MR3591 Syllabus - Fluid Power Systems And Industrial Automation - 2021 Regulation Anna University
MR3591 Syllabus - Fluid Power Systems And Industrial Automation - 2021 Regulation Anna University
MR3591 | FLUID POWER SYSTEMS AND INDUSTRIAL AUTOMATION | LTPC |
---|
3003
COURSE OBJECTIVES:
• To recognize the standard symbols and to understand the functions of basic fluid power generation and actuation elements.
• To realize the functions of fluid regulation and control elements and its typical uses in fluid power circuit and to acquire the practice on assembling the various types of pneumatic circuits
• To familiar and exercise the design procedure of various types of pneumatic and hydraulic fluid power circuits and to provide a training to create the various types of hydraulic circuits.
• To learn about the fundamentals of Programmable Logic Controller.
• To familiarize the Data Communication and Supervisory Control Systems.
• To realize the functions of fluid regulation and control elements and its typical uses in fluid power circuit and to acquire the practice on assembling the various types of pneumatic circuits
• To familiar and exercise the design procedure of various types of pneumatic and hydraulic fluid power circuits and to provide a training to create the various types of hydraulic circuits.
• To learn about the fundamentals of Programmable Logic Controller.
• To familiarize the Data Communication and Supervisory Control Systems.
UNIT I | FLUID POWER SYSTEM GENERATION AND ACTUATORS | 9 |
---|
Need For Automation, Classification of Drives - Hydraulic, Pneumatic and Electric –Comparison – ISO Symbols for their Elements, Selection Criteria. Generating Elements- Hydraulic Pumps and Motor Gears, Vane, Piston Pumps – Motors - Selection and Specification - Drive Characteristics – Utilizing Elements - Linear Actuator – Types, Mounting Details, Cushioning – Power Packs – Accumulators.
UNIT II | CONTROL AND REGULATIING ELEMENTS | 9 |
---|
CONTROL AND REGULATIING ELEMENTS
UNIT III | CIRCUIT DESIGN FOR HYDRAULIC AND PNEUMATICS | 9 |
---|
Typical Design Methods – Sequencing Circuits Design - Combinational Logic Circuit Design - Cascade Method – KV Mapping - Electrical Control of Pneumatic and Hydraulic Circuits - Use of Relays, Timers, Counters and PLC in pneumatics and hydraulics
UNIT IV | PROGRAMMABLE LOGIC CONTROLLER | 9 |
---|
Industrial Automation - Programmable Logic Controller - Functions of PLCs - Features of PLC - Selection of PLC - Architecture – IEC61131-3 programming standard and types - Basics of PLC Programming – Ladder Logic Diagrams – Communication in PLC – Programming Timers and Counters – Data Handling - PLC modules – Advanced motion controlled Multi Axis PLC
UNIT V | DATA COMMUNICATION AND SUPERVISORY CONTROL SYSTEMS | 9 |
---|
Industrial Data Communications -– Modbus – HART – DeviceNet – Profibus – Fieldbus – RS232- RS485- Modbus/ Modbus TCP/IP - mechatrolink – CAN – EtherCAT - Introduction to Supervisory Control Systems – SCADA - Distributed Control System (DCS) – Safety Systems – human machine interfaces - Total Integrated Automation (TIA) – Industry 4.0.
TOTAL: 45 PERIODS
COURSE OUTCOMES: Upon successful completion of the course, students should be able to:
CO 1: Recognize the various concepts of fluid power and PLC systems.
CO 2: Comprehend functions of fluid power and PLC systems.
CO 3: Explain the various standard fluid power circuits, functions, communication and IO details of PLC.
CO 4: Demonstrate the standard fluid power circuits and PLC based interfaces. CO 5: Construct the fluid power circuits and PLC based automation system.
CO 2: Comprehend functions of fluid power and PLC systems.
CO 3: Explain the various standard fluid power circuits, functions, communication and IO details of PLC.
CO 4: Demonstrate the standard fluid power circuits and PLC based interfaces. CO 5: Construct the fluid power circuits and PLC based automation system.
TEXT BOOKS:
1. Antony Esposito, “Fluid Power Systems and Control”, Prentice-Hall, 2006.
2. Peter Rohner, “Fluid Power Logic Circuit Design”, the Macmillan Press Ltd., London, 1979.
3. Frank D, Petruzella, “Programmable Logic Controller” McGraw – Hill Publications, Fourth Edition, 2016.
2. Peter Rohner, “Fluid Power Logic Circuit Design”, the Macmillan Press Ltd., London, 1979.
3. Frank D, Petruzella, “Programmable Logic Controller” McGraw – Hill Publications, Fourth Edition, 2016.
REFERENCES:
1. Lucas, M.P., “Distributed Control System”, Van Nastrand Reinhold Company, New York, 1986.
2. Mackay S., Wrijut E., Reynders D. and Park J., “Practical Industrial Data Networks Design, Installation and Troubleshooting”, Newnes Publication, Elsevier, First Edition, 2004.
3. Patranabis. D, “Principles of Industrial Instrumentation”, Tata McGraw-Hill Publishing Ltd., New Delhi, 1999.
2. Mackay S., Wrijut E., Reynders D. and Park J., “Practical Industrial Data Networks Design, Installation and Troubleshooting”, Newnes Publication, Elsevier, First Edition, 2004.
3. Patranabis. D, “Principles of Industrial Instrumentation”, Tata McGraw-Hill Publishing Ltd., New Delhi, 1999.
Comments
Post a Comment