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PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 1
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 2 1. Hierarchy of Industrial Automation, Industrial Automation pyramid. Hierarchy of Industrial Automation, also known as Industrial Automation Pyramid that describes the structure and levels of automation within an industrial setting. The Industrial Automation Pyramid is typically divided into five hierarchical levels, 1. Field Level: The field level is the lowest level of the pyramid and represents the physical devices and sensors directly involved in the industrial processes. This includes sensors, actuators, switches, and other input/output devices. 2. Control Level: The control level is responsible for managing the field-level devices. It consists of programmable logic controllers (PLCs) or remote terminal units (RTUs) that monitor and control the field devices. 3. Supervisory Level: The supervisory level, also known as the supervisory control and data acquisition (SCADA) level, focuses on supervising and coordinating multiple control systems. It collects data from the control level, provides visualization of the process, and enables operators to monitor and control the overall industrial operations. 4. Manufacturing Execution System (MES) planning level: The MES level manages the execution of manufacturing operations and serves as a bridge between the supervisory level and the enterprise level. It gathers data from multiple SCADA systems, analyses production performance, tracks inventory, and ensures production efficiency. 5. Enterprise Level: The enterprise level represents the highest level of the industrial automation pyramid and is concerned with the integration of the industrial processes with the overall business operations. It involves business planning, resource allocation, product lifecycle management, and enterprise resource planning (ERP) systems.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 3 2. Present an Overview on the Levels of Automation- Device level, Machine Level, Cell Level, Plant Level, Enterprise Level 1. Device Level: The device level is the lowest level of automation and involves individual machines or devices with limited independent capabilities. These devices typically perform specific tasks or functions and may have basic sensing, actuating, and control capabilities. Examples include sensors, actuators, switches, and basic automated tools. 2. Machine Level: At the machine level, automation extends to a single machine or equipment, integrating multiple devices and components. At this level often have more advanced control systems, allowing them to perform complex tasks alone. Examples include CNC machines, industrial robots, and automated assembly lines. 3. Cell Level: The cell level refers to a group of machines or equipment working together in a coordinated manner to perform a specific task or process. These cells are usually focused on a particular operation or function within a larger manufacturing system. 4. Plant Level: The plant level encompasses the entire manufacturing or production facility. Automation at this level involves the integration of multiple cells, machines, and systems to create a comprehensive and interconnected manufacturing environment. 5. Enterprise Level: The enterprise level represents the highest level of automation and involves the integration of multiple plants, facilities, or sites within an organization. At this level, automation focuses on interconnecting various systems, processes, and data across different locations, departments, and functions.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 4 3. Importance of Industrial automation in the Indian manufacturing industry. Challenges and Limitations of industrial automations Industrial automation plays a crucial role in the Indian manufacturing industry for several reasons. 1. Increased productivity and efficiency: It enable companies to modernize their manufacturing processes, reduce human error, and improve overall productivity. 2. Quality improvement: They are designed to perform tasks with a high level of accuracy and precision, reduces defects, resulting in improved product quality. 3. Cost reduction: It can help reduce operational costs in the long run. It can lead to cost savings through increased production efficiency. 4. Safety and risk reduction: Automation systems can improve workplace safety by taking over hazardous tasks (Spray painting, welding, etc.) 5. Flexibility and scalability: Automation technologies offer flexibility and scalability to adapt to changing market demands. Manufacturers can easily reprogram or reconfigure. While industrial automation offers numerous benefits, it also faces certain challenges and limitations. 1. High initial investment: Implementing often requires high investment. The costs related with purchasing and installing automation equipment, integrating systems, training employees, and upgrading infrastructure. 2. Complexity of implementation: Industrial automation systems can be complex and require expertise in engineering, programming, and system integration. 3. Workforce adaptation and retraining: It creates a demand for skilled workers who can operate, maintain, and program automated systems. 4. Limited suitability for certain tasks: Some manufacturing operations involve complex decision-making, creative tasks, which are challenging to replicate with automation. 5. Maintenance and reliability: Automation systems require regular maintenance and upkeep to ensure optimal performance.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 5 Industry 4.0 and Challenges in implementation of Industry 4.0 in India Industry 4.0, also known as the Fourth Industrial Revolution, refers to the integration of digital technologies and automation into industrial processes to create smart, interconnected systems. Key technologies and concepts associated with Industry 4.0 include, 1. Internet of Things (IoT): Connecting physical devices and systems to collect and exchange data. 2. Cyber-Physical Systems (CPS): Combining physical and digital components to create intelligent systems. 3. Big Data Analytics: Utilizing large volumes of data to derive valuable insights for decision-making. 4. Cloud Computing: Providing scalable computing resources and storage for data processing. 5. Additive Manufacturing: Using 3D printing and other techniques to create products layer by layer. 6. Artificial Intelligence (AI): Enabling machines to simulate human intelligence and make independent decisions. 7. Augmented Reality (AR) and Virtual Reality (VR): Enhancing human-machine interactions and training processes. Challenges in Implementing Industry 4.0 in India: 1. Infrastructure: Implementation of Industry 4.0 requires robust digital infrastructure, including high-speed internet connectivity, reliable power supply, and adequate data storage capabilities. 2. Skilled Workforce: Industry 4.0 technologies demand a skilled workforce talented in digital technologies, data analytics, and automation. 3. Affordability and Accessibility: The cost of implementing Industry 4.0 technologies can be a barrier for small and medium-sized enterprises in India. 4. Data Security and Privacy: With the increased connectivity and data exchange in Industry 4.0, ensuring the security and privacy of sensitive information becomes critical. 5. Regulatory Framework: Implementing Industry 4.0 requires a supportive regulatory environment that encourages innovation, investment, and collaboration.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 6 4. Modern tools used for Industrial Automation- PAC, SCADA, HMI, DCS, AI, IIOT, etc Programmable Automation Controllers (PACs): PACs are powerful industrial control systems that combine the capabilities of a PLC (Programmable Logic Controller) and a PC. They offer advanced processing capabilities, robust networking, and integration with various devices and protocols. Features of a Programmable Automation Controller include: 1. Processing Power: PACs are equipped with powerful processors and large memory, enabling them to handle complex control tasks. 2. Real-time Operation: PACs are designed to execute control logic and respond to input/output (I/O) signals in real-time, ensuring precise and timely control. 3. Multi-tasking: PACs support multitasking, allowing them to run multiple programs or tasks simultaneously. 4. Programming Flexibility: PACs typically support multiple programming languages, including ladder logic (LD), structured text (ST), function block diagrams (FBD), and more. 5. Communication Protocols: PACs come with various built-in communication interfaces to communicate with a wide range of devices and systems, such as sensors, actuators, HMIs (Human Machine Interfaces), and other industrial devices. 6. Data Handling and Storage: PACs have the capability to handle and store large amounts of data, which is essential for analysing process information. 7. Scalability: PACs can be easily expanded by adding modules for additional I/O points or communication interfaces. 8. High Reliability: PACs are designed to be rugged and reliable, ensuring continuous operation in harsh industrial environments. 9. Remote Monitoring and Control: With built-in communication capabilities, PACs can be accessed remotely for monitoring and control purposes, allowing engineers to manage processes from a central location.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 7 Differences Between PLCs & PACs Device PLC PAC Process Modules 1 per Rack Module Multi-processor per Rack module Process Chips per Module 1 Microprocessor 2 or more High Performance chips for multitasking Programming Ladder logic Diagram Supports ST, FBDs and LD Functionality Sequential scan upto 64k Dual Logic scan, Motion control, Data acquisition and process control Memory Memory space upto 64k Memory space upto 32,000k I/O 3,000 1,28,000 Communication Typically, Single Option Through open network, multiple options like Ethernet/IP etc.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 8 Supervisory Control and Data Acquisition (SCADA): SCADA systems provide centralized control and monitoring of industrial processes. They collect real-time data from sensors, manage and control devices, and present information to operators. Applications of SCADA system are: 1. Manufacturing: Used to monitor and control production processes, assembly lines, and equipment. 2. Energy and Utilities: Extensively used in the power generation, distribution, and transmission. 3. Water and Wastewater Management: SCADA is applied to monitor water quality, control pumping stations, manage reservoir levels, and ensure efficient water distribution. 4. Oil and Gas: Used to monitor and control remote pipelines, drilling operations, refineries, and storage facilities. SCADA helps detect leaks, optimize production, and ensure safety compliance. 5. Transportation: Employed in transportation systems, such as railways, airports, and traffic management, to monitor and control operations, track vehicle movements, and enhance safety. 6. Building Automation: SCADA is used in commercial and industrial buildings for energy management, HVAC control, and monitoring of various systems. 7. Telecommunications: SCADA systems are applied in telecommunications networks to monitor the performance of network elements, track signal quality, and manage network traffic. 8. Environmental Monitoring: Used for environmental monitoring and control in areas like air quality, pollution monitoring, and weather stations. 9. Agriculture: In agricultural applications, SCADA can be used for irrigation control, greenhouse automation, and livestock management. 10. Pharmaceuticals: SCADA systems are employed in pharmaceutical manufacturing for process monitoring.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 9 Human-Machine Interface (HMI): HMI stands for Human-Machine Interface, and it refers to the technology that allows humans to interact with machines or computer systems. These are graphical interfaces (GI) that allow operators to interact with automation systems. They provide a user-friendly way to monitor processes, control devices, and receive alarms or notifications. HMIs display real-time data, trends (Graph), and reports, enabling operators to make decisions. Applications and features of HMIs are: 1. Process Monitoring and Control: HMIs provide real-time data visualization, allowing operators to monitor the status of various processes, machines, and equipment. 2. Machine Control: HMIs allow operators to control individual machines or entire production lines. 3. Parameter Setting and Adjustment: HMIs provide a user-friendly interface for setting and adjusting parameters for different processes and equipment. 4. Data Logging and Historical Trend Analysis: HMIs store and log historical data, allowing operators and engineers to analyze trends over time. 5. Alarms and Notifications: HMIs can generate alarms and notifications to alert operators about critical events or abnormal conditions. 6. Safety Integration: HMIs often incorporate safety features, such as emergency stop buttons and safety interlocks, to provide quick and easy access to safety functions for operators. 7. Remote Monitoring and Control: Some HMIs support remote access, enabling operators and maintenance personnel to monitor and control the industrial processes from a central control room or even via mobile devices. 8. Integration with PLCs and SCADA Systems: HMIs interface with Programmable Logic Controllers (PLCs) and Supervisory Control and Data Acquisition (SCADA) systems, allowing seamless communication between different components of the automation system. 9. Maintenance and Diagnostics: HMIs can display equipment status, maintenance schedules, and diagnostic information, helping maintenance personnel.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 10 A Distributed Control System (DCS) is a specialized type of control system used in various industries, particularly in large-scale industrial processes. It is designed to control and monitor multiple devices, processes, and equipment distributed throughout a manufacturing plant or an industrial facility. The key features and characteristics of a DCS include: 1. Distributed Architecture: Unlike traditional centralized control systems, a DCS is distributed across the plant or facility. It consists of multiple control units or nodes, each responsible for specific purpose. 2. Redundancy: DCS often incorporates redundant hardware and communication paths. Redundancy helps to prevent system failures and minimize downtime, critical for continuous and safe industrial operations. 3. Communication Network: DCS relies on a robust communication network to facilitate data exchange between the different control units and devices. 4. Real-time Control: DCS provides real-time control capabilities, enabling rapid response to process changes. 5. Scalability: Additional control units and devices can be easily integrated into the system as the process expands or new equipment is added. 6. Process Optimization: DCS systems often include advanced control algorithms that can optimize the process by adjusting parameters dynamically. This leads to increased efficiency, reduced energy consumption, and improved product quality. 7. Data Logging and Historization: DCS systems log process data, alarms, and events over time. 8. Safety and Emergency Shutdown: DCS can integrate safety features and emergency shutdown systems to protect the process from potential hazards. DCS finds applications in various industries, such as oil and gas, petrochemicals, power generation, pharmaceuticals, water treatment, and manufacturing. By providing a comprehensive and distributed control approach, DCS enhances process efficiency, reliability, and safety, contributing to improved overall productivity and reduced operational costs.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 11 Difference Between SCADA, HMI and DCS Criterion SCADA HMI DCS Scope and Scale It provides centralized monitoring and control of geographically dispersed processes or systems. It interacts with a single machine or a small portion of a process. It covers a broader range of processes compared to HMI but is generally limited to a single facility or plant. Architecture and Distribution SCADA systems have a centralized architecture with a master station that communicates with remote terminal units (RTUs) or programmable logic controllers (PLCs) placed at various field locations. HMIs are part of a larger control system, such as SCADA or DCS, and are often located near the equipment or process they control. They may also be integrated into individual machines or devices. DCS has a distributed architecture, consisting of multiple control units or nodes. Application Focus Well-suited for industries that require remote (isolated) monitoring and control. HMI is primarily used for local monitoring and control of individual machines. DCS is personalised for managing and controlling complex processes within an industrial plant. Data Acquisition and Visualization SCADA focuses on real-time data acquisition and visualization of remote locations. HMI offers a graphical and user- friendly interface for local operators to visualize and interact. DCS provides real- time data acquisition and visualization for the entire industrial process, offering insights into various interconnected units and equipment.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 12 Artificial Intelligence (AI) plays a significant role in revolutionizing industrial automation. It empowers machines and systems to exhibit intelligent behaviours, making them more adaptive, efficient, and capable of handling complex tasks. Here are some key applications of AI in industrial automation: 1. Predictive Maintenance: AI-powered predictive maintenance systems analyze data from sensors and equipment for predicting when machines might fail, maintenance can be performed. 2. Process Optimization: AI algorithms can optimize industrial processes by adjusting parameters in real-time based on data analysis. This helps improve efficiency, reduce energy consumption, and enhance overall productivity. 3. Autonomous Robots: AI enables robots to perceive their surroundings, make decisions, and carry out tasks without human intervention. 4. Quality Control: AI-powered vision systems can inspect products for defects and ensure adherence to quality standards. 5. Supply Chain Management: AI is used to optimize supply chain operations, including demand forecasting, inventory management, and route optimization. 6. Process Monitoring and Control: AI systems continuously monitor processes, analyzing data to maintain optimal control. 7. Energy Management: AI can optimize energy usage in industrial facilities, reducing energy waste and optimizing energy consumption patterns. 8. Decision Support Systems: AI provides valuable visions and decision support for human operators and managers.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 13 Industrial Internet of Things (IIoT): IIoT refers to the integration of modern Internet of Things (IoT) technologies with industrial processes, machinery, and systems. It extends the concept of IoT from consumer devices and applications to the industrial sector, focusing on improving efficiency, productivity, safety, and overall performance in various industries. Key features and components of the Industrial Internet of Things (IIoT) include: 1. Connected Devices and Sensors: IIoT relies on a network of smart devices and sensors embedded in industrial equipment, machinery, and infrastructure. These devices gather data, monitor operations, and provide real-time insights to optimize processes. 2. Data Communication and Connectivity: IIoT relies on reliable and secure communication protocols to transfer data between devices and the central processing system. Common communication technologies include Wi-Fi, Ethernet, Bluetooth, etc. 3. Cloud Computing and Data Analytics: Collected data is often sent to cloud-based platforms for storage, processing, and analysis. 4. Artificial Intelligence (AI) and Machine Learning (ML): IIoT leverages AI and ML algorithms to analyze vast amounts of data and extract meaningful insights. Predictive maintenance, anomaly detection, and optimization are common AI/ML applications in IIoT. 5. Industrial Automation: IIoT enables enhanced automation in manufacturing, logistics, and other industrial processes. This includes automated workflows, and robotic control. 6. Cybersecurity: IIoT systems must prioritize robust cybersecurity measures to safeguard sensitive industrial data and protect critical infrastructure from cyber threats and attacks. 7. Industry-specific Applications: IIoT can be applied in various sectors, such as manufacturing, energy, healthcare, transportation, agriculture, and more.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 14 5. Importance of IEC, ISO, NEMA, JIC and other standards used in automation. IEC, ISO, NEMA, JIC, and other standards play a crucial role in automation. These standards ensure consistency, compatibility, safety, and efficiency in various aspects of automation. IEC (International Electrotechnical Commission): 1. Safety: IEC standards provide guidelines and specifications for the safe design, installation, and operation of electrical and electronic systems, including automation equipment. 2. Interoperability: IEC standards promote compatibility and interoperability among different automation devices and systems, allowing continuous integration and communication between them. 3. Performance: These standards define performance criteria, test methods, and measurement techniques for automation products. 4. Global Acceptance: IEC standards are internationally recognized and adopted, facilitating the global trade and exchange of automation products. ISO (International Organization for Standardization): 1. Quality Management: ISO standards, such as ISO 9001, provide a framework for implementing effective quality management systems in automation companies. 2. Environmental Management: ISO 14001 standards address environmental management systems, helping organizations minimize their environmental impact and promote sustainable practices in automation processes. 3. Risk Management: ISO 31000 provides guidance on risk management principles, processes, and frameworks. In automation, this helps identify risks associated with equipment, processes, and cybersecurity. 4. Data Exchange: ISO standards like ISO 15926 enable efficient data exchange and interoperability between different software applications.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 15 NEMA (National Electrical Manufacturers Association): 1. Electrical Equipment Standards: NEMA develops standards for electrical equipment used in automation, including motors, drives, control systems, enclosures, and connectors. These standards ensure compatibility, safety, and performance of electrical products. 2. Advocacy and Industry Representation: NEMA represents the interests of electrical manufacturers in policy-making, code development, and regulatory matters related to automation. They work to promote efficient and sustainable electrical systems. JIC (Joint Industrial Council): 1. Standardization: JIC standards provide guidelines for the design and installation of electrical control equipment in industrial applications. These standards ensure uniformity, safety, and reliability in automation systems. 2. Wiring and Schematic Diagrams: JIC standards define conventions for wiring and schematic diagrams, making it easier to understand and interpret electrical drawings in automation. Other standards organizations, such as ISA (International Society of Automation), IEEE (Institute of Electrical and Electronics Engineers), and UL (Underwriters Laboratories), also contribute to automation standards development, focusing on specific areas like instrumentation, communication protocols, and safety certifications.
PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 16 6. Programming with IEC 61131-3 Languages IEC 61131-3 is a standard that defines a set of programming languages for PLCs. The standard includes five languages, each with its own characteristics and purpose. Ladder Diagrams Ladder Diagrams are one of the most widely used programming languages in the PLC. They are graphical representations of relay logic circuits. Ladder Diagrams consist of rungs that contain various ladder elements such as contacts, coils, timers, and other logic functions. Structural Text language Structural Text is a high-level text-based language similar to structured programming languages like Pascal or C. It allows the programmer to write structured code using statements and control structures such as loops and conditionals. Sequential function Chart Sequential Function Chart is a graphical language used to model complex sequential processes. It consists of steps, transitions, and actions. Steps represent states or sub-procedures, transitions define the conditions for moving between steps, and actions represent operations to be executed. SFCs provide a visual representation of the control flow and allow for hierarchical structuring of the program. Functional block diagram Function Block Diagram is a graphical language that enables modular and reusable programming. It represents the program as a network of interconnected function blocks, which are graphical representations of reusable software components. Instruction list List is a low-level, text-based language that resembles assembly language. It uses mnemonics to represent PLC instructions and operates on registers and memory locations. Instruction List provides a way to write code in a more direct and efficient manner, suitable for tasks that require fine-grained control over hardware resources.

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  • 1. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 1
  • 2. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 2 1. Hierarchy of Industrial Automation, Industrial Automation pyramid. Hierarchy of Industrial Automation, also known as Industrial Automation Pyramid that describes the structure and levels of automation within an industrial setting. The Industrial Automation Pyramid is typically divided into five hierarchical levels, 1. Field Level: The field level is the lowest level of the pyramid and represents the physical devices and sensors directly involved in the industrial processes. This includes sensors, actuators, switches, and other input/output devices. 2. Control Level: The control level is responsible for managing the field-level devices. It consists of programmable logic controllers (PLCs) or remote terminal units (RTUs) that monitor and control the field devices. 3. Supervisory Level: The supervisory level, also known as the supervisory control and data acquisition (SCADA) level, focuses on supervising and coordinating multiple control systems. It collects data from the control level, provides visualization of the process, and enables operators to monitor and control the overall industrial operations. 4. Manufacturing Execution System (MES) planning level: The MES level manages the execution of manufacturing operations and serves as a bridge between the supervisory level and the enterprise level. It gathers data from multiple SCADA systems, analyses production performance, tracks inventory, and ensures production efficiency. 5. Enterprise Level: The enterprise level represents the highest level of the industrial automation pyramid and is concerned with the integration of the industrial processes with the overall business operations. It involves business planning, resource allocation, product lifecycle management, and enterprise resource planning (ERP) systems.
  • 3. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 3 2. Present an Overview on the Levels of Automation- Device level, Machine Level, Cell Level, Plant Level, Enterprise Level 1. Device Level: The device level is the lowest level of automation and involves individual machines or devices with limited independent capabilities. These devices typically perform specific tasks or functions and may have basic sensing, actuating, and control capabilities. Examples include sensors, actuators, switches, and basic automated tools. 2. Machine Level: At the machine level, automation extends to a single machine or equipment, integrating multiple devices and components. At this level often have more advanced control systems, allowing them to perform complex tasks alone. Examples include CNC machines, industrial robots, and automated assembly lines. 3. Cell Level: The cell level refers to a group of machines or equipment working together in a coordinated manner to perform a specific task or process. These cells are usually focused on a particular operation or function within a larger manufacturing system. 4. Plant Level: The plant level encompasses the entire manufacturing or production facility. Automation at this level involves the integration of multiple cells, machines, and systems to create a comprehensive and interconnected manufacturing environment. 5. Enterprise Level: The enterprise level represents the highest level of automation and involves the integration of multiple plants, facilities, or sites within an organization. At this level, automation focuses on interconnecting various systems, processes, and data across different locations, departments, and functions.
  • 4. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 4 3. Importance of Industrial automation in the Indian manufacturing industry. Challenges and Limitations of industrial automations Industrial automation plays a crucial role in the Indian manufacturing industry for several reasons. 1. Increased productivity and efficiency: It enable companies to modernize their manufacturing processes, reduce human error, and improve overall productivity. 2. Quality improvement: They are designed to perform tasks with a high level of accuracy and precision, reduces defects, resulting in improved product quality. 3. Cost reduction: It can help reduce operational costs in the long run. It can lead to cost savings through increased production efficiency. 4. Safety and risk reduction: Automation systems can improve workplace safety by taking over hazardous tasks (Spray painting, welding, etc.) 5. Flexibility and scalability: Automation technologies offer flexibility and scalability to adapt to changing market demands. Manufacturers can easily reprogram or reconfigure. While industrial automation offers numerous benefits, it also faces certain challenges and limitations. 1. High initial investment: Implementing often requires high investment. The costs related with purchasing and installing automation equipment, integrating systems, training employees, and upgrading infrastructure. 2. Complexity of implementation: Industrial automation systems can be complex and require expertise in engineering, programming, and system integration. 3. Workforce adaptation and retraining: It creates a demand for skilled workers who can operate, maintain, and program automated systems. 4. Limited suitability for certain tasks: Some manufacturing operations involve complex decision-making, creative tasks, which are challenging to replicate with automation. 5. Maintenance and reliability: Automation systems require regular maintenance and upkeep to ensure optimal performance.
  • 5. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 5 Industry 4.0 and Challenges in implementation of Industry 4.0 in India Industry 4.0, also known as the Fourth Industrial Revolution, refers to the integration of digital technologies and automation into industrial processes to create smart, interconnected systems. Key technologies and concepts associated with Industry 4.0 include, 1. Internet of Things (IoT): Connecting physical devices and systems to collect and exchange data. 2. Cyber-Physical Systems (CPS): Combining physical and digital components to create intelligent systems. 3. Big Data Analytics: Utilizing large volumes of data to derive valuable insights for decision-making. 4. Cloud Computing: Providing scalable computing resources and storage for data processing. 5. Additive Manufacturing: Using 3D printing and other techniques to create products layer by layer. 6. Artificial Intelligence (AI): Enabling machines to simulate human intelligence and make independent decisions. 7. Augmented Reality (AR) and Virtual Reality (VR): Enhancing human-machine interactions and training processes. Challenges in Implementing Industry 4.0 in India: 1. Infrastructure: Implementation of Industry 4.0 requires robust digital infrastructure, including high-speed internet connectivity, reliable power supply, and adequate data storage capabilities. 2. Skilled Workforce: Industry 4.0 technologies demand a skilled workforce talented in digital technologies, data analytics, and automation. 3. Affordability and Accessibility: The cost of implementing Industry 4.0 technologies can be a barrier for small and medium-sized enterprises in India. 4. Data Security and Privacy: With the increased connectivity and data exchange in Industry 4.0, ensuring the security and privacy of sensitive information becomes critical. 5. Regulatory Framework: Implementing Industry 4.0 requires a supportive regulatory environment that encourages innovation, investment, and collaboration.
  • 6. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 6 4. Modern tools used for Industrial Automation- PAC, SCADA, HMI, DCS, AI, IIOT, etc Programmable Automation Controllers (PACs): PACs are powerful industrial control systems that combine the capabilities of a PLC (Programmable Logic Controller) and a PC. They offer advanced processing capabilities, robust networking, and integration with various devices and protocols. Features of a Programmable Automation Controller include: 1. Processing Power: PACs are equipped with powerful processors and large memory, enabling them to handle complex control tasks. 2. Real-time Operation: PACs are designed to execute control logic and respond to input/output (I/O) signals in real-time, ensuring precise and timely control. 3. Multi-tasking: PACs support multitasking, allowing them to run multiple programs or tasks simultaneously. 4. Programming Flexibility: PACs typically support multiple programming languages, including ladder logic (LD), structured text (ST), function block diagrams (FBD), and more. 5. Communication Protocols: PACs come with various built-in communication interfaces to communicate with a wide range of devices and systems, such as sensors, actuators, HMIs (Human Machine Interfaces), and other industrial devices. 6. Data Handling and Storage: PACs have the capability to handle and store large amounts of data, which is essential for analysing process information. 7. Scalability: PACs can be easily expanded by adding modules for additional I/O points or communication interfaces. 8. High Reliability: PACs are designed to be rugged and reliable, ensuring continuous operation in harsh industrial environments. 9. Remote Monitoring and Control: With built-in communication capabilities, PACs can be accessed remotely for monitoring and control purposes, allowing engineers to manage processes from a central location.
  • 7. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 7 Differences Between PLCs & PACs Device PLC PAC Process Modules 1 per Rack Module Multi-processor per Rack module Process Chips per Module 1 Microprocessor 2 or more High Performance chips for multitasking Programming Ladder logic Diagram Supports ST, FBDs and LD Functionality Sequential scan upto 64k Dual Logic scan, Motion control, Data acquisition and process control Memory Memory space upto 64k Memory space upto 32,000k I/O 3,000 1,28,000 Communication Typically, Single Option Through open network, multiple options like Ethernet/IP etc.
  • 8. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 8 Supervisory Control and Data Acquisition (SCADA): SCADA systems provide centralized control and monitoring of industrial processes. They collect real-time data from sensors, manage and control devices, and present information to operators. Applications of SCADA system are: 1. Manufacturing: Used to monitor and control production processes, assembly lines, and equipment. 2. Energy and Utilities: Extensively used in the power generation, distribution, and transmission. 3. Water and Wastewater Management: SCADA is applied to monitor water quality, control pumping stations, manage reservoir levels, and ensure efficient water distribution. 4. Oil and Gas: Used to monitor and control remote pipelines, drilling operations, refineries, and storage facilities. SCADA helps detect leaks, optimize production, and ensure safety compliance. 5. Transportation: Employed in transportation systems, such as railways, airports, and traffic management, to monitor and control operations, track vehicle movements, and enhance safety. 6. Building Automation: SCADA is used in commercial and industrial buildings for energy management, HVAC control, and monitoring of various systems. 7. Telecommunications: SCADA systems are applied in telecommunications networks to monitor the performance of network elements, track signal quality, and manage network traffic. 8. Environmental Monitoring: Used for environmental monitoring and control in areas like air quality, pollution monitoring, and weather stations. 9. Agriculture: In agricultural applications, SCADA can be used for irrigation control, greenhouse automation, and livestock management. 10. Pharmaceuticals: SCADA systems are employed in pharmaceutical manufacturing for process monitoring.
  • 9. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 9 Human-Machine Interface (HMI): HMI stands for Human-Machine Interface, and it refers to the technology that allows humans to interact with machines or computer systems. These are graphical interfaces (GI) that allow operators to interact with automation systems. They provide a user-friendly way to monitor processes, control devices, and receive alarms or notifications. HMIs display real-time data, trends (Graph), and reports, enabling operators to make decisions. Applications and features of HMIs are: 1. Process Monitoring and Control: HMIs provide real-time data visualization, allowing operators to monitor the status of various processes, machines, and equipment. 2. Machine Control: HMIs allow operators to control individual machines or entire production lines. 3. Parameter Setting and Adjustment: HMIs provide a user-friendly interface for setting and adjusting parameters for different processes and equipment. 4. Data Logging and Historical Trend Analysis: HMIs store and log historical data, allowing operators and engineers to analyze trends over time. 5. Alarms and Notifications: HMIs can generate alarms and notifications to alert operators about critical events or abnormal conditions. 6. Safety Integration: HMIs often incorporate safety features, such as emergency stop buttons and safety interlocks, to provide quick and easy access to safety functions for operators. 7. Remote Monitoring and Control: Some HMIs support remote access, enabling operators and maintenance personnel to monitor and control the industrial processes from a central control room or even via mobile devices. 8. Integration with PLCs and SCADA Systems: HMIs interface with Programmable Logic Controllers (PLCs) and Supervisory Control and Data Acquisition (SCADA) systems, allowing seamless communication between different components of the automation system. 9. Maintenance and Diagnostics: HMIs can display equipment status, maintenance schedules, and diagnostic information, helping maintenance personnel.
  • 10. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 10 A Distributed Control System (DCS) is a specialized type of control system used in various industries, particularly in large-scale industrial processes. It is designed to control and monitor multiple devices, processes, and equipment distributed throughout a manufacturing plant or an industrial facility. The key features and characteristics of a DCS include: 1. Distributed Architecture: Unlike traditional centralized control systems, a DCS is distributed across the plant or facility. It consists of multiple control units or nodes, each responsible for specific purpose. 2. Redundancy: DCS often incorporates redundant hardware and communication paths. Redundancy helps to prevent system failures and minimize downtime, critical for continuous and safe industrial operations. 3. Communication Network: DCS relies on a robust communication network to facilitate data exchange between the different control units and devices. 4. Real-time Control: DCS provides real-time control capabilities, enabling rapid response to process changes. 5. Scalability: Additional control units and devices can be easily integrated into the system as the process expands or new equipment is added. 6. Process Optimization: DCS systems often include advanced control algorithms that can optimize the process by adjusting parameters dynamically. This leads to increased efficiency, reduced energy consumption, and improved product quality. 7. Data Logging and Historization: DCS systems log process data, alarms, and events over time. 8. Safety and Emergency Shutdown: DCS can integrate safety features and emergency shutdown systems to protect the process from potential hazards. DCS finds applications in various industries, such as oil and gas, petrochemicals, power generation, pharmaceuticals, water treatment, and manufacturing. By providing a comprehensive and distributed control approach, DCS enhances process efficiency, reliability, and safety, contributing to improved overall productivity and reduced operational costs.
  • 11. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 11 Difference Between SCADA, HMI and DCS Criterion SCADA HMI DCS Scope and Scale It provides centralized monitoring and control of geographically dispersed processes or systems. It interacts with a single machine or a small portion of a process. It covers a broader range of processes compared to HMI but is generally limited to a single facility or plant. Architecture and Distribution SCADA systems have a centralized architecture with a master station that communicates with remote terminal units (RTUs) or programmable logic controllers (PLCs) placed at various field locations. HMIs are part of a larger control system, such as SCADA or DCS, and are often located near the equipment or process they control. They may also be integrated into individual machines or devices. DCS has a distributed architecture, consisting of multiple control units or nodes. Application Focus Well-suited for industries that require remote (isolated) monitoring and control. HMI is primarily used for local monitoring and control of individual machines. DCS is personalised for managing and controlling complex processes within an industrial plant. Data Acquisition and Visualization SCADA focuses on real-time data acquisition and visualization of remote locations. HMI offers a graphical and user- friendly interface for local operators to visualize and interact. DCS provides real- time data acquisition and visualization for the entire industrial process, offering insights into various interconnected units and equipment.
  • 12. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 12 Artificial Intelligence (AI) plays a significant role in revolutionizing industrial automation. It empowers machines and systems to exhibit intelligent behaviours, making them more adaptive, efficient, and capable of handling complex tasks. Here are some key applications of AI in industrial automation: 1. Predictive Maintenance: AI-powered predictive maintenance systems analyze data from sensors and equipment for predicting when machines might fail, maintenance can be performed. 2. Process Optimization: AI algorithms can optimize industrial processes by adjusting parameters in real-time based on data analysis. This helps improve efficiency, reduce energy consumption, and enhance overall productivity. 3. Autonomous Robots: AI enables robots to perceive their surroundings, make decisions, and carry out tasks without human intervention. 4. Quality Control: AI-powered vision systems can inspect products for defects and ensure adherence to quality standards. 5. Supply Chain Management: AI is used to optimize supply chain operations, including demand forecasting, inventory management, and route optimization. 6. Process Monitoring and Control: AI systems continuously monitor processes, analyzing data to maintain optimal control. 7. Energy Management: AI can optimize energy usage in industrial facilities, reducing energy waste and optimizing energy consumption patterns. 8. Decision Support Systems: AI provides valuable visions and decision support for human operators and managers.
  • 13. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 13 Industrial Internet of Things (IIoT): IIoT refers to the integration of modern Internet of Things (IoT) technologies with industrial processes, machinery, and systems. It extends the concept of IoT from consumer devices and applications to the industrial sector, focusing on improving efficiency, productivity, safety, and overall performance in various industries. Key features and components of the Industrial Internet of Things (IIoT) include: 1. Connected Devices and Sensors: IIoT relies on a network of smart devices and sensors embedded in industrial equipment, machinery, and infrastructure. These devices gather data, monitor operations, and provide real-time insights to optimize processes. 2. Data Communication and Connectivity: IIoT relies on reliable and secure communication protocols to transfer data between devices and the central processing system. Common communication technologies include Wi-Fi, Ethernet, Bluetooth, etc. 3. Cloud Computing and Data Analytics: Collected data is often sent to cloud-based platforms for storage, processing, and analysis. 4. Artificial Intelligence (AI) and Machine Learning (ML): IIoT leverages AI and ML algorithms to analyze vast amounts of data and extract meaningful insights. Predictive maintenance, anomaly detection, and optimization are common AI/ML applications in IIoT. 5. Industrial Automation: IIoT enables enhanced automation in manufacturing, logistics, and other industrial processes. This includes automated workflows, and robotic control. 6. Cybersecurity: IIoT systems must prioritize robust cybersecurity measures to safeguard sensitive industrial data and protect critical infrastructure from cyber threats and attacks. 7. Industry-specific Applications: IIoT can be applied in various sectors, such as manufacturing, energy, healthcare, transportation, agriculture, and more.
  • 14. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 14 5. Importance of IEC, ISO, NEMA, JIC and other standards used in automation. IEC, ISO, NEMA, JIC, and other standards play a crucial role in automation. These standards ensure consistency, compatibility, safety, and efficiency in various aspects of automation. IEC (International Electrotechnical Commission): 1. Safety: IEC standards provide guidelines and specifications for the safe design, installation, and operation of electrical and electronic systems, including automation equipment. 2. Interoperability: IEC standards promote compatibility and interoperability among different automation devices and systems, allowing continuous integration and communication between them. 3. Performance: These standards define performance criteria, test methods, and measurement techniques for automation products. 4. Global Acceptance: IEC standards are internationally recognized and adopted, facilitating the global trade and exchange of automation products. ISO (International Organization for Standardization): 1. Quality Management: ISO standards, such as ISO 9001, provide a framework for implementing effective quality management systems in automation companies. 2. Environmental Management: ISO 14001 standards address environmental management systems, helping organizations minimize their environmental impact and promote sustainable practices in automation processes. 3. Risk Management: ISO 31000 provides guidance on risk management principles, processes, and frameworks. In automation, this helps identify risks associated with equipment, processes, and cybersecurity. 4. Data Exchange: ISO standards like ISO 15926 enable efficient data exchange and interoperability between different software applications.
  • 15. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 15 NEMA (National Electrical Manufacturers Association): 1. Electrical Equipment Standards: NEMA develops standards for electrical equipment used in automation, including motors, drives, control systems, enclosures, and connectors. These standards ensure compatibility, safety, and performance of electrical products. 2. Advocacy and Industry Representation: NEMA represents the interests of electrical manufacturers in policy-making, code development, and regulatory matters related to automation. They work to promote efficient and sustainable electrical systems. JIC (Joint Industrial Council): 1. Standardization: JIC standards provide guidelines for the design and installation of electrical control equipment in industrial applications. These standards ensure uniformity, safety, and reliability in automation systems. 2. Wiring and Schematic Diagrams: JIC standards define conventions for wiring and schematic diagrams, making it easier to understand and interpret electrical drawings in automation. Other standards organizations, such as ISA (International Society of Automation), IEEE (Institute of Electrical and Electronics Engineers), and UL (Underwriters Laboratories), also contribute to automation standards development, focusing on specific areas like instrumentation, communication protocols, and safety certifications.
  • 16. PLC, SCADA & HMI: INDUSTRIAL AUTOMATION PRACTICAL HAND BOOK Page 16 6. Programming with IEC 61131-3 Languages IEC 61131-3 is a standard that defines a set of programming languages for PLCs. The standard includes five languages, each with its own characteristics and purpose. Ladder Diagrams Ladder Diagrams are one of the most widely used programming languages in the PLC. They are graphical representations of relay logic circuits. Ladder Diagrams consist of rungs that contain various ladder elements such as contacts, coils, timers, and other logic functions. Structural Text language Structural Text is a high-level text-based language similar to structured programming languages like Pascal or C. It allows the programmer to write structured code using statements and control structures such as loops and conditionals. Sequential function Chart Sequential Function Chart is a graphical language used to model complex sequential processes. It consists of steps, transitions, and actions. Steps represent states or sub-procedures, transitions define the conditions for moving between steps, and actions represent operations to be executed. SFCs provide a visual representation of the control flow and allow for hierarchical structuring of the program. Functional block diagram Function Block Diagram is a graphical language that enables modular and reusable programming. It represents the program as a network of interconnected function blocks, which are graphical representations of reusable software components. Instruction list List is a low-level, text-based language that resembles assembly language. It uses mnemonics to represent PLC instructions and operates on registers and memory locations. Instruction List provides a way to write code in a more direct and efficient manner, suitable for tasks that require fine-grained control over hardware resources.