Pre-Lab Exercise Full Name:

Similar documents
Experiment 11: Rotational Inertia of Disk and Ring

Rotational Motion. 1 Purpose. 2 Theory 2.1 Equation of Motion for a Rotating Rigid Body

E X P E R I M E N T 11

Rotational Dynamics Smart Pulley

13-Nov-2015 PHYS Rotational Inertia

General Physics I Lab. M1 The Atwood Machine

Rotational Inertia (approximately 2 hr) (11/23/15)

Human Arm. 1 Purpose. 2 Theory. 2.1 Equation of Motion for a Rotating Rigid Body

Second Law. In this experiment you will verify the relationship between acceleration and force predicted by Newton s second law.

Activity P10: Atwood's Machine (Photogate/Pulley System)

Rotary Motion Sensor

LAB 5: ROTATIONAL DYNAMICS

Hooke s Law. Equipment. Introduction and Theory

Rotational Dynamics. Goals and Introduction

EXPERIMENT 7: ANGULAR KINEMATICS AND TORQUE (V_3)

Lab 11: Rotational Dynamics

General Physics I Lab (PHYS-2011) Experiment MECH-2: Newton's Second Law

Experiment P28: Conservation of Linear and Angular Momentum (Smart Pulley)

Activity P24: Conservation of Linear and Angular Momentum (Photogate/Pulley System)

Rotational Dynamics. Moment of Inertia of a point mass about an axis of rotation a distance r away: I m = mr 2

Experiment P13: Atwood's Machine (Smart Pulley)

Laboratory Manual Experiment NE02 - Rotary Motions Department of Physics The University of Hong Kong

Newton's 2 nd Law. . Your end results should only be interms of m

Developing a Scientific Theory

1. Write the symbolic representation and one possible unit for angular velocity, angular acceleration, torque and rotational inertia.

Theory An important equation in physics is the mathematical form of Newton s second law, F = ma

Materials: One of each of the following is needed: Cart Meter stick Pulley with clamp 70 cm string Motion Detector

The University of Hong Kong Department of Physics. Physics Laboratory PHYS3350 Classical Mechanics Experiment No The Physical Pendulum Name:

Experiment P26: Rotational Inertia (Smart Pulley)

Activity P10: Atwood's Machine (Photogate/Pulley System)

Motion on a linear air track

Newton s Second Law. Sample

Work and Energy. Objectives. Equipment. Theory. In this lab you will

Lab Partner(s) TA Initials (on completion) EXPERIMENT 7: ANGULAR KINEMATICS AND TORQUE

Experiment P09: Acceleration of a Dynamics Cart I (Smart Pulley)

Newton s Second Law. Newton s Second Law of Motion describes the results of a net (non-zero) force F acting on a body of mass m.

Name Class Date. Activity P21: Kinetic Friction (Photogate/Pulley System)

Simple Harmonic Motion Investigating a Mass Oscillating on a Spring

M61 1 M61.1 PC COMPUTER ASSISTED DETERMINATION OF ANGULAR ACCELERATION USING TORQUE AND MOMENT OF INERTIA

Rotational Motion. 1 Introduction. 2 Equipment. 3 Procedures. 3.1 Initializing the Software. 3.2 Single Platter Experiment

The Damped Pendulum. Physics 211 Lab 3 3/18/2016

Lab: Newton s Second Law

General Physics I Lab. M7 Conservation of Angular Momentum

Rotational Motion. Variable Translational Motion Rotational Motion Position x θ Velocity v dx/dt ω dθ/dt Acceleration a dv/dt α dω/dt

Constant velocity and constant acceleration

L03 The Coefficient of Static Friction 1. Pre-Lab Exercises

PHY 123 Lab 6 - Angular Momentum

LAB 8: ROTATIONAL DYNAMICS

College Physics I Laboratory Angular Momentum

Experiment P30: Centripetal Force on a Pendulum (Force Sensor, Photogate)

Semester I lab quiz Study Guide (Mechanics) Physics 135/163

Physics. in the Laboratory. Robert Kingman and Gary W. Burdick. PHYS130 Applied Physics for the Health Professions First Edition Spring Semester 2001

Lab 1 Uniform Motion - Graphing and Analyzing Motion

PHY 111L Activity 9 Moments of Inertia

Physical Properties of the Spring

Lab 9 - Rotational Dynamics

Newton's Laws and Atwood's Machine

Force vs time. IMPULSE AND MOMENTUM Pre Lab Exercise: Turn in with your lab report

The purpose of this laboratory exercise is to verify Newton s second law.

Plane Motion of Rigid Bodies: Forces and Accelerations

Physics 1050 Experiment 6. Moment of Inertia

Physical Pendulum Torsion Pendulum

SIMPLE PENDULUM AND PROPERTIES OF SIMPLE HARMONIC MOTION

Prelab for Friction Lab

PHY 221 Lab 7 Work and Energy

PHY 123 Lab 4 The Atwood Machine

Forces and Newton s Second Law

Rotation. PHYS 101 Previous Exam Problems CHAPTER

ATWOOD S MACHINE. 1. You will use a tape timer to measure the position of one of the masses of the Atwood s machine as it falls.

Experiment 9: Simple Harmonic M otion

Simple Harmonic Motion - MBL

Please read this introductory material carefully; it covers topics you might not yet have seen in class.

Activity P08: Newton's Second Law - Constant Force (Force Sensor, Motion Sensor)

LAB 4: FORCE AND MOTION

COMPLETE ROTATIONAL SYSTEM

Gravity Pre-Lab 1. Why do you need an inclined plane to measure the effects due to gravity?

Experiment 11. Moment of Inertia

Lab 11 Simple Harmonic Motion A study of the kind of motion that results from the force applied to an object by a spring

Physics Spring 2006 Experiment 4. Centripetal Force. For a mass M in uniform circular motion with tangential speed v at radius R, the required

Uniform Circular Motion

SHM Simple Harmonic Motion revised May 23, 2017

Physics 103 Newton s 2 nd Law On Atwood s Machine with Computer Based Data Collection

Rotational Dynamics. Introduction:

Kinematics Lab. 1 Introduction. 2 Equipment. 3 Procedures

Physical Pendulum, Torsion Pendulum

Conservation of Energy and Momentum

Incline Plane Activity

Physics Labs with Computers, Vol. 1 P23: Conservation of Angular Momentum A

PHY 221 Lab 9 Work and Energy

SAMPLE FINAL EXAM (Closed Book)

Physics 4A Lab: Simple Harmonic Motion

Lab 10 Circular Motion and Centripetal Acceleration

Static and Kinetic Friction

PHYSICS LAB Experiment 9 Fall 2004 THE TORSION PENDULUM

LAB 5: Induction: A Linear Generator

Lab 8: Centripetal Acceleration

Atwood s Machine: Applying Newton s Second Law (approximately 2 hr.) (10/27/15)

Big Ideas 3 & 5: Circular Motion and Rotation 1 AP Physics 1

Work and Energy. This sum can be determined graphically as the area under the plot of force vs. distance. 1

1 M62 M62.1 CONSERVATION OF ANGULAR MOMENTUM FOR AN INELASTIC COLLISION

Transcription:

L07 Rotational Motion and the Moment of Inertia 1 Pre-Lab Exercise Full Name: Lab Section: Hand this in at the beginning of the lab period. The grade for these exercises will be included in your lab grade this week. In class we derived the moment of inertia about the center of mass of a homogeneous rod of mass M, length L and width W to be I cm rod = (1/12) M L 2. Now, derive the expression for the moment of inertia about the center of mass of a homogeneous rectangular plate of mass M, length L and width W and show that I cm plate = (1/12) M [ L 2 + W 2 ] As shown below, consider the plate as being made up of an infinite number of differential rods, each of mass dm, length L, and width dy, and each having a moment of inertia about their own center of mass given by di cm = (1/12) dm L 2. By using the Parallel Axis Theorem, each differential rod has a moment of inertia about the axis P given by dip = di cm + dm h 2 where h is equal to y. Since we are dealing with a homogeneous plate, you can relate the mass dm to its area da = L dy as the total mass M is related to the total Area (L W) and then sum all dip. Show all work here.

L07 Rotational Motion and the Moment of Inertia 2 Rotational Motion and the Moment of Inertia Full Name: Lab Partners Names: Lab Section: Introduction: This experiment deals with some of the characteristics of rotational motion. You will be using the relations between linear variables (x, v, a, F) and angular variables (θ, ω, α,τ) as well as the angular equivalent of Newton s Second Law (τ = I α) throughout this experiment. In doing so, you will determine the moment of inertia of a plate and an aluminum disc both experimentally and by calculation. Materials Pasco Rotary Motion Sensor with pulley Aluminum Disc 50 g hanger. Rectangular plate Meter stick Balance Vernier Calipers Set of Masses Procedure: 1. Calculate the Moment of Inertia of the Plate and Disc at their center of mass points. Record all your information below and in the table on page 6. 1.1 Find and record the mass and radius of the aluminum disc. Calculate its moment of inertia. Aluminum Disk: Mass (kg) Radius I (kg*m^2) 1.2 Measure the mass, length and width of the aluminum plate. Calculate its moment of inertia. Record the ID number that is stamped on the plate. Rectangular Plate ID Number : Mass (kg) Length Width I (kg*m^2) 1.3 Find the radius of the large and small pulley by first finding the diameters using a vernier caliper. Radius Small Pulley Large Pulley

L07 Rotational Motion and the Moment of Inertia 3 2. Setting Up the Equipment: 2.1 The aluminum disc is free to rotate about an axis as shown below. It passes through a rotary motion sensor and is attached to a small shaft and a pulley. The sensor can measure the shaft s rotation as a function of time. A light cord is wrapped around the pulley and is attached to a hanging hook weight. The hook weight which is held at rest and then is let go, moves downward with a constant acceleration. 2.2 Connect the Science Workshop interface to the computer, turn on the interface and then turn on the computer. This may have already been done for you. 2.3 Open the Data Studio software package by double clicking on the icon from the desktop menu. 2.4 In the Experiment Setup screen doubleclick the Rotary Motion Sensor picture. This will add it to the interface box diagram, showing the proper connections. Connect the leads as indicated. 2.5 Click on the Rotary Motion Sensor icon in the wiring diagram. Under the General tab, set the sample rate to 50 Hz (fast). Under the Measurement tab, select Angular Velocity (rad/s). Close the setup window. 2.6 Under the Displays Menu on the lower left, select an angular velocity vs time graph. 2.7 The rotary motion system (pulley and detector) should be assembled for you when you enter the lab. Thread the cord through the hole in the side of the pulley. At first, the cord should be wrapped on the larger pulley. Connect the other end to the mass hanger.

L07 Rotational Motion and the Moment of Inertia 4 3. Calculating the Moment of Inertia for the Systems: 3.1 Draw an extended free body diagram (EFBD) below for the disc-shaft-pulley and an FBD for the hook weight mass point M H. 3.2 From the free body diagrams above, write Newton s 2nd Law for the pulley system (Eq. 1) and for the hook weight (Eq. 2). 3.3 Express the linear acceleration of the hook weight in your Eq. 1 in terms of the angular acceleration, α of the pulley system and rewrite it as Eq. 3. 3.4 Add your Eq. 3 and Eq. 1 equations and solve for the moment of inertia, I of the system. Your equation for I should only be a function of the hanging mass MH, the radius of the pulley R, the angular acceleration α, and g.

L07 Rotational Motion and the Moment of Inertia 5 4. Measuring angular accelerations: 4.1 With just the pulley attached to the rotary motion detector, wind the string on the large pulley. Place the hook weight on the string hanging off the pulley making sure that it is stationary and start collecting data for a few seconds before letting the mass fall. Stop collecting data just after the mass hits the bottom. The first portion of your graph indicates the initial descent of the 50 gram hook weight. 4.2 Select a portion of the sloping straight line on the angular velocity vs. time graph and perform a linear fit on it using the fit/linear command in the menu immediately above the graph. Note the slope. It represents the angular acceleration of the rotary detector. Label it as α det and record it in the table below as Run 1. 4.3 Repeat steps 4.1 & 4.2 with the rectangular plate fastened to the pulley so that the plate s center of mass lies on the axis of rotation. The slope represents the angular acceleration of the plate and the rotary detector. Label it as α plate + det and record it as Run 2. 4.4 Repeat steps 4.1 & 4.2 with the aluminum disc fastened to the pulley system so that its center of mass lies on the axis of rotation.. The slope represents the angular acceleration of the disc and rotary detector. Label it as α disc + det and record it as Run 3. 4.5 Repeat 4.1 thru 4.4 with the cord wound on the small pulley this time. Record the angular accelerations as Runs 4, 5, and 6 respectively. 4.6 Print Run 1,2 & 3 graphs with all 3 slopes displayed and include them in your post lab report. 5. Finding the Moment of Inertia of the Plate and Disc Experimentally: 5.1 The moment of inertia of just the plate, I plate, can be calculated using your equation in 3.4 by finding an expression for I plate + det minus I det. Write this expression here. It will be a function of m h, g, r, α plate and α det. Do the same and write an expression for just the disc. 5.2 Calculate and record I plate I disc and I det. On a separate page stapled to this writeup, show all your detailed calculations for a) I plate using data from Runs 1 & 2, and 4 & 5, b) for I disc using data from Runs 1 & 3 and 4 & 6, and c) for I det using your Run 1 data. 5.3 Find the percent difference between your experimental moments of inertia of the plate and of the disc, and your calculated values as the accepted value.

L07 Rotational Motion and the Moment of Inertia 6 Plate ID Number: Disc Mass (g) = Plate Mass (g) = Disc Radius = Plate Length = I calc disc (kgm 2 ) = Plate Width = Small Pulley Radius = cm I calc plate (kgm 2 ) = Large Pulley Radius= cm 5.4 What physical reasons might there be for the difference in 5.3?

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