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Automated Systems

Automated Systems. Standard Grade. What Is An Automated System?. A system in which computers are used to control machines and equipment For example: Traffic light system Robot arms in car manufacturing industry

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Automated Systems

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  1. Automated Systems Standard Grade

  2. What Is An Automated System? • A system in which computers are used to control machines and equipment • For example: • Traffic light system • Robot arms in car manufacturing industry • To control and monitor the temperatures of dangerous chemicals processes in such places as oil refineries

  3. Types of Automated System • Everyday automated systems: • Toaster, washing machine, fridge, etc • Robots: • Arms • Mobile

  4. The Need for Automated Systems • Hazardous Environment • Repetitive Tasks • Speed • Efficiency • Accuracy • Adaptability

  5. Sensors & Feedback • A sensor is used to detect something and then give feedback to computer • Feedback allows the computer to make a decision based on the information • Examples of sensors: • heat • light • collisions • proximity • magnetic fields • Pressure

  6. Signal Converters • A computer is connected to a device by a circuit called an interface. • The interface must be able to convert the computer’s digital signals to analogue signals if required. • This is done by a digital to analogue converter. • Signals can be changed in the other direction by an analogue to digital converter.

  7. Analogue Input/Output A/D & D/A Converters Analogue Signal A/D Converter Digital Data Processor 1 0 1 0 1 1 Signal Converters

  8. Real-Time Processing Example: • A nuclear power station uses an automated system to control temperature of the dangerous chemicals • The temperature rises above safe levels which could cause a major explosion • The system is not real-time and will get to the problem when it next gets the chance!

  9. Hardware & Software • ROM Software • ROM is faster to load than disk • But are more expensive • Embedded systems • Are a small computer inside a large piece of machinery (Like a washing machine or mobile phone) • Control languages • The programming language that is used to control the automated system

  10. Simulations • Used to model real-life situations • Training • Flight simulators • Practise • Emergency procedures • Testing • Car crash simulators

  11. Computer Aided Design (CAD) • Using specialised software and hardware to design anything from kitchens to cars. • Hardware used: • Graphics Tablet • Computer Software • High Resolution Monitor • Plotter

  12. Computer uses the information given to create the item Always perfect Computer Aided Manufacture (CAM)

  13. Automated Systems Standard Grade

  14. Robots : Stationary • Stay in one place all the time • e.g. used on factory assembly lines • Control programs are stored on disc or tape • Can be reprogrammed to do a different task

  15. Anatomy of Robot Arm • Some robots have parts that resemble human limbs Elbow Shoulder Wrist Waist Tool

  16. Tools • The ‘hand’ of the robot arm is specialised to the task the robot is programmed to do. • For example: • gripper • paint spray gun • welding electrode • suction cap • paint stripper • magnet

  17. Robots : Mobile • Robots which move are called mobile robots. • They use tracks, wheels or legs to move. • Good for getting to places that humans can’t, for example the Mars robot.

  18. Robots : AGVs • Autonomous Guided Vehicles • These are robots which move around factories following guides. • AGVs can practically work on its own.

  19. Guides • If a mobile robot is designed to move around a factory it may use guides • Guides can be • Magnetic: Magnetic strips are placed under the surface of the factory floor • Expensive but will not need to be replaced • Light: White lines are painted on floor and robot follows these with light sensors • Very cheap but can wear easily.

  20. A robot follows an instruction called a program Programs are written in High Level Language This is a language similar to everyday English. This program can be changed so robot can be used for other tasks, e.g. A robot arm that welds cars can be reprogrammed to paint cars Programmable

  21. DigiDog VacuumRobot Goalie Robot Other Robots

  22. The Future?

  23. Implications: Social • Retraining • Redundancy • Nature of the job • Increased leisure time

  24. Implications: Technical • Safety Precautions must be taken when using industrial automation • Workplace Design • With humans we need the right temperature, frequent breaks, low noise, etc • Automated systems don’t.

  25. Systems Analysis • Before designing a new factory a Systems Analysis needs to be carried out • A Systems Analyst looks at how various jobs are done manually and sees if these can be done by computer

  26. Factories of the Future • We now have very few people working in factories • This means that factories can be designed around the automated systems, not the humans

  27. High Initial Cost Purchasing equipment Modernising factory Long term savings Increased Productivity Wages Labour Intensive Relies on Workers Capital Intensive Uses expensive machinery Productivity Replacement Costs Implications : Economic £$£$£$£$£$£

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