Potential and Kinetic Energy: The Roller Coaster Lab Student Version

Similar documents
Chapter 6. You lift a 10 N physics book up in the air a distance of 1 meter at a constant velocity of 0.5 m/s. The work done by gravity is

Energy Skate Park - Conservation of Energy. Skate Park Energy Simulation - Conservation of Energy

Motion. 1 Describing Motion CHAPTER 2

5. A bead slides on a curved wire, starting from rest at point A in the figure below. If the wire is frictionless, find each of the following.

STATION 1: HOT WHEELIN PHYSICS 1. Define Newton s First Law. 2. Describe the motion of the untaped washer when the car hits the pencils.

Copyright 2014 Edmentum - All rights reserved.

Equilibrium. Observations

(Lab Interface BLM) Acceleration

Physics 11 Unit III Practice Test Projectile Motion. Instructions: Pick the best answer available in Part A and Show all your work for Part B

AP Physics 1 Fall Semester Review Problems 1-10 Due Thursday, Due Friday, Test on Monday

DATA EQUATIONS MATH ANSWER

CHANGES IN FORCE AND MOTION

Homework #10 Due Monday, May Compute the moment of inertia of the objects below.

Appendix : Categorization Task. Instructions

Screwed Tubes. December 4, Andreas Bastias Luis Castellanos Howard Hensley Jessica Rhyne

Exam 3 Phys Fall 2002 Version A. Name ID Section

Activities for Measuring Acceleration and Deceleration due to Gravity and Friction. Grade Level: Middle School

PHYSICS REVIEW SHEET 2010 MID-TERM EXAM

Describing a journey made by an object is very boring if you just use words. As with much of science, graphs are more revealing.

PHYSICS 12 NAME: Kinematics and Projectiles Review

3. Approximately how far will an object near Earth's surface fall in 3.0 seconds? m m m m

NAME:... SCHOOL: LINEAR MOTION. Answer ALL questions in this paper in the spaces provided.

Activity Overview. Granny on the Ramp: Exploring Forces and Motion MO-BILITY. Activity 4B MS. Activity Objectives: Activity Description:

Circular Motion - Horizontal

1. Find the potential energy of 20 Kg mass child sitting on a roof 10 m above the ground.

Physics Acceleration and Projectile Review Guide

Mechanical Energy I. Name: Date: Section C D F. Mr. Alex Rawson Physics

POTENTIAL ENERGY BOUNCE BALL LAB

PHYS 101 Previous Exam Problems

SC.5.P.13.2 Investigate and describe that the greater the force applied to it, the greater the change in motion of a given object.

Practice Test: Vectors and Projectile Motion

Projectiles Shot up at an Angle

HONORS PHYSICS One Dimensional Kinematics

Energy of a Rolling Ball

Regents Exam Practice: Measurement, Kinematics, Free Fall, PJM, and UCM

Compare the scalar of speed and the vector of velocity.

6 Motion in Two Dimensions BIGIDEA Write the Big Idea for this chapter.

THE BALLISTIC PENDULUM

Ch. 2 & 3 Velocity & Acceleration

Secondary Physics: The Compass Rose, Cars and Tracks

How do we know if something is moving quickly or slowly? What about the speed of things we can t see? (think about internet speed ) Has our idea of

Rocket Activity Foam Rocket

Advanced Hydraulics Prof. Dr. Suresh A. Kartha Department of Civil Engineering Indian Institute of Technology, Guwahati

Motion Graphing Packet

EF 151 Exam #2 - Spring, 2016 Page 1 of 6

Station 1: The NFL and Newton s First Law

Experiment 13: Make-Up Lab for 1408/1420

Harmonic Motion: Pendulums Student Version

D) 83 m D) Acceleration remains the same and speed increases. C) 216 m B) 6.0 m shorter A) 4.5 s A) 15 km/hr C) 47 m C) 20 m/sec B) 20 m/sec

You should know how to find the gradient of a straight line from a diagram or graph. This next section is just for revision.

Gravity: How fast do objects fall? Teacher Version (Grade level: 4 7)

Kinematics Review. What distance did the object travel in moving from point A to point B? A) 2.5 m B) 10. m C) 20. m D) 100 m

MULTIPLE CHOICE. Choose the one alternative that best completes the statement or answers the question.

Force and Motion Test Review

Motion in 1 Dimension

Page 2. Indicate with ticks ( ) in the table below which of the quantities are vectors and which are scalars. Velocity Speed Distance Displacement

1. Which one of the following is a vector quantity? A. time B. speed C. energy D. displacement

PHYSICS 218 EXAM 1 Monday, September 24, 2007

Prelab for the Ballistic Pendulum

Speed Reading. Forces Cause Change. The force of a bat hitting a baseball causes the baseball to change direction.

Today Mr. Happer told us to use the following physics vocabulary words and relate them to our experiment:

Angle Projectiles Class:

Unit 2 Review: Projectile Motion

Bottle Rockets. The bottle rocket, like the squid, uses water as the driving agent and compressed air instead of heat to provide the energy.

Kinematics-Projectiles

WONDERLAB: THE EQUINOR GALLERY. The science and maths behind the exhibits 30 MIN INFORMATION. Topic FORCES. Age

During the Push What kind of motion does the puck have at this time? Is it speeding up, slowing down, not moving, or moving at a steady speed?

Chapters 25: Waves. f = 1 T. v =!f. Text: Chapter 25 Think and Explain: 1-10 Think and Solve: 1-4

Figure 1 shows the distance time graph for a person walking to a bus stop. Figure 1. Time in seconds

Exam Unit 5: Motion and Forces

Honors Physics Semester 2 Final Exam Review

The grade 5 English science unit, Speed, meets the academic content standards set in the Korean curriculum, which state students should:

Movement and Position

Physics 8, Fall 2017, Homework #5. Due at start of class on Friday, October 13, 2017

End of Chapter Exercises

Ch06 Work and Energy.notebook November 10, 2017

Smooth Track, Steel Marble, Wood Block, Stopwatch, Ditto (carbon) paper, white paper, meter stick.

BROCK UNIVERSITY. Name: Student #: Page 1 of 12

Answer: Team Name: Time Completed: 1 st min. 2 nd min. 3 rd min. 4 th min. 5 th min.

Applying Hooke s Law to Multiple Bungee Cords. Introduction

Force, Motion and Energy Review

EOY Force and Motion REVIEW

Wild Thing. Objective 1 (E1): To calculate the average speed of the train for one trip.

Kinematics 1. A. coefficient of friction between the cart and the surface. B. mass of the cart. C. net force acting on the cart

Harmonic Motion: Pendulums

Physics: Principles and Applications, 6e Giancoli Chapter 3 Kinematics in Two Dimensions; Vectors. Conceptual Questions

Anatomy of a Homer. Purpose. Required Equipment/Supplies. Optional Equipment/Supplies. Discussion

Calculate the size of the force(s) acting on Sarah just after the take- off, in position 2 in the above diagram.

7.3.9 Unbalanced forces

STUDY GUIDE UNIT 7 - PROJECTILES

The speed of an inline skater is usually described in meters per second. The speed of a car is usually described in kilometers per hour.

The Science of Golf. Test Lab Toolkit The Swing: Driving. Grades Education

Organize information about waves. Differentiate two main types of waves.

AP Physics Chapter 2 Practice Test

POTENTIAL ENERGY AND ENERGY CONSERVATION

The diagram below represents the path of a stunt car that is driven off a cliff, neglecting friction.

Exploration Series. MODEL ROCKET Interactive Physics Simulation Page 01

End of Chapter Exercises

Motion, Vectors, and Projectiles Review. Honors Physics

x 2 = (60 m) 2 + (60 m) 2 x 2 = 3600 m m 2 x = m

Transcription:

Potential and Kinetic Energy: The Roller Coaster Lab Student Version Key Concepts: Energy is the ability of a system or object to perform work. It exists in various forms. Potential Energy is the energy an object has inside a force field due to its position. In the roller coaster s case, the potential energy comes from its height because the Earth s gravity force is acting on it. Roller coasters are able to move their passengers very rapidly up and down the hills because the cars have a large amount of potential energy on the very first hill. Kinetic Energy is mechanical energy that is due to motion of an object. Thermal Energy is energy due to the heat of a system or object. Energy can be converted to heat through frictional dissipation. Friction, or frictional dissipation, is a phenomenon in which mechanically useful energy, such as the motion of the roller coaster, is converted to mechanically useless energy such as heat or sound. Friction acts on all moving objects, and it is the reason that a ball rolled across an open space will eventually slow down and stop. Conservation of Energy is a fundamental principle that energy cannot be created or destroyed. Rather, it is transferred between different forms, such as those described above. Procedure: 1. You will have 4 pieces of foam insulation. To start, tape 3 pieces of the foam insulation together. 2. Tape the beginning of the rollercoaster at around 140 cm higher than the floor. 3. Tape the slide down 40 cm away from the edge of the wall. (See Diagram 1 for the set-up instructions 2-4)

SET UP DIAGRAM: TAPE FOAM PIPE AT 140 CM 4 PIECES OF FOAM PIPE INSULATION ADD TAPE HERE: TAPE SLIDE 40 CM AWAY Diagram 1 Effects of Dropping Height PREDICTION DIAGRAM: START= 60 CM PULL ON IT HERE! TAPE HERE:40 CM? 1 METER Diagram 2 4. Have one partner form a hill, with its peak located 1 m away horizontally from the starting point as shown in Diagram 2. Do this by pulling up on the insulation to form the peak of the hill. As one partner holds it still, have the other partner drop the marble from 60 cm vertical height. 5. If the marble makes it over the hill, then raise the height and retry. If it does not roll over, lower the hill and retry. Repeat this process until the maximum hill height is determined. Record it in the table below.

6. Now drop the marble from 120 cm. Determine the maximum height of the hill and record it in the table below: Dropping Height / cm Hill Height/ cm Q1. How does the increase in dropping height affect the maximum hill height? Q2. Is your dropping height larger than the height of the hill? Why do you think this is the case? Energy Dissipation 7. Using the same hill height as when you dropped the marble from 120 cm, stretch the hill out further from the wall by 50 centimeters (so the center of the hill is 150 centimeters from the wall). This should result in a more gradual slope of the hill up to the same height as in the previous test. 8. Observe if the marble clears the hill. 9. If it does not clear the hill, then adjust the height of the hill until the marble can clear the hill and the maximum height of the hill is determined. Record it below: Maximum hill height at 150 cm separation = Q3. Is your maximum hill height at 150 cm separation larger or smaller than the maximum hill height at 100 cm separation?

Q4. Why do you think this is the case? 10. Now, tape down the insulation 90 cm away from the starting point as shown in Diagram 3 below, but keep the hill height the same as the maximum height determined in the previous step: (Note: This should give you a steeper slope.) FRICTION DIAGRAM: START= 120 CM TAPE HERE:40 CM TAPE HERE:90 CM FROM THE START POINT 150 CM Diagram 3 11. Observe if the marble makes it over the hill. 12. If it does not make it over the hill, then adjust the height of the hill until the marble can, and the maximum height of the hill is determined. Record it below: Maximum steep hill height at 150 cm separation = Another way energy is dissipated is through the flexibility of the foam, allowing the slide itself to absorb some energy as the marble rides up, and slightly pushes into, the side of the hill. Q5. Why do you think the maximum hill height was different for the steep hill and the gradual hill? 13. Now, make a loop, which at its tallest point, is the same height as the value recorded directly above. Have a partner hold it in place. See Diagram 4 below.

LOOP DIAGRAM: START= 120 CM TAPE HERE:40 CM TAPE HERE:90 CM FROM THE START POINT 100 CM= 1 METER Diagram 4 14. Drop the marble from 120 cm and observe whether it completes the loop. Q6. Does your marble complete the loop? Q7. Describe what you saw, if the marble did not complete the loop. 15. Try dropping the marble through a loop that is small enough for the marble to get through the highest point. If it does not complete the loop, then lower the loop size until it succeeds. Actual maximum loop height = If an object is to continue through a vertical loop, it is not enough for it to merely reach the highest point of the loop. It must actually have a minimum non-zero velocity (it must be moving) along the track at the top point in order to stay in contact with the loop. This velocity depends on the acceleration due to gravity, g, and the radius of the loop, r: v = min gr 16. The acceleration due to gravity is 9.8 m/s 2 (980 cm/ s 2 ). Calculate the minimum velocity the marble must have to complete the loop: First calculate the radius of your loop. Measure how high your loop is and divide by 2:

Radius = Predicted minimum velocity =

Conceptual Questions Q8. Where is the kinetic energy greatest on the course of the roller coaster illustrated below? Where is the potential energy greatest? Label the diagram below: LABEL: Q9. Why is the first hill on all the roller coasters always the highest one? Competition: Build your own rollercoaster! Now, you will have a competition to see who can make the best roller coaster! As you know, the most fun roller coasters are those that send the riders over the highest hills. The group who can make the most number of hills with the highest combined height (add up all the heights hills need to touch the ground in between) on their rollercoaster will win!

2024 © sportdocbox.com Privacy Policy | Terms of Service | Feedback