Springs and Dampers. MCE371: Vibrations. Prof. Richter. Department of Mechanical Engineering. Handout 2 Fall 2017

Similar documents
Deriving 1 DOF Equations of Motion Worked-Out Examples. MCE371: Vibrations. Prof. Richter. Department of Mechanical Engineering. Handout 3 Fall 2017

In the presence of viscous damping, a more generalized form of the Lagrange s equation of motion can be written as

Review: control, feedback, etc. Today s topic: state-space models of systems; linearization

Modeling and Simulation Revision III D R. T A R E K A. T U T U N J I P H I L A D E L P H I A U N I V E R S I T Y, J O R D A N

Introduction to Controls

Modeling and Simulation Revision IV D R. T A R E K A. T U T U N J I P H I L A D E L P H I A U N I V E R S I T Y, J O R D A N

Dynamic Modeling. For the mechanical translational system shown in Figure 1, determine a set of first order

1-DOF Forced Harmonic Vibration. MCE371: Vibrations. Prof. Richter. Department of Mechanical Engineering. Handout 8 Fall 2011

Modeling of Dynamic Systems: Notes on Bond Graphs Version 1.0 Copyright Diane L. Peters, Ph.D., P.E.

EQUIVALENT SINGLE-DEGREE-OF-FREEDOM SYSTEM AND FREE VIBRATION

Contents. Dynamics and control of mechanical systems. Focus on

EE Homework 3 Due Date: 03 / 30 / Spring 2015

ECEN 420 LINEAR CONTROL SYSTEMS. Lecture 6 Mathematical Representation of Physical Systems II 1/67

Chapter 8. Model of the Accelerometer. 8.1 The static model 8.2 The dynamic model 8.3 Sensor System simulation

Mechatronics Modeling and Analysis of Dynamic Systems Case-Study Exercise

Chapter 6. Second order differential equations

I Laplace transform. I Transfer function. I Conversion between systems in time-, frequency-domain, and transfer

2.004 Dynamics and Control II Spring 2008

LECTURE 14: DEVELOPING THE EQUATIONS OF MOTION FOR TWO-MASS VIBRATION EXAMPLES

Solutions for homework 1. 1 Introduction to Differential Equations

d = k where k is a constant of proportionality equal to the gradient.

MATH 312 Section 3.1: Linear Models

Appendix A: Exercise Problems on Classical Feedback Control Theory (Chaps. 1 and 2)

Problem 1: Find the Equation of Motion from the static equilibrium position for the following systems: 1) Assumptions

Mathematical Models. MATH 365 Ordinary Differential Equations. J. Robert Buchanan. Fall Department of Mathematics

Mathematical Models. MATH 365 Ordinary Differential Equations. J. Robert Buchanan. Spring Department of Mathematics

Wave Phenomena Physics 15c

ET3-7: Modelling II(V) Electrical, Mechanical and Thermal Systems

State Space Representation

Translational Mechanical Systems

Vibration Measurements Vibration Instrumentation. MCE371: Vibrations. Prof. Richter. Department of Mechanical Engineering. Handout 11 Fall 2011

Experiment 4 Oscillations

Systems of Ordinary Differential Equations

Mathematical Modeling and response analysis of mechanical systems are the subjects of this chapter.

I. Impedance of an R-L circuit.

1-DOF Vibration Characteristics. MCE371: Vibrations. Prof. Richter. Department of Mechanical Engineering. Handout 7 Fall 2017

Assignment 13 Assigned Mon Oct 4

P441 Analytical Mechanics - I. RLC Circuits. c Alex R. Dzierba. In this note we discuss electrical oscillating circuits: undamped, damped and driven.

Physics Fall Mechanics, Thermodynamics, Waves, Fluids. Lecture 20: Rotational Motion. Slide 20-1

Applications of Second-Order Differential Equations

MCE380: Measurements and Instrumentation Lab. Chapter 5: Electromechanical Transducers

Wave Phenomena Physics 15c

Formula Sheet. ( γ. 0 : X(t) = (A 1 + A 2 t) e 2 )t. + X p (t) (3) 2 γ Γ +t Γ 0 : X(t) = A 1 e + A 2 e + X p (t) (4) 2

Noise - irrelevant data; variability in a quantity that has no meaning or significance. In most cases this is modeled as a random variable.

SCHOOL OF COMPUTING, ENGINEERING AND MATHEMATICS SEMESTER 1 EXAMINATIONS 2012/2013 XE121. ENGINEERING CONCEPTS (Test)

Dylan Zwick. Spring 2014

Engineering Mechanics Prof. U. S. Dixit Department of Mechanical Engineering Indian Institute of Technology, Guwahati Introduction to vibration

Lecture Fluid system elements

Topic 5 Notes Jeremy Orloff. 5 Homogeneous, linear, constant coefficient differential equations

Differential Equations

Homework #5 Solutions

4.2 Graphs of Rational Functions

Module 24: Outline. Expt. 8: Part 2:Undriven RLC Circuits

Mechatronics 1: ME 392Q-6 & 348C 31-Aug-07 M.D. Bryant. Analogous Systems. e(t) Se: e. ef = p/i. q = p /I, p = " q C " R p I + e(t)

Phys 2025, First Test. September 20, minutes Name:

Differential Equations: Homework 8

PHYSICS 211 LAB #8: Periodic Motion

Chapter 14. PowerPoint Lectures for University Physics, Thirteenth Edition Hugh D. Young and Roger A. Freedman. Lectures by Wayne Anderson

AP Physics C Mechanics Objectives

Definition of differential equations and their classification. Methods of solution of first-order differential equations

Dynamics of Physical System Prof. S. Banerjee Department of Electrical Engineering Indian Institute of Technology, Kharagpur

2.5 Translational Mechanical System Transfer Functions 61. FIGURE 2.14 Electric circuit for Skill- Assessment Exercise 2.6

Computer Problems for Methods of Solving Ordinary Differential Equations

ELEC4631 s Lecture 2: Dynamic Control Systems 7 March Overview of dynamic control systems

Introduction to Mechanical Vibration

Lecture 13: Forces in the Lagrangian Approach

Worksheet for Exploration 10.1: Constant Angular Velocity Equation

Chapter 14. Oscillations. Oscillations Introductory Terminology Simple Harmonic Motion:

2.003 Engineering Dynamics Problem Set 4 (Solutions)

Capacitance. A different kind of capacitor: Work must be done to charge a capacitor. Capacitors in circuits. Capacitor connected to a battery

WPI Physics Dept. Intermediate Lab 2651 Free and Damped Electrical Oscillations

07/13/07 Name, Roster # Physics 152 Midterm 1

ME8230 Nonlinear Dynamics

APPLICATIONS OF SECOND-ORDER DIFFERENTIAL EQUATIONS

Modeling of Electrical Elements

REUNotes08-CircuitBasics May 28, 2008

ES205 Analysis and Design of Engineering Systems: Lab 1: An Introductory Tutorial: Getting Started with SIMULINK

2.4 Harmonic Oscillator Models

Chapter 6 DIRECT CURRENT CIRCUITS. Recommended Problems: 6,9,11,13,14,15,16,19,20,21,24,25,26,28,29,30,31,33,37,68,71.

=================~ NONHOMOGENEOUS LINEAR EQUATIONS. rn y" - y' - 6y = 0. lid y" + 2y' + 2y = 0, y(o) = 2, y'(0) = I

The basic principle to be used in mechanical systems to derive a mathematical model is Newton s law,

Physics 1C. Lecture 12B

Physics 405/505 Digital Electronics Techniques. University of Arizona Spring 2006 Prof. Erich W. Varnes

Passive control. Carles Batlle. II EURON/GEOPLEX Summer School on Modeling and Control of Complex Dynamical Systems Bertinoro, Italy, July

Current and Resistance

CHAPTER 12 OSCILLATORY MOTION

16.30/31, Fall 2010 Recitation # 13

dx n a 1(x) dy

EE292: Fundamentals of ECE

MCE603: Interfacing and Control of Mechatronic Systems. Chapter 1: Impedance Analysis for Electromechanical Interfacing

MATH 251 Week 6 Not collected, however you are encouraged to approach all problems to prepare for exam

PHY 3221 Fall Homework Problems. Instructor: Yoonseok Lee. Submit only HW s. EX s are additional problems that I encourage you to work on.

Problem info Geometry model Labelled Objects Results Nonlinear dependencies

Study of Electromagnetic Induction

Chapter 2 Vibration Dynamics

School of Engineering Faculty of Built Environment, Engineering, Technology & Design

Vector Basics, with Exercises

Review. Multiple Choice Identify the letter of the choice that best completes the statement or answers the question.

2.4 Models of Oscillation

Chapter 2 Second Order Differential Equations

Transcription:

MCE371: Vibrations Prof. Richter Department of Mechanical Engineering Handout 2 Fall 2017

Spring Law : One End Fixed Ideal linear spring law: f = kx. What are the units of k? More generally: f = F(x) nonlinear spring What physical elements obey f = F(x)?

Physical Elements with Approx. Linear Spring Laws

Damper Law : One End Fixed Ideal linear damper law: f = cv. What are the units of k? More generally: f = F(v) nonlinear damper What physical elements obey f = F(v)?

Rotational versions of linear element laws By linear spring we mean that the relationship between force (torque) and displacement (angular displacement) is direct proportionality By linear damper we mean that the relationship between force (torque) and velocity (angular velocity) is direct proportionality Linear and nonlinear springs and dampers can be designed for rectilinear or rotary motion. Rotary linear spring law: T = kθ. What are the units of k now? Rotary linear damper law: T = c dθ dt = c θ. What are the units of c now?

Equivalent Spring Constant: Parallel We now derive the equivalent spring constant for the arrangement of Fig.1.3-7 (a) in Palm: The equivalent spring constant of a parallel spring arrangement (common displacement) is the sum of the individual constants. That is, springs in parallel combine like resistors in series (capacitors in parallel).

Equivalent Spring Constant: Series We now derive the equivalent spring constant for the arrangement of Fig.1.3-7 (b) in Palm: The equivalent spring constant of a series spring arrangement (common force) is the inverse of the sum of the reciprocals of the individual constants. That is, springs in series combine like resistors in parallel (capacitors in series).

Mechanical-Electrical Analogy Spring Law: f = kx Ohm s Law: V = Ri Capacitor Law: V = (1/C)q If we interpret force as voltage and displacement as charge, there is an analogy between springs and capacitors: Note that force x displacement = work and voltage x charge = work. The power-based analogy is SPRING=CAPACITOR. This is usually done in the field of Mechatronics (MCE503/603/703).

Examples and Exercises 1 Read and understand Example 1.3-3 on your own. 2 In class: we explain/solve Ex. 1.3-5 and 1.3-7. 3 Recommended: 1.21, 1.23, 1.28, 1.36 and 1.41c. 4 Homework 1: 1.24, 1.25, 1.41b.

Equivalent Damper Constant: Parallel We now derive the equivalent damper constant for the arrangement of Fig.1.4-14 (a) in Palm: The equivalent damping constant of a parallel damper arrangement (common displacement) is the sum of the individual constants.

Equivalent Damper Constant: Series We now derive the equivalent damper constant for the arrangement of Fig.1.4-14 (b) in Palm: The equivalent damping constant of a series damper arrangement (common force) is the inverse of the sum of the reciprocals of the individual constants.

Mechanical-Electrical Analogies Damper Law: f = cẋ Ohm s Law: V = Ri Capacitor Law: V = (1/C)q If we interpret force as voltage and velocity as current, there is an analogy between dampers and resistors: Note that force x velocity = power and voltage x current = power. The power-based analogy is DAMPER=RESISTOR. This is usually done in the field of Mechatronics (MCE503/603/703). Also note that capacitors and springs conserve energy, while dampers and resistors dissipate it.

Examples and Exercises 1 Recommended: 1.47a. 2 Homework 1: 1.47b.

Methodology for Springs/Dampers with 2 Moving Ends Springs: k x l x r 1 Draw a pair of arrows for the displacements of the ends. Label them with two variables like x r and x l. It doesn t mean the spring always moves like that. It just says that when it does, the variables have positive values. If a calculation gave a negative value for a variable, you can interpret. 2 The directions of the arrows can be drawn as you please, but they are usually dictated by whatever is connected to the spring. Don t complicate yourself with weird choices. We ll do that in class once.

Springs with 2 Moving Ends... 1 Assume that the spring is in tension or compression (arbitrary choice). 2 Now you re committed to your earlier choices: Figure out which variable is larger than the other to match your tension/compression assumption. 3 Draw a pair of forces on the spring to match your assumption. 4 Write the expression for the force in the spring so that a positive quantity results for the force.

Examples Springs and Dampers Write the force equation for the following schematics x l k x r a. Compression b. Tension x l k x r a. Compression b. Tension

Dampers with 2 Moving Ends c ẋ l ẋ r 1 Draw a pair of arrows for the velocities of the ends. Label them with two variables like ẋ r and ẋ l. It doesn t mean the damper always moves like that. It just says that when it does, the variables have positive values. If a calculation gave a negative value for a variable, you can interpret. 2 The directions of the arrows can be drawn as you please, but they are usually dictated by whatever is connected to the damper.

Warm-Up Example: 2 Masses and 2 Springs Choose a positive direction for x 2. Make the tension/compression assumption and draw a free-body diagram accordingly. Apply Newton s Law to mass 2. F(t) k 1 x 1 k 2 m 1 m 2

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