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Automation

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Title: Automation


1
Automation
  • Year 2 Lecture 1
  • Dr Linda Newnes

2
Methods
  • Start at 3.15 p.m. finish at 4.05 p.m.
  • All videos / slides examinable
  • 1 question in exam from this work.
  • Questions at the beginning of each lecture from
    previous lecture notes. Please read before the
    lecture!
  • Groover and Zimmer, CAD/CAM, library shortloan.

3
Course contents
  • Manufacturing Automation
  • Automation Building Blocks
  • Hard Flexible Automation
  • Robotics
  • Manual Systems vs. Automated Systems

4
Typical areas of automation
  • Automotive Industry
  • Bomb Disposal
  • Surgery
  • Aerospace
  • Food
  • Pharmaceutical

5
Automation and Robotics in the Automotive Industry
  • Brief History and overview.
  • Applications
  • Case studies
  • Limitations
  • The future?

6
Brief History
1945 - Automation coined by Ford employee.
1962
1954
Present
1980s
1990s
1910
1913
1920 - 1940
1957
1970
1976
  • Present
  • Huge highly competitive industry. Drive for
    higher production rates, low cost high
    quality. Typically 200-300,000 cars per year per
    line.
  • Industry uses over 50 of all industrial robots
    globally 60 of these for spot welding.
  • 1910.
  • Cars built in small workshops
  • Skilled workers.
  • No automation.
  • High cost. Low volume. Up to 10 days per car.
  • 1913.
  • Mass production techniques introduced.
  • Large moving assembly line.
  • One task per worker
  • Standardised parts.
  • 1980-1990s
  • Sensor based machines
  • Integrated manufacturing systems
  • Unattended cells
  • AI
  • 1954
  • First highly automated factories
  • Ford reduces work force from 117 to 40
  • 1962
  • First industrial robot saw service
  • Stacking metal from die-casting m/c
  • 1970s
  • Microprocessors
  • Mini-computer control industrial robots
  • 1957
  • First commercially available NC machines
  • 1976
  • First spray painting robots
  • 1970
  • First integrated manufacturing system
  • First spot welding of auto bodies.
  • 1920- 40
  • Automatic transfer machines integrated into
    assembly lines.

7
Applications in the automotive industry
  • Positioners
  • General CNC
  • Welding
  • Spray painting
  • Assembly
  • Other

8
Limitations
  • Difficulty of getting information into a robot
    without human intervention.
  • The level of dexterity required for some
    operations is too high for current systems
  • The cost of some robots is prohibitive.
  • People are more flexible for production lines
    which change operations frequently.

9
Automation in the Bomb Disposal Industry
10
Introduction
  • Bomb technicians wear protective suits that
    reduce the effect of a blast but do not provide
    protection in all cases.
  • Bomb disposal units are increasing relying on
    robots.
  • Robots reduce or eliminate the technicians
    time-on-target.
  • A robot takes the risk out of potentially deadly
    scenarios.
  • Enables technician to focus fully on the bomb
    rather than the immediate danger.

Figure 1. Example of a bomb disposal robot.
11
History
  • Even before WWII a rope and hook procedure was
    used to move packages to less dangerous
    locations.
  • During the early 1970s remotely operated systems
    began to emerge to handle bomb threats.
  • The death of several bomb technicians over a
    short period of time in N.Ireland prompted
    development.
  • A remotely controlled electric wheelchair was
    developed. Fitted to carry several items of bomb
    disposal equipment.

12
Development
  • First robot was a battery operated wheelbarrow.
    Used to tow away suspect vehicles to safer areas.
  • Improved to have the ability to drop explosive
    charges into cars.
  • Further development with an improved chassis and
    four wheel drive.
  • Addition of closed circuit television camera for
    remotely viewing objects.
  • Wheels were replaced with tracks.
  • More improvements to tracks and manipulator arm
    had been produced.
  • A modified electric wheelbarrow had evolved to a
    tracked vehicle able to fire a disrupter, conduct
    surveillance and perform a number of other tasks.

13
Common Design Components
  • Manipulator
  • 2-3 joints
  • Large coverage area
  • Electrically powered
  • Replaceable
  • End-Effector
  • Usually 2-fingered gripper
  • 2 degrees of freedom
  • Integrated vision system
  • Manuverability Unit
  • Extremely versatile
  • Robust
  • Adaptive to terrain
  • Drive vision system
  • Features
  • Modular construction
  • Radio controlled
  • Multi-robot capable control systems

14
BRAT
  • Vision
  • BW drive cameras with halogen spotlights
  • Colour zoom camera with spotlights for
  • manipulator arm.
  • Manoeuvrability chassis
  • Wheeled or tracked module
  • Adjustable front tracks for stair climbing/
  • obstacle crossing
  • Electric power pack
  • End effector/arm
  • Interchangeable manipulator
  • arm/disrupter deployment module
  • Manipulator arm has 5 degrees of
  • freedom, including a rotating turret.
  • Package
  • Small and lightweight
  • Number of optional add-ons
  • High speed and robust

15
Future Developments
  • Increasing use of Explosive ordinance disposal
    robots
  • Mine Clearance
  • Surveillance and Reconnaissance
  • Hostage Rescue Observation Support
  • Nuclear, Biological, and Chemical Detection
    systems
  • Incorporation of leading edge technologies,
    e.g.. Virtual
  • reality head set control equipment
  • Robots becoming more compact and
  • versatile with development.
  • Artificial Intelligence?

Virtual reality equipment
16
Automation in the Electronics Industry
ltInsert Picturegt
17
Traditional Electronic Production
  • Reasons for Automation
  • Accuracy
  • Handling small components
  • Pick and Place
  • Repeatability
  • Consistent Processing
  • Minimise Human Error
  • Processing Speed
  • Assembly in Clean Environment
  • Harsh Environment
  • Hot solder
  • Acid Dip tanks
  • RSI - (Repetitive Strain Injury)
  • lt pictures of people soldering / assemblegt

18
Applications - Positioning of Components
  • Gripper
  • Mechanical (jaws)
  • Suction cup
  • Types of Drive
  • Electric
  • Pneumatic
  • Pick and place of components onto the circuit
    board
  • Robot configuration
  • Cartesian
  • SCARA

19
Applications - Soldering of Components
  • Conventional components / surface mount
  • Robot configuration Polar Coordinate
  • End Effector soldering iron with continuous
    solder feed
  • Electrically driven
  • Sensoring - Vision System

20
The Outlook - Micro Robots
  • Used for component assembly on PCBs
  • Pick and place of components
  • Soldering components
  • Control from central computer
  • Advantages
  • Simultaneous use of multiple robots
  • Robot paths can cross over
  • Robots can work in a team - communicate
    co-operate

21
Aerospace Industry
  • Aerospace Industry
  • Types of robot
  • End effectors
  • Common uses and applications

22
The Aerospace Industry
  • Aerospace Companies generally have
  • Very small production quantities.
  • A large quantity of active part numbers for both
    current and out of date models.
  • Very high tooling start-up costs.
  • High Labour content, with manually operated and
    manipulated tools.
  • Minimal opportunity to design for mechanism.
  • Highly developed use of CAD/CAM techniques.

23
Manufacture and Assembly
Final Assembly - Low Volume - Static
Build Component Manufacture - Higher
Volume - High Automation
24
Component Manufacture
  • High Volumes
  • \ Highly Automated
  • Electronic circuits/wiring
  • Seating
  • Small bought in parts
  • Consistent Accuracy
  • \ Highly Automated
  • Composite fibre lay-up
  • Parts with complex geometry

25
Aircraft Assembly
  • Dimensional / quality inspection
  • Airframe skin attachment
  • Painting
  • Jigless assembly
  • Refurbishment
  • Modifications
  • Cleaning

26
In General Across Aerospace
  • Companies Interested In Processing Capabilities
    As Opposed To Parts Handling
  • e.g.. Spray Painting etc.
  • Development towards Fully Integrated CAD / CAM
    Cells
  • Removing Human Link In Programming Robot
  • Hence Removing Error

27
Types of Robot Used
  • Articulated robotic arms (e.g. welding,
    inspection)

28
Types of Robot Used
  • Cartesian gantry (e.g. drilling holes for an
    aeroplane trail)

29
Types of Robot Used
  • Selective Compliance Automatic Robot Arms (e.g.
    sub assemblies, pick and place)

30
Aerospace Robotic End Effectors
  • CNC Aerodrill
  • Drill and fill
  • Fastner installation tool
  • Aerorouter
  • Fastner removal
  • Stem Shaver
  • Air router
  • Aeroquick change
  • Measurement tools

31
Common Uses and Applications
  • Industrial use focuses on process handling such
    as complex positioning and assembly
  • Drill and routing of aluminium sheet metal, also
    mating parts together and feeding the piece
    through an automatic riveter
  • Accurate finishing processes on engine parts e.g.
    turbine blades

32
Conclusion Future
  • Aerospace Industry Increasing
  • Competition in Air Travel
  • Lean Manufacture
  • Higher Level of Automation

33
Robotics in Surgery
  • The robots fit into one of two categories
    Passive or Active.
  • Passive devices rely on an external operator to
    move them.
  • Active devices move solely under computer control.

34
The Acrobot
  • This procedure requires high accuracy.
  • Acrobot is an active device but it is positioned
    by a passive one.
  • It uses the Active Constraint Principal.
  • Co-operates with surgeons by allowing them to
    work under force and spatial constraints.

35
The Bloodbot
  • The procedure is to take blood samples from the
    forearm.
  • Needle overshoot often occurs with the manual
    procedure.
  • Robot prevents overshoot.

36
Open-heart Surgery
  • Traditional
  • High patient trauma
  • High infection risk
  • Long recovery
  • Robot assisted
  • Ribs intact, far less trauma
  • Reduced infection risk
  • Increased precision

37
Neurophysiological Monitoring
  • Use of robotics
  • Electrodes inserted into brain for monitoring
  • Using robotics electrons can be positioned with
    accuracy of 50 microns
  • Electrons can be advanced through brain in steps
    of 1 micron

38
Laparoscopic Surgery
  • Robot assisted routine
  • Used for gall-bladder,gynecological,chest and
    abdomen pin-hole surgery
  • Robot hands manipulate fibre-optic light and
    camera while surgeon carries out surgery
  • Voice controlled robot can hold tools steadier
    and longer than a human equivalent

39
Advantages of Robotic in Surgery
  • Reduced costs after initial set-up
  • Less chance of complications
  • Eliminates surgeon fatigue and tremor

Robot training using sensorised glove
40
Future Advancements
  • Increase Autonomy, walking away from the
    master-slave approach.
  • Decrease operating times even further.
  • Expand the use of the technology into more
    hospitals.

41
Future Advancements
  • Increased dexterity.
  • Reduce size of the technology.
  • Future work involves the development of new
    technologies for producing powerful autonomous
    microrobots capable of moving within the human
    body.

42
The Use of Robots in Space
43
Space Robots
  • Space robots originally pictured as Humanoid or
    Mechanical Men
  • Nowadays applied to any device that works
    automatically, or by remote control.
  • Particularly devices programmed to perform tasks
    normally done by people
  • In space, robots perform tasks that are too dull,
    dirty, delicate or dangerous for people.

44
Space Robots - How they work?
  • Similar in design to terrestrial robots.
  • Each has controller, sensors, actuators, radio
    communications and power supply.
  • Differences between space and earth robots
  • Weightlessness. No need to support any weight,
    only required to apply accelerating /
    decelerating force, so can be much lighter.
  • Reliability. On-site repairs are costly and
    difficult. Robots have Orbital Replacement Units
    (ORU) to allow modular repairs
  • End effectors. Must have a hard contact point and
    a solid connection to prevent the target drifting
    away.

45
Space Robots Different types
  • Exploration Reconnaissance.
  • Space probes such as Galileo and Cassini fully
    merit the name of robots.
  • They perform programmed tasks over long periods
    without direct human supervision.
  • They operate in the vacuum of space withstanding
    exposure to radiation and extremes of
    temperature, where humans cannot explore.

46
Space Robots Different types
  • Exploration Reconnaissance.
  • Roving vehicles such as the Mars Sojourner
    explore planet surfaces autonomously, receiving
    periodic updates instructions.
  • Control module based on insect behaviour.
  • Modules are organised into a pecking order to
    avoid conflicts.

47
Space Robots Different types
  • Astronaut Assistance.
  • Robot Arm such as the Shuttle Remote Manipulator
    System.
  • Deploys payloads and captures free floating or
    stationary objects for maintenance repair.
  • All systems are designed to be maintained by
    humans.
  • The robots make use of the existing tools, spare
    parts handholds.
  • Consequently, space robots are designed to mimic
    human design movement.

48
Space Robots Different types
  • Astronaut Assistance.
  • Free Flying Television Camera.
  • Used for remote inspections of the exterior of
    space stations spacecraft.
  • Contains 2 TV cameras a floodlight.
  • Steered by 12 nitrogen thrusters.
  • Can operate continuously for 7 hours.

49
The Space Station Remote Manipulator System
(SSRMS) at the International Space Station (ISS).
50
Properties of the SSRMS.
  • Multi-purpose manipulator arm.
  • 17m long.
  • Handling capacity of 100,000 kg due to the use of
    Servo Power Amplifiers at the joints.
  • 3 segments and 7 joints combined with the ability
    to move along the Space Station give all over
    access for the primary use of servicing.

51
End Effector for the SSRMS.
  • Equipped with
  • Vision and force sensors.
  • Control systems for astronauts performing space
    walks.

52
Mobile Serving System (MSS)
53
Special Purpose Dexterous Manipulator (SPDM)
  • 15 degrees of freedom.
  • 600 kg mass handling capacity.
  • 3.5 m long.
  • 1662 kg.
  • Can attach to either the MBS or the SSRMS.

54
Orbital Replacement Unit/Tool Changeout
Mechanism (OTCM)
  • Keyed parallel jaws.
  • Retractable nut drive unit.
  • An offset camera and light.

55
In Summary
  • Various Applications.
  • Relevant and crucial to all industrial / other
    sectors.
  • In the next few weeks we will cover the building
    blocks.
  • Learn the correct vocabulary.
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