Tokyo, Japan - May 31, 2022 - Yokogawa Electric Corporation and Mitsubishi Heavy Industries, Ltd (MHI) announce that they have been selected by the Nippon Foundation, a private, non-profit grant-making organization, to undertake a project as part of the Nippon Foundation - DeepStar*1 Joint Research and Development Program for the promotion of decarbonization in the field of offshore oil and natural gas. The project is scheduled to commence on June 1.
The aim of this project is to develop an automatic inspection system that utilizes robots to identify and predict hazards in offshore facilities. The use of a wide variety of robots to enable unmanned operations and thereby reduce the risk of performing inspections on offshore platforms has long been considered; however, the centralized coordination of individual robots is complex as it requires the management of multiple systems and the data that they acquire. Yokogawa has already been engaged in the research and development of a robot service platform that centralizes the management of multiple robots and seamlessly links them with existing control systems. Leveraging the findings of this R&D, this project will build a communications infrastructure and robot system that is well suited for the environment found on offshore platforms, and utilize an AI application to convert for use in offshore platform operations the image and sound data acquired by robots.
As part of the project, a proof-of-concept test will be carried out using the second-generation EX ROVR plant inspection robot that MHI introduced to the market in April under the name ASCENT. With its explosion-proof features*2, the EX ROVR makes positive contributions to enhancing worker safety, boosting work efficiency, and improving facility operating rates by performing round-the-clock inspections under potentially explosive atmosphere conditions. The robot’s explosion-proof qualification has already been certified both domestically and globally by the International Electrotechnical Commission (IEC)*3 and ATEX certification*4, explosion-proof standards widely adopted in Europe and other regions. These qualifications will enable the EX ROVR’s safe usage under Zone 1 combustible gas conditions.
The adoption of a 6-DOF*5 explosion-proof manipulator with light-equipped camera enables close-up and front-facing photography, from diverse positions, of complexly arranged plant instrumentation. Measurement of gas density, sound recording, and acquisition of thermal images are also possible. In addition, when used in combination with the online application provided as a standard feature, the operator can perform remote setting and management of inspection schedules and confirmation of inspection data. In the event of an incident occurring in the plant, remote monitoring enables swift identification of on-site conditions, thereby contributing to higher plant inspection efficiency and safe, swift resolution of the incident in question.
Yokogawa provides solutions and services to its customers that will enable a digital transformation (DX) in their businesses, and is preparing the way for a future in which industries will make the transition from industrial automation to industrial autonomy (IA2IA). Robotics is a key technology that is paving the way to industrial autonomy. Yokogawa and MHI have already entered into a cooperation agreement regarding the utilization of robots in the oil, gas, and petrochemical industries. With this project, Yokogawa and MHI will jointly research and develop a robot system that is well suited for a variety of environments and situations.
X ROVR mobile inspection robot explosion-proof featuresMitsubishi Heavy Industries
Project overview
Development of an automatic inspection system that utilizes robots to predict hazards in offshore facilities
- Objective
Development of technology to improve the safety of inspection work on offshore platforms - Background
Currently on offshore oil and gas platforms, workers conduct daily patrol inspections and emergency inspections, but due to changing weather conditions and the risk of exposure to toxic gases, this can be a difficult task. Robots offer a promising solution, however, the image and sound data acquired by the robots cannot be interpreted as is by the operators who man the plant control systems, so it is necessary to convert that into meaningful data. Also, unlike onshore plants, offshore platforms have limited access to public telecommunication services, and it is therefore necessary for each facility to have its own telecommunications infrastructure for the operation of robot systems. - Method
- Develop a robot service platform that links robots and control systems on offshore platforms
- Develop an AI application for the robot service platform
- Develop a robot system consisting of the robot service platform, robots, and a plant control system
- Carry out a PoC test using MHI's EX ROVR robot
*1 A global offshore technology development consortium based in Houston, Texas. Companies from around the world participate.
*2 A robot described as “explosion-proof” is equipped with features that collectively limit the danger of the robot causing an explosion or fire from its own electric sparks or heat in environments filled with inflammable gas.
*3 The IEC issues IECEx certificates that attest to equipment’s suitability for use in explosive atmospheres. IECEx certification, which is widely adopted internationally, is based on quality assessment standards set by the IEC.
*4 ATEX certification refers to two directives relating to explosive atmospheres (French: ATmospheres EXplosibles). The directives, which are based on IECEx, stipulate the health and safety requirements, and conformity assessment procedures, that must be met in order to bring to the EU market equipment or protective systems for use in explosive atmospheres. As the ATEX directives and IECEx follow the same standards, there is fundamentally no difference in terms of their technical details.
*5 Degrees of freedom. The EX ROVR’s manipulator end-effector can move in the upward, downward, right, left, forward and rear directions. It can also tilt forward or backward, swing to the left or right, and rotate tilted to the left or right.
About the Nippon Foundation - DeepStar Joint Research and Development Program to Promote Decarbonization in the Field of Offshore Oil and Natural Gas
Based on a memorandum of understanding between the Nippon Foundation and the DeepStar consortium that was concluded in December 2021, and with funding provided by the Nippon Foundation, the two organizations will work together to promote the development of decarbonization technologies.
About Yokogawa
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 MHI Group
Mitsubishi Heavy Industries (MHI) Group is one of the world’s leading industrial groups, spanning energy, smart infrastructure, industrial machinery, aerospace and defense. MHI Group combines cutting-edge technology with deep experience to deliver innovative, integrated solutions that help to realize a carbon neutral world, improve the quality of life and ensure a safer world. For more information, please visit www.mhi.com or follow our insights and stories on spectra.mhi.com
The names of corporations, organizations, products, services and logos herein are either registered trademarks or trademarks of Yokogawa Electric Corporation, Mitsubishi Heavy Industries, Ltd., or their respective holders.
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