MSD P15280 RIT HOT WHEELZ TEST BENCH. AGENDA ❖ Review Problem Definition Material ❖ System Level Design Review ▪Functional Decomposition ▪Morphological.

Slides:



Advertisements
Similar presentations
Advanced Powertrain Research Facility Downloadable Dynamometer Database MSU September 9 th, 2013 Henning Lohse-Busch, Ph.D.
Advertisements

John Consiglio The Cooper Union February 24, 2009 Using Hardware-in-the-Loop Simulations to Improve EPA Emissions Testing.
Sophomore Design Class Automated Highway Simulation Group 2: Jeremy Sletten Patrick Murphy Michael Olson Randa Ibrahim.
PROJECT MEMBERS: COLIN PAYNE-ROGERS JACOB LENNOX Change of Resistance Test Stand PROJECT GUIDE/MENTOR: DR. BENJAMIN VARELA PRIMARY CUSTOMER: JOE MANAHAN.
Daniel Graves –Project Lead James Reepmeyer – Lead Engineer Brian Smaszcz– Airframe Design Alex Funiciello – Airfoil Design Michael Hardbarger – Control.
Team #2 Solar Car Project Senior Design
Pedal Purification University of Notre Dame Senior Design Group A6 November 28, 2006 Team Rallye (from left): Nicole Del Rey Eric Sabelhaus Mike McConnell.
BRAKE DYNAMOMETER DEVELOPMENT FOR DREXEL UNIVERSITY FSAE RACE TEAM MEM-01 Dr. Tein-Min Tan Frank DiMentoAlfredo Vitale Anthony TofaniJohn Henry.
Course Name : DESIGN OF MACHINE ELEMENTS
Measurement of force torque and pressure
Robotics Intensive: Day 6 Gui Cavalcanti 1/17/2012.
P11211: L AND V EHICLE FOR E DUCATION : C HASSIS, M OTOR, P OWER Ryan Sutton: Project Manager / Mechanical Engineer Jonathan Fabian: Interface Manager.
P11310: Parabolic Dish Autopoint Solution Project Family Team Leader: Trae Rogers (ME) Project Engineer: Pat Ryan (EE) Kyle Norlin (ME) Chris Reed (CE)
1. P09203 – 1kg Robotic Motor Module Gen 2 Platform This project is Sponsored by the Kate Gleason Foundation.  Team Members:  Lauren Farnsworth → Team.
Hybrid-Electric HMMWV: Platform for Advanced Lead Acid Battery Testing Future Work Dr. Herb Hess Adapt the thermal management system to the advanced lead.
R I T Team Members: Nathan Boyer → Team Lead Brandon Howell → Power Electronics Engineer Brad Whitlock → Electrical Lead Joe Krisher → Mechanical Systems.
Team Hybrid  Daniel Farley  John Hoyt  Sean Frost Hoyt.
Wind Instrument Testing Apparatus Project WITAP Team: Rob Koch Andy Lawrence.
Motor Coupling Design Review The 2004 Idaho Future Truck needs a system to couple the AC induction motor to the power train. + = Motor Future Truck Happy.
R I T Team Members: Dan Lester → Team Lead Chris Feuerstein → Lead Engineer/Electrical Lead Mike Schwec → Electrical Support Jacob Hillmon → Electrical.
Team Hybrid Hoyt MemberSubsystem Sean Frost Electric motor, motor controller, charge controller, charge accumulators Dan Farley Hydraulics system: Pumps,
MSD P15280 RIT HOT WHEELZ TEST BENCH. AGENDA ❖ Detailed Design Review ➢ Competition Benchmarking ➢ Mechanical ●Motor Mount & Baseplate ●Modular Cart.
MSD P15280 RIT HOT WHEELZ TEST BENCH. AGENDA ❖ Review Problem Definition Material ❖ Review System Design Material ❖ Sub-System Design Review ▪Motor.
Sponsor –UROP –ZWORLD Corp. –W. M. Berg Corp. Advisor –Professor David J. Reinkensmeyer.
Critical Design Review Wind Turbine with Gearbox
P14474: Hydrostatic Test Apparatus Jake Manley Anushka Kalicharan Mitchell Sedore Brian Benner Kyle Abbott.
Recruitment Info Session January 26 th, Agenda 2 The Team Our Goal Technical Organization Timeline Recruiting and Expectations.
Sponsor/Customer: Dr. Ferat Sahin Multi Agent Bio-Robotics Lab Faculty Guide: Prof. George Slack Team Members: Matthew LeStrange – Electrical Engineering.
Athletic Field Marking Device Anthony Cortese, Ryan Crump, Matthew Lawler, Patrick Shaughnessy (Team Leader), John Sudia.
Chapter 5 Engineering Tools for Electrical and Computer Engineers.
Acceleration Based Pedometer
Wearable Sensors Final Presentation Problem Background Inferred Transmission (short range) Bulky Design, hard to wear 20 Samples per second.
Automatic Shift Controls for ATV Sponsored by: Joel Notaro Polaris Industries Advised by : Professor George Slack Project Family: Modular, Scalable, Open.
Heather Beam Thomas Bean Megan Chapman Steven Geiger Kimberly Keating.
P16221 – FSAE Shock Dynamometer System Level Design Review September 29, 2015.
MSD P15280 RIT HOT WHEELZ TEST BENCH. AGENDA ❖ Project Background ❖ Project Summary ❖ Use Scenarios ❖ Customer Requirements ❖ Engineering Requirements.
Wind Turbine Design and Implementation. Team Members Members: Luke Donney Lindsay Short Nick Ries Dario Vazquez Chris Loots Advisor: Dr. Venkataramana.
Update of SAE J2908 Activities Mike Duoba Argonne National Laboratory 19 October
Daniel Bressan David Tran Robbie Banks Amit Kapoor MACH 1/7.
P16221 – FSAE Shock Dynamometer Preliminary Detailed Design Review November 13, 2015.
Subsystem Design Review P16203 Andre Pelletreau, Kerry Oliviera, Jeremy Willman, Vincent Stowbunenko, Kai Maslanka.
P16221 – FSAE Shock Dynamometer Problem Definition Review.
Thank You Sponsors. Thank You Sponsors Problem Statement Identification of Critical Subsystems Identification of Vehicle States Analysis of Vehicle States.
Presented By: Jeff Andrews Adrian Simon Jon Brownlow.
TEST PROCEDURE Testing the Controller Board, Power Supply Board, and Unit as a Whole.
E-NABLE Hand Test Rig P16061 David Schwartz, Tia Parks, Shannon Barry, Samantha Mason, Charles Rumfola.
P16680: AATech Universal Oil and Bag System System Design Review 9/29/15.
ECE4006 Senior Design Project Linda Milor and Jay Schlag
Project Final Presentation Joe Featherall.
January 16, 2009Senior Design I - System Level Design Review System Level Design Review Senior Design I Low Energy Printing Project P09505.
SYSTEM LEVEL DESIGN REVIEW P16318 Gaseous Mass Flow Rate Controller Luke McKean, Lianna Dicke, Selden Porter, Schuyler Witschi ?
14471 Vibration Test Apparatus: Systems Design Review Team Lead: Brett Billings Lead Engineer: Nicholas G Scribe: Ashley W EDGE: Claire Kobal Team Members:
Motor Assisted Wheelchair Design Review 10/01/15.
Lightweight Fuel Efficient Engine Package. Team Members Evan See, ME Chris Jones, ME John Scanlon, ME Stanley Fofano, EE Taylor Hattori, ME Brittany Borella,
HOW TO SELECT A SERVO SYSTEM
Wireless Bluetooth Controller For DC Motor. Introduction Wireless becoming more and more available and widely used Bluetooth is one of the major players.
P10203 LV1 MOTOR CONTROLLER FINAL REVIEW MAY 14, 2010 Electrical: Kory Williams, Adam Gillon, Oladipo Tokunboh Mechanical: Louis Shogry, Andrew Krall.
Mechanical Measurements and Metrology
Sensorless position control of direct driven hydraulic actuators Master’s thesis seminar presentation Tom Sourander Aalto University School of Engineering.
P07203 Dynamometry Laboratory Infrastructure
Baja Hybrid Drivetrain Design P14224
Baja Hybrid Drivetrain Design P14224
Kris Kidder | John Dolan | Shay Stanistreet | Anthony Miuccio
MSD P15280 RIT HOT WHEELZ TEST BENCH
SQUIGGLE NANOMANIPULATOR
P15661 Reciprocating Friction Tester Base Subsystem
ME 481 Engineering Modeling
P17452 Dresser-Rand System Health Monitor System Level Design Review
P15611: Digital Microfluidics Packaging
Wednesday, February 16, 4:00-6:00PM
Presentation transcript:

MSD P15280 RIT HOT WHEELZ TEST BENCH

AGENDA ❖ Review Problem Definition Material ❖ System Level Design Review ▪Functional Decomposition ▪Morphological Chart & Pugh Chart ▪Benchmarking ▪Concept Selection & Systems Architecture ▪Feasibility Analysis ▪Risk Assessment ▪Further Engineering Analysis Needed

PROJECT BACKGROUND ❖ The RIT Hot Wheelz Electric Vehicle Team is a group of all female undergraduate engineers who come together to form a team of innovative and creative race enthusiasts. ❖ The team seeks to enter the 2016 Formula Hybrid competition in the Electric-only class. ❖ A test bench is needed to test the drivetrain of the vehicle and ensure timely completion of the vehicle.

CUSTOMER REQUIREMENTS

PROJECT PLANNING

OPEN ITEMS FROM LAST REVIEW ❖ No existing design for Hot Wheelz electromechanical drive system ➢ Working closely with Hot Wheelz team to understand needs ❖ "Surrogate" customer ➢ Working well for us ❖ Interdependence between MSD team and Hot Wheelz ➢ Resolving issues as they arise and planning for future conflicts ❖ Budget unclear ➢ Working with customer to finalize budget Estimated Budget Powertrain Test Bench Labview Software$3, Electrical Components$3, Motor$2, Bench Components$ Mounting Hardware$ Powertrain to Bench Connection$ TOTAL9,500.00

SYSTEM LEVEL DESIGN

Functional Decomposition

Pugh Chart

PUGH CHART

BENCHMARKING- Dyno Visit ❖ Visit provided insight into loading mechanisms ➢ Eddy Current Brake ➢ Generator - Resistor Bank ❖ Sample GUI ➢ Easy to view dials ➢ Large window to view results ❖ Example of safety precautions ➢ Straps, fans, ventilation ❖ Output data as Excel file

BENCHMARKING- Example Test Benches ❖ Speed Control Test Bench (Left) ➢ Allows the study of the operation of a servodrive when a variety of loads are applied to the motor. ➢ Powder Brake to vary motor load ➢ Main Components: ■Motor Voltage ■Motor Temperature ■Load amount and type ❖ Motor Test Bench (Below) ➢ Robust, multi-compatible ➢ Flexibility through modular design ➢ Motor Torque, Power & Efficiency

SELECTED CONCEPT- MECHANICAL ❖ Two mechanical structures ➢ Mobile Cart to mimic Hot Wheelz Chassis ➢ Enclosed T-framed structure to house motors and moving parts ➢ UI will be located on top of the T-framed enclosure. ➢ All pieces are portable and compact Above: Preliminary CAD model of a 36in by 30in T-slot aluminum framing enclosure with two removable plexiglass panels for access and electrical attachment.

Selected Concept - Electrical User InterfaceLoading Mechanism Sensors MCU Hot Wheelz System

ELECTRICAL FEASIBILITY ANALYSIS ❖ How often will the tach counter need to be polled to avoid aliasing? ➢ max speed=4,500 rpm=75 rev/sec = Nyquist Rate of 150 Hz ➢ microcontroller will need to handle a count rate of 150 counts/second ➢ tach counter will need to be polled at a frequency greater than 150 Hz ➢ A frequency of 150 Hz should be no problem considering MCU can run up to 15MHz ❖ How close to real time can the data from the sensors be displayed on screen? ➢ Assuming uC clock runs at 15MHz -> 66.6ns/cycle ➢ Assuming max sample rate of 10us/sample ➢ Max clock cycles to obtain sample = less than 100 ➢ Max clock cycles to send data to computer = less than 100 ➢ Assuming baud rate of 115,200 bits/second ➢ Assumption that computer side delay is negligible ➢ Total time = (2x100x66.6x10^-9)+(12bits)(1/115200)+(10x10^-6) = 127us delay

MECHANICAL FEASIBILITY ANALYSIS- Load Calculations ❖ Determine Track Requirements (New Hampshire Motor Speedway) ➢ Longest Straightaway 77m ➢ Hairpin Turn- Minimum 9m Diameter ➢ Constant Turn- Minimum Diameter 30m ➢ Drag Race- 75m ❖ Determine Approximate Speeds and Acceleration Rates ➢ Max Endurance/Autocross Speed of 65-70MPH ➢ Hairpin Turns 10-15MPH (~1G) ➢ Constant Turns 25-30MPH(~1G) ➢ Drag Race 75MPH (~1.5G) ❖ Estimated Vehicle Parameters ➢ Mass = 340kg ➢ Wheel Diameter = 23 inches = m ➢ Friction Coefficient = 0.90 ➢ Drag Coefficient =0.95 ➢ Grade Angle = 4 degrees

MECHANICAL FEASIBILITY ANALYSIS- Load Calculations

MECHANICAL FEASIBILITY ANALYSIS ❖ Potential Hot Wheelz Motor Specs ➢ 250 Nm → 2500 RPM ❖ Proposed Test Bench Load Varying Motor ➢ 125 Nm → 5000 RPM ❖ 2:1 Gear Ratio Between Test Bench and Hot Wheelz Motor Test Bench: 2 X RPM ½ X Torque Hot Wheelz Motor: ½ X RPM 2 X Torque

MECHANICAL FEASIBILITY ANALYSIS ❖ Hot Wheelz Motor ~ $11,000 ❖ Proposed Test Bench Motor $ 2,500 → Within Test Bench Budget ❖ Will be able to vary loads similar to: ➢ Endurance Race Conditions ➢ Long Runs ➢ Most Autocross Race Conditions ❖ Will not be able to vary loads similar to: ➢ Drag Race ➢ Max Acceleration ❖ Still allows for testing most scenarios, check for safety, tune and debugging

Golisano Institute of Sustainability (GIS) Dynamometer vs. Hot Wheelz Test Bench Using the Existing GIS Dyno Pros:Cons: ●Capabilities: the machine already exists and has the capabilities that we need. ●Cost: we would not need to build a load varying system at all. ●Complexity: ensures project will be completed in one senior design session. ●Testing/Calibrating: decrease in magnitude of systems to test and calibrate. ●Availability of the Dyno: we would have to work by the schedule of the dyno to run testing and to work out integration issues. ●Location: drive system would have to be transported to dyno to run testing. ●Interface with dyno: concrete existing hardware and software, no flexibility; also would have to create partial chassis to allow testing. Using a Test Bench of Our Own Design and Construction Pros:Cons: ●Convenience: custom tailored to our specific need ●Expandability: bench would be an investment for future HW team vehicles. ●Availability: ability to use the device when needed without prior scheduling and arranging ●Cost: expensive to source a load varying device ●Timeframe: difficulty in adhering to strict schedule if problems arise ●Testing/Calibrating: increase in magnitude of systems to test and calibrate.

❖ Compromise between budget and load variance ❖ Test bench will have limited capabilities ❖ Max Load Testing will be done at GIS Dyno GIS Dynamometer vs. Hot Wheelz Test Bench

RISK ASSESSMENT Scale:

RISK ASSESSMENT Scale:

ENGINEERING ANALYSIS NEEDED ❖ Mechanical ➢ Safety Calculations ■Moving Objects ➢ Connection of Test Bench Motor to Vehicle Motor ➢ Structural Integrity Analysis ➢ Cooling Solutions for Motor ■Make vs. Buy Cost Analysis ❖ Electrical ➢ Control power dissipation method ➢ System Integration - Whether the test bench will communicate with Hot Wheelz electrical system to obtain results from its sensors

QUESTIONS? FEEDBACK?