Presentation is loading. Please wait.

Presentation is loading. Please wait.

T101-Q-1 Figure 1 shows the spring force as a function of position x for a spring-block system resting on a frictionless table. The block is released at.

Published byLucinda Norman Modified over 4 years ago

Similar presentations

Presentation on theme: "T101-Q-1 Figure 1 shows the spring force as a function of position x for a spring-block system resting on a frictionless table. The block is released at."— Presentation transcript:

1 T101-Q-1 Figure 1 shows the spring force as a function of position x for a spring-block system resting on a frictionless table. The block is released at x = + 10 cm. How much work (in Joules) does the spring do on the block when the block moves from xi = cm to xf=-4 cm? +2.4 T101: Q3. A particle is acted on by a constant force F = (2.0 N)i– (5.0 N)j and is displaced from an initial position of di= (0.50 m)i+ (0.80 m)j at time t = 0 s to a final position of df= (3.5 m)i+ (9.8 m)j at time t = 10 s. Find the average power (in Watts) on the particle due to this force in this time interval. A) –3.9 T101Q4. A single force acts on a 5.0 kg object. The position of the object as a function of time is given by x = 10 t – 5.0 t2, where x is in meters and t is in seconds. Find the work done by this force on the object in the interval from t = 0 s to t = 5.0 s. A) 3.8 ×103 J T101Q5. An object of mass 1.0 kg is moving in a straight line over a rough horizontal surface. The coefficient of kinetic friction between the object and the floor is What is the power that must be supplied to the object in order to keep it moving at a constant speed of 2.0 m/s? A) 3.9 W

2

3 T102 Q2. An elevator is designed to carry a load of 20
T102 Q2. An elevator is designed to carry a load of 20.0 × 103 N from the ground to a height of 87.5 m in a time of 18.0 seconds. What is the average power that must be supplied by the motor of the elevator to lift this load? × 103 W T102-Q4. A block, of mass m= 200 g , slides back and forth on a frictionless surface between two springs, as shown in Figure 3. The left-hand side spring has k1= 130 N/m and its maximum compression is 16 cm. The right-hand side spring has k2= 280 N/m . Find the maximum compression of the right-hand side spring. A) 11 cm. T112: Q3. In Figure 2, a 5.0-kg block is moving at 5.0 m/s along a horizontal frictionless surface toward an ideal spring that is attached to a wall. After the block collides with the spring, the spring is compressed a maximum distance of xm. What is the speed of the block when the spring is compressed to only xm/2 ? Ans: 4.3 m/s

Download ppt "T101-Q-1 Figure 1 shows the spring force as a function of position x for a spring-block system resting on a frictionless table. The block is released at."

Similar presentations

Physics 111: Mechanics Lecture 7

Physics 111: Mechanics Lecture 7
Physics 1D03 - Lecture 22 Energy, Work and Power.

Physics 1D03 - Lecture 22 Energy, Work and Power.
1997B1. A kg object moves along a straight line

1997B1. A kg object moves along a straight line
Chapter 5 Energy 1. Dot product of vectors 2. Kinetic Energy 3. Potential Energy 4. Work-Energy Theorem 5. Conservative and non-conservative forces 6.

Chapter 5 Energy 1. Dot product of vectors 2. Kinetic Energy 3. Potential Energy 4. Work-Energy Theorem 5. Conservative and non-conservative forces 6.
Work, Energy, And Power m Honors Physics Lecture Notes.

Work, Energy, And Power m Honors Physics Lecture Notes.
a) The kinetic energy of the car. b) The distance it takes to stop.

a) The kinetic energy of the car. b) The distance it takes to stop.
More Conservation of Mechanical Energy

More Conservation of Mechanical Energy
Physics 1D03 Work and Kinetic Energy Work by a variable force Kinetic Energy and the Work-Energy Theorem Power Serway & Jewett 7.3, 7.4.

Physics 1D03 Work and Kinetic Energy Work by a variable force Kinetic Energy and the Work-Energy Theorem Power Serway & Jewett 7.3, 7.4.
Instructor: Dr. Tatiana Erukhimova

Instructor: Dr. Tatiana Erukhimova
General Physics 1, Additional questions By/ T.A. Eleyan

General Physics 1, Additional questions By/ T.A. Eleyan
A block is launched up a frictionless 40° slope with an initial speed v and reaches a maximum vertical height h. The same block is launched up a frictionless.

A block is launched up a frictionless 40° slope with an initial speed v and reaches a maximum vertical height h. The same block is launched up a frictionless.
1a. Positive and negative work

1a. Positive and negative work
T101Q7. A spring is compressed a distance of h = 9.80 cm from its relaxed position and a 2.00 kg block is put on top of it (Figure 3). What is the maximum.

T101Q7. A spring is compressed a distance of h = 9.80 cm from its relaxed position and a 2.00 kg block is put on top of it (Figure 3). What is the maximum.
Chapter 5 Work and Energy. Force, displacement  WORK.

Chapter 5 Work and Energy. Force, displacement  WORK.
Potential Energy and Conservative Forces

Potential Energy and Conservative Forces
Energy m m Physics 2053 Lecture Notes Energy.

Energy m m Physics 2053 Lecture Notes Energy.
Physics 3.3. Work WWWWork is defined as Force in the direction of motion x the distance moved. WWWWork is also defined as the change in total.

Physics 3.3. Work WWWWork is defined as Force in the direction of motion x the distance moved. WWWWork is also defined as the change in total.
Formative Assessment. FA6.2: 1. A 5.20 kg object speeds up from 3.10 m/s to 4.20 m/s. What is the change in kinetic energy? (20.9 J)

Formative Assessment. FA6.2: 1. A 5.20 kg object speeds up from 3.10 m/s to 4.20 m/s. What is the change in kinetic energy? (20.9 J)
Q06. Work Energy & Power.

Q06. Work Energy & Power.
Work-2 & Power. Work and Area If the force is constant, we can graphically interpret the work done ( W = F d ) as the area of a rectangle F tall and d.

Work-2 & Power. Work and Area If the force is constant, we can graphically interpret the work done ( W = F d ) as the area of a rectangle F tall and d.

Similar presentations

Ads by Google