magnetic particle flux tracking in river simulators
DESCRIPTION
Magnetic Particle Flux Tracking in River Simulators. Team 47: Ali Albayat Kyle Barringer James Butler Geoffrey Daniel Joe Sobeski. Magnetic Particle Flux Tracking in River Simulators. Team 47: Kyle Barringer, Geoffrey Daniel, Joe Sobeski , James Butler, Ali Albayat - PowerPoint PPT PresentationTRANSCRIPT
Magnetic Particle Flux Tracking in River Simulators
Team 47: Ali AlbayatKyle BarringerJames ButlerGeoffrey DanielJoe Sobeski
Magnetic Particle Flux Tracking in River Simulators
Team 47: Kyle Barringer, Geoffrey Daniel, Joe Sobeski, James Butler, Ali Albayat
Faculty Technical Advisor: Dr. A. Weston
Client: Little River Research & Design in Carbondale, Illinois
Contact: Mr. Steve Gough
KB
OutlineExecutive Summary
Background (KB)Organization & Responsibilities
(GD)Project Description
Subsystems (All)Time Management (AA/JB)Resources (JB)
Summary (JS)KB
Executive Summary-Project Background
Tracking particle flux through simulator
Provides more information
Less confined environment
Emriver Em2 model KB
Executive Summary- Organization & Responsibilities
Kyle BarringerElectrical / Computer Engineer
Project Manger
Optical sensor
James ButlerMechanical Engineer
Fluid Dynamics Effects
Joe SobeskiElectrical Engineer
Magnetic Speed & Position Sensor
Ali AlbayatElectrical Engineer
Magnetic Separation
Geoffrey DanielComputer Engineer
Microcontroller
Organizational Chart
GD
Executive Summary- Resources : Deliverables
Array of speed & position sensors
Analysis of best location for camera with MATLAB code to track particles
Design of magnetic separation technique
Arduino code
Fluid dynamic analysisGD
Project Description- Subsystems
(Existing sub-systems)
Simulated river with flowing water, dyes, and modeling media particles (JB)
Magnetic speed & position sensors
(JS)
Magnetic separation
(AA)
Camera-based optical sensor
(KB)
Microcontroller
(GD)
Box, supports, reservoir, pump, power supply, valve array, flow controller
Information output / display
(GD)Particle
information
Particle
informatio
n
Particle
informa
tion
(Sub-systems to be created) JS
Project Description- Subsystems : Speed and Direction Sensors
Sensors manufactured by Cherry Corporation intended for detecting non-magnetic ferrous objects
Sensors output a voltage when detecting the presence of a ferrous metallic object
Sensors operate by using the Hall Effect with a bias magnetic field
GS101205 sensor JS
Project Description- Subsystems : Speed and Direction Sensors
The Hall Effect is the voltage created when a magnetic field passes over a conductor
Typical Hall Effect sensors only measure the presence of a magnetic field
Particles are ferrous, not magnetic. Therefore a bias magnet is introduced.
This will allow us to detect the motion of the particles
JS
Project Description- Subsystems : Camera-based Optical Sensor
Digital Particle Image Velocimetry (DPIV)
Particle Tracking Velocimetry (PTV)
KB
Project Description- Subsystems : Camera-based Optical Sensor
Acquire images from a digital camera
Process images to locate particles of interest
Link particle locations from a series of images to form particle trajectories
MATLAB and free toolboxes from previous research
KB
Project Description- Subsystems : Fluid Dynamics
Develop a computer model for the Emriver River Simulator
Using MATLAB and InventorAnalyze a simple systemCompare to known dataGeneralizations and predictions will be madePredictions will be testedDetermination to the cause of instabilities
being the main goal
JB
Project Description- Subsystems : Fluid Dynamics
Sediment transport processes There are dozens of different transport models that can be generally grouped
by particles addressed, complexity of water sources, whether the model is steady state or dynamic, and time period modeled.
The flow regime and sediment transport characteristics of rivers are
systematically correlated to temporal and spatial changes in channel geometry and bed material size.
The total sediment load refers to the sediment transport rate and is defined as the total amount of sediment passing through a given channel cross-section per unit of time
Information on bed-material particle size is needed for a variety of qualitative and quantitative purposes. They include streambed monitoring, computations of flow hydraulics, and the advancement in understanding of stream processes.
JB
Project Description- Subsystems : Microcontroller
Small computer dedicated to doing one task
Can be embedded
Low voltage
Ex: TVs, toys, power tools, remote controls
GD
Project Description- Subsystems : Microcontroller
Arduino microcontroller
Cost-effective hardware / open-source software
Programmed to handle inputs and outputs GD
Project Description- Subsystems : Magnetic Separation
ElectrophoresisUses a potential difference to collect particles
in one areaMostly used in biological applications
AA
Project Description- Subsystems : Magnetic Separation
Use an electromagnet to collect particles in one area
Quantify the number of particles
AA
Project Description- Time Management
Draft ScheduleAA
Project Description- Time Management
List of ActionsJB
Project Description- Resources
Subsystem Item Description Quantity Cost Each ($) Subtotal ($)
Speed & Position Sensor
1 Cherry Corp. GS101205-ND sensor 5 17.05 85.25
2 Wires Variable On hand 0.00
Subtotal: 85.25
Electrophoresis
1 RE-07121 electromagnet 1 26.00 26.00
2 Wires Variable On hand 0.00
Subtotal: 26.00
Optical Sensor
1 HP Deluxe Webcam camera 1 40.00 40.00
2 Computer with MATLAB software 1 On hand 0.00
3 Computer with Arduino software 1 On hand 0.00
Subtotal: 40.00
Microprocessor
1 Arduino Duemilanove 1 24.95 24.95
2 Computer with Arduino programming software 1 On hand 0.00
Subtotal: 24.95
Fluid Dynamics
1 Pitot Tube-Style Flowmeter 1 79.00 79.00
2 Computer with MATLAB software 1 On hand 0.00
Subtotal: 79.00
Total 255.20 JB
SummaryOutline
Executive Summary
Project DescriptionSubsystem DescriptionsTime ManagementEstimated Costs
JS