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Introduction about the history and inspection of spherical robots in nuclear plants.Ball shaped robotsMain parts of the system.
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Ball-shaped robots to Inspect nuclear power plants
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CONTENTS
Introduction about the history and inspection of spherical robots in nuclear plants.
Ball shaped robots
Main parts of the system.
Propulsion system
Conclusions.
NEED OF ROBOTIC SYSTEMS
To perform automated and repetitive work.
Safety of workers and regulation.
Profitibility
ROBOTS USED FOR MONITORING
SIMON-developed in 1990.
MACS-developed in 1996.
UBIB –developed 1996.
ARIES-developed in 1999
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INSPECTION AND MAINTANENCE
Inspection of reactor vessel.
Underwater inspection.
Pipe inspection.
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Second Outline Level Third Outline
Level Fourth
Outline Level
Fifth Outline Level
Sixth Outline Level
Seventh Outline Level
Eighth Outline Level
Ninth Outline LevelHaga clic para modificar el estilo de texto del patrón
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Tercer nivel
Cuarto nivel
Quinto nivel
BALL SHAPED ROBOTS
Developed by Massachuttus Institute of Technology.
Harry Asada,Fond Professor of MIT.
Designed to efficiently enter the underground pipes.
About the size of an egg.
Inspection is done without digging up the buried pipes.
Signs of corrosion and leakage are detected.
Onboard camera takes images along the pipe’s interior.
Wireless underwater
communications across distances
of upto 100m.
Design and construction
Works on the principle of change in center of gravity.
Energy source-NiCd battery.
Same as hamster ball.
Moving eye ball mechanism.
Controlling speed of drive controls the speed of robot.
Mobility was provided by generating torque directly to the lever.
Revolutions are counted by an inductive sensor.
Large instrument board carries an onboard computer and interactivity tools.
Pulse encoders for motor
rotation measurement.
Sensors for temperature,pan,tilt and heading of inner mechanics.
Local server transmits control
using commands that are
kinematics-invariant.
Has an automatic localization
command.
User interface contains
virtual model for
communication between
remote user and a local system.
Main parts of the system
Sensors:
Gyroscope: It will be used to calculate the angular velocity of the roll angle of the ball.
Accelerometer: It will be used to measure the motor acceleration
Encoder: Used to measure
the rotational speed of the
motor.
Wireless camera.
Wireless camera node
A computer module.
Wireless LAN adaptor.
Wired LAN adaptor utilized for connecting image card.
CMOS camera with fisheye lens.
GPS locator.
System configuration of camera node
Prototype of wireless camera
Passive self-righting structure keeps the camera vertical.
Examples of captured view developed by wireless camera.
Main parts of the system
Processor & Software: Teensy++, based in Arduino Software..
Electronics Board: It integrates H-Bridge. Teensy, sensors and motor will be connected in it.
Power supply: Cells or batteries.
Motor: DC Motor with nominal
voltage between 12V-15V.
MATHEMATICAL MODEL
Model was established by using
o No rolling slip constraints.
o Conservation of angular
momentum.
o Algorithm motion planning
Spherical structure offer extra
- ordinary motion properties.
PROPULSION SYSTEM
No external propellers or rudders.
Smarter propulsion method.
A multi-axis thrust mechanism with a network of Y-shaped valves within the skin.
Creating a jet stream that propels robot in opposite direction.
Devised of special valve for switching direction of flow with a tiny change in pressure.
Advantages
Shorten the maintenance time and number of workers.
Allow inspection without digging out the buried pipes.
Easy to handle, less power
consumption.
Overcome large obstacles since
it is small in size.
Conclusion
Asada’s ball shaped robot’s system
has a simplicity, which is very
attractive.
For inspecting tight,confined spaces.
Able to withstand a reactor’s environment and can transmit images in real time for within.
references
A.Halme,T.Schonberg,Y.Wang,Motion control of a spherical mobile robot in 4th IEEE International Workshop on Advanced Motion control.
Ferriere,L, Raucent. B”Automation RollMOBS,A New universal Wheel concepts”.1998 IEEE conference on Robotics and A
R.E Sharp and D.R Garlick ,”Radiation Effects on Electronic Equipment “for the nuclear power industry.1994.
“Industial Remote Inspection System”by E.B.Silveman,Proceedings of the Robotics and remote handling in Hostile Environments,National topical meeting ,American Nuclear Society 1984
Cavale .J(2009) Ball shaped robot online accessed .
http://trendsupdates.com/spherical-robot-looks-futuristic-but-is-amazingly-mundane/
accelerometer
Used to measure the motor acceleration.
Consists of 3D-MEMS sensing element.
Temperature sensor, internal oscillator and non-volatile memory.
BACK
encoder
Used to measure the rotational speed of the motor.
AEDA-3300 .
BACK
H-bridge
Inputs-
- supply voltage.
-PWM(30Hz).
- EN
-DI
Output-
-voltage to drive the motor.BACK
Power distribution
Lead acid batteries provide power.
Generates electricity by electrochemistry reaction.
BACK
motor
Used to control the attitude of
pendulum for rolling and
steering.
Gear boxes installed to increase
torque output.
BACK