. Der Innere Schweinehund (The inner Pigdog)

Chapters 17, 18 Review. Der Innere Schweinehund (The inner Pigdog)
ENGR 214 Chapter 16 Plane Motion of Rigid Bodies:

ENGR 214 Chapter 16 Plane Motion of Rigid Bodies:
Problem y x Collars A and B are connected P

Problem y x Collars A and B are connected P
Problem A small 200-g collar C can slide on a

Problem A small 200-g collar C can slide on a
MOMENT OF A COUPLE (Section 4.6)

MOMENT OF A COUPLE (Section 4.6)
“Dynamics by Hibbeler,” Dr. S. Nasseri, MET Department, SPSU Today’s Objectives: Students will be able to: 1.Apply the three equations of motion for a.

“Dynamics by Hibbeler,” Dr. S. Nasseri, MET Department, SPSU Today’s Objectives: Students will be able to: 1.Apply the three equations of motion for a.
EQUILIBRIUM OF RIGID BODIES

EQUILIBRIUM OF RIGID BODIES
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.
PLANAR KINETIC EQUATIONS OF MOTION: TRANSLATION (Sections )

PLANAR KINETIC EQUATIONS OF MOTION: TRANSLATION (Sections )
ME 221Lecture 221 ME 221 Statics Lecture #22 Sections 5.1 – 5.4.

ME 221Lecture 221 ME 221 Statics Lecture #22 Sections 5.1 – 5.4.
Chapter 2 Statics of Particles

Chapter 2 Statics of Particles
Axially loaded member Axial load and normal stress under equilibrium load, Elastic Deformation.

Axially loaded member Axial load and normal stress under equilibrium load, Elastic Deformation.
Chapter 16 PLANE MOTION OF RIGID BODIES: FORCES AND ACCELERATIONS The relations existing between the forces acting on a rigid body, the shape and mass.

Chapter 16 PLANE MOTION OF RIGID BODIES: FORCES AND ACCELERATIONS The relations existing between the forces acting on a rigid body, the shape and mass.
Plane Motion of Rigid Bodies: Forces and Accelerations

Plane Motion of Rigid Bodies: Forces and Accelerations
MOMENT OF A COUPLE Today’s Objectives: Students will be able to

MOMENT OF A COUPLE Today’s Objectives: Students will be able to
Equilibrium of a Rigid Body

Equilibrium of a Rigid Body

Similar presentations

Ads by Google