- Putting into practical use a next-generation control technology that takes into account quality, yield, energy saving, and sudden disturbances -
(BUSINESS WIRE) -- Yokogawa Electric Corporation (TOKYO: 6841) and JSR Corporation (JSR, TOKYO: 4185) announce the successful conclusion of a field test in which AI was used to autonomously run a chemical plant for 35 days, a world first*1. This test confirmed that reinforcement learning AI can be safely applied in an actual plant, and demonstrated that this technology can control operations that have been beyond the capabilities of existing control methods (PID control*2/APC*3) and have up to now necessitated the manual operation of control valves based on the judgements of plant personnel. The initiative described here was selected for the 2020 Projects for the Promotion of Advanced Industrial Safety subsidy program of the Japanese Ministry of Economy, Trade and Industry.
Control in the process industries spans a broad range of fields, from oil refining and petrochemicals to high-performance chemicals, fiber, steel, pharmaceuticals, foodstuffs, and water. All of these entail chemical reactions and other elements that require an extremely high level of reliability.
In this field test, the AI solution successfully dealt with the complex conditions needed to ensure product quality and maintain liquids in the distillation column at an appropriate level while making maximum possible use of waste heat as a heat source. In so doing it stabilized quality, achieved high yield*4, and saved energy. While rain, snow, and other weather conditions were significant factors that could disrupt the control state by causing sudden changes in the atmospheric temperature, the products that were produced met rigorous standards and have since been shipped. Furthermore, as only good quality products were created, fuel, labor, time, and other losses that occur when off-spec products are produced were all eliminated. Safe operations were ensured through a three-step process.
The AI used in this control experiment, the Factorial Kernel Dynamic Policy Programming (FKDPP) protocol, was jointly developed by Yokogawa and the Nara Institute of Science and Technology (NAIST) in 2018, and was recognized at an IEEE International Conference on Automation Science and Engineering as being the first reinforcement learning-based AI in the world that can be utilized in plant management*7. Through initiatives including the successful conduct of a control training system*8 experiment in 2019, and an experiment in April 2020 that used a simulator to recreate an entire plant*9, Yokogawa has confirmed the potential of this autonomous control AI*10 and advanced it from a theory to a technology suitable for practical use. It can be used in areas where automation previously was not possible with conventional control methods (PID control and APC), and its strengths include being able to deal with conflicting targets such as the need for both high quality and energy savings.
Given the numerous complex physical and chemical phenomena that impact operations in actual plants, there are still many situations where veteran operators must step in and exercise control. Even when operations are automated using PID control and APC, highly-experienced operators have to halt automated control and change configuration and output values when, for example, a sudden change occurs in atmospheric temperature due to rainfall or some other weather event. This is a common issue at many companies’ plants. Regarding the transition to industrial autonomy*11, a very significant challenge has been instituting autonomous control in situations where until now manual intervention has been essential, and doing so with as little effort as possible while also ensuring a high level of safety. The results of this test suggest that this collaboration between Yokogawa and JSR has opened a path forward in resolving this longstanding issue.
Yokogawa welcomes customers who are interested in these initiatives globally. The company aims to swiftly provide products and solutions that lead to the realization of industrial autonomy.
JSR believes that this demonstration shows AI’s potential for addressing challenges that previously could not be resolved at chemical plants, and will investigate its application to other processes and plants with the aim of achieving further improvements in productivity.
Going forward, the two companies will continue to work together and investigate ways of using AI in plants.
Masataka Masutani, general manager of production technology at JSR, commented, “In an environment that is changing due to factors such as the fully-fledged introduction of 5G and other developments towards a digital society, as well as the aging of the human resources who ensure plant safety and a lack of human resources to replace them, the petrochemical industry is under strong pressure to improve safety and efficiency in its production activities by utilizing new technologies such as IoT and AI. The orientation of JSR is toward making production smart through a proactive incorporation of drones, IoT sensors, cameras, and other new technologies, and in this experiment, we took on the challenge of the automation of plant process control using AI control technology. We verified that AI is able to autonomously control the processes that were previously performed manually on the basis of operators’ experience, and we are firmly convinced of the usefulness and future potential of AI control. From those in the field, we have heard comments saying that not only has the burden on operators been reduced, but the very fact that we have taken on the challenge of this new technology and succeeded is motivation for taking forward DX into the future. Henceforth, we shall expand operations controlled with AI, and work to enhance chemical plant safety, stability, and competitiveness.”
Takamitsu Matsubara, associate professor at NAIST, remarked, “I am very glad to hear that this field test was successful. Data analysis and machine learning are now being applied to chemical plant operations, but technology that can be used in autonomous control and the optimization of operations has not been fully ready until now. The reinforcement learning AI FKDPP algorithm was jointly developed by Yokogawa and NAIST in 2018 to realize autonomous control in chemical plants. Despite having to refer to a large number of sensors and control valves, the AI can generate a robust control policy in a limited number of learning trials. These features helped to improve the efficiency of the development process, and led to the achievement of autonomous control for a long period of 840 hours during the field test. I think this very difficult achievement of autonomous control in an actual distillation column and the fact that the level of practical application has been raised to the point where the entire production process and safety are integrated into one system have great significance for the entire industry. I look forward to seeing what happens next with this technology.”
Yokogawa Electric vice president and head of Yokogawa Products Headquarters, Kenji Hasegawa, added, “The success of this field test came from bringing together the deep knowledge of the production process and operational aspects that only the customer can provide, and Yokogawa’s strength of leveraging measurement, control, and information to produce value. It suggests that an autonomous control AI (FKDPP) can significantly contribute to the autonomization of production, maximization of ROI, and environmental sustainability around the world. Yokogawa led the world in the development of distributed control systems that control and monitor the operation of plant production facilities, and has supported the growth of a range of industries. With our gaze fixed firmly on a world of autonomous operation that forms the model for the future of industries, we are now promoting the concept of IA2IA – Industrial Automation to Industrial Autonomy. To achieve strong and flexible production that takes into consideration the impact of differences in humans, machines, materials, and methods, the 4Ms, in the energy, materials, pharmaceuticals, and many other industries, we will accelerate the joint development of autonomous control AI with our customers around the world.”
Based on Yokogawa Electric survey conducted in February 2022 regarding AI that directly changes the manipulative variable in the chemical plant.
Proportional-Integral-Derivative control. First proposed by Nicolas Minorsky in 1922, this is an infrastructure control technology for processing industries that is used to control items such as quantity, temperature, level, pressure, and ingredients. It implements control toward a target value while using the results of each of the P, I, and D calculations according to the deviation between the current value and the set value. There are issues with this mode of control such as an inability to deal with multiple external disturbances (weather, climate, material composition changes) and frequent changes to target values, thereby necessitating manual control.
Advanced Process Control. This uses a mathematical model that can predict process responses and gives set values to the PID control loop in real time in order to improve productivity, quality, and controllability. It is also easily applied to control for the purpose of increasing production, reducing labor time, and saving energy. Incorporating APC results in smaller deviations in data, making it possible to get closer to the limits of operating performance (i.e., the state in which the optimum performance can be obtained). However, it is limited by the fact that it is not adept at responding to the rapid vaporization of fluids and other such chemical reactions, major changes in material composition, and changes in machinery.
The volume of the target substance that is actually obtained from raw materials through the refinement process
The CENTUM VP integrated control system allows the entire production process to proceed while monitoring and controlling pressures, flow rates, temperatures, and other such factors, as well as integrating various interlocking functions for safe and stable operation and accident prevention. To prevent plant accidents, it is possible to operate in cooperation with safety instrumented systems (SIS), emergency shutoff devices (ESD), fire protection systems (F&G), etc.
A mechanism that prevents startup unless certain conditions are fulfilled prior to operation. It increases safety by preventing incorrect operations, procedural mistakes, and the like.
Factorial Kernel Dynamic Policy Programming for Vinyl Acetate Monomer Plant Model Control, August 2018. https://ieeexplore.ieee.org/document/8560593/authors#authors IEEE (Institute of Electrical and Electronics Engineers). The IEEE is a US-based academic research and technical standardization organization that focuses on the fields of electrical and information engineering. It has more than 400,000 members in 160 countries around the world.
A three tank level control system that is used to perform training and experiments involving the regulation of the flow of water from one level to the next, with the overall aim of controlling the water level at the lowest stage. It also includes devices to artificially create disturbances that randomly change the flow of water. Given the nature of fluids, the control of their flow rates is a difficult challenge in the processing industries. Being able to adequately perform this control leads to increased productivity at manufacturing sites.
Scalable Reinforcement Learning for Plant-wide Control of Vinyl Acetate Monomer Process, Control Engineering Practice, Volume 97, April 2020 https://www.sciencedirect.com/science/article/pii/S0967066120300186
Yokogawa defines autonomous control AI as AI that deduces the optimum method for control independently and has a high level of robustness enabling it to autonomously handle, to a certain extent, situations that it has not previously encountered.
Industrial autonomy is defined by Yokogawa as follows: “Plant assets and operations have learning and adaptive capabilities that allow responses with minimal human interaction, empowering operators to perform higher-level optimization tasks." In the responses to the Global End-User Survey on the Implementation of Industrial Autonomy carried out by Yokogawa in 2021 covering 534 decision makers at 390 manufacturing companies, 42% said that the application of AI to plant process optimization will have a significant impact on industrial autonomy in the next three years.
The names of corporations, organizations, products, services and logos herein are either registered trademarks or trademarks of Yokogawa Electric Corporation, JSR Corporation, or their respective holders.
Yokogawa provides advanced solutions in the areas of measurement, control, and information to customers across a broad range of industries, including energy, chemicals, materials, pharmaceuticals, and food. Yokogawa addresses customer issues regarding the optimization of production, assets, and the supply chain with the effective application of digital technologies, enabling the transition to autonomous operations.
Founded in Tokyo in 1915, Yokogawa continues to work toward a sustainable society through its 17,500 employees in a global network of 119 companies spanning 61 countries.
For more information, visit www.yokogawa.com
About JSR Corporation
JSR Corporation is a multinational company employing more than 9,000 people worldwide and a leading materials supplier in a variety of technology driven markets, driving materials innovation and creating value through materials to enrich society, people and the environment. JSR's global network is headquartered in Tokyo (Japan) and has factories and offices in Europe, USA, China, Taiwan, Korea, and Thailand. JSR is a research-oriented organization that pursues close collaborations with leading innovators in a number of industries that are a key to the present and future welfare of human society: life-sciences, electronic materials, display, plastics and synthetic rubbers.
For more information about JSR Corporation, please visit https://www.jsr.co.jp/jsr_e/
Overview of Field Test
1. Purpose of field test
(1) To demonstrate that reinforcement learning AI (FKDPP: Factorial Kernel Dynamic Policy Programming algorithm) can be applied safely in plants where safety is an absolute necessity
(2) To demonstrate that reinforcement learning AI can be used to control areas that existing control methods (PID control/APC) cannot automate
A JSR chemical plant in Japan
Areas where existing control methods (PID control/APC) could not be applied and control could only be performed manually (where operators considered the level of operation for valves and input this themselves)
Areas where rain, snow, and other weather conditions were significant factors that could disrupt the control state by causing sudden changes in the atmospheric temperature
When substances A and B, which had similar boiling points, were heated and separated, optimum control was performed to maintain liquids in the distillation column at an appropriate level so that all products were compliant with standards, while, to save energy, valves were operated to maximize the use of waste heat as the heat source for the distillation column and extract the desired substance A in an ideal state.
Reinforcement learning AI (FKDPP: Factorial Kernel Dynamic Policy Programming algorithm)
Products & technologies
OmegaLand plant simulator (provided by Yokogawa Electric Corporation subsidiary Omega Simulation Co., Ltd.)
CENTUM VP integrated production control system
Exaopc OPC interface package (software that enables management of a variety of databases used in the processing industries. Uses an interface that is compliant with the OPC interface standard defined by the OPC foundation. Its functions include the automatic saving of process data.)
GA10 data logging software (for operation screen and input device (HMI) and data recording), etc.
Managed by CENTUM VP integrated production control system
Allows the entire production process to proceed while monitoring and controlling pressures, flow rates, temperatures, and other such factors, as well as integrating various interlocking functions for safe and stable operation and accident prevention. To prevent plant accidents, it operates in cooperation with emergency shutoff devices (ESD), fire protection systems (F&G), etc.
Process to AI implementation
Generate AI control model with a plant simulator
Plant model generated from design information for the relevant plant
Reinforcement learning-based AI (FKDPP algorithm) learned and generated a control model
Comprehensively assess AI control model validity and reliability
Checked with past operating data
- Was it stable?
- What kind of control was performed when problems occurred?
Checked with real-time data
- Was it stable?
- Was product quality within spec?
- Were veteran operators satisfied with FKDPP control instructions?
Ensure safety, then control a real plant
Ensured safety with existing interlocks and other safety functions
Integrated with CENTUM VP integrated production control system, and incorporated into plant operations
Ensured safety in operations (planned responses and established system for dealing with AI system malfunctions)
August 2020 - February 2022 (1 year 6 months)
Period of continuous operation
35 days, from January 17 to February 21, 2022 (840 hours)
3. Company roles
Provision of venue for experiment, detailed plant information, operating status
Setting of challenges for AI control system to solve
Engineering (connection with existing CENTUM VP integrated production control system)
Evaluation of safety and validity from the perspective of the AI control system
Consideration of safety systems for introduction of AI control systems in actual plants
Planning of proposals (AI system specs, schedule, etc.)
AI system construction
Engineering (adjustment of connection with existing CENTUM VP integrated production control system, etc.)
4. Results and comparison with conventional control
By combining both companies’ know-how and focusing on those areas at an actual plant that could not be automated with existing control methods, it was possible to find a method for the safe application of reinforcement learning AI in systems and operations.
Continuous control for a period of 35 days was achieved using an integrated production control system, and products suitable for shipment were successfully produced.
This suggests that as a next-generation control technology, reinforcement learning AI (FKDPP) can significantly contribute to autonomization, maximization of ROI, and environmental sustainability at plants around the world.
AI autonomous control integrated with CENTUM VP integrated production control system
Only monitoring was needed; basically, no human intervention was required.
Stable production of good quality products that met rigorous standards and were able to be shipped
Raw materials could be efficiently turned into products.
Energy savings were achieved by maximizing use of waste heat as the heat source, enabling a reduction in CO2 emissions.
Only good quality products were produced, so fuel and labor costs that are incurred due to the production of off-spec products were eliminated.
Only good quality products were produced, so time losses that occur due to the production of off-spec products were eliminated.
There is no longer a need for highly experienced operators to perform manual control 24 hours a day 365 days a year, meaning the burden on humans decreases and errors are prevented, leading to higher levels of safety.
5. [Reference] Main characteristics of AI used in plant control
For areas that cannot be automated with existing control methods (PID control/APC), the AI deduces the optimum method for control on its own and has the robustness to autonomously control, to a certain extent, situations that have not yet been encountered.
Based on the control model it learns and deduces, the AI inputs the level of control required for each situation.
The benefits of FKDPP are as follows:
(1) Can be applied in situations where control cannot be automated with existing control techniques (PID control and APC), and can handle conflicting targets, such as achieving both high quality and energy savings.
(2) Increases productivity (quality, energy saving, yield, shorter settling time)
(3) Simple (small number of learning trials, no need to import labeled data)
(4) Explainable operation
(5) Same safety as conventional systems (highly robust, can be directly linked to existing integrated production control systems)
AI can take over the task, currently performed by operators, of inputting target values for areas where automation has been implemented using existing control methods (PID control/APC).
AI uses past control data to perform calculations, and enters target values.
Automation of manual tasks and achievement of stable operations is possible.
Operational support for
AI proposes target values that operators will refer to when performing operations.
AI uses past control data to suggest target values to humans.
Differences due to operator proficiency level will disappear.
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