Lecture

Lecture - 36 Chromatography - II

This module continues the study of chromatography, focusing on advanced techniques and applications. Key topics include:

  • High-performance liquid chromatography (HPLC)
  • Mass spectrometry and its integration with chromatography
  • Applications in research and industry
  • Emerging trends and future directions in chromatographic techniques

Students will explore the advancements in chromatography and how they enhance analysis and quality control processes.


Course Lectures
  • Lecture -1 Introduction
    Prof. Alok Barua

    This module provides an introduction to the field of industrial instrumentation. It covers the fundamental concepts and terminologies that are crucial for understanding the course. Topics such as measurement range, span, settling time, and input impedance are introduced. The module sets the stage for exploring various instruments and their applications in industrial settings.

  • This module delves into the dynamic characteristics of instruments used in industrial settings. It explores how instruments respond to different types of inputs such as step, ramp, and sinusoidal. The focus is on understanding the behavior of first and second-order instruments, analyzing their response times, and determining their suitability for various applications.

  • This module continues the discussion on dynamic characteristics, delving deeper into the analysis of first and second-order systems. It further explores the mathematical modeling of these systems and their response to various inputs. The module aims to enhance the understanding of dynamic behavior and improve the selection process for specific industrial applications.

  • Lecture -4 Strain gauge
    Prof. Alok Barua

    This module introduces the strain gauge, a key component in measuring mechanical strain. It covers the derivation of the gauge factor, the use of strain gauge rosettes, and the application of unbalanced Wheatstone bridges. The module also discusses different load cell types, such as link, beam, and ring, emphasizing their sensitivities and use in industry.

  • Lecture -5 Load cell
    Prof. Alok Barua

    This module focuses on load cells, which are essential devices used to measure force and weight. It covers various types of load cells, including link, beam, and ring types, and discusses their specific applications. The module also examines the frequency response of link-type load cells and how these devices are integral in industrial settings for accurate force measurement.

  • This module explores torque measurement techniques in industrial instrumentation. It covers the use of torque cells and introduces data transmission methods such as slip rings and radio telemetry. The module emphasizes practical applications of torque measurement in industrial processes, ensuring accurate and reliable data collection.

  • Lecture -7 Thermistor
    Prof. Alok Barua

    This module discusses the thermistor, a temperature-sensitive resistor used in various applications. It covers the principles of thermistor operation, methods for linearization, and how thermistors are applied in temperature measurement. The module aims to enhance the understanding of thermistors' versatility and precision in different industrial contexts.

  • Lecture -8 Thermocouples
    Prof. Alok Barua

    This module explores thermocouples, devices used for temperature measurement in various environments. It covers the construction and types of thermocouples, their relative comparisons, and cold junction compensation techniques using devices like AD590. The module also discusses grounded thermocouples and their applications in industrial settings.

  • This module focuses on the Resistance Temperature Detector (RTD), a temperature sensor known for its precision and accuracy. It covers RTD construction, the three-wire and four-wire measurement methods, and the application of the Muller bridge. The module aims to provide a comprehensive understanding of RTDs and their use in industrial temperature sensing.

  • Lecture -10 LVDT
    Prof. Alok Barua

    This module introduces the Linear Variable Differential Transformer (LVDT), a device used for measuring linear displacement. It covers the working principle of LVDTs, phase compensation techniques, and phase-sensitive demodulation. The module highlights LVDTs' advantages in providing accurate displacement measurements in industrial applications.

  • This module examines capacitance transducers used for displacement and level measurement. It covers the principles of capacitance measurement, the push-pull arrangement, and the application of these transducers in various industrial contexts. The module provides insights into the advantages and limitations of using capacitance transducers.

  • Lecture - 12 Flowmeter - I
    Prof. Alok Barua

    This module focuses on flow measurement devices, introducing various types of flowmeters and their applications. It covers the fundamentals of venturimeters, orifice meters, and pitot tubes, analyzing their working principles and advantages. The module also discusses factors affecting flowmeter accuracy and selection criteria for different industrial processes.

  • Lecture -13 Flow meter -II
    Prof. Alok Barua

    This module continues the exploration of flow measurement devices, focusing on advanced techniques and types of flowmeters. It introduces the rotameter, electromagnetic flowmeter, and hot wire anemometer, detailing their principles and applications. The module emphasizes the importance of selecting the right flowmeter for specific industrial settings.

  • Lecture -14 Flowmeter -III
    Prof. Alok Barua

    This module delves into specialized flowmeters, discussing their unique features and applications. It covers variable reluctance displacement sensors, tachogenerators, and turbine flowmeters, explaining their operation and use in different industrial processes. The module aims to enhance understanding of these specialized devices and their roles in accurate flow measurement.

  • Lecture -15 Flowmeter -IV
    Prof. Alok Barua

    This module provides an in-depth look at flow measurement devices, focusing on the practical aspects of their implementation. It covers the challenges faced in real-world applications, solutions to common issues, and strategies for optimizing flow measurement efficiency. The module emphasizes the importance of continuous monitoring and calibration in maintaining measurement accuracy.

  • Lecture -16 Flowmeter -V
    Prof. Alok Barua

    This module concludes the series on flow measurement by summarizing key concepts and applications. It reviews the principles of volumetric flow rate expressions and velocity calculations, ensuring a comprehensive understanding of all types of flowmeters discussed. The module serves as a recap and reinforces the importance of accurate flow measurement in industrial processes.

  • This module presents a series of problems related to temperature sensors, providing solutions and insights into troubleshooting common issues. It covers various types of sensors such as thermocouples, thermistors, and RTDs, emphasizing practical techniques for improving measurement accuracy and reliability in industrial settings.

  • This module focuses on pressure sensors, exploring various device types and their applications in industrial environments. It covers Bourdon gauges, diaphragm gauges, and other pressure measurement techniques, discussing their advantages and limitations. The module aims to provide a comprehensive understanding of pressure measurement and its critical role in industrial processes.

  • This module delves into low-pressure measurement techniques, discussing the unique challenges and solutions involved in measuring low pressure. It covers various types of vacuum gauges and their applications, highlighting the importance of precision and calibration in ensuring accurate low-pressure measurements in industrial settings.

  • This module discusses the measurement of pH and viscosity, two critical parameters in industrial processes. It covers the principles of pH measurement, types of pH meters, and the methods used to measure viscosity. The module emphasizes the importance of accurate measurement for quality control and process optimization in various industries.

  • This module offers problem-solving exercises and solutions related to industrial instrumentation. It provides practical examples and challenges that reinforce the concepts learned throughout the course. The module aims to enhance critical thinking and problem-solving skills, ensuring that learners can apply their knowledge effectively in real-world situations.

  • This module covers the basics of signal conditioning circuits, focusing on their importance in industrial instrumentation. Signal conditioning involves the manipulation of signals to prepare them for the next stage of processing. Key topics include:

    • Types of signal conditioning
    • Amplification techniques
    • Filtering methods
    • Analog-to-digital conversion
    • Noise reduction techniques

    By understanding these concepts, students will gain insight into the essential role of signal conditioning in ensuring accurate and reliable measurements in various industrial applications.

  • This module delves deeper into signal conditioning circuits, expanding on the concepts introduced in the previous lecture. It will explore advanced topics such as:

    • Instrumentation amplifiers and operational amplifiers
    • Data acquisition systems
    • Signal processing algorithms
    • Dynamic range and resolution considerations
    • Real-world applications in various industries

    Students will learn how these advanced techniques improve measurement systems and ensure high-quality data acquisition.

  • This module introduces piezoelectric sensors, which convert mechanical stress into electrical signals. Topics covered include:

    • Operating principles of piezoelectric materials
    • Types of piezoelectric sensors
    • Applications in various fields such as robotics and manufacturing
    • Advantages and limitations of using piezoelectric sensors

    Students will learn how these sensors are employed in real-time monitoring and control systems, enhancing their understanding of sensor technology.

  • This module focuses on ultrasonic sensors, which utilize high-frequency sound waves for measurement applications. Key topics include:

    • Basic operating principles of ultrasonic sensing
    • Types of ultrasonic sensors
    • Applications in distance measurement, thickness gauging, and level detection
    • Advantages over other sensing technologies

    Students will gain insights into how ultrasonic sensors are applied in various industries and their effectiveness in non-contact measurements.

  • This module covers nucleonic instrumentation, focusing on the use of radioactive isotopes for measurement applications. Topics include:

    • Principles of nucleonic measurement
    • Applications in level measurement, density measurement, and thickness gauging
    • Safety considerations and regulatory aspects
    • Comparison with other measurement techniques

    Students will learn about the unique advantages of nucleonic instrumentation and the critical safety protocols associated with their use.

  • This module focuses on the measurement of magnetic fields, exploring various techniques and instruments used. Key topics include:

    • Types of magnetic field sensors
    • Measurement techniques (Hall effect, fluxgate sensors)
    • Applications in various industries (medical, automotive, manufacturing)
    • Impact of magnetic fields on electronic devices

    Students will gain a comprehensive understanding of how magnetic field measurements are conducted and their significance in ensuring safety and operational efficiency.

  • This module introduces optoelectronic sensors, which utilize light to detect and measure physical properties. Topics covered include:

    • Principles of optoelectronic sensing
    • Types of optoelectronic sensors (photodiodes, phototransistors)
    • Applications in environmental monitoring, industrial automation, and consumer electronics
    • Advantages and challenges of using light-based sensors

    Students will learn how optoelectronic sensors contribute to innovative measurement technologies across diverse fields.

  • This module continues the exploration of optoelectronic sensors, diving into more complex applications and technologies. Key topics include:

    • Advanced optoelectronic devices
    • Integration with other technologies for enhanced functionality
    • Case studies of optoelectronic sensors in real-world applications
    • Future trends in optoelectronic sensing technology

    Students will develop a deeper understanding of the innovations in optoelectronic sensors and their emerging roles in various industries.

  • Lecture - 30 Synchro
    Prof. Alok Barua

    This module focuses on synchro devices, which are used for angular position measurement in various applications. Topics include:

    • Types of synchros and their operating principles
    • Applications in military, aerospace, and industrial sectors
    • Advantages of synchros over other position sensors
    • Calibration and troubleshooting techniques

    Students will gain practical knowledge on how synchros function and are applied in critical systems.

  • This module introduces dissolved oxygen sensors, essential for monitoring oxygen levels in various applications. Key topics include:

    • Operating principles of dissolved oxygen measurement
    • Types of dissolved oxygen sensors (galvanic and polarographic)
    • Applications in water quality monitoring, aquaculture, and wastewater treatment
    • Calibration methods and data interpretation

    Students will learn the significance of dissolved oxygen in environmental monitoring and how sensors are used to ensure compliance with standards.

  • This module continues the study of dissolved oxygen sensors, focusing on advanced applications and technologies. Key topics include:

    • Innovative designs and technologies in dissolved oxygen sensing
    • Integration with data logging and remote monitoring systems
    • Case studies highlighting the use of these sensors in various industries
    • Future developments in dissolved oxygen measurement technology

    Students will explore how advancements in sensor technology enhance environmental monitoring practices.

  • This module focuses on the flapper-nozzle system, a critical component in control systems for fluid dynamics. Topics include:

    • Principles of operation and design
    • Applications in aviation, robotics, and industrial processes
    • Control strategies and performance optimization
    • Advantages over traditional control mechanisms

    Students will learn about the significance of flapper-nozzle systems in achieving precise control in various applications.

  • Lecture - 34 Smart Sensors
    Prof. Alok Barua

    This module covers smart sensors, focusing on their capabilities to process information and communicate with other devices. Key topics include:

    • Concepts of smart sensing technology
    • Integration of sensors with IoT and automation systems
    • Applications in smart cities, healthcare, and industry 4.0
    • Challenges and future directions for smart sensors

    Students will understand how smart sensors are transforming traditional measurement techniques and enabling smarter environments.

  • This module focuses on chromatography, a critical technique for separating and analyzing compounds in various substances. Topics include:

    • Basic principles of chromatography
    • Types of chromatography (gas, liquid, thin-layer)
    • Applications in pharmaceuticals, food safety, and environmental analysis
    • Instrumentation and methodologies used in chromatography

    Students will gain insights into how chromatography is employed in laboratories and industries for quality control and analysis.

  • This module continues the study of chromatography, focusing on advanced techniques and applications. Key topics include:

    • High-performance liquid chromatography (HPLC)
    • Mass spectrometry and its integration with chromatography
    • Applications in research and industry
    • Emerging trends and future directions in chromatographic techniques

    Students will explore the advancements in chromatography and how they enhance analysis and quality control processes.

  • This module covers pollution measurement techniques, essential for monitoring environmental quality. Key topics include:

    • Types of pollutants and their effects on health and environment
    • Measurement techniques for air, water, and soil pollutants
    • Regulatory standards and compliance strategies
    • Innovative technologies for pollution detection

    Students will learn about the importance of pollution measurement in ensuring public health and environmental protection.

  • This module focuses on control valves, which are essential components in fluid control systems. Topics covered include:

    • Types of control valves and their mechanisms
    • Applications in various industries
    • Design considerations and sizing
    • Maintenance and troubleshooting techniques

    Students will gain practical insights into how control valves function and their critical role in maintaining process efficiency.

  • This module continues the study of control valves, focusing on advanced applications and technologies. Key topics include:

    • Smart control valves and their integration with automation systems
    • Performance optimization techniques
    • Case studies of control valve applications in industries
    • Future trends in valve technology

    Students will explore how advancements in control valve technology improve process control and contribute to operational excellence.

  • This module focuses on signal conditioning integrated circuits, which play a vital role in processing signals from sensors. Key topics include:

    • Overview of integrated circuit technology
    • Types of signal conditioning ICs
    • Applications in various measurement systems
    • Design considerations for integrating these circuits

    Students will learn how integrated circuits enhance signal processing capabilities and contribute to the development of reliable measurement systems.