Analysis of Operator Expertise Leads to
at Gas Plant in Niigata, Japan
To improve safety and efficiency at this plant, INPEX needed to bring the graphical user interface (GUI) on its production control system (PCS) human-machine interface (HMI) stations up to international standards, specifically the ASM Design Guidelines1, ISA-5.52, ISO-92413, and API RP 11654. INPEX turned to Yokogawa for a solution because the company had expertise in developing advanced operator graphics (AOG5) solutions. A team of Yokogawa engineers visited the plant to conduct a detailed analysis, review the tasks carried out by operators, and learn about the plant's operations. In accordance with general principles on industrial design and human engineering, Yokogawa then redesigned the GUIs for the HMI displays to reduce operator errors, make their work easier to perform, and reduce physical stress. Throughout this project, the Yokogawa team followed the Six Sigma DMAIC methodology:
|Define||Design scope, design team setup||1 week|
|Measure||Investigation of operation environments||2 weeks|
|Analyze||Style design, task analysis, proposal||6 months|
|Improve||Evaluation, consulting to the team||6 months|
|Control||Final evaluation, final report||1 month|
As the work periods overlapped, this process took 9 months, from start to finish.
The Challenges and the Solutions
After a careful review of the operation and the design of the GUI, the team identified five issues:
- Plant operators had to quickly scan many different process graphic displays and trend displays to understand what was happening throughout the plant, hampering their ability to take quick and appropriate action.
- The information displayed was not color coded based on priority.
- The layout of text, graphics, etc. was confusing and easy to misread, leading to operator errors.
- The overview displays lacked detailed information and were of limited use to the operators.
- Although the operators had access to multiple monitors at their workstations, they had received no training in their use and the extra monitors were not being used.
Yokogawa's industrial design and ergonomics engineers proposed the following solutions
Design of task-based displays
The team reviewed and analyzed how the plant's most experienced operators carry out their monitoring and control tasks, examining the purpose of each task, the data needed, the displays used, how information was used to control an operation, and how information was used to monitor operations. Based on this, the process data was ranked by level of importance and documented in a task analysis sheet.
In the redesign of the displays, careful consideration was given to factors such as the relationships between information, pop-up window position, and navigation between displays. Some of the redesigned task-based graphic displays are shown below.
Improved presentation of process data
In a display, the color of the background, text, and graphics can have a significant impact on usability. Based on interviews with this plant's most experienced operators, and in accordance with ergonomic principles, the project team employed the AOG approach to redesign the GUI color scheme and layout and make process data easier to read. This also was done with CAMS for HIS, a standard consolidated alarm management function for Yokogawa's CENTUM VP PCS that was introduced to address the issue of alarm flooding. After a reprioritization of all the system alarms, the alarm color scheme was redesigned based on priority.
Utilization of KPI display
A KPI display provides information on every aspect of a plant's operations that its operators are responsible for, including output, quality, efficiency, and safety. They help motivate operators by showing how their work impacts plant performance. The following display shows four different types of KPIs and can be viewed on a single large screen positioned behind the double-tiered HMI screens.
Define graphic display hierarchy / monitor layout
To make effective use of the double-tiered HMI screens and a single large screen in the control room, a four-level hierarchy was defined for the graphic displays. Since plant operators mainly interact with task- and plant facility-based displays (levels 2 and 3), these were mainly assigned to the lower monitor in the double-tiered HMI. Level 1 displays along with the level 2 loop-watch displays were assigned to the upper monitor in order to navigate into level 3. KPI display is presented on the single large screen to share plant performance information between all control room users. This arrangement allows operators to stay on top of what is happening throughout the plant and quickly identify any abnormal conditions.
Through the AOG service, other package solutions were also proposed to help this plant achieve operational excellence. For example, to make use of a task time estimation program that INPEX developed, Yokogawa proposed the introduction of the Exapilot operation efficiency improvement package to eliminate operational mistake by manual calculation, and to reduce working time for alternative tanks usage.
The operators and managers at the INPEX Oyazawa plant initially were not sure how ergonomic design and knowledge-based technology could benefit them, but came to appreciate this approach after seeing how it improved not only alarm design and procedural automation but also the overall operations at their plant. The project team created the radar chart shown on the right, and assigned scores for a range of criteria, before and after this consulting project.
The following points are the major benefits that this project provided to INPEX:
- Shortened operation monitoring cycle
- Timely identification of abnormal conditions
- Fewer operator errors
- Reduced operator workload / eye fatigue
- Improved transfer of skills and expertise
- Increased motivation to improve operations
- Effective operator display design
- Graphic symbols for process displays
- Ergonomic requirements for office work with visual display terminals
- Recommended practice for pipeline SCADA displays
- A PCS graphic design service provided by Yokogawa that is based on human factors engineering and knowledge engineering. AOG emphasizes ergonomic design, and seeks through improved color selection, layout, and so on to improve operators' situational awareness. Based on insights gained from experienced personnel, this ensures operators have ready access to all the information they need to make effective decisions.
업스트림(Upstream) 산업에는 유전 또는 해저의 원유 및 천연가스의 채취 및 생산을 위한 유정제어, 증류, 분리 및 제품 완성을 포함한 해상 및 육상 플랜트가 포함됩니다.
석유는 육상으로 옮겨져야 하는 관계로 운송 전에 분리 작업이 필요합니다. 1차 및 2차 분리 단계는 일반적으로 가스 흐름, 물 흐름 및 오일 흐름의 3단계로 분류됩니다. 가스 이동은 파이프라인을 필요로 하며, 이동하기 전에 상류 공정에서 분류 공정을 거치게 됩니다. 액체는 탱크 또는 파이프라인에 넣고 운송을 하므로 정확한 레벨 측정이 가능한 레벨계가 필요합니다.
Yokogawa는 해상 및 육상 시설에서 파이프라인, 터미널 및 심해 운전에 이르기까지 석유 및 가스 사업의 모든 부분에서 풍부한 경험을 보유하고 있습니다. 우리는 안전을 강화하고 정확하고 신뢰성 있는 운전을 보장하며 플랜트 효율을 높이는 솔루션을 제공합니다.
FAST(Flexible Advanced System Techniques) 프로젝트로 시작된 FAST/TOOLS는 포괄적인 완전 통합형 SCADA 애플리케이션 제품군입니다. 강력하고 유연한 FAST/TOOLS는 50포인트 단위공정에서 수천 마일이상 확장되는 수백만 포인트 규모의 offshore 생산 및 Pipeline 시스템에 이르는 설비를 제공합니다.
Modular Procedural Automation (MPA)는 공정 플랜트에서 프로시저 지식을 수집, 최적화 및 보존하기 위한 유연한 방법론을 제공하며 신뢰성, 유연성 및 수명주기 비용 요구 사항을 충족합니다.
IoT와 호환되는 SCADA (Supervisory Control and Data Acquisition) 시스템은 전사적으로 자동화 및 모니터링을 최적화합니다.
Yokogawa는 프로세스 자동화를 위해서 중요한 운영 인프라를 제공합니다. 분산제어시스템(DCS)은 플랜트 또는 산업 공정의 자동화 된 제어 및 운영을 위한 플랫폼입니다. 10,000개 이상의 플랜트에서 고객의 생산 목표 달성하기 위해서 Yokogawa DCS가 적용되었습니다.