Editing Industrial process control (section)

{{Short description|Discipline that uses industrial control to achieve a production level of consistency}}
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<!--definition-->'''Industrial process control''' ('''IPC''') or simply '''process control''' is a system used in modern [[manufacturing]] which uses the principles of [[control theory]] and physical [[industrial control system]]s to monitor, control and optimize continuous [[Industrial processes|industrial production processes]] using control algorithms. This ensures that the industrial [[machine]]s run smoothly and safely in [[factories]] and efficiently use [[energy]] to transform [[raw material]]s into high-quality [[finished product]]s with reliable [[consistency]] while reducing [[Efficient energy use#Industry|energy waste]] and economic [[cost]]s, something which could not be achieved purely by human manual control.<ref name="Sanjoy2024">{{Cite book |title=Computational Intelligence Techniques for Sustainable Supply Chain Management |first1=Sanjoy Kumar |last1=Paul |first2=Sandeep |last2=Kautish |publisher=Elsevier |date=May 24, 2024 |pages=146–147 }}</ref> 

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In IPC, control theory provides the theoretical framework to understand system dynamics, predict outcomes and design control strategies to ensure predetermined objectives, utilizing concepts like feedback loops, stability analysis and controller design. On the other hand, the physical apparatus of IPC, based on automation technologies, consists of several components. Firstly, a network of sensors continuously measure various process variables (such as temperature, pressure, etc.) and product quality variables. A programmable logic controller (PLC, for smaller, less complex processes) or a distributed control system (DCS, for large-scale or geographically dispersed processes) analyzes this sensor data transmitted to it, compares it to predefined setpoints using a set of instructions or a mathematical model called the control algorithm and then, in case of any deviation from these setpoints (e.g., temperature exceeding setpoint), makes quick corrective adjustments through actuators such as valves (e.g. cooling valve for temperature control), motors or heaters to guide the process back to the desired operational range. This creates a continuous closed-loop cycle of measurement, comparison, control action, and re-evaluation which guarantees that the process remains within established parameters. The HMI (Human-Machine Interface) acts as the "control panel" for the IPC system where small number of human operators can monitor the process and make informed decisions regarding adjustments.<ref name="Sanjoy2024" /> IPCs can range from controlling the temperature and level of a single process vessel (controlled environment tank for mixing, separating, reacting, or storing materials in industrial processes.) to a complete chemical processing plant with several thousand control feedback loops. 

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IPC provides several critical benefits to manufacturing companies. By maintaining a tight control over key process variables, it helps reduce energy use, minimize waste and shorten downtime for peak efficiency and reduced costs. It ensures consistent and improved product quality with little variability, which satisfies the customers and strengthens the company's reputation. It improves safety by detecting and alerting human operators about potential issues early, thus preventing accidents, equipment failures, process disruptions and costly downtime. Analyzing trends and behaviors in the vast amounts of data collected real-time helps engineers identify areas of improvement, refine control strategies and continuously enhance production efficiency using a data-driven approach.<ref name="Sanjoy2024" />

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IPC is used across a wide range of industries where precise control is important.<ref>{{Cite web |date=2019-05-14|title=A Guide To Statistical Process Control|url=https://redmeters.com/a-guide-to-statistical-process-control/|access-date=2021-03-29|website=Red Meters |language=en-US}}</ref> The applications can range from controlling the temperature and level of a single process vessel, to a complete chemical processing plant with several thousand control loops. In automotive manufacturing, IPC ensures consistent quality by meticulously controlling processes like welding and painting.  Mining operations are optimized with IPC monitoring ore crushing and adjusting conveyor belt speeds for maximum output. Dredging benefits from precise control of suction pressure, dredging depth and sediment discharge rate by IPC, ensuring efficient and sustainable practices. Pulp and paper production leverages IPC to regulate chemical processes (e.g., pH and bleach concentration) and automate paper machine operations to control paper sheet moisture content and drying temperature for consistent quality. In chemical plants, it ensures the safe and efficient production of chemicals by controlling temperature, pressure and reaction rates. Oil refineries use it to smoothly convert crude oil into gasoline and other petroleum products. In power plants, it helps maintain stable operating conditions necessary for a continuous electricity supply. In food and beverage production, it helps ensure consistent texture, safety and quality. Pharmaceutical companies relies on it to produce life-saving drugs safely and effectively. The development of large industrial process control systems has been instrumental in enabling the design of large high volume and complex processes, which could not be otherwise economically or safely operated.<ref>{{Cite book |first=Bill |last=Bolton |title=Control Engineering |edition=2nd |publisher=Longman Publishing Group |date=1998 }}</ref>