MSD P15280 RIT HOT WHEELZ TEST BENCH. AGENDA ❖ Detailed Design Review ➢ Competition Benchmarking ➢ Mechanical ●Motor Mount & Baseplate ●Modular Cart.

Slides:

Advertisements

Similar presentations

Formula 1 Group Members: Quinn Collett Steve Godlewski Tobiah Halter Jeff Swanson Academic Advisor: Dr. Chien Wern June 4, 2003.

Advertisements

Feasibility Study of Replacing an Industrial Hydraulic Lift System with an Electro-Mechanical Lift System Critical Design Review Thursday, 21 September.

Engineer Training XL1200 Mechanics. Engineer Training XL1200 Mechanics Confidential 2 The XL1200 is both a Roll to Roll and a Roll to Sheet Printing Machine.

Chapter 19: Flexible Machine Elements

PACE Collaborative Project: Emerging Market Vehicle Transmission Design Team member: Anthony Smith Kevin Scott Decorian Harris Jacque Thornton Advisor:

Steering Columns.

R·I·T Kate Gleason College of Engineering Design of a Tensile Load Frame for a Scanning Electron Microscope Senior Design Project Project Manager.

Drive Train Ryan Barba Patrick Hickey Andrew Hill.

0 Beach Cities Robotics FRC Team 294 Summer Academy Motors and Gears July 20, 2008 Rick Wagner, Mentor, Beach Cities Robotics FIRST Team 294.

1. P09203 – 1kg Robotic Motor Module Gen 2 Platform This project is Sponsored by the Kate Gleason Foundation.  Team Members:  Lauren Farnsworth → Team.

PIT Crew Design Concepts By Dan Chapman, Tim Wilson, and Jon Miller December 11, 2002.

R I T Team Members: Dan Lester → Team Lead Chris Feuerstein → Lead Engineer/Electrical Lead Mike Schwec → Electrical Support Jacob Hillmon → Electrical.

Development of Laser Fuser Test Bed Project Number: P07501 Justin McMillan.

Motors: a System Approach Kurt Heinzmann DEKA Research & Development Corp. January 2007.

Vex 1.0 © 2006 Carnegie Mellon Robotics Academy Inc. Test Bed Assembly.

R I T Team Members: Nathan Boyer → Team Lead Brandon Howell → Power Electronics Engineer Brad Whitlock → Electrical Lead Joe Krisher → Mechanical Systems.

Team HazardHawk Team HazardHawk The HazardHawk Team HazardHawk 2008.

Airbag Automaton John Bailey Hattie Hiatt Chun Hau Low Jason Harwood Wayne Gallup Jason Canaday.

AUTOMATION & PRODUCTION TECHNOLOGY. PROJECTS Students learned about group dynamics and the Engineering Design Process How can we build the tallest structure.

12/7/2004 AME470 Ltd. - Team Pratham 1Open-Aid TEAM PRATHAM Team Leader: Matt Ryan Chief Engineer: Nick Martin Fabrication: Reed Langton CADCAM: Fraterno.

Engineer Training Mechanical Overview. Engineer Training Confidential 2 XL1500 is both Roll-to-Roll and Roll-to-Sheet Printer MachineXL1500-2mXL1500-3mXL1500-5m.

MSD P15280 RIT HOT WHEELZ TEST BENCH. AGENDA ❖ Review Problem Definition Material ❖ Review System Design Material ❖ Sub-System Design Review ▪Motor.

A Preliminary Design of the Rotator for the DES Simulator Stand February 28, 2008 Edward Chi Fermilab/PPD/MD.

Sponsor/Customer: Dr. Ferat Sahin Multi Agent Bio-Robotics Lab Faculty Guide: Prof. George Slack Team Members: Matthew LeStrange – Electrical Engineering.

Redler Chain and Components

Openergo A self-build rowing machine

Design of a Robotic Manipulator for a Wheelchair Gateway Coalition Ohio State University Sinclair Community College Wright State University December.

Automated Bridge Scour Inspection FSU/FAMU College of Engineering Team 7 Concept Design Review 12/1/2010.

AVC COLLEGE OF ENGINEERING Mechanical Engineering DESIGN OF DRILL PCD ADJUSTABLE MECHANISM AND RESPECT MODIFICATION OF MULTI DRILLING MACHINE. Guided By.

Control System and Electrical Assembly Produced by Ed Latimer, Team 476 Ken York, Team 476 Ron Markum, Team

GEARMOTORS FOR INDUSTRIAL SECTIONAL DOORS GEARMOTORS FOR INDUSTRIAL SECTIONAL DOORS.

Development of the Mechanical Battery Dept of Mechanical & Industrial Engineering, TAMUK Faculty Mentor: Dr. Larry D Peel, P.E. Students: Javier A. Lozano,

D-R Compressor Cell RIT Senior Design Team P13458 Systems Design Review.

NCSX Modular Coil Turning Fixture FDR. Background Modular Coil winding forms are cast structures which provide the foundation on which the coils are constructed.

MKT May 2012 C850: Fast sliding gate operator. MKT May 2012 Summary  Why a fast slider operator?  USPs  Applications  Details  Technical specifications.

Flat Saw Training. Flat Saw Sizes –Low Horsepower Blade diameters range from 8” (200mm) to 18” (450mm) Power ranges from 4 to 25 horsepower.

+ P14043 – Smart Cane Phase 4 Lauren Bell Jessica Davila Jake Luckman William McIntyre Aaron Vogel.

LARP LHC PHASE II COLL RC1 TESTS - S. Lundgren 06 June 2006 No 1 /17 LARP Phase II Secondary Collimator RC1 Collimator Test Program Plan Forward Revised.

RADIATION SOURCE Design Review Dmitry Gudkov BE-BI-ML.

SAND SAMPLING APPARATUS Eglin Air Force Base Gina Teofilak Richard Klimas Dan Mortensen Ruben De Sousa.

P16221 – FSAE Shock Dynamometer Preliminary Detailed Design Review November 13, 2015.

GCS400 Lift & Tilt Dozer Control System

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

LEFB Belt Drive AC Servo

Mechanical Workshop FIRST Mid Atlantic Region January 2016.

Gates automation. Summary  Choosing the appropriate model  Faac Product Range (Sliding Gates)

Project Final Presentation Joe Featherall.

P16221 – FSAE Shock Dynamometer Detailed Design Review December 8, 2015.

Mechanical Power Transmissions II. Gear Ratios Gears are not just used to transfer power, they also provide an opportunity to adjust the mechanical advantage.

PROJECT PRESENTATION ON ELECTRICITY GENERATION FROM SPEED BREAKER

Concept Review - P08001 Balance Training Bicycle Team Members Jennifer Zelasko - IE Carl Mangelsdorf - ME Jeff Tempest - ME James Nardo - ME Jon Bawas.

Drive systems for livestock

ShingleBot Mechanical Design

Planetary Lander PDR Team Name

Design of Shaft References:

Asahi/America Electric Actuators Series 94.

ActivRAC® 16P Mobilized Storage System

Chris D. McCoy| Berkeley Mechanical Design

Angel Hambrecht, Justin Kibler, Nate Watts, and Maxine Laroche

ActivRAC® 7M Mobilized Storage System

Tigerbot VI Final Detailed Design Review

MSD P15280 RIT HOT WHEELZ TEST BENCH

Balance Training Bicycle 2.0 P10001

ActivRACTM 30P Mobilized Storage System

Asahi/America Electric Actuators Series 94.

Internal Mount Flange Facing Machine

FS ” Maximum Blade Capacity 9 HP Honda engine Weight – 141Lbs

Detailed Design Presentation

Enrobing+ wheelmachine 50Kg

Presentation transcript:

MSD P15280 RIT HOT WHEELZ TEST BENCH

AGENDA ❖ Detailed Design Review ➢ Competition Benchmarking ➢ Mechanical ●Motor Mount & Baseplate ●Modular Cart Design ●Motor Coupling Design ➢ Electrical ●Dyno Interface ●Sourced Components ●KGCOE Dynamometer Lab Quick Start Guide

Formula Hybrid Competition Benchmarking ❖ Variety of Designs ❖ Lack of Preparation ❖ Strenuous Inspection Procedure ❖ Attention to Detail is Critical

Formula Hybrid Competition Benchmarking ❖ 2+ Teams using Emrax Electric Motors ❖ Benchmarking the Motor Mounting

Formula Hybrid Competition Benchmarking ❖ Suggestion to use Rinehart Controller ➢ User Friendly ➢ Isolation Built-in ❖ PM kW Class ➢ 300 Arms Continous ➢ 350Arms Peak ➢ VDC

MECHANICAL

UPDATED DESIGN CONCEPT CONT.

Mounting Design Concept- Revision 1 Issues ❖ Easily change position to mount to the chain ❖ Adaptable to different configurations ❖ Failed FEA under maximum loading conditions ❖ Covered critical ports into the motor

Mounting Design Concept- Revision 2 ❖ More robust design ❖ 304 Stainless Steel ➢ 0.25” Baseplate ➢ 0.5” Upright Mount ❖ Incorporates proper hole pattern of the motor

Mounting Design Concept- Revision 2 ❖ Added Gussets for Strength in Bending at the base ❖ Fillet Welds will be used to join the gussets, the base plate and the upright mount

Mounting Design Concept- Assembly

Mounting Design Concept- Base Plate ❖ Slotted Base Plate to Match Current Dyno Mounting ❖ Allows for adjustability when lining up the chain ❖ 0.25” X 10” X 10” 304 Stainless Steel

Mounting Design Concept- Motor Mount ❖ 100 N/m Torque on Each Bolt Hole ~800 N/m combined loading ❖ 0.03 mm of Maximum Displacement ❖ Does not exceed yield strength of 304 Stainless Steel ❖ Minimum Factor of Safety of 2.5

Mounting Design Concept- Assembly

Mounting Design Concept- Moving Forward ❖ Detailed Budget ❖ Weight Minimization to use the same design on the car

DETAILED CART DESIGN ❖ A 30” X 60” cart was sourced from Global Industrial bases on the cost saving between building a cart and buying one. ➢ ~$700 for raw materials & mounting accessories ➢ ~$500 for base cart & mounting accessories ❖ Cart Specifications ➢ 1000 lb capacity ➢ 5” Wheel Diameter ➢ Removeable Handle can be mounted on either side

DETAILED CART DESIGN CONT. Cart Components & Mounting Controller

DETAILED CART DESIGN CONT. Battery Enclosures & Mounting Battery Specifications Width (in):9.65 Depth (in):14.09 Height (in):11.22 Quantity:4.00 Weight (kg):24.00 Weight (lbs)52.91 Total Weight (kg):96.00 Total Weight (lbs):211.64

DETAILED CART DESIGN CONT. Battery Enclosures & Mounting Battery AssemblyMounting Plate

❖ Waiting on CAD files & more dimensions of the Cart to finalize Motor Mount design dimensions ❖ Finish mounting hole pattern ❖ Finalize layout options for the Hot Wheelz Components NEXT STEPS

MOTOR COUPLING DETAILED DESIGN Current Dyno Existing Idler / tensioner system

MOTOR COUPLING DETAILED DESIGN ●Chain ○Heavy Duty, ⅝” pitch, 1620 lb working load ○Length TBD ●Idler Sprocket ○OD not critical ○Built-in bearing for ease of mounting to shaft *images from McMaster-Carr

MOTOR COUPLING DETAILED DESIGN ●Transmission Sprockets ○Hot Wheelz team gear ratio (2) ○Pinion (~4” OD) ■Keyway to fit motor output shaft ●Multiple keyways in consideration ●Unknown bore size ■ (20 teeth) ○Gear (flat, ~8” OD) ■Machinable to fit existing dyno mount ■ (40 teeth)

MOTOR COUPLING DETAILED DESIGN Pinion *images from McMaster-Carr Gear *images from McMaster-Carr

MOTOR COUPLING DETAILED DESIGN ●Idler ○Creating our own

MOTOR COUPLING DETAILED DESIGN ●Idler ○Fits existing dyno table hole pattern ■Slots allow for position adjustment ○Two springs provide tension to chain ○Height adjustable to take up chain slack ■Locked in place with 4 screws

ELECTRICAL

Sensor Sourcing

Overall Preliminary Wiring Diagram Dyno RoomControl Room Dedicated thermocouple DAQ

Custom PCB Diagram 1N5818: Schottky diode with maximum reversed voltage of 30V, and nominal forward voltage of ~0.5V L78S10CV: Linear 10V 2A voltage regulator Equivalent Resistances determined by maximum supply current for corresponding sensors

Wiring Harnesses Dyno-Control Harness Dummy Connector Sensor Terminal Harness Sensor-PCB Harness PCB-DAQ Harness -Twisted pairs for signal paths -Molex or APP connectors -18 AWG

❖ Quick Start Guide ■Document can be found on the P15280 edge site under /public/Final Documents ■Overview of the environment ●Dyno room & Controller room ■Steps to operate the Dyno without a DUT ●Manually with push buttons on Dyn-Loc IV Controller ●Digitally with RealTerm software. ■Problems encountered and discrepancies with official manual KGCOE Dynamometer Lab Quick Start Guide

QUESTIONS? FEEDBACK? SUGGESTIONS?