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Course code: 000531
School of Engineering
PROD001 – Artificial Lift Systems
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Currently, this course is conducted only in an intracorporate format.
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What this course about?

In today's rapidly evolving oil and gas industry, the need for proficient knowledge in artificial lift systems is paramount. Our comprehensive training program is meticulously designed to equip participants with the essential skills and understanding necessary for mastering these systems. The program begins with an "Introduction to Artificial Lift Systems," where learners delve into the basics of artificial lift technology, understand various selection criteria, and analyze economic considerations. This module sets the foundation by exploring reservoir performance, emphasizing well productivity, and addressing formation damage causes and prevention.

Building upon this foundation, the course advances into "Understanding Reservoir Dynamics and Fluid Flow." Here, participants engage with the intricacies of fluid flow fundamentals, including Black Oil PVT and Inflow Performance Relationships, crucial for any professional in this field. We tackle the challenges in well production, discussing problems like asphaltenes, waxes, hydrates, and scale formation, and their impact on lift requirements. This module is pivotal for understanding the changing dynamics of well conditions and how they dictate the necessity for artificial lift.

The heart of the program lies in the "Artificial Lift Systems - Types and Applications" module. Participants are introduced to various systems such as Beam (Rod) Pump Systems, Gas Lift Systems, Electric Submersible Pumps (ESP), and more. The focus is not only on understanding the design and components of each system but also on their practical applications, limitations, and power requirements. This module is vital for grasping the nuances of each system and their suitability for different operational scenarios.

Lastly, the course culminates with "Best Practices and System Optimization." This module synthesizes all the learning into practical applications, emphasizing techniques to maximize oil production economically and ensure the longevity of lift systems. It covers the design and operation under challenging conditions and encourages the application of theoretical knowledge through case studies and real-world scenarios. This final module is designed to transform participants into well-rounded professionals, capable of making informed decisions and optimizing artificial lift systems for maximum efficiency and productivity.

In conclusion, this training program is an invaluable resource for professionals seeking to excel in the artificial lift domain. It offers a blend of theoretical knowledge and practical application, ensuring participants are well-equipped to face the challenges and opportunities in the oil and gas industry.

Who is this course for?
The Artificial Lift Systems training program is ideally suited for a range of professionals in the oil and gas industry who are looking to deepen their understanding and skills in artificial lift technologies. The following groups would particularly benefit from attending this course:
- Petroleum Engineers: Engineers who are directly involved in the exploration, development, and optimization of oil and gas wells will find this course particularly beneficial. It will enhance their understanding of how artificial lift systems can maximize production efficiency.
- Production Engineers: These professionals, responsible for managing and optimizing the production of oil and gas wells, will gain valuable insights into the selection, design, and operation of various artificial lift systems.
- Reservoir Engineers: While primarily focused on the subsurface aspects of oil and gas production, reservoir engineers can benefit from understanding how artificial lift impacts reservoir performance and overall production strategy.
- Field Operations Personnel: Supervisors and technicians involved in the day-to-day operations of oil fields will acquire practical knowledge and skills for managing and troubleshooting artificial lift systems.
- Maintenance and Reliability Engineers: Those responsible for the maintenance and reliability of production equipment will gain essential knowledge on maintaining and optimizing artificial lift systems, which are critical for continuous production.
- Project Managers and Planners in Oil and Gas: Managers overseeing projects related to oil extraction will benefit from understanding how artificial lift systems fit into the overall production strategy and affect project economics.
- Technical Support Staff: Technical assistants and support staff involved in production and engineering departments will enhance their understanding of the systems, improving their ability to provide effective support.
By attending this course, these professionals will not only enhance their technical expertise but also contribute to more efficient, cost-effective, and sustainable production operations in their respective organizations.
Pre-course requirements
  • Educational Background: A basic understanding of engineering principles is essential. Participants should ideally hold a degree in engineering, preferably in petroleum, mechanical, or chemical engineering. This background ensures familiarity with fundamental concepts relevant to oil and gas production
  • Industry Experience: Some level of experience in the oil and gas industry, particularly in areas related to production, reservoir management, or field operations, is highly beneficial. This experience allows participants to better understand the practical applications of the concepts taught in the training
  • Familiarity with Basic Oil and Gas Concepts: Understanding key terms and concepts related to oil and gas production, such as wellbore dynamics, reservoir properties, and fluid mechanics, will be advantageous. This knowledge aids in grasping more advanced topics covered in the training
  • Mathematical Proficiency: Competence in basic mathematics and physics is necessary. Skills in algebra, calculus, and physics principles are important for understanding the technical aspects of artificial lift systems and their design
  • Analytical Skills: The ability to analyze and interpret data is crucial, as the course will likely involve working with performance data, production curves, and other technical information
  • Computer Literacy: Proficiency in using standard computer software, especially those related to engineering applications, is helpful. Familiarity with industry-specific software for modeling and analysis would be an added advantage
What will you learn?
  • Understand Comprehensive Artificial Lift Concepts: Gain a thorough understanding of various artificial lift methods, including their principles, applications, and limitations. This encompasses a deep dive into systems like Sucker Rod Pumping, Gas Lift, Electric Submersible Pumps (ESP), Hydraulic and Jet Pumping, and Progressing Cavity Pumping
  • Analyze Reservoir and Fluid Dynamics: Develop the ability to analyze reservoir performance, including understanding inflow and outflow relationships, and the impact of various reservoir conditions on artificial lift system selection and efficiency
  • Apply Practical Knowledge to Real-World Scenarios: Utilize the knowledge gained to apply artificial lift technologies in practical settings. This includes the ability to select the appropriate lift system based on specific well conditions and operational requirements
  • Design and Optimize Artificial Lift Systems: Acquire the skills to design and optimize various artificial lift systems. This includes understanding the components and operation of each system, troubleshooting common problems, and implementing best practices for maintenance and operation
  • Make Informed Economic Decisions: Learn to conduct economic analyses for different artificial lift systems, enabling the ability to make informed decisions regarding the most cost-effective and efficient methods for specific scenarios
  • Implement Best Industry Practices: Understand and implement the best industry practices for the installation, maintenance, and operation of artificial lift systems, thereby prolonging the life of the equipment and ensuring sustainable operations
  • Master Data Interpretation: Gain proficiency in interpreting and utilizing data for diagnosing well and equipment issues, thereby enhancing the ability to make data-driven decisions for system improvement
  • Collaborate Effectively in Multidisciplinary Teams: Enhance collaboration skills by working effectively in multidisciplinary teams, sharing insights, and integrating knowledge from different aspects of artificial lift systems for improved operational outcomes
Courses in this discipline
Course outline
  • Basic concepts and necessity of artificial lift in oil production
  • Selection criteria for different lift systems
  • Economic analysis considerations
  • Wellbore and reservoir performance
  • Pressure loss in the wellbore
  • Well productivity and productivity index
  • Inflow and outflow relationships
  • Formation damage: causes and prevention
  • Black Oil PVT
  • Inflow Performance Relationships
  • Nodal Analysis Technology
  • Well production problems: asphaltenes, waxes, hydrates, inorganic, scale formation, corrosion
  • Impact of changing well conditions on lift requirements
  • Beam (Rod) Pump Systems
  • Gas Lift Systems
  • Electric Submersible Pumps (ESP)
  • Hydraulic and Jet Pumping / Progressing Cavity Pumping Systems
  • Surface and Subsurface Equipment
  • Power Requirements
  • Dynamometers and Troubleshooting
  • Optimization strategies
  • Designing a Sucker Rod Pump (SRP) System: Exercise
  • Principles of Gas Lift
  • Gas Lift Valves
  • Intermittent vs. Continuous Systems
  • Design and Operations: Exercise
  • Applications, Design and Selection
  • Installation and Operations
  • Troubleshooting and Best Practices
  • Designing an ESP System: Exercise
  • Concept, Design, and Limitations
  • Operating conditions and maintenance best practices
  • Selection Criteria
  • Designing a PCP System: Exercise
  • Best practices for each system
  • Techniques to maximize oil production economically
  • Design and operation under harsh conditions
  • Applying basic design and analysis concepts
  • Applying techniques to different scenarios
  • Case studies on system selection and design
  • Problem-solving exercises
Eni
Total
Eni
Endesa
Shell
Chevron
Gas Natural
Iberdrola
Eni
Inpex
Eni
Exonmobile

Training can take place in 4 formats:

  • Self-paced
  • Blended learning
  • Instructor-led online (webinar)
  • Instructor-led offline (classroom)

Description of training formats:

  • Self-paced learning or e-Learning means you can learn in your own time and control the amount of material to consume. There is no need to complete the assignments and take the courses at the same time as other learners.
  • Blended learning or "hybrid learning" means you can combine Self-paced learning or e-Learning with traditional instructor-led classroom or webinar activities. This approach requires physical presence of both teacher and student in physical or virtual (webinars) classrooms or workshops. Webinar is a seminar or presentation that takes place on the internet, allowing participants in different locations to see and hear the presenter, ask questions, and sometimes answer polls.
  • Instructor-led training, or ILT, means that the learning can be delivered in a lecture or classroom format, as an interactive workshop, as a demonstration under the supervision and control of qualified trainer or instructor with the opportunity for learners to practice, or even virtually, using video-conferencing tools.

When forming groups of students, special attention is paid to important criteria - the same level of knowledge and interests among all students of the course, in order to maintain stable group dynamics during training.

Group dynamics is the development of a group in time, which is caused by the interaction of participants with each other and external influence on the group. In other words, these are the stages that the training group goes through in the process of communicating with the coach and among themselves.

The optimal group size for different types of training:

  • Self-paced / E-learning: 1
  • Instructor-led off-line (classroom): 6 – 12
  • Instructor-led on-line (webinar): 6 – 12
  • Blended learning: 6 – 12
  • Workshop: 6 – 12
  • On-the-job: 2 – 4
  • Simulator: 1 – 2

Feedback in the form of assessments and recommendations is given to students during the course of training with the participation of an instructor and is saved in the course card and student profile.

In order to control the quality of the services provided, students can evaluate the quality and training programme. Forms of assessment of the quality of training differ for courses with the participation of an instructor and those that are held in a self-paced format.

For courses with an instructor, start and end dates are indicated. At the same time, it is important to pay attention to the deadlines for passing tests, exams and practical tasks. If the specified deadlines are missed, the student may not be allowed to complete the entire course programme.

A personal account is a space for storing your training preferences, test and exam results, grades on completed training, as well as your individual plan for professional and personal development.

Users of the personal account have access to articles and blogs in specialized areas, as well as the ability to rate the completed training and leave comments under the articles and blogs of our instructors and technical authors

Registered users of a personal account can have various roles, including the role of a student, instructor or content developer. However, for all roles, except for the student role, you will need to go through an additional verification procedure to confirm your qualifications.

Based on the results of training, students are issued a certificate of training. All training certificates fall into three main categories:

  • Certificate of Attendance - students who successfully completed the course but did not pass the tests and exams can apply for a certificate of attendance.
  • Certificate of Completion - students who have successfully completed a course could apply for a Certificate of Completion, this type of certificate is often required for compliance training.
  • Verified Certificate - it is a verified certificate that is issued when students have passed exams under the supervision of a dedicated proctor.

You can always download a copy of your training certificate in PDF format in your personal account.

You will still have access to the course after completing it, provided that your account is active and not compromised and Tecedu is still licensed for the course. So if you want to review specific content in the course after completing it, or do it all over again, you can easily do so. In rare cases, instructors may remove their courses from the Tecedu marketplace, or we may need to remove a course from the platform for legal reasons.

During the training, you may encounter various forms of testing and knowledge testing. The most common assessment methods are:

  • preliminary (base-line assessment) - to determine the current level of knowledge and adapt the personal curriculum
  • intermediate - to check the progress of learning
  • final - to complete training and final assessment of knowledge and skills, can be in the form of a project, testing or practical exam

Travel to the place of full-time training is not included in the cost of training. Accommodation during full-time studies can be included in the full board tuition fees.

While Tecedu is not an accredited institution, we offer skills-based courses taught by real experts in their field, and every approved, paid course features a certificate of completion or attendance to document your accomplishment.

You can preview samples of the training materials and review key information about the course on our website. You can also review feedback and recommendations from students who already completed this course.

We want you to be happy, so almost all purchased courses can be returned within 30 days. If you are not satisfied with the course, you can request a refund, provided the request complies with our return policy.

The 30-day money back policy allows students to receive quality teaching services with minimal risk, we must also protect our teachers from fraud and provide them with a reasonable payment schedule. Payments are sent to instructors after 30 days, so we will not process refund requests received after the refund period.

We reserve the right, in our sole discretion, to limit or deny refund requests in cases where we believe there is refund abuse, including but not limited to the following:

  • A significant portion of the course has been consumed or downloaded by a student before the refund was requested.
  • Multiple refunds have been requested by a student for the same course.
  • Excessive refunds have been requested by a student.
  • Users whose account is blocked or access to courses is disabled due to violation of our Terms and Conditions or the Rules of Trust and Security.
  • We do not grant refunds for any subscription services.
  • These refund restrictions will be enforced to the extent permitted by applicable law.

We accept most international credit and debit cards like Visa, MasterCard, American Express, JCB and Discover. Bank Transfers also may be an option.

Smart Virtual Classroom (open digital / virtual classroom).

Conducting classes is based on the fact that the teacher demonstrates text, drawings, graphics, presentations on an interactive board, while the content appears in the student's electronic notebook. A specially designed digital notepad and pen are used to create and edit text and images that can be redirected to any surface via a projector.

Classes are live streamed online, automatically recorded and published on the Learning Portal, allowing you to save them for reuse anytime, anywhere, on any mobile device. This makes it possible not to miss classes and keep up with classes and keep up with the passage of new material.

Game Based Learning (learning using a virtual game environment)

Real-life training uses the principles of game organization, which allows future professionals to rehearse and hone their skills in a virtual emergency. Learning as a game provides an opportunity to establish a connection between the learning activity and real life.

The technology provides the following learning opportunities:

  • Focused on the needs of the user
  • Instant feedback
  • Independent decision making and choice of actions
  • Better assimilation and memorization of the material
  • Adaptive pace of learning tailored to the individual needs of the student
  • Better transfer of skills learned in a learning situation to real conditions

Basic principles of training:

  • A gradual increase in the level of difficulty in the game;
  • Using a simplified version of a problem situation;
  • Action in a variable gaming environment;
  • The right choice is made through experimentation.

The main advantages of Game Based Learning technology:

  • Low degree of physical risk and liability
  • Motivation to learn while receiving positive emotions from the process;
  • Practice - mirroring the real situation
  • Timely feedback
  • Choice of different playing roles
  • Learning in collaboration
  • Developing your own behavior strategy
Laboratory workshops using remote access technologies

Conducting practical classes online using remote access technologies for presentations, multimedia solutions and virtual reality:

  • Laboratory workshops that simulate the operation of expensive bench equipment in real production
  • Virtual experiment, which is visually indistinguishable from a remote real experiment performed
  • Virtual instruments, which are an exact copy of real instruments
  • Mathematical modeling to clarify the physical characteristics, chemical content of the investigated object or phenomenon.
PROD001 – Artificial Lift Systems
Language: English, Russian
Level: Intermediate
mail@tecedu.org
+7 747 898 5041
+7 7182 901 933