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Mechatronics Introduction
- 1. Dr.S.Ganeshkumar Assistant Professor Mechanical Engineering Title of the subject : Mechatronics Topic: Introduction
- 2. Overview of syllabus and CO of the Course Introduction to mechatronics and System Concept of Mechatronics approach Need for Mechatronics Sensors and Transducers - Introduction 1 2 3 4 5 Chapter - 1 2
- 3. Discuss the interdisciplinary applications of Electronics, Electrical, Mechanical and Computer Systems for the Control of Mechanical, Electronic Systems and sensor technology. CO 1 CO 2 Discuss the architecture of Microprocessor and Microcontroller, Pin Diagram, Addressing Modes of Microprocessor and Microcontroller. CO 3 Discuss Programmable Peripheral Interface, Architecture of 8255 PPI, and various device interfacing 3
- 4. Explain the architecture, programming and application of programmable logic controllers to problems and challenges in the areas of Mechatronic engineering. CO 4 CO 5 Discuss various Actuators and Mechatronics system using the knowledge and skills acquired through the course and also from the given case studies 4
- 5. Introduction to Mechatronics 5 Mechatronics is a multidisciplinary branch of engineering that focuses on the engineering of both electrical and mechanical systems, and also includes a combination of robotics, electronics, computer, telecommunications, systems, control, and product engineering.
- 6. Definition of Mechatronics In 1996, Harashima, Tomizuka, and Fukuda defined mechatronics as being “the synergistic integration of mechanical engineering, with electronics and intelligent computer control in the design and manufacturing of industrial products and processes.” 6
- 7. Introduction to Mechatronics 7 Mechanical Engineering Electronics Engineering Mechatronics
- 8. 8 Examples of Mechatronics system in day to day life Watch gears Printed circuit boards Sensors etc.,
- 9. 9 Examples of Mechatronics system in day to day life
- 10. 10 Examples of Mechatronics system in day to day life
- 11. 11 Examples of Mechatronics system in day to day life
- 12. 12 Examples of Mechatronics system in day to day life
- 13. 13 Components of a Mechatronics system INPUT DEVICES CONTROLLERS OUTPUT DEVICES
- 14. 14 System MotorInput Electric Power Rotation A system is a collection of elements or components that are organized for a common purpose.
- 15. 15 Measurement System It has the input as the quantity being measured and the output as a measured value of that quantity. Thermometer Output (Number on scale) Input Temperature Sensing element sensor
- 16. 16 Elements of Measurement system Signal conditioner Output devicesSensor A sensor consists of transducer whose function is to convert the one form of energy into electrical form of energy. A sensor is a sensing element of measurement system that converts the input quantity being measured into an output signal which is related to the quantity. Sensors Temperature Sensor –Thermocouple Input –Temperature Output –E.M.F (Electrical Parameter).
- 17. 17 Signal Conditioner A signal conditioner receives signal from the sensor and manipulates it into a suitable condition for display. The signal conditioner performs filtering, amplification or other signal conditioning on the sensor output.
- 18. 18 Output devices A display system displays the data (output) from the signal conditioner by an analog or digital. A digital system is a temporary store such as recorder.
- 19. 19 Signal processing through microprocessors Input signal amplification and output signal modulation attained by microprocessors like Arduino, Rasberry Pi, Arduino Evive etc.,
- 20. 20 Elements of Measurement system Signal conditioner Output devicesSensor A sensor consists of transducer whose function is to convert the one form of energy into electrical form of energy. A sensor is a sensing element of measurement system that converts the input quantity being measured into an output signal which is related to the quantity. Sensors
- 21. 21 Mechatronic system Actuators Sensors Input signal conditioning and interfacing Digital control techniques Output signal conditioning and interfacing Graphical displays Example: Washing Machine
- 22. 22 System control – open and Closed Loops Open Loop control system
- 23. 23 System control – open and Closed Loops Closed Loop control system
- 24. 24 Elements of Closed Loop system Comparison unit Control unit Correction unit Process unit Measurement Device This element compares the required or reference variable condition being controlled with the measured value and produces an error signal This element decides the corrective action to be taken when an error signal received, Example – ON / OFF switch The correction element produces a change in the process to correct or change the controlled condition. An element that controls the process is called as process elements Measuring element produces signal proportional to the physical conditions
- 25. Input device that can detect physical condition such as temperature, pressure, etc., 25 INPUT DEVICES - SENSORS Sensors Best example of sensor is human ear A Mechatronic system utilizes sensors to detect the physical conditions
- 26. 26 Performance Terminologies – Precision and Accuracy Accuracy Precision Accuracy of a measurement is how close it is to the true value How consistent a series of value are with each other
- 27. 27 Performance Terminologies Resolution Sensitivity Minimum measurable value of the input variable Ability to detect small change in the quantity to be measured
- 28. Performance Terminologies Ability to detect small change in the quantity to be measured Sensitivity The minimum value of input below which no output can be appeared is known as threshold Threshold Error It is the difference between actual value and the indicated value of a measuring instrument 28
- 29. Repeatability Performance Terminologies Repeatability is the closeness of agreement among a number of consecutive measurements of the output for the same value of input under the same operating conditions Dead Zone Dead zone is the largest range of values of a measured variable to which the instrument does not respond. 29
- 30. Performance Terminologies Hysteresis Maximum difference for the same measured quantity between upscale and downscale readings during a full traverse in each direction. True Value The errorless value of the measured variable is known as true value. 30
- 31. Performance Terminologies Backlash Lost motion or free play of mechanical elements such as gears, linkages etc. 31
- 32. Performance Terminologies Bias The constant error which exists over the full range of measurement Tolerance It is the maximum allowable error in the measurement 32
- 33. Session Recap Introduction Applications System Mechatronic systems Open loop and Closed Loop Sensors Elements of Mechatronics systems Terminologies in performance of system 33