Problem 3 ME 115 Final – Troy Topping. Initial Construction A box with m = 1250 kg is input to simulate the forklift Only half the mass is used since.

Slides:

Advertisements

Similar presentations

Advertisements

Practice Problem #1 A weightlifter bench presses 80kg (approx. 175lbs.) 0.75m straight up. a. How much work does she do, assuming constant velocity, in.

Physics 101: Lecture 8, Pg 1 Centripetal Acceleration and Circular Motion Physics 101: Lecture 08 l Today’s lecture will cover Chapter 5 Exam II Problems.

Fall Final Review WKS: WORD PROBLEMS. Average Speed 1. A rock is dropped from the top of a tall cliff 9 meters above the ground. The ball falls freely.

Mechanics Exercise Class Ⅲ

KINETIC ENERGY, WORK, PRINCIPLE OF WORK AND ENERGY

Motion p in red text #13.1 worksheet accelerated Speed activity.

Section 8-2: Kinematic Equations Recall: 1 dimensional kinematic equations for uniform (constant) acceleration (Ch. 2). We’ve just seen analogies between.

Goal: To understand angular motions Objectives: 1)To learn about angles 2)To learn about angular velocity 3)To learn about angular acceleration 4)To learn.

Angular Momentum of a Particle

Controlling a 3D Vehicle with Simulink Jeff Bender ME

Roller Coaster Dynamics-1: Energy Conservation

Using the Science Formula Page And Calculator Help

A propeller (arm length 1.2 m) starts from rest and begins to rotate

ROBOTIC DESIGN CHALLENGE Robotics and Automation Copyright © Texas Education Agency, All rights reserved.

Kinetic Energy A moving object has energy because of its motion. This energy is called kinetic energy.

Chapter 3 Energy. The Goal of this activity is to Introduce the student to the terms work, kinetic energy and gravitational potential energy, Illustrate.

ROTATIONAL MOTION AND EQUILIBRIUM

ESS 303 – Biomechanics Angular Kinetics. Angular or rotary inertia (AKA Moment of inertia): An object tends to resist a change in angular motion, a product.

Chapter C14 Conservation of angular momentum Problem S.2 Due Wednesday.

Motion and Point of Reference Motion is a ___________in _____________. Determining whether or not something has changed its position depends on your ___________.

Uniform Circular Motion (UCM) The object travels in a circular path with a constant speed. Its velocity is tangent to the circle and is changing due to.

CIRCULAR MOTION. Linear Motion d – distance (in meters) v – velocity (in meters/second) a – acceleration (in meters/second 2 ) Distance = 2  r.

CIRCULAR MOTION. WHAT IS UNIFORM CIRCULAR MOTION The motion of an object in a circle at constant speed. However, direction and therefore velocity are.

Goal: To understand Newton’s 2 nd law and its applications to motions. Objectives: 1)To learn about how accelerations work 2)To understand Newton’s Force.

 Force Due to Gravity. What’s the difference between Mass and Weight?  Mass (m) is the amount of material an object is made from. Also, mass is the.

Conceptual Physics Notes on Chapter 9 CircularMotion.

TAKS Objective 5 Motion, Forces and Energy Motion can be described as a change in an object’s position Average velocity (speed) is the change of position.

The center of gravity of an object is the point at which its weight can be considered to be located.

Instructions for using this template. Remember this is Jeopardy, so where I have written “Answer” this is the prompt the students will see, and where.

Which of the following angles equals 2p radians?

Six Flags Review JEOPARDY!.

QotD Make a list of what types of forces we have on Earth?

9 rad/s2 7 rad/s2 13 rad/s2 14 rad/s2 16 rad/s2

Uniform Circular Motion. Q: You are swinging a ball around in a circle on a string. Suddenly the string breaks. Where does the ball go? A) out from the.

Friday, October 30, 1998 Chapter 8: Center of Gravity Moment of Inertia.

Newton’s Laws 10min test q1 Motion direction pull Weight (force due to gravity – don’t just say ‘gravity’) Friction (opposite to the motion) Contact force.

Momentum & Angular Momentum. Momentum Example on pg 178 in chapter 9 packet.

Chapter 9 Circular Motion. Axis: The straight line about which rotation takes place Rotation: Spin, when an object turns about an internal axis Revolution:

Centrifugal and Centripetal Force

TAKS Objective 5 Force and Motion Day 13 Forces and Motion Forces can create changes in motion. Acceleration Deceleration What happens if I put force.

ADAMS Assignment 2 ME451:Kinematics and Dynamics of Machine Systems (Spring 09)

Rotational Motion Uniform Circular Motion 2 Conditions: Uniform speed Circle has a constant radius. Caused by acceleration!

Newton’s “4 th law”. Law of Universal Gravitation 1.Gravity is universal: ALL objects attract each other. 2.The force of gravity is directly proportional.

 Distance vs. Displacement  Speed vs. Velocity.

Get your software working before putting it on the robot!

Lecture 7Purdue University, Physics 2201 UNIMPORTABLE: #817EE11E, 4.00 #8279AE55, 2.00 #834C955A, 4.00 #83CA7831, 4.00 #841D4BD2,4.00.

ME 115 Final Spring 2003 Problem 2 By Luke Saxelby.

Today: (Ch. 8)  Rotational Motion.

Rotational Mechanics 1 We know that objects rotate due to the presence of torque acting on the object. The same principles that were true for what caused.

Goal: To understand angular motions

Goal: To understand Newton’s 2nd law and its applications to motions.

ENERGY EQUATIONS By the end of this presentation you should be able to: Calculate kinetic energy, work and power.

Kinetic Work Theorem Physics.

Perry Assistance for Senior Success

Newton’s Laws Of Motion

Find the velocity of a particle with the given position function

Chapter 6 Section 3 Inertia & Momentum

Newton’s 2nd Law for Rotation

Vector Problems.ppt Vector Problems.ppt.

Chapter 5 - Red Station 1. ……..…… …….…..

Kinetics of a particle.

Acceleration The rate at which velocity changes.

Do Now Heading: Newton’s 2nd Law

Chapter 12 Work and Energy

How to draw, read, and work with free body diagrams.

1. What is the force of gravity between a 3

3. a. What is the force of gravity between a 2

Objectives Define work in terms of energy.

Presentation transcript:

Problem 3 ME 115 Final – Troy Topping

Initial Construction A box with m = 1250 kg is input to simulate the forklift Only half the mass is used since this is a 2-d model and there are really 4 wheels Gravity is not turned off because we want to use mass

Model Assembled Wheels are put on the model with a radius of.1 meter Ground is put in and dimensional alignments are made

More Parts and Crate The rest of the forklift is simulated The center of gravity of the crate is properly oriented

Giving the Forklift Initial Velocity An initial velocity is given to the forklift This was unspecified in the problem – in the model –5 m/s is used

Metering Forces Force meters are put in for the wheels A decelerating motor is put on each wheel Since the linear deceleration was 3m/s^2, and the radius was.1 meters, an angular deceleration of –4.77 rev/s^2 was used

Final Model Running Here is the model running (not too well) At this point the reactions in the y-direction are small

Results I needed more time to generate a more accurate model The reactions determined in the system don’t seem reliable yet With fine tuning, this model might work better