Distance - Steam Turbine Technology (1.2 CEUs)

ARE YOU:

  • Looking for professional development but do not have the time to take off from work?

  • Looking for refresher course on specific engineering topics and cannot find an intensive course to serve your needs?

  • This may be your ideal Professional Development course!

Find out more on how the Professional Development Distance Program may work for you - Click here

Duration:

This course is approximately 3 weeks in duration.

Learning Method:

  • The PDDP program is more of a self-guided learning style.

  • You are required to read the notes and materials given, complete the follow-up assignments on your own, send in your questions prior to your 1 hour webinar meeting (if required) and be involved in live discussion via the internet.

  • Once you have completed the course, you will receive a certificate of completion

Course Description:

This seminar will cover all aspects of steam turbines including design and features of modern turbines, material, rotor balancing, features enhancing the reliability and maintainability of steam turbines, rotor dynamic analysis, Campbell, Goodman and SAFE diagrams, Blade failures: causes and solutions, maintenance and overhaul of steam turbines, and modeling of steam turbines. This seminar will also cover in detail all the components of these turbines, instrumentation, control systems, governing systems, and selection criteria. The main focus of this seminar will be on the failure modes of steam turbine components, causes and solutions for component failure, maintenance, refurbishment and overhaul, rotor dynamic analysis of steam turbines, and computer simulation of steam turbine rotor dynamics. All possible failure modes of steam turbine components and the maintenance required to prevent them will be discussed in detail. Examples of rotor dynamic analysis, and stability criteria will be covered thoroughly. This seminar will also provide up-dated information in respect to all the methods used to enhance the availability, reliability, and maintainability of steam turbines, increase the efficiency and longevity of steam turbines, and improve the rotor dynamic stability.

The PDDP Distance Education program works as follows:

  • Once you register for this course, you will be sent a login username and password for our online distance website.

  • You will receive the course notes in hard copy through the online website, you will receive a set of notes each week covering the course material.

  • A one hour video-conference session will be conducted by your instructor each week (if required). The objective of this session is to assist in solving the assignments, as well as answer student questions that should be sent to instructor early enough prior to the meeting time. In addition with being able to communicate with the instructor, you will also be able to communicate with other students in the same class and watch their questions being answered as well. (A high speed internet connection is strongly recommended for this feature).

  • Each set of exercises can be completed and submitted by the indicated date and your completed exercise will be marked online and and returned by your instructor.

  • To gain the most from your course, it is highly recommended that you participate fully in all discussions and exercises. Please remember that each course has a form of quiz or exercise at the end to test your understanding of the material. You will be informed of these dates when you receive the course schedule.

*Course commencement date is subject to instructor availability.

Philip Kiameh

Philip Kiameh, M.A.Sc., B.Eng., D.Eng., P.Eng. (Canada) has been a teacher at University of Toronto and Dalhousie University, Canada for more than 24 years. In addition, Prof Kiameh has taught courses and seminars to more than four thousand working engineers and professionals around the world, specifically Europe and North America. Prof Kiameh has been consistently ranked as "Excellent" or "Very Good" by the delegates who attended his seminars and lectures.
Prof Kiameh wrote 5 books for working engineers from which three have been published by McGraw-Hill, New York. Below is a list of the books authored by Prof Kiameh:
  1. Power Generation Handbook: Gas Turbines, Steam Power Plants, Co-generation, and Combined Cycles, second edition, (800 pages), McGraw-Hill, New York, October 2011.
  2. Electrical Equipment Handbook (600 pages), McGraw-Hill, New York, March 2003.
  3. Power Plant Equipment Operation and Maintenance Guide (800 pages), McGraw-Hill, New York, January 2012.
  4. Industrial Instrumentation and Modern Control Systems (400 pages), Custom Publishing, University of Toronto, University of Toronto Custom Publishing (1999).
  5. Industrial Equipment (600 pages), Custom Publishing, University of Toronto, University of Toronto, University of Toronto Custom Publishing (1999).
Prof. Kiameh has received the following awards:
  1. The first "Excellence in Teaching" award offered by the Professional Development Center at University of Toronto (May, 1996).
  2. The "Excellence in Teaching Award" in April 2007 offered by TUV Akademie (TUV Akademie is one of the largest Professional Development centre in world, it is based in Germany and the United Arab Emirates, and provides engineering training to engineers and managers across Europe and the Middle East).
  3. Awarded graduation “With Distinction” from Dalhousie University when completed Bachelor of Engineering degree (1983).
  4. Entrance Scholarship to University of Ottawa (1984).
  5. Natural Science and Engineering Research Counsel (NSERC) scholarship towards graduate studies – Master of Applied Science in Engineering (1984 – 1985).
Prof. Kiameh performed research on power generation equipment with Atomic Energy of Canada Limited at their Chalk River and Whiteshell Nuclear Research Laboratories. He also has more than 30 years of practical engineering experience with Ontario Power Generation (formerly, Ontario Hydro - the largest electric utility in North America).
While working at Ontario Hydro, Prof. Kiameh acted as a Training Manager, Engineering Supervisor, System Responsible Engineer and Design Engineer. During the period of time that Prof Kiameh worked as a Field Engineer and Design Engineer, he was responsible for the operation, maintenance, diagnostics, and testing of gas turbines, steam turbines, generators, motors, transformers, inverters, valves, pumps, compressors, instrumentation and control systems. Further, his responsibilities included designing, engineering, diagnosing equipment problems and recommending solutions to repair deficiencies and improve system performance, supervising engineers, setting up preventive maintenance programs, writing Operating and Design Manuals, and commissioning new equipment.
Later, Prof Kiameh worked as the manager of a section dedicated to providing training for the staff at the power stations. The training provided by Prof Kiameh covered in detail the various equipment and systems used in power stations.
Professor Philip Kiameh was awarded his Bachelor of Engineering Degree "with distinction" from Dalhousie University, Halifax, Nova Scotia, Canada. He also received a Master of Applied Science in Engineering (M.A.Sc.) from the University of Ottawa, Canada. He is also a member of the Association of Professional Engineers in the province of Ontario, Canada.

Steam Power Plants, Steam Turbine Components, Steam Turbine Auxiliaries, Impulse and Reaction Turbines, Rotor Balancing, Features of Advanced Steam Turbines, and Features Enhancing The Reliability and Maintainability of Steam Turbines

  • Review of thermodynamics principles, efficiency and heat rate
  • Steam power plants, steam turbines
  • Mechanisms of Energy Conversion in a Steam Turbine, Steam balance considerations
  • Steam turbine types (straight noncondensing, automatic extraction noncondensing, automatic extraction condensing
  • Steam turbine controls, Automatic extraction condensing controls,
  • Geared and direct-drive steam turbines, modular design concepts
  • Turbine components, Rotating and stationary blades
  • Steam Turbine casing and major stationary components: casing design, steam admission sections, steam turbine diaphragms and labyrinth packing
  • Steam turbine bearings: journal bearings for industrial turbo-machinery, fixed-geometry journal bearing stability, tilted-pad journal bearings, advanced tilting-pad journal bearings, lubrication-starved tilting pad bearings, key design parameters, thrust bearings for turbo-machinery, active magnetic bearings
  • Rotors for impulse turbines: long-term operating experiences, pitch diameter and speed, steam turbines, built-up construction, materials of construction for multi-stage steam turbines, solid construction, shaft ends, turbine rotor balance methods, at-speed rotor balancing, advantages and disadvantges of at-speed balancing, balance tolerance
  • Rotors for reaction turbines: solid rotors, finite element analysis for steam turbines, materials for solid rotors, welded rotor design, welded rotor materials
  • Thrust bearings, labyrinth seals
  • Steam turbine blade design: blade material, blade root attachments, types of airfoils and blading capabilities, guide blades for reaction turbines, low-pressure final stage blading, Campbell diagram
  • Turbine auxiliaries lube systems, barring or turning gears, trip-throttle or main stop valves, overspeed trip devices, gland seal systems, lube oil purifiers
  • Testing of Turbine blades
  • Quality Assurance of Turbine Generator Components
  • Assembly and testing of turbine components
  • Turbine Types, Compound Turbines
  • Turbine Control Systems
  • Steam Turbine Maintenance
  • Power Station Performance Monitoring
  • The Turbine Governing Systems
  • Steam Chests and Valves
  • Turbine Protective Devices
  • Turbine Instrumentation
  • Lubrication Systems
  • Gland Sealing System
  • Features of Advanced Steam Turbines
  • Constant and sliding pressure operation of steam turbines
  • Frequently Asked Questions about Turbine-Generator Balancing, Vibration Analysis and Maintenance
  • Steam turbine rotor failures: causes and solutions: rotor rubs, blade rubs causing bending, rotor and casing misalignment, bearing problems, alignment of diaphragms, achieving precise alignment, rotor imbalance, corrosion causing rotor imbalance, failures due to poor maintenance, casing problems
  • Steam Turbine Deposition, Erosion, and Corrosion
  • Features Enhancing The Reliability and Maintainability of Steam Turbines: steam turbine design, measures of reliability, availability, and maintainability, design attributes enhancing reliability, overall mechanical design approach, modern steam turbine design features, design attributes enhancing maintainability, maintainability features, maintenance recommendations, cost/benefit analysis of high reliability, availability, and maintenance performance, reliability, availability, and maintainability value calculation

Steam Turbine Rotor Dynamic Analysis, Campbell, Goodman, and SAFE Diagrams, Advanced Steam Turbine Design, Materials and Coatings, Steam Turbine Blade Failures, Causes and Solutions, Maintenance and Overhaul of Steam Turbines

  • Steam turbine rotor dynamic technology: rotor model, dynamic stiffness, effects of damping on critical speed prediction, bearing-related developments, refinements, bearing support considerations, foundations, impedance, partial arc forces, design procedure, rotor response, instability mechanisms, sub-synchronous vibration, service examples, labyrinth and cover seal forces, rotor stability criteria, experimental verification
  • Campbell, Goodman, and SAFE Diagrams for Steam Turbine Blades: Goodman diagram, Goodman-Soderberg diagram, Campbell diagram, exciting frequencies, SAFE diagram-evaluation tool for packeted bladed disk assembly, definition of resonance, mode shape, fluctuating forces, SAFE diagram for bladed disk assembly, mode shapes of a packeted bladed disk, interference diagram beyond N/2 limit, explaining published data by using SAFE diagram
  • Frequency Evaluation of Steam Turbine Rotors: natural frequency and mode shape, vibratory forces, resonance, Campbell diagram, SAFE diagram,
  • Reaction vs impulse type steam turbines: impulse and reaction turbines compared, efficiency, design, impulse type, reaction type, critical speed, blading, vibration, control stage, full-admission stages, blade damage, blade clearances, erosion, axial thrust, maintenance, design features of modern reaction turbines, deposit formation and turbine water washing
  • Shortcut graphical methods of turbine selection: estimating steam rates, steam turbine selection procedure, examples of steam turbine selection, quick reference information to estimate steam rates of multivalve multistage steam turbines
  • Elliott shortcut selection method for multivalve, multistage steam turbines: approximate steam rates, stage performance determination, examples of steam turbine selection process, extraction turbine performance
  • Rerates, Upgrades, and Modifications of Steam Turbines: performance and efficiency upgrade, brush seals and labyrinth seals, wavy face dry seals, replacing carbon rings with wavy dry seals, design goals and available technologies, seal design specifics, installation of seals, installation sequence, cost vs. benefit analysis, buckets, reliability upgrade, electronic controls, monitoring systems, life extension, modification and reapplication, casing, flange sizing, nozzle ring capacity, steam path analysis, rotor blade loading, thrust bearing loading, governor valve capacity, rotor, shaft and reliability assessment, speed range changes, auxiliary equipment review, oil mist lubrication for general-purpose steam turbines, wet sump (purge mist) vs. dry sump (pure mist) application, control and application of oil mist, header temperature and header size, experience and conducting comments, problem solving
  • Advanced Ultra Supercritical Steam Turbine Materials: design of ultra supercritical steam turbines, steam oxidation, creep resistance, rupture ductility, nickel-based alloys, creep curves of different steam turbine materials, yield strength of different steam turbine materials, temperature capabilities of nickel-based superalloys for high pressure and intermediate pressure steam turbines, composition of various high-temperature superalloys considered for advanced ultra supercritical steam turbines, advanced ultra supercritical turbine designs using nickel-based superalloys
  • Advanced Steam Turbine Design, Materials, and Coatings: materials used in advanced steam turbines, design and materials used in high pressure steam turbine rotors, intermediate pressure rotors, steam turbine casings, and bolting, rotor materials – advanced processing of current alloys, nickel-base rotors, welding of udimet 720 and Inconel 617, isothermally forged nickel-base rotors, high temperature disc materials, rotor blade materials – advanced processing of current alloys, erosion resistant coatings, casing materials and large scale nickel castings, bolting – high temperatures bolt alloy, high strength pipe materials, efficiency improvement of steam turbines, characteristics of 50 and 60-inch last stage blades, fluid performance design, development of supersonic turbine blades, structural reliability design, vibration design, conclusions
  • Steam Turbine Blade Failures, Causes and Solutions, failure investigation
  • Steam turbine risk assessment – a tool for optimizing inspection and overhauls of steam turbines: outage planning factors,
  • Maintenance and Overhaul of Steam Turbines: steam turbine component characteristics, failure mechanisms, arrangements and applications, monitoring, operations, maintenance, and training infrastructure, steam turbine availability and failure experience, scheduled maintenance and overhaul practices, approaches/methodologies/criteria for establishing longer time intervals between major overhauls, issues with new steam turbine technologies and applications
  • Methods of Strategic Oil Flushing Program; high-velocity turbine lube oil flushing using pulse-induced wave technology
  • Turbine Blasting
  • Steam Turbine Rotor Dynamic Analysis: comparative analysis of different components of rotor dynamic stability, Bode plot of rotor dynamic analysis
  • Steam Turbine Rotor Dynamics and Vibration Diagnostics
  • Modeling of Steam Turbine Rotor Dynamics: understanding rotor dynamics, solid model rotor dynamics, modeling methods, results
  • Advanced Water Treatment Technology: reverse osmosis systems, nanofiltration, ultrafiltration and microfiltration, electrodeionization (EDI), activated carbon filtration, multimedia filtration, ozonation systems, ultraviolet irradiation, steam turbine water treatment
  • Glossary of turbo-machinery and related equipment terms
  • Computer Simulation of Steam Turbine Rotor Dynamics: rotor equations, examples of computer simulation of rotor dynamic analysis

GIC reserves the right to cancel or change the date or location of its events. GIC's responsibility will, under no circumstances, exceed the amount of the fee collected. GIC is not responsible for the purchase of non-refundable travel arrangements or accommodations or the cancellation/change fees associated with cancelling them. Please call to confirm that the course is running before confirming travel arrangements and accommodations. Please click here for complete policies.

This is a Professional Development Distance Program course. These are open to a start date after you register, not scheduled for a specific date.

We could offer any of our courses at a location of your choice and customized contents according to your needs, please contact us at : inhouse@gic-edu.com or click here  to submit an online request.


Course Materials

Each participant will receive a complete set of course notes and handouts that will serve as informative references.

$1,045

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CEUs Certificate

A certificate of completed Continuing Education Units (CEUs) will be granted at the end of this course. A fee is required for all complimentary webinars.

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