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14. Suppose that you have a mass of 62.0 kg and that you walk to the top of a stairway which is h = 12.0 meters high and L= 15.0 meters deep. a. How much work will you have to do in walking to the top of the stairway? Ans. To get to the top of the stairs, W = F d=mgh = 62.0 kg . . 12 m =7291.2 J b.

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14. Suppose that you have a mass of 62.0 kg and that you walk to the top of a stairway which is h = 12.0 meters high and L= 15.0 meters deep. a. How much work will you have to do in walking to the top of the stairway? Ans. To get to the top of the stairs, W = F d=mgh = 62.0 kg . . 12 m =7291.2 J b.

AP Physics Practice Test: Work, Energy, Conservation of Energy

AP Physics Practice Test: Work, Energy, Conservation of Energy ©2011, Richard White www.crashwhite.com Part II. Free Response 6. A block of mass m rests on a rough surface, and has a light spring of spring constant k and unstretched length d attached to one side as shown, with the other end of the spring attached to an anchor. There is a

Page: Unit: Work, Energy & Momentum Conservation of Energy

2. A 70. kg pole vaulter converts the kinetic energy of running at ground level into the potential energy needed to clear the crossbar at a height of 4.0 m above the ground. What is the minimum velocity that the pole vaulter must have when taking off from the ground in order to clear the bar? Answer: s 8.9m

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2.29 A vertical spring stores 0.962 J in spring potential energy when a 3.0-kg mass is suspended from it. (a) By what multiplicative factor does the spring potential energy change if the mass attached to the spring is doubled? (b) Verify your answer to part (a) by calculating the spring potential energy when a 6.0-kg mass is attached to the spring.

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Chapter 6 Homework Assignment – Work-Energy Theorem Work Qu. 1 A factory worker pushes a 30 kg crate a distance 4.5 m along a level floor at constant velocity by pushing horizontally on it. The coefficient of kinetic friction µk = 0.25. a) What magnitude of pushing force P must the worker apply? (Ans: 73.5 N)

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mechanical energy would not remain constant however, since non-conservative forces such as friction are also involved. PROCEDURE I. Conservation of Mechanical Energy A. Using conservation of mechanical energy to predict the change in height, Δh, of a cart traveling up a frictionless ramp and coming to a halt.

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Work and Conservation of Energy Topics Covered: 1. The definition of work in physics. 2. The concept of potential energy ... which works out to W gravity = - 150 J where J=Joule is a unit of energy. One Joule=Ntäm ... Work & Energy Conservation Rev2.nb 11. Some Properties of Gravitational Potential Energy

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Physics 03-01 Work and the Work-Energy Theorem Name: _____ Created by Richard Wright – Andrews Academy To be used with OpenStax College Physics Homework 1. A box is being moved with a velocity v by a force P (parallel to v) along a level horizontal floor.The normal force is

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PhyzSpringboard Conservation of Energy LEVEL I: THE FLOW OF ENERGY 1. Suppose Belly-flop Benny were to climb a ladder to a diving platform some height above the ground. a. When he’s at rest on the ground, what is his potential energy? His kinetic energy? Label these values appropriately in the diagram. b.

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What is nice is that this example illustrates two very important conservation principles: conservation of (linear) momentum and conservation of mechanical energy Below is a before and after picture of this situation: incoming bullet embeds in large block which swings up to a certain height. The

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Physics Conservation of Energy Worksheet Solutions Part I 1. A trolley makes two separate runs down an inclined plane. It is released ﬁrst from Y, halfway up the slope and then from X at the top of the slope. Which of the following statements is/are true? (i) The trolley takes twice as long to run from X to Z as it take to run from Y to Z.

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Truck suspensions often have “helper springs” that engage at high loads. One such arrangement is a leaf spring with a helper coil spring mounted on the axle, as in Figure P7.17. The helper spring engages when the main leaf spring is compressed by distance 0, and then helps to support any additional load.

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AP Physics – Work/Energy – 6 ans 1. A 0.50 kg cart moves on a straight horizontal track. The graph of velocity Vx versus time t for the cart is given below. (a) Indicate every time t for which the cart is at rest.

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Work and Energy 1. If the velocity of a moving object is doubled, the object's kinetic energy is (1)unchanged (3)doubled (2)halved (4)quadrupled 2. Which cart shown below has the greatest kinetic energy? (1) (3) (2) (4) 3. As a block is accelerated from rest along a horizontal surface, its gravitational potential energy (1)decreases (3)remains ...

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9 Energy Work is done when a net force acts on an object and the object moves in the direction 9.1 Work of the net force. 9 Energy Work is the product of the force on an object and the distance through which the object is moved: the quantity force × distance We do work when we lift a load against Earth’s gravity.

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Physics Worksheet Work and Energy Section: Name: Mr. Lin 1 Show all work for the following questions, including the equation and substitution with units. 1. An 80 N force has been applied to a block and move it 20 m along the direction of the force. How much work has been done to the block? 2.

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The end goal of each problem is to complete the energy bar graphs. 1. Diver Problem A stuntman (85 kg) stands atop of a high platform. At the top of the platform his potential energy is 15,000J. If he jumps from the platform (v o = 0), complete the bar graphs for each of the following locations:

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How much work is done ... Assume no friction. The mass of the block is 10.0 kg. Since the problem involves a change in height and speed, we make use of the generalized WorkEnergy Theorem, WNC = E = P ... surface where it passes over a 2.00m rough patch.

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Ch 8 – Energy & Work! Work, Energy, Power! “Work,” “energy,” and “power” ... These words have very speciﬁc meanings in physics; you’ll need to be careful not to mix up the two ways of speaking.! Deﬁnition of Work!!!! Note that the Force and the displacement have to be in ... I lift a 8-kg bowling ball up 50 cm into the air ...

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Physics Practice Problems: Work and Energy Page 1 of 5 Please ignore air resistance, treat all surfaces as frictionless unless otherwise specified or implied. Work and work-energy theorem: 1. A 2kg crate rests on the floor.

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2. A toy cork gun contains a spring whose spring constant is 10.0 N/m. The spring is compressed 5.00 cm and then used to propel a 6.00-g cork. The cork, however, sticks to the spring for 1.00 cm beyond its unstretched length before separation occurs. The muzzle velocity of this cork is: A) 1.02 m/s B) 1.41 m/s C) 2.00 m/s D) 2.04 m/s E) 4.00 m/s 3.

physics: work and energy - Freelance Teacher

physics: work and energy How to use “Ei + net Wnc = Ef ” and “Ei=Ef” (conservation of mechanical energy) to solve problems 1. Identify and label the initial and final points of the interval you are considering. 2. Identify all the forces on the object.

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A spring-loaded toy dart gun is used to shoot a dart straight up in the air, and the dart reaches a maximum height of 24 m. The same dart is shot straight up a second time from the same gun, but this time the spring is compressed only half as far as before ﬁring. How far up does the dart go this time, neglecting friction and assuming an ideal ...

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Work and Energy 2 W = F·d ... Change in KE is the area under the net force vs. position graph. This should be contrasted with the use of the net force vs. time graph, where change in momentum is the area under the net force vs. time graph. Work-KE Theorem. 10. Two disks . Two disks are initially at rest. The mass of disk B is two times

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Work Energy Review . As shown in the diagram below, a child applies a ... As a ball falls freely (without friction) toward the ground, its total mechanical energy A. decreases B. increases C. remains the same . A pendulum is pulled to the side and released from rest.

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22.) A spring with k=53 N/m hangs vertically next to a ruler. The end of the spring is next to the 15 cm mark on the ruler. If a 2.5 kg mass is now attached to the end of the spring, where will the end of the spring line up with the ruler marks? 23.) A novice skier, starting from rest, slides down a frictionless 35.0º incline whose vertical

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6. Calculate the power expended when a 500 N barbell is lifted 2.2 m in 2 s. 7. An escalator is used to move 20 passengers every minute from the first floor of a department store to the second. The second floor is located 5-meters above the first floor. The average passenger's mass is 60 kg. Determine the power requirement of the escalator in ...

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AP Physics Final Examples: Work, Energy SCROLL DOWN FOR SOLUTIONS 49. (II) A ski starts from rest and slides down a 22º incline 75 m long. (a) If the coefficient of friction is 0.090, what is the ski’s speed at the base of the incline?b

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Work-Energy Bar Charts Read from Lesson 2 of the Work, Energy and Power chapter at The Physics Classroom: ... of physical situations is a work-energy bar chart. A work-energy bar chart represents the amount of energy present in a system by means of a vertical bar. The length of a bar is representative of the amount

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Relation between Kinetic energy and the TOTAL work done on an object: the work-energy theorem The next idea couples kinematics (changes in velocity of an object) and Netwon’s second law of motion (total force on an object leading to an acceleration) to the total work done on an object. The work done by the net (total) force on an object is

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AP Physics 1 - Energy, Work, and Power Practice Test (Multiple Choice Section) Directions: Mark only one answer for each question. Use g = 10 m/s2 for simplicity. 1. Weightlifter A lifts a 50 kg mass 1 m above the ground. Weightlifter B lifts an identical 50 kg mass 2 m above the ground.

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KINETIC ENERGY • KINETIC ENERGY: Ability to do work as a result of the velocity of the system. • Energy associated with the velocity (v) of an object. • Example: A cool 1200 kg yellow car is running at 45 m/s. As a sharp turn is coming ahead the driver slows down to 20 m/s.

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Physics 11 – Momentum, Work, Power, Energy Test Review IMPULSE AND MOMENTUM: 1. What is the momentum of a 0.25 kg hockey puck traveling at 9 m/s? 2. A 300 N force is applied to a stalled car for 4 seconds. If the car has a mass of 1500 kg, what is the change in velocity of the car? 3.

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WorkEnergy Theorem Reviewed - Physics and Astronomy at TAMU

Work on a Sliding Block Description: A box is pushed up a frictionless incline. Find the work done by gravity, the pushing force, and the normal force. A block of weight sits on a frictionless inclined plane, which makes an angle with respect to the horizontal, as shown. A

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54 Holt Physics Problem Workbook NAME _____ DATE _____ CLASS _____ Work and Energy Problem E CONSERVATION OF MECHANICAL ENERGY PROBLEM The largest apple ever grown had a mass of about 1.47 kg. Suppose you hold such an apple in your hand.You accidentally drop the apple, then

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7. Kinetic Energy and Work Kinetic Energy: The kinetic energy of a moving object: k = 1 2 mv 2 • Kinetic energy is proportional to the square of the velocity. If the velocity of an object doubles, the kinetic energy increases by a

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previous page, all five joules of input work were transformed to five joules of output work. An engineer would say the machine was 100 percent efficient, because all the input work became output work and none was lost. How friction affects real machines In real machines, the work output is always less than the work input.

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Physics--Chapter 5: Work and Energy Chapter 5 Test Review 10) A 40.0 N crate starting at rest slides down a rough 6.0 m long ramp inclined at 30.0° with the horizontal. The force of friction between the crate and ramp is 6.0 N. Find the velocity of the crate at the bottom of the incline. (6.4 m/s)

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a. TME conserved b. TME increases c. TME decreases 7. A marble starts from rest and rolls down an inclined plane. Ignore friction. a. TME conserved b. TME increases c. TME decreases 8. A physics student runs up a flight of stairs at constant speed. a. TME conserved b. TME increases c. TME decreases 9. A baseball makes its flight through the air ...

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Chapter 8: Potential Energy and Conservation of Energy Work and kinetic energy are energies of motion. We need to introduce an energy that depends on location or position. This energy is called potential energy. Consider a vertical spring oscillating with mass m attached to one end. At the extreme ends of travel

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Chapter 7 – Potential energy and conservation of energy I. Potential energy Energy of configuration II. Work and potential energy III. Conservative / Non-conservative forces IV. Determining potential energy values: - Gravitational potential energy - Elastic potential energy I. V. Conservation of mechanical energy VI. External work and thermal ...

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Equation Chapter 8 Section 1 Chapter 14 Potential Energy and Conservation of Energy There is a fact, or if you wish, a law, governing all natural phenomena that are known to date. There is no exception to this law — it is exact as far as we know. The law is called the conservation of energy. It states that

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Potential Energy and Energy Conservation. Goals for Chapter 7 – To study gravitational and elastic potential energy (conservative forces) – To determine when total mechanical energy is conserved – To examine situations when total mechanical energy is not ... conservative forces and the ones done by non-conservative forces (e.g. friction) ...

Chapter 8: POTENTIAL ENERGY AND CONSERVATION OF ENERGY

The wound spring of a clock possesses: A. kinetic but no potential energy B. potential but no kinetic energy C. both potential and kinetic energy in equal amounts D. neither potential nor kinetic energy E. both potential and kinetic energy, but more kinetic energy than potential energy

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Chapter 8 Potential Energy and Conservation of Energy

8-1 Conservative and Nonconservative Forces Conservative force: the work it does is stored in the form of energy that can be released at a later time Example of a conservative force: gravity Example of a nonconservative force: friction Also: the work done by a conservative force moving an object around a closed path is zero;

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214 CHAPTER 7 Potential Energy and Energy Conservation 7.1 Gravitational Potential Energy 215 7.1 As a basketball descends, gravitational potential energy is converted to kinetic energy and the basketball’s speed increases. y1 y2 2 y1, 0, so w does positive work and gravitational

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You throw a 0.145 kg baseball straight up in the air, and while you are throwing the ball your hand moves up 0.50 m. The ball leaves your hand with an initial upward velocity of magnitude 20.0 m/s. Ignore air resistance. a) assuming your hand exerts a constant upward force on the ball, find the magnitude of that force. b) Find the speed of the ...