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Professional Development Program
On
Program Dates : 23rd to 25th January 2014. Venue : Hotel Radha Regent, Chennai.
By Dr. Richard Lundstrom
This seminar will present an introduction to Vehicle Dynamics from a
vehicle system perspective. The theory and applications are associated with
the interaction and performance balance between the powertrain, brakes,
steering, suspensions and wheel and tire vehicle subsystems. The role that
vehicle dynamics can and should play in effective automotive chassis
development and the information and technology flow from vehicle system
to subsystem to piece-part is integrated into the presentation. Governing
equations of motion are developed and solved for both steady and
transient conditions. Manual and computer techniques for analysis and
evaluation are presented. Vehicle system dynamic performance in the
areas of drive-off, braking, directional control and rollover is emphasized.
The dynamics of the powertrain, brakes, steering, suspension and wheel
and tire subsystems and their interactions are examined along with the
important role of structure and structural parameters related to vehicle
dynamics. Physical experiments, applicable to vehicle dynamics are also
introduced.
Learning Objectives
By attending this seminar, you will be able to:
Summarize how vehicle dynamics is related to the voice of the
customer
Identify important vehicle system parameters useful for effective
application of vehicle dynamics to chassis development
List and explain parameters that effect vehicle performance relative to
drive-off, braking, directional control and rollover
Identify physical measurements needed to effectively apply vehicle
dynamics to passenger cars and light trucks
Define the value of vehicle dynamics simulation in the development
and evaluation of vehicles
Explain the balance required between ride, directional control and
rollover and the essential process for this balance to be obtained for
marketplace vehicles
Who Should Attend
Automotive engineers and quality professionals who work in
product design, testing, quality, process or development will
benefit from attending.
Prerequisites
Participants should have an undergraduate engineering degree
and some exposure to vehicle dynamics.
Topical Outline
DAY ONE
The Role of Vehicle Dynamics in Passenger Car and Light Truck
Product Development
Vehicle Dynamics and the Voice of the Customer
o Use of QFD to manage vehicle dynamics performance in
drive-off, braking, ride and handling
o Thinking systemically about automotive chassis design
and development through the logic of vehicle dynamics
Effective Metrics for Vehicle Dynamics
o Vehicle system, subsystem and piece-part metrics used to
link vehicle dynamics to vehicle system design and
development: bounce frequencies, lateral acceleration
gain, understeer gradient, roll gradient, roll stiffness, etc.
Tire Fundamentals: Tire Wheel System Anatomy and
Architecture, Tire Axis System, Parameters and Characteristics
Elementary Tire Patch Forces and Moments: Forces and
Moments at the Tire Contact Patch During Steady Braking,
Steady Cornering and Steady Drive-Off Manoeuvres.
Acceleration (Drive-Off) Performance
o Basic powertrain system anatomy and architecture
o Power limited and traction limited drive-off including
powertrain system dynamics required to produce vehicle
motive force at the tire patch
o Road load considerations: aerodynamic resistance, rolling
resistance, grade resistance
o Performance prediction in acceleration and fuel economy
DAY TWO
Braking Performance
o Basic brake system anatomy and architecture
o Braking dynamics: braking forces, weight transfer, center of
weight, brake force distribution, stability
o Pedal force gain, brake proportioning, braking efficiency,
anti-lock braking systems
o Tire - road limitations
o Federal requirements for braking performance
o Brake system performance prediction
Ride Fundamentals
o Input excitation signals: road roughness, vehicle sources
(tire/wheel system, driveline and engine)
o Vehicle response properties: suspension isolation, tire
vertical stiffness, spring rate ratio, suspension stiffness, ride
rate, suspension damping, pitch and bounce frequencies
o Quarter vehicle and pitch plane ride simulations
o Ride performance prediction based on flat ride criteria
DAY THREE
Cornering Fundamentals
o Low speed turning
o High speed cornering: tire forces, Bundorf bicycle model,
understeer gradient, characteristic speed, lateral
acceleration gain, yaw velocity gain, side-slip
o Suspension effects on cornering: tire cornering stiffness,
camber thrust, roll steer, lateral force compliance steer,
aligning torque, lateral load transfer, steering system
o Experimental methods for vehicle handling development
Suspension Systems
o Suspension system anatomy and suspension system
performance requirements relative to drive-off, braking,
ride and handling
o Solid live axles, twist beam suspensions and independent
suspensions
o Side view pitch poles and pitch axis considerations: anti-
squat and anti-dive suspension geometry, wheel travel and
caster geometry
o Role axis considerations: roll center location, roll axis
geometry and location, wheel travel and toe geometry,
wheel travel and camber geometry
Steering Systems
o Steering system anatomy, architecture and performance
requirements
o Steering geometry, wheel geometry, steering system forces
and moments, steering ratio, steering compliance
o Experimental methods for steering system performance
evaluation and development
Roll-Over Fundamentals
o Vehicle system roll-over prevention requirements
o Elementary and suspended vehicle simulations
o Suspension system and steering system considerations
Introduction to CAE Applications for Vehicle Dynamics: CarSim
and sSNAP and Manual Analysis Methods.
Instructor Profile :
Dr. Richard Lundstrom is an independent research and project
engineer specializing in dynamic system engineering, automotive
chassis development , and application of the science of
improvement. He teaches Chassis Design, Systems Analysis and
Mechanical Control Systems at Kettering University, where he also
served as team leader for the annual Kettering Industry Symposium.
Dr. Lundstrom previously taught several mechanical engineering
courses, developed Vehicle Dynamics and Thermal System Design
courses, and founded and directed the Vehicle Dynamics Lab at
Lawrence Tech. He has worked as a product engineer with Ford
Motor Company and developed and taught a Fundamentals of
Vehicle Design course. Dr. Lundstrom is a member of SAE, ASME,
ASQ, ASEE and SCCA. He received a B.S. in Mechanical Engineering
from the University of Illinois, a M.S. from the University of Michigan
and a Ph.D. from Oakland University.
Professional Development Program
on
Vehicle Dynamics for Passenger Cars & Light Trucks
by Dr. Richard Lundstrom
From 23rd to 25th January 2014
at
Hotel Radha Regent,
Jawaharlal Nehru Road, Chennai.
Category Fee* per participant
SAEINDIA Members Rs. 15,500/-
Professional Participants Rs. 17,073/-
SAEINDIA Academia Members Rs. 9,000/-
Academia Participants Rs.10,236/-
Corporate Booking (5 members & above) 10% discount
Program Fee Details:
Please send the completed registration form along with a cheque on par or DD drawn in favour of SAEINDIA payable at Chennai or pay into SAEINDIA ICICI A/c No 000101202792 to the address :
Dy. Director - Marketing, No. 1/17 Ceebros Arcade, 2nd Floor, 3rd Cross St, Kasturba Nagar, Adyar, Chennai 600 020.
Tel: +91 44-2441 1904, 4215 2280, Mob: +91 94443 92613.
E-Mail us at: [email protected]
Registration Form
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Participants for this Program can apply forSAEINDIA membership online atthe website
www.saeindia.org
VehicleDynamicsforPassengerCars&LightTrucksby
Dr.RichardLundstromFrom23rdto25thJanuary2014
Vehicle Dynamics BrochureVehicle Dynamics_Reg formRegistration Form