Technical Proficiency: The GDS simulator helps personnel develop advanced skills in troubleshooting and maintaining complex machinery, which is crucial for achieving SIRE 2.0’s standards for operational excellence. Environmental Compliance: With a growing emphasis on environmental regulations, the simulator enables crew members to familiarize themselves with compliance standards and practice procedures that reduce environmental impact, such as optimizing fuel usage and managing waste effectively. Safety Protocols: Through realistic training scenarios, the simulator reinforces safety protocols, ensuring that personnel can identify and mitigate risks, which is a core component of the SIRE 2.0 inspection program.

GDS SERS™ Makes IMO Engine Room Resource Management (ERM) Certificate Trainings Conducted Efficiently and Effectively

Description of an ERM Training

Engine Room Resource Management (ERM) is a system of achieving safe engineering operations by proactively utilizing and managing personnel, equipment, and information in the machinery space. A review the team roles, human factors, and situational awareness is required to plan and implement a proper ERM program. Remember, good ERM practices can save personnel and vessels from unwanted risks.

The course complies with the standards of Regulation III/1, III/2, III/6 and VIII/2 of STCW Convention, Section A-III/1, III/2, III/6, A-VIII/2 and B-VIII/2 of STCW Code and SIRE requirements.

Topics in a ERM training includes

  • Learn about effective resource allocation including crew, plant, equipment, and information management
  • Understand the leadership responsibilities of the Chief Engineer, including staff training and motivation, preventing crew fatigue, and conducting appropriate drills
  • Review individual and team roles, and how to reduce human error using situational awareness and closed loop communication
  • See engine room equipment functions and standard operating procedures

Relevance of this Training with existing IMO Model Courses

This course includes the topics using the guidance provided by the following IMO Model Courses.

  • IMO Model Course 7.02 Chief Engineer Officer and Second Engineer Officer
  • IMO Model Course 7.04 Officer in Charge of an Engineering Watch
  • IMO Model Course 2.07 Engine Rooms Simulator. 2017 Ed.
  • IMO Model Course 1.39 Leadership and Teamwork
  • IMO Model Course 1.38 Marine Environmental Awareness

Referenced Documents

The following documents must be used along with this document for effectively planning and providing an ERM training.

GDS SERS User Manuals and Documents

  • User Manual Vol I (SERS Software Description) describe the SERS software with the SERS Graphical User Interface (GUI) Panels accessed from the SERS Main Graphical User Interface (GUI) Panel.
  • User Manual Volume II (Engine Room Operations) includes the operational instructions on how to operate the engine room systems and machinery using the SERS.
  • User Manual Vol III (Installation & Configuration) describes the installation and the configuration of software and hardware items
  • This manual, User Manual Volume IV (Instructor’s Manual), includes guides and information for the instructors to utilize SERS in their trainings according to their specific training objectives.
  • Refer to “SERS Philosophy Document” for selecting the configuration of the SERS for your training objectives.  Then use Vol. III for the proper installation of the SERS and reading the configuration guidelines.

External Referenced Documens

  • IMO Model Course 7.02 Chief Engineer Officer and Second Engineer Officer
  • IMO Model Course 7.04 Officer in Charge of an Engineering Watch
  • IMO Model Course 2.07 Engine Rooms Simulator. 2017 Ed.
  • IMO Model Course 1.39 Leadership and Teamwork
  • IMO Model Course 1.38 Marine Environmental Awareness

ENGINE ROOM RESOURCE MANAGEMENT TRAINING MODEL

Engine Room Resource Management (ERM) is a system of achieving safe engineering operations by proactively utilizing and managing personnel, equipment, and information in the machinery space. A review the team roles, human factors, and situational awareness is required to plan and implement a proper ERM program. Remember, good ERM practices can save personnel and vessels from unwanted risks.

The course complies with the standards of Regulation III/1, III/2, III/6 and VIII/2 of STCW Convention, Section A-III/1, III/2, III/6, A-VIII/2 and B-VIII/2 of STCW Code and SIRE requirements.

The course is aimed at officers of the engineering watch (operational level), 2nd Engineer and Chief Engineer (management level).

The course is a mix of theory case studies and simulation exercise covering topics below. The following are the four main areas to cover in an ERM training:

GDS SERS IMO Engine Room Resource Management Course Model 2.07 IMO. Certification Training. Marine Engineering Cadets. Class Regulations.
  • RESOURCE ALLOCATION: Effective resource allocation including crew, plant, equipment, and information management.
  • LEADERSHIP: The leadership responsibilities of the Chief Engineer, including staff training and motivation, preventing crew fatigue, and conducting appropriate drills
  • TEAM ROLES AND RESPONSIBILITIES: The roles and responsibilities for both individuals and team. Planning and execution must be reviewed with past experiences with the aim of reducing human error using situational awareness and closed loop communication.
  • TECHNICAL OPERATIONS MANAGEMENT: A study with a thorough review of equipment functions, standard operating procedures including safety procedures.

Designing your ERM Training with SERS

In this section, we provide a guidance on how to design an IMO ERM training with step by step approach. We hope that it helps you provide an effective training for your cadets or engineers already working onboard.

1. Certification of the Simulator

Certification of the simulator is highly important. You must ensure that it has all capabilities to provide the capabilities training based on STCW 2010. As for the ERM training, the simulator must be capable of demonstrating the IMO Model Course (2.07) exercises.

GDS Ship Engine Room Simulator (SERS™) is a Training Simulator System with a Full Mission (Class A) type approval certificate obtained from ClassNK. ClassNK is an IACS affiliate Classification Organization. Certificate of SERS™ lists the IMO STCW 2010 competencies, as provided in Table 1, which includes the compliance to IMO STCW Tables A-III. The class certification of SERS includes the IMO Model Course 2.07 (207) Ed.). The trainee is able to perform all exercises contained in the IMO Model Course 2.07. All exercises were demonstrated during the Class Type Approval.

Table 1: SERS™ Certification Items for STCW Training Competencies.

IMO STCW-2010 ReferenceCompetence
Table A-III/1.1Maintain a safe engineering watch
Table A-III/1.2Use English in written and oral form
Table A-III/1.3Use internal communication systems
Table A-III/1.4Operate main and auxiliary machinery and associated control systems
Table A-III/1.5Operate fuel, lubrication, ballast and other pumping systems and associated control systems
Table A-III/1.6Operate electrical, electronic and control systems
Table A-III/1.10Ensure compliance with pollution prevention requirements
Table A-III/1.11Maintain seaworthiness of the ship
Table A-III/1.12Prevent, control and fight fires on board
Table A-III/1.16Application of leadership and team working skills
Table A-III/2.1Manage the operation of propulsion plant machinery
Table A-III/2.2Plan and schedule operations
Table A-III/2.3Operation, surveillance, performance assessment and maintaining safety of propulsion plant and auxiliary Machinery
Table A-III/2.4Manage fuel, lubrication and ballast operations
Table A-III/2.5Manage operation of electrical and electronic control equipment
Table A-III/2.6Manage troubleshooting restoration of electrical and electronic control equipment to operating condition
Table A-III/2.8Detect and identify the cause of machinery malfunctions and correct faults
Table A-III/2.10Control trim, stability and stress
Table A-III/2.11Monitor and control compliance with legislative requirements and measures to ensure safety of life at sea and protection of the marine environment
Table A-III/2.14Use leadership and managerial skills
Table A-III/4.2For keeping a boiler watch: Maintain the correct water levels and steam pressures
Table A-III/6.1Monitor the operation of electrical, electronic and control systems
Table A-III/6.2Monitor the operation of automatic control systems of propulsion and auxiliary machinery
Table A-III/6.3Operate generators and distribution systems
Table A-III/6.4Operate and maintain power systems in excess of 1,000 volts
Table A-III/6.5Operate computers and computer networks on ships
Table A-III/6.7Use internal communication systems
Table A-III/6.9Maintenance and repair of automation and control systems of main propulsion and auxiliary machinery
Table A-III/6.12Ensure compliance with pollution-prevention requirements

2. Simulator Detail Specs

This is probably the most tricky part. Some simulators could be cheap (!) and may be simulating the systems at a very high level. Does it have a main engine lubricating oil system? Probably yes. Does it satisfy the IMO competencies. Well this is the tricky part. It must have the LO Temperature Control System appropariately and realistically simulating the systems. We gave a simple example. Most trainers learn the specifics of the simulator after some experience of using it and become aware of the isues that prevent providing an efficient engine room simulator training. This may not be of an issue for a freshman level students; however, it becomes important when trainees are already completed their training onboard a ship and that they completed their marine engine engineering courses (Diesel Engines, Ship Auxiliary Engines, Electrical Systems, Automatic Control Systems, etc.). Additionally, the models and simulated systems has critical importance when the trainees are the personnel already have experience onboard a ship. Usually, the trainees in an ERM course will be watchkeeping officers or even chief engineers and they will probably critisize the training if the simulations are not realistic!

We have written the full specifications list for an engine room simulator, generalized with a focus on how it must help the instructors in the training. We went through each section of both the IMO STCW 2010 and IMO Model Course 2.07 and ensure the full list is at hand with the training in focus. Do not hesitate to request a copy if you are establishing an engine room training facility. We will be glad to help as trainers with ERS training experience of more than 20 years.

We should warn you that you must prepare the requirements for purchasing an Engine Room Simulator not the manufacturer.

3. Simulator Configurations

The training area must be organized with a focus into the training goals and objectives. The number of students to train at once is also an important element.

There are two examples of simulator configırations shown with the following figures. You must define your objectives first and ensure that a satisfactory number of stations and area is provided during the training.

ERS Training Plant GDS Engineering Inc SERS Full Mission Engine Room Simulator Layout and Equipment Arrangement
ERS Training Plant GDS Engineering Inc SERS Full Mission Engine Room Simulator Layout and Equipment Arrangement
Ship Engine Room Simulator (ERS) SERS GDS Engineering R&D IMO STCW 2010, Engine Performance, Main Diesel Engine, Marine, Maritime, IMO Model Course 2.07. Certified by ClassNK. ITU Maritime Faculty. Yıldız Technical University. Competencies. Operation and Management Level. Education and Training. Assessment of Marine Engineers. Troubleshooting with Fault Tree Scnearious and Analysis Reporting. Objective Assessment. Nippon Kaiji Kyokai.High Voltage Training Functions 6600 VAC. Ship Propulsion Systems. Maritime Education and Training. Main Engine Performance. Sunken Diagrams. Energy Efficiency. Marine Engineering. Effect of Draft Change in the Ship Main Engine Performance Parameters. Management Level Training Exercices, Marine Engineering Education and Training. SERS Trademark

Operating Marine Diesel Engines – IMO STCW 2010 Competency Requirements

Operation of the engine room machinary and systems: Watch GDS Engine Room Simulator Demonstration Videos

Watch the videos demonstrated by our students. Operation of the engine room machinary and system in accordance with the IMO Compentency Requirements.

Thanks fr watching and please communicate with us if you would like to have this training system be incorporated in your training programms.

Ship Engine Room Simulator (ERS) SERS GDS Engineering R&D IMO STCW 2010, Engine Performance, Main Diesel Engine, Marine, Maritime, IMO Model Course 2.07. Certified by ClassNK. ITU Maritime Faculty. Yıldız Technical University. Competencies. Operation and Management Level. Education and Training. Assessment of Marine Engineers. Troubleshooting with Fault Tree Scnearious and Analysis Reporting. Objective Assessment. Nippon Kaiji Kyokai.High Voltage Training Functions 6600 VAC. Ship Propulsion Systems. Maritime Education and Training. Main Engine Performance. Sunken Diagrams. Energy Efficiency. Marine Engineering. Effect of Draft Change in the Ship Main Engine Performance Parameters. Management Level Training Exercices, Marine Engineering Education and Training. SERS Trademark

A Study of the Main Propulsion Engine Performance with Ship’s Draft Change

Purpose: Exercise the weather effect to engine performance using the Ship ERS. Generate a report with capturing the images using SERS GUI panels and tools provided. Note that this exercise is generated as part of the IMO Model Course 2.07 (2017 Edition) exercises. This training exercise was developed as part of the IMO STCW 2010 Management Level objectives using the Model Course 2.07 guidelines ans steps. 

Note: This classroom exercise was provided in this page as an example. Click here to visit the Ship Engine Room Simulator product to read more.

Step 1: ERS is operated in Navigation Mode and Ballast Transfer System is lined up for ballast operations. Draft is Low (i.e. d=9 m.)

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Step 2: ME Processes GUI Panel displays the ME Parameters while the draft is increasing. Check Figure 2 for that the the baseline (sea test) data/graphs are displayed. Being able to understand the ME performance graphs are important in this exercise. 

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Step 3: Ensure the  control of the main engine is set to “RPM”.

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Step 4: Graphs and Plots GUI Panel displays the trend data for the selected parameters. In this exercise, it is important to plot the draft and ME Power. Additionally, it is important to select the ME Power versus ME RPM in the X-Y plot area to see the ME Power change while the RPM is controlled.

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Step 5: Status of the Ballast Tanks and Levels are important to observe.

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Step 6: Students should be able to interpret time (trend) and X-Y graphs for this operation, as part of the MANAGEMENT LEVEL exercise objectives.

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Step 7: Complete the exercise with noting the ME parameter changes.

Effect of Draft Change in the Ship Main Engine Performance Parameters IMO Model Course 2.07, IMO, STCW 2010, Management Level Training Exercices, Marine Engineering Education and Training, Maritime. GDS Engineering R&D, SERS, Trademark

Ship Engine Room Simulator (ERS) SERS GDS Engineering R&D IMO STCW 2010, Engine Performance, Main Diesel Engine, Marine, Maritime, IMO Model Course 2.07. Certified by ClassNK. ITU Maritime Faculty. Yıldız Technical University. Competencies. Operation and Management Level. Education and Training. Assessment of Marine Engineers. Troubleshooting with Fault Tree Scnearious and Analysis Reporting. Objective Assessment. Nippon Kaiji Kyokai.High Voltage Training Functions 6600 VAC. Ship Propulsion Systems. Maritime Education and Training. Main Engine Performance. Sunken Diagrams. Energy Efficiency. Marine Engineering. Effect of Draft Change in the Ship Main Engine Performance Parameters. Management Level Training Exercices, Marine Engineering Education and Training. SERS Trademark

Capture GDS Vision in the Engine Room Simulator Development

In recent years, the maritime industry has seen a significant push towards technological advancement and stricter safety and operational standards. As vessels become more sophisticated and regulations evolve, the role of well-trained onboard maritime personnel becomes increasingly essential. In this context, the SIRE 2.0 program and GDS Ship Engine Room Simulator represent pioneering tools designed to equip maritime crews with deep technical skills necessary to meet new demands and improve the safety and efficiency of maritime operations.

Understanding SIRE 2.0 and Its Impact on Maritime Training

The Ship Inspection Report Programme (SIRE) has long been a fundamental tool in maintaining safety and operational standards across the maritime industry, particularly for tanker operations. Launched by the Oil Companies International Marine Forum (OCIMF), the program provides a comprehensive inspection system that evaluates the condition and operations of vessels. However, with the growing complexity of modern vessels and stricter environmental and safety regulations, the traditional SIRE program required enhancements to address these evolving needs. This led to the development of SIRE 2.0, an upgraded version that integrates data-centric inspection methodologies with a stronger focus on crew competency, operational excellence, and technical skills.

One of the key features of SIRE 2.0 is its focus on assessing the competency of crew members in handling complex equipment and operations. Rather than focusing solely on vessel condition, SIRE 2.0 evaluates the practical skills, knowledge, and decision-making abilities of onboard personnel. This ensures that crew members are not only familiar with equipment and operational standards but are also capable of responding effectively to critical situations.

The emphasis on crew competency in SIRE 2.0 aligns with the industry’s shift toward a human-centered approach in safety and operational excellence. This paradigm shift means that training programs must go beyond traditional instruction and delve into more practical, technology-driven skills, which is where simulators like the GDS Ship Engine Room Simulator come into play.

The Role of the GDS Ship Engine Room Simulator in Skill Development

The GDS Ship Engine Room Simulator is an advanced training tool that replicates the engine room environment of modern vessels, providing maritime personnel with hands-on experience in a controlled setting. This simulator covers a wide range of critical systems found in ship engine rooms, including propulsion, auxiliary machinery, electrical systems, and emergency protocols. By using the simulator, crew members can practice their skills, refine their decision-making processes, and gain confidence in handling complex systems without the risks associated with real-world errors.

The simulator allows trainees to engage in realistic scenarios, such as equipment failures, power management issues, and environmental challenges. This training is invaluable in helping them develop deep technical skills needed to respond effectively under pressure. Given the increasing complexity of ship machinery, which often integrates digital and automated controls, such simulator-based training ensures that personnel are well-prepared for both routine and emergency operations.

Developing Deep Technical Skills with SIRE 2.0 and the GDS Simulator

By integrating SIRE 2.0’s competency standards with the practical capabilities of the GDS Ship Engine Room Simulator, maritime training institutions can foster deep tech skills that are essential in today’s high-stakes maritime environment. Training programs using these tools can address various aspects, including:

Operational Readiness: By simulating real-life engine room conditions, the GDS simulator enables personnel to develop an intuitive understanding of systems and processes, which aligns with SIRE 2.0’s focus on crew readiness and situational awareness.

Crisis Management and Decision-Making: The simulator provides scenarios that replicate emergency situations, allowing trainees to practice crisis response, prioritize actions, and make critical decisions under pressure.

Technical Proficiency: The GDS simulator helps personnel develop advanced skills in troubleshooting and maintaining complex machinery, which is crucial for achieving SIRE 2.0’s standards for operational excellence.

Environmental Compliance: With a growing emphasis on environmental regulations, the simulator enables crew members to familiarize themselves with compliance standards and practice procedures that reduce environmental impact, such as optimizing fuel usage and managing waste effectively.

Safety Protocols: Through realistic training scenarios, the simulator reinforces safety protocols, ensuring that personnel can identify and mitigate risks, which is a core component of the SIRE 2.0 inspection program.

Ship Engine Room Simulator (ERS) SERS GDS Engineering R&D IMO STCW 2010, Engine Performance, Main Diesel Engine, Marine, Maritime, IMO Model Course 2.07. Certified by ClassNK. ITU Maritime Faculty. Yıldız Technical University. Competencies. Operation and Management Level. Education and Training. Assessment of Marine Engineers. Troubleshooting with Fault Tree Scnearious and Analysis Reporting. Objective Assessment. Nippon Kaiji Kyokai.High Voltage Training Functions 6600 VAC. Ship Propulsion Systems. Maritime Education and Training. Main Engine Performance. Sunken Diagrams. Energy Efficiency. Marine Engineering. Effect of Draft Change in the Ship Main Engine Performance Parameters. Management Level Training Exercices, Marine Engineering Education and Training. SERS Trademark

A new and modern Engine Room Simulator (ERS) has recently been certified by Class NK: It Meets the Online Training Requirements of IMO STCW 2010 and Model Course 2.07

Ship Engine Room Simulator (Ship ERS or SERS™) is certified to meet both IMO STCW 2010 and IMO Model Course 2.07 Exercise Requirements

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SERS™ User Manuals

SERS™ is provided with a total of seven (7) user manuals, student exercise workbooks, and documents as complementary to the training practices. All these documents are supplied with a license purchase. Using the SERS™ document set in classroom study also promotes the real-world engine room best work practices of using manuals in operation and management of the engine room machinary and systems.

SERS User Manual Vol I (Software Description) describes the SERS software with the SERS Graphical User Interface (GUI) Panels accessed from the SERS Main Graphical User Interface (GUI) Panel.

SERS User Manual Volume II (Engine Room Operations) includes the operational instructions on how to operate the engine room systems and machinery using the SERS. The training institutions can directly use the contents of this manual in their training procedures. There are also exercises included for use by the trainees for reporting.

SERS User Manual Vol III (Installation & Configuration) describes the installation and the configuration of the software and hardware items. Using this manual, SERS can be configured to run as a Distributed System and the touch screen hardware panels can be assigned to desired GUI panels using the configuration files.

SERS User Manual Volume IV (Instructor’s Manual) includes guides, information, and additional exercise tips for the instructors to utilize SERS in their trainings according to a specific training objective.

Student Exercise Workbooks per IMO Model Course 2.07

Student Exercise Workbook, Volume I: We are already using the simulator in our own training programs and developed Volume I with exercies that meets each objectives of the IMO Model Course 2.07. Volume I exercises includes the Engine Room Operational Level training objectives.

Student Exercise Workbook,Volume II: Volume II exercises includes the Engine Room Management Level training objectives in accordance with IMO Model Course 2.07.

SERS Philosophy Document provides how SERS may be used in a curricula or in engine room simulator training programs. It provides guides for selecting the configuration of the SERS according to the training objectives.

Students can Complete and Report the IMO Model Course 2.07 Exercises with Online Training

IMO Model Course Engine-Room Simulator 2.07 (2017 Edition)

  • Familiarization
  1. Familiarization
    1.1 Plant arrangement
    1.2. Instrumentation
    1.3. Alarm system
    1.4. Controls
  • Operation of plant machinery
    2.1. Operational procedures
    2.2 Operate main and auxiliary machinery and
    systems
    2.3. Operation of diesel generator 20
    2.4. Operation of steam boiler
    2.5. Operation of main engine and associated
    auxiliaries
    2.6. Operation of steam turbo generator
    2.7. Operation of fresh water generator
    2.8. Operation of pumping system
    2.9. Operation of oily water separator
    2.10. Fault detection and measures
  • Maintain a safe engineering watch 19
    3.1. Thorough knowledge of principles to be observed in keeping an engineering watch
    3.2. Safety and emergency procedures; changeover of remote/automatic to local control of all systems
    3.3. Safety precautions to be observed during a watch and immediate actions to be taken in the event of fire or accident, with particular reference to oil systems
    3.4. Knowledge of engine room resource management principles
  • Operate electrical, electronic and control systems
    4.1. Operation of main switch board
    4.2. High-voltage installations
  1. Manage operation of electrical and electronic……

Click here to read more.

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