Friday, July 23, 2010

IAR Embedded Workbench for AVR v5.50

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IAR Embedded Workbench for AVR v5.50

IAR Embedded Workbench for AVR v5.50 | 196 MB


IAR Embedded Workbench for AVR - is a powerful integrated development environment and debug programs for the AVR Microcontroller with assembly language, C and C + +. It provides extensive support for AVR devices and generates very compact and efficient code. It includes a C compiler and C + +, assembler, linker and debugger, with the possible interaction with external programs such as AVR Studio. Built-in editor specially configured C syntax, and additional tools and a good built-in help system further facilitates writing programs.

Source Editor
- Convenient user interface;
- Automatic allocation errors
- Customizable toolbar;
- Allocation directives C / C + +;
- Developed search tools.

Compiler C / C + +
- One of the best compilers on the effectiveness of the code;
- Full compatibility with ANSI C;
- Several models for the efficient allocation of memory;
- Optimization algorithms specifically for the AVR-microcontroller;
- Language extensions for embedded systems.

Assembler
- Integrated Macroassembler for real-time applications;
- Includes a compiler preprocessor for C.

Linker
- Supports full layout, placement, and establishment size;
- Supports more than 30 standard output formats for use with in-circuit emulator;
- Load modules only when needed;
- Output format is fully compatible with AVR Studio.

Simulator and debugger
- Debugging in codes C, C + + and assembler;
- Multiple breakpoints;
- Language descriptions of the periphery and I / O;
- View domains CODE, DATA, EEPROM, and register I / O;
- Handling interrupts with the prediction;
- Control all the variables and stack;
- Complex data types.

It supports most of the microcontrollers Atmel AVR.

Main innovations
IAR Embedded Workbench for AVR microcontrollers now supports ATtiny4, ATtiny5, ATtiny9, ATtiny10, ATtiny20 and ATtiny40.

Requirements
- Operating system Microsoft Windows XP (SP3), Vista (SP2) or Windows 7.
- 1 GB of RAM and 900 MB of free disk space.
- Adobe Acrobat Reader, to access the product documentation.

Year: 2010
Developer: IAR SYSTEMS
OC: Windows XP/Vista/7
Language: English
Medicine: Yes (Crack)

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Thursday, July 22, 2010

Electronics Workbench 5.12

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Electronics Workbench 5.12

Electronics Workbench 5.12 | 7MB


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Wind Energy Systems for Electric Power Generation

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Wind Energy Systems for Electric Power Generation
Springer | 2008 | ISBN: 3540687629 | PDF | 194 pages | 10,7 MB

This book deals with the electronics of Wind-Energy systems and their implementation into the grid. Starting from an overview on energy conversion and general concepts for Wind Energy systems, the concept, design and control of the electrical components are treated: generators, converters and storage devices. Much attention is spent on the implementation of Wind turbines and the requirements for power quality are non-trivial tasks. In this way, the book provides the fundamental knowledge for designer and developer of wind energy systems.

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Wind Power Integration: Connection and system operational aspects

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Wind Power Integration: Connection and system operational aspects

Wind Power Integration: Connection and system operational aspects
The Institution of Engineering and Technology | Pages: 288 | 2007-01-01 | ISBN 0863414494 | PDF | 13 MB


The rapid growth of wind power and the implications of this on future power system planning, operation and control has become an even greater challenge in today's liberated electricity market conditions. This essential new book examines the main problems of wind power integration and guides the reader through a number of the most recent solutions based on current research and operational experience of wind power integration.

This new series of books from the IET brings together the engineering aspects of renewable energy technology, power generation and systems integration. Covering all aspects of renewable and sustainable power and highlighting the key principles behind each technology, its state of development and its relevance in the power industry. With energy and sustainability being areas of primary concern, these books are practical in approach and appeal to specialists and non-specialists alike, providing a thorough understanding to the economical and environmental issues as well as key engineering features.

The Institution of Engineering and Technology is one of the world's leading professional societies for the engineering and technology community. The IET publishes more than 100 new titles every year; a rich mix of books, journals and magazines with a back catalogue of more than 350 books in 18 different subject areas including:

-Power & Energy
-Renewable Energy
-Radar, Sonar & Navigation
-Electromagnetics
-Electrical Measurement
-History of Technology
-Technology Management


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Tuesday, July 20, 2010

NI Multisim 10 : Electronics Workbench Suite Power Pro

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NI Multisim 10 : Electronics Workbench Suite Power Pro

NI Multisim 10 : Electronics Workbench Suite Power Pro | 280MB

Multisim is part of the latest suite of innovative circuit design software from Electronics Workbench, providing the unparalleled power and flexibility of truly interactive simulations. Multisim provides schematic capture and simulation, including patented co-simulation of SPICE and VHDL, for the professional designer.Also, included in the Electronics Workbench suite are Ultiboard for advanced PCB Layout and Ultiroute for grid-based or gridless autoroutingMultisim is a powerful simulation tool that includes a complete, fully integrated version of Multicap for design entry leading to simulation.Verify circuits and locate errors before they propagate further down the design flow and become costly mistakes.Investigate circuits using the industry’s only virtual instruments and "change-on-the-fly” interactive simulation.Gain true understanding of your circuit’s performance with a comprehensive suite of analyses. Multisim helps optimize designs and minimize time-to-market.

Multisim, the world’s only interactive circuit simulator, allows you to design better products in less time.

Multisim includes a completely integrated version of Multicap, making it the ideal tool for creating and then instantly simulating circuits.

Multisim 9 also offers integration with National Instruments LabVIEW and SignalExpress, allowing you to tightly integrate design and test.

Featuring unparalleled ease-of-use and packed with unique and powerful functions, Multisim boasts an impressive history that has made it the most successful simulator in the industry with over 180,000 users worldwide. Combined with Multisim’s aggressive price, there is now no reason not to simulate every design.

TIME-SAVING PRODUCT INNOVATIONS:

* Integration with National Instruments LabVIEW and SignalExpress
* A 67% increase in simulation speed
* Simulated “real” Tektronix® instruments
* Robust measurement probes annotate circuit with dynamic values
* Support for design variants
* Simulation profiles (save and reuse SPICE parameter sets)
* New Circuit Wizards and Model Makers
* Powerful new Worst-Case Analysis
* Significantly enhanced schematic capture, including industry-leading bus support
* Full support for hierarchical designs
* Comprehensive circuit-annotation capabilities

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Transient Analysis of Electric Power Circuits Handbook

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Transient Analysis of Electric Power Circuits Handbook
Transient Analysis of Electric Power Circuits Handbook
2005 | 569 pages | ISBN:0387287973 | PDF | 25 Mb

This transient analysis of electric circuits handbook is a unique text, which covers most of the useful methods of transient analysis of electrical circuits. The book is written from a power engineering viewpoint as compared to the numerous texts dedicated to electronic and communication engineering. One of the most important features of the book is that it covers the topic methodically "from simple to complicated" and therefore it will be helpful to all those specializing in electrical engineering for a better understanding of the very specific technical books

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Word Power Made Easy

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Word Power Made Easy

Word Power Made Easy
Pocket 1991 | ISBN-10: 067174190X | 528 Pages | LQ PDF | 88 MB


Do You Always Use the Right Word?
Can You Pronounce It -- and Spell It -- Correctly?
Do You Know How to Avoid Illiterate Expressions?
Do You Speak Grammatically, Without Embarrassing Mistakes?
If the answer to any of these questions is NO, you ought to read Word Power Made Easy. Now thoroughly revised to eliminate outmoded references and to to reflect current idioms, it remains the best and quickest means to a better vocabulary in the English language.

Each chapter ends with review. Each section ends with a progressive check. Numerous tests will help you increase and retain the knowledge you acquired. Word Power Made Easy does more than just ass words to you vocabulary. It teaches ideas and a method of broadening knowledge as an integral part of the vocabulary building process.


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Electric Power Distribution Handbook (Electric Power Engineering Series)

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Electric Power Distribution Handbook (Electric Power Engineering Series)
Electric Power Distribution Handbook (Electric Power Engineering Series)
2003 | 784 pages | ISBN: 0849317916| PDF | 7 Mb

This book is also a comprehensive source for the hard-to-find tables, graphs, methods, and statistics that distribution system engineers need. It includes tips and solutions for solving problems and improving performance, all aimed at delivering the best quality while keeping costs down. In short, the Electric Power Distribution Handbook gives readers the tools they need to understand the science and practices of distribution systems.

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Friday, July 16, 2010

Developments in the Design of Thermal Systems

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Developments in the Design of Thermal Systems
Developments in the Design of Thermal Systems
Cambridge University Press | 1997 | 308 pages | ISBN:0521462045 | PDF | 7.2 Mb

As the cost and complexity of designing thermal systems have increased, the need to understand and improve the design process has also grown. This book describes recent progress. The book begins with a brief history and outline of developments in thermal system design. Chapters then discuss computer design tools for the power and chemical industries, predicting physical properties with computational tools, "pinch analysis" to improve thermal efficiency, applications of the energy concept, thermoeconomics, and the potential for artificial intelligence and expert systems in the design of thermal systems

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Invention Of Integrated Circuits: Untold Important Facts (International Series on Advances in Solid State Electronics)

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Invention Of Integrated 
Circuits: Untold Important Facts (International Series on Advances in 
Solid State Electronics)


Invention Of Integrated Circuits: Untold Important Facts (International Series on Advances in Solid State Electronics)
World Scientific Publishing Company | English | 2009-04-01 | ISBN: 9812814450 | 550 pages | PDF | 32,4 MB


This book is the first to give an authoritative and comprehensive account of the invention of Integrated Circuits (ICs) from an insider who had participated and contributed from the beginning of their invention and advancement to the Ultra Large Scale ICs (ULSICs) of today. It reads like a mystery novel to engross the reader, but it is not based on fiction; it gives documented facts of the invention of ICs, analyzes the patents, and highlights additional details and clarifications to its history.


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Technology Computer Aided Design for Si, SiGe and GaAs Integrated Circuits

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Technology Computer Aided
 Design for Si, SiGe and GaAs Integrated Circuits


C.K. Maiti, G.A. Armstrong "Technology Computer Aided Design for Si, SiGe and GaAs Integrated Circuits"
IET | English | 2007-01-01 | ISBN: 0863417434 | 456 pages | PDF | 3,3 MB


The first book to deal with a broad spectrum of process and device design, and modelling issues related to semiconductor devices, bridging the gap between device modelling and process design using TCAD. Examples for types of Si-, SiGe-, GaAs- and InP-based heterostructure MOS and bipolar transistors are compared with experimental data from state-of-the-art devices. With various aspects of silicon heterostructures, this book presents a comprehensive perspective of emerging fields and covers topics ranging from materials to fabrication, devices, modelling and applications. Aimed at research-and-development engineers and scientists involved in microelectronics technology and device design via Technology CAD, and TCAD engineers and developers.


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Millimeter-Wave Integrated Circuits

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Millimeter-Wave Integrated Circuits
Millimeter-Wave Integrated Circuits
Publisher: Springer 2004 | 272 Pages | ISBN: 0387236651 | PDF | 11 MB

This book will consist of a detailed overview of MMIC design, specifically focusing on designs for the millimeter-wave (mm-wave) frequency range. The scope of the book will be quite broad, and will include detailed discussions on high frequency materials and technologies, high frequency devices, and the design of high frequency circuits. The design material will be supplemented as appropriate by theoretical analyses. The broad scope of the book will give the reader a good theoretical and practical understanding of mm-wave circuit design.

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Thermal and Power Management of Integrated Circuits

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Thermal and
 Power Management of Integrated Circuits
Thermal and Power Management of Integrated Circuits
Springer | 2006 | 179 pages | ISBN:0387257624 | PDF | 8 Mb

This book reviews the significance of the junction temperature as a reliability measure under nominal and burn-in conditions. The latest research in the area of electro-thermal modeling of integrated circuits will also be presented. Recent models and associated CAD tools are covered and various techniques at the circuit and system levels are reviewed. Subsequently, the authors provide an insight into the concept of thermal runaway and how it may best be avoided. A section on low temperature operation of integrated circuits concludes the book.

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Engineering Thermodynamics of Thermal Radiation: for Solar Power Utilization

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Engineering Thermodynamics of Thermal Radiation: for Solar Power 
Utilization
Engineering Thermodynamics of Thermal Radiation: for Solar Power Utilization
McGraw-Hill Professional | 2010 | 416 pages | ISBN:0071639624 | PDF | 6.8 Mb

This comprehensive guide reviews the fundamentals of the thermodynamics of radiation matter--photon gas. The book introduces the exergy of radiation through the most advanced thermodynamic analysis of the solar power processes involving radiation.

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Power Electronic Modules: Design and Manufacture

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Power 
Electronic Modules: Design and Manufacture
Power Electronic Modules: Design and Manufacture
CRC | 2004 | 296 pages | ISBN:084932260X | PDF | 8 Mb

Designing and building power semiconductor modules requires a broad, interdisciplinary base of knowledge and experience, ranging from semiconductor materials and technologies, thermal management, and soldering to environmental constraints, inspection techniques, and statistical process control. This diversity poses a significant challenge to engineers, and a book that brings together the essential elements of these technologies is long overdue. Power Electronic Modules: Design and Manufacture fills that void. It covers not only the basic technologies, but also the latest advances in these areas. Organized into three main sections, coverage begins with discussions on the materials used and their key properties

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Power Hybrid Circuit Design and Manufacture

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Power 
Hybrid Circuit Design and Manufacture
Power Hybrid Circuit Design and Manufacture
CRC | 1996 | 496 pages | ISBN:0824797493 | PDF | 10 Mb

Microelectronics and Reliability " [an] authoritative reference ...should be in the hands of every designer of hybrid circuits." Review "This handbook concentrates on a variety of design and manufacturing techniques and materials used in high reliability military and commercial power hybrids.

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Rating of Electric Power Cables in Unfavorable Thermal Environment

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Rating of
 Electric Power Cables in Unfavorable Thermal Environment
Rating of Electric Power Cables in Unfavorable Thermal Environment
Wiley-IEEE Press | 2006 | 326 pages | ISBN:0471679097 | PDF | 13.8 Mb

Rating of Electric Power Cables in Unfavorable Thermal Environment is the first text to provide you with the computational tools and techniques needed to successfully design and install power cables in areas affected by such factors as outside heat sources, ground moisture, or impediments to heat dissipation. After thoroughly reviewing standard rating models, the author discusses several new techniques designed to improve cable ampacity, as well as new computational techniques for analysis of cyclic loads.

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Computer Simulations in Condensed Matter: From Materials to Chemical Biology. Volume 2

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Computer Simulations in Condensed Matter: From Materials to Chemical Biology. Volume 2
Publisher: Springer; 1 edition (December 4, 2006) | ISBN: 354035283X | Pages: 599 | PDF | 61 MB

This extensive and comprehensive collection of lectures by world-leading experts in the field introduces and reviews all relevant computer simulation methods and their applications in condensed matter systems. Volume 1, published as LNP 703 (ISBN 3-540-35270-8) is an in-depth introduction to a vast spectrum of computational techniques for statistical mechanical systems of condensed matter. It will enable the graduate student and both the specialist and nonspecialist researcher to get acquainted with the tools necessary to carry out numerical simulations at an advanced level.

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Elements of Chemical Reaction Engineering (4th Edition)

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Elements of Chemical Reaction Engineering (4th Edition)
Prentice Hall PTR; 4 edition (September 2, 2005) | English | 0130473944 | 1080 pages | PDF | 103.70 MB

The fourth edition of Elements of Chemical Reaction Engineering is a completely revised version of the worldwide best-selling book. It combines authoritative coverage of the principles of chemical reaction engineering with an unsurpassed focus on critical thinking and creative problem solving, employing open-ended questions and stressing the Socratic method. Clear and superbly organized, it integrates text, visuals, and computer simulations to help readers solve even the most challenging problems through reasoning, rather than by memorizing equations.

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Hawley's Condensed Chemical Dictionary (15th Edition)

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Hawley's Condensed 
Chemical Dictionary (15th Edition)
Hawley's Condensed Chemical Dictionary (15th Edition)
Wiley-Interscience (January 29, 2007) | ISBN: 0471768650 | PDF | 1400 pages | 22.9 Mb

Hawley's Condensed Chemical Dictionary, 15th Edition is a compilation of technical data and descriptive information covering thousands of chemicals and chemical phenomena, trade name products, processes, reactions, products, and related terminology.

* Updates and expands the coverage from the previous edition.
* Adds entries for notable chemists and Nobel Prize winners, equipment and devices, natural forms and minerals, named reactions, and chemical processes.
* Provides concise, condensed, and prompt definitions of terms and phenomena in chemistry, biology, biochemistry, and more.
* Is ideal for those with only minutes to devote to any given chemical substance or topic.

Flow Measurement Handbook: Industrial Designs, Operating Principles, Performance, and Applications

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Flow Measurement Handbook:
 Industrial Designs, Operating Principles, Performance, and 
Applications
Flow Measurement Handbook: Industrial Designs, Operating Principles, Performance, and Applications
Cambridge University Press | 2000 | ISBN: 0521480108, 0521017653 | 524 pages | PDF | 17,5 MB

This volume is an information-packed reference for engineers on flow measuring techniques and instruments. Striking a balance between laboratory ideal and the realities of field experience, this handy tool provides a wealth of practical advice on the design, operation, and performance of a broad range of flowmeters.

The book begins with a brief review of fluid mechanics principles, how to select a flowmeter, and a variety of calibration methods. Each of the following chapters is devoted to a class of flowmeters and includes detailed information on design, applications, installation, calibration, operation, and advantages and disadvantages. Among the flowmeters discussed are orifice plate meters, venturi meter and standard nozzles, critical flow venturi nozzles, positive displacement flowmeters, turbine and related flowmeters, vortex shedding and fluidic flowmeters, electromagnetic flowmeters, ultrasonic flowmeters, and coriolis flowmeters. Also covered are mass flow measurements using multiple sensors, thermal flowmeters, angular momentum devices, probes, and modern control systems. Many chapters conclude with an appendix on the theory behind the techniques discussed. It will be a valuable reference for practicing engineers and will also be of interest to researchers in mechanical, chemical and aerospace engineering.

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The Condensed Handbook of Measurement and Control, 3rd Edition

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The 
Condensed Handbook of Measurement and Control, 3rd Edition
The Condensed Handbook of Measurement and Control, 3rd Edition
2006 | 441 pages | ISBN:1556179952 | PDF | 22 Mb

Selecting and implementing measurement and control devices for process automation applications is made easier with this best-selling reference. This clear and concise third edition provides quick access to ISA symbology, instrument and control valve selection criteria, and conversion guidelines, with new sections on maintenance, calibration, decision-making skills, and consulting. A bonus CD-ROM is also included. Whether you are an experienced engineer, technician, salesperson, or project manager, or new to the field, you will better understand how to assess, compare, and select the various methods of measurement and control with this valuable and economical handbook in your library.

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Classical Topology and Combinatorial Group Theory

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Classical
 Topology and Combinatorial Group Theory
Classical Topology and Combinatorial Group Theory
2000 | 352 pages | ISBN:0387979700 | PDF | 11 Mb

This is a well-balanced introduction to topology that stresses geometric aspects. Focusing on historical background and visual interpretation of results, it emphasizes spaces with few dimensions, where visualization is possible, and interaction with combinatorial group theory via the fundamental group. It also present algorithms for topological problems. Most of the results and proofs are known, but some have been simplified or placed in a new perspective. Over 300 illustrations, many interesting exercises, and challenging open problems are included. New in this edition is a chapter on unsolvable problems, which includes the first textbook proof that the main problem of topology, the homeomorphism problem, is unsolvable.

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How to Be Irresistible to Colleges: The Essential Guide to Being Accepted

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How to 
Be Irresistible to Colleges: The Essential Guide to Being Accepted
How to Be Irresistible to Colleges: The Essential Guide to Being Accepted
2009 | pages | ISBN:1932662324 | PDF | 15 Mb

Likening the search for the perfect college to the search for the perfect mateboth are confusing, stressful, and importantthis guide full of real-world examples and advice from students and college admissions deans, makes the admissions process clear to both students and their parents. Offering answers to the applicant's common questionsWhat should I expect in an interview? What should I do if I am wait-listed? How can I improve my scores?the relatable resource

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Handbook of Electrical Engineering Calculations

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Handbook of Electrical Engineering Calculations
Handbook of Electrical Engineering Calculations
1999 | 336 pages | ISBN:0824719557 | PDF | 6 Mb

Identifies and solves the seminal problems with numerical techniques for the principal branches of the field; electric power, electromagnetic fields, signal analysis, communication systems, control systems, and computer engineering. DLC: Electrical engineering Problems, exercises.
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Transformer and Inductor Design Handbook (Electrical Engineering and Electronics, Vol 49)

0 comments
Transformer and Inductor Design Handbook (Electrical Engineering 
and Electronics, Vol 49)
Transformer and Inductor Design Handbook (Electrical Engineering and Electronics, Vol 49)
2000 | 416 pages | ISBN:0824778286 | PDF | 7.5 Mb

This useful Second Edition gives an in-depth look at how the core geometry Kg approach affects power transformation regulation capability, transformer design, inductor energy-handling capability, gapped inductor design, and toroidal inductor design.

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Optimal Control Systems (Electrical Engineering Handbook)

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Optimal
 Control Systems (Electrical Engineering Handbook)
Optimal Control Systems (Electrical Engineering Handbook)
2001 | 464 pages | ISBN:0849308925 | PDF | 14 Mb

The theory of optimal control systems has grown and flourished since the 1960's. Many texts, written on varying levels of sophistication, have been published on the subject. Yet even those purportedly designed for beginners in the field are often riddled with complex theorems, and many treatments fail to include topics that are essential to a thorough grounding in the various aspects of and approaches to optimal control.Optimal Control Systems provides a comprehensive but accessible treatment of the subject with just the right degree of mathematical rigor to be complete but practical. It provides a solid bridge between "traditional" optimization using the calculus of variations and what is called "modern" optimal control. It also treats both continuous-time and discrete-time optimal control systems

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RF and Microwave Passive and Active Technologies

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RF and 
Microwave Passive and Active Technologies
RF and Microwave Passive and Active Technologies
2007 | 736 pages | ISBN:0849372208 | PDF | 8 Mb

In the high frequency world, the passive technologies required to realize RF and microwave functionality present distinctive challenges. SAW filters, dielectric resonators, MEMS, and waveguide do not have counterparts in the low frequency or digital environment. Even when conventional lumped components can be used in high frequency applications, their behavior does not resemble that observed at lower frequencies. RF and Microwave Passive and Active Technologies provides detailed information about a wide range of component technologies used in modern RF and microwave systems.

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Handbook of Multisensor Data Fusion: Theory and Practice, Second Edition

0 comments
Handbook of Multisensor Data Fusion: Theory and Practice, Second 
Edition
Handbook of Multisensor Data Fusion: Theory and Practice, Second Edition
2008 | 856 pages | ISBN:1420053086 | PDF | 8 Mb

Handbook of Multisensor Data Fusion: Theory and Practice, Second Edition represents the most current concepts and theory as information fusion expands into the realm of network-centric architectures. It reflects new developments in distributed and detection fusion, situation and impact awareness in complex applications, and human cognitive concepts. With contributions from the world’s leading fusion experts, this second edition expands to 31 chapters covering the fundamental theory and cutting-edge developments that are driving this field.

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Computers, Software Engineering, and Digital Devices (Electrical Engineering Handbook)

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Computers, Software Engineering, and Digital Devices (Electrical 
Engineering Handbook)
Computers, Software Engineering, and Digital Devices (Electrical Engineering Handbook)
2005 | 576 pages | ISBN: 0849373409 | PDF | 9.8 Mb

Computers, Software Engineering, and Digital Devices examines digital and logical devices, displays, testing, software, and computers, presenting the fundamental concepts needed to ensure a thorough understanding of each field. It treats the emerging fields of programmable logic, hardware description languages, and parallel computing in detail. Each article includes defining terms, references, and sources of further information. Encompassing the work of the world's foremost experts in their respective specialties, Computers, Software Engineering, and Digital Devices features the latest developments, the broadest scope of coverage, and new material on secure electronic commerce and parallel computing.

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Electrical Power Systems Quality, 2nd Edition

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Electrical Power Systems Quality, 2nd Edition
Electrical Power Systems Quality, 2nd Edition
McGraw-Hill 2002 | ISBN-10: 007138622X | 528 Pages | PDF | 5 MB

Dugan's book is an excellent reference on power quality. Nicely organized, starting with terms and definitions, and finishing with advice on making measurements. Very readable, with minimal use of equations, and maximum use of sketches, drawings, and graphical data. A must have for every power quality professional

* Basic power quality strategies and methods to protect electronic systems

* Nearly twice the size of the last edition--new chapters on distributed generation and benchmarking--over 200 pages of new material

"A reader from Santa Cruz, CA; Dugan's book is an excellent reference on power quality. Nicely organized, starting with terms and definitions, and finishing with advice on making measurements. Very readable, with minimal use of equations, and maximum use of sketches, drawings, and graphical data. A must have for every power quality professional

http://hotfile.com/dl/52766457/a1a8ff6/Electrical.rar.html

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Dictionary Of Energy Efficiency Technologies

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Dictionary Of Energy Efficiency Technologies
Dictionary Of Energy Efficiency Technologies
9Mb | PDF | 359 pages | ISBN-10: 0881734551 | English
[/center]

Review Source: Product Description
The comprehensive Dictionary of Energy Efficiency Technologies addresses the diverse topics that form the backbone of energy efficiency in a timesaving dictionary format. Entries include a broad range of important topics, covering such areas as advanced power system infrastructure, power options and configurations, systems of generator backup, redundancy, capacity, power quality problems, power protection, computer-controlled systems, auditing, energy reduction, lighting systems, cogeneration, waste heat recovery, and HVAC systems. Each entry ranges from one to several pages in length and covers critical issues and solutions in many important emerging areas of the energy efficiency field.

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Technologies for Electrical Power Conversion, Efficiency, and Distribution: Methods and Processes

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Technologies for Electrical Power Conversion, Efficiency, and 
Distribution: Methods and Processes

Technologies for Electrical Power Conversion, Efficiency, and Distribution: Methods and Processes
IGI Global | 2009 | ISBN: 1615206477 | 427 pages | PDF | 14 MB


As societal population increases, the need for energy becomes a crisis of great importance.
Technologies for Electrical Power Conversion, Efficiency, and Distribution: Methods and Processes combines unparalleled research, contemporary achievements, and emerging trends within electrical energy conversion technologies and renewable energy sources. The scholarly findings compiled provide a background for discussion of the problems and opportunities of power efficiency and energy conversion in order to develop innovative ways to implement such cutting-edge technologies in the future.
 
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Transmission and Distribution Electrical Engineering, Third Edition

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Transmission and Distribution Electrical Engineering, Third 
Edition
Transmission and Distribution Electrical Engineering, Third Edition
2006 | 1040 pages | ISBN:0750666730 | PDF | 8.6 Mb

Most books on transmission and distribution electrical engineering are student texts that focus on theory, brief overviews, or specialised monographs. Colin Bayliss and Brian Hardy have produced a unique and comprehensive handbook aimed squarely at practising engineers and planners involved in all aspects of getting electricity from the power plant to the user via the power grid.

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Wednesday, July 14, 2010

50 Inspirational Positive Quotes That Make You Think By Ellesse Chow

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inspirational quotes
I’ve always have this penchant for inspirational positive quotes. It’s amazing what those mere strings of words can do. Seemingly simple. Yet interestingly profound.
If you’ve some time today, I invite you to join me in this self discovery journey as we go through this 50 wonderful inspirational positive quotes.
Indulge in the tranquil moment as you read with both your eyes and heart.
Remember, eyes may provide sight. But it’s the heart which gives insight.
Enjoy.

“Think like a man of action, and act like a man of thought.”
- Henri L. Bergson
“I am only one, but still I am one. I cannot do everything, but still I can do something. And because I cannot do everything I will not refuse to do the something that I can do.”
Hellen Keller
“Half of the troubles of this life can be traced to saying yes too quickly and not saying no soon enough.”
- Josh Billings
“Even if you’re on the right track, you’ll get run over if you just sit there”
- Will Rogers
“Man often becomes what he believes himself to be. If I keep on saying to myself that I cannot do a certain thing, it is possible that I may end by really becoming incapable of doing it. On the contrary, if I have the belief that I can do it, I shall surely acquire the capacity to do it even if I may not have it at the beginning.”
- Mahatma Gandhi
“You can never cross the ocean unless you have the courage to lose sight of the shore.”
- Christopher Columbus
“To a brave man, good and bad luck are like his left and right hand. He uses both.”
- St Catherine of Siena
“When one door of happiness closes, another opens, but often we took so long at the closed door that we do not see the one that has been opened up for us”
- Helen Keller
“We don’t see the things the way they are. We see things the way WE are.”
- Talmund
“Every problem has in it the seeds of its own solution. If you don’t have any problems, you don’t get any seeds.”
- Norman Vincent Peale
“If you change the way you look at things, the things you look at change.”
- Dr Wayne Dyer
“The problem is not that there are problems. The problem is expecting otherwise and thinking that having problems is a problem.”
- Theodore Rubin
“Pessimist : A person who says that O is the last letter of ZERO, instead of the first letter in word OPPORTUNITY.”
- Anonymous
“Opportunity is missed by most people because it is dressed in overalls and looks like work.”
- Thomas A Edison
“Blessed are those who can give without remembering and take without forgetting”
- Elizabeth Bibesco
“Yesterday is history, tomorrow is a mystery. And today? Today is a gift. That’s why we call it the present.”
- B. Olatunji
“When you get to the end of the rope, tie a knot and hang on.”
- Franklin D Roosevelt
“Your attitude, not your aptitude, determines your altitude.”
- Zig Ziglar
“If you’re going through hell, keep going.”
- Winston Churchill
“The secret to success is to start from scratch and keep on scratching.”
- Dennis Green
“Champions aren’t made in gyms. Champions are made from something they have deep inside them a desire, a dream, a vision. They have to have the skill and the will. But the will must be stronger than the skill.”
- Muhammad Ali
“Most of the important things in the world have been accomplished by people who have kept on trying when there seemed to be no hope at all.”
- Dale Carnegie
“So many of our dreams at first seems impossible, then they seem improbable, and then, when we summon the will, they soon become inevitable.”
- Christopher Reeve
“Hard work spotlights the character of people. Some turn up their sleeves. Some turn up their noses, and some don’t turn up at all.”
- Sam Ewing
“There are those who work all day. Those who dream all day. And those who spend an hour dreaming before setting to work to fulfill those dreams. Go into the third category because there’s virtually no competition.”
- Steven J Ross
“Our greatest glory is not in never falling, but in rising every time we fall.”
- Confucious
“Many of life’s failures are people who had not realized how close they were to success when they gave up.”
- Thomas A Edison
“The main thing is to keep the main thing the main thing.”
- Stephen Covey
“Efficiency is doing things right. Effectiveness is doing the right things.”
- Peter Drucker
“Do you know what happens when you give a procrastinator a good idea? Nothing!”
- Donald Gardner
“Success is what you attract by the person you become.”
- Jim Rohn
“You have to ‘Be’ before you can ‘Do’ and ‘Do’ before you can ‘Have’.
- Zig Ziglar
“You can have everything in life that you want if you will just help enough other people to get what they want.”
- Zig Ziglar
“The test we must set for ourselves is not to march alone but to march in such a way that others wish to join us.”
- Hubert Humphrey
“Lots of people want to ride with you in the limo, but what you want is someone who will take the bus when the limo breaks down.”
- Oprah Winfrey
“Formal education will make you a living. Self education will make you a fortune.”
- Jim Rohn
“It isn’t what the book costs. It’s what it will cost you if you don’t read it.”
- Jim Rohn
“You must be the change you want to see in the world.”
- Mahatma Gandhi
“The future has several names. For the weak, it is the impossible. For the fainthearted, it is the unknown. For the thoughtful and valiant, it is the ideal.”
- Victor Hugo
“There is nothing more genuine than breaking away from the chorus to learn the sound of your own voice.”
- Po Bronson
“Do not go where the path may lead, go instead where there is no path and leave a trail.”
- Waldo Emerson
“Use what talents you possess, the woods will be very silent if no birds sang there except those that sang best.”
- Henry van Dyke
“Do not fear to be eccentric in opinion, for every opinion now accepted was once eccentric.”
- Bertrand Russell
“History will be kind to me, for I intend to write it.”
- Winston Churchill
“Life isn’t about finding yourself. Life’s about creating yourself.”
- George Bernard Shaw
“Live your life each day as you would climb a mountain. An occasional glance towards the summit keeps the goal in mind, but many beautiful scenes are to be observed from each new vintage point.”
- Harold B Melchart
“The tragedy of life doesn’t lie in not reaching your goal. The tragedy lies in having no goals to reach.”
- Benjamin Mays
“More often in life, we end up regretting the chances in life that we had, but didn’t take them, than those chances that we took and wished we hadn’t.”
- Anonymous
“An excuse is worse and more terrible than a lie, for an excuse is a lie guarded.”
- Pope John Paul I
“Don’t wish it were easier, wish you were better. Don’t wish for fewer problems, wish for more skills. Don’t wish for less challenges, wish for more wisdom.”
- Earl Shoaf

The Carnot Cycle

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Nicolas Léonard Sadi Carnot (1796-1832)
In the XIX century, Nicolas L. Sadi Carnot made statement concerning the efficiency of engines. He declared that the term "perfectly efficient heat engine" could not be applied to any heat engine. He believed that an engine in which all heat would be converted to mechanical work did not exist. Carnot also believed that the efficiency of a heat engine depended on the difference between the highest and lowest temperature reached in one cycle. That is, in mathematical terms, E = (T1 - T2 ) / T1.The difference of the temperatures is directly proportional to the efficiency of the heat engine. This conception was proved with his thermodynamic cycle (thermodynamic processes that after numerous stages return a system to its initial state) known as the Carnot cycle, which is the basis cycle of all heat engines. This idea is also presented in the second law of thermodynamics stating that there is a limit, less than a hundred percent, in the efficiency of engines.

Description of the Carnot Cycle

Stage 1: In the first stage, the piston moves downward while the engine absorbs heat from a source and gas begins to expand. The portion of the graphic from point A to point B represents this behavior. Because the temperature of the gas does not change, this kind of expansion is called isothermic.
Stage 2: In the second stage, the heat source is removed; the piston continues to move downward and the gas is still expanding while cooling (lowering in temperature). It is presented by the graphic from point B to point C. This stage is called a adiabatic expansion (Energy stays)
Stage 3: The piston begins to move upward and the cool gas is recompressed in the third stage. The heat goes to sink. Point C point D represents the decrease in volume and increase in pressure. The engine gives energy to the environment. This stage is called isothermal compression.
Stage 4: In the final stage, the piston to move upward and the cool gas is secluded and compressed. Its temperature rises to its original state. Point C to point D illustrate this behavior; a continuing increase in pressure and decrease in volume to their initial position. Energy stays, so it's an adiabatic compression.



Application in engines

The Carnot Cycle forms the perfect process of a heat engine. Many engineers tried to reach this kind of cycle. Rudolf Diesel had the most success and his engine is nearly as perfect as the Carnot engine (See Technology part). There are also other cycles, e.g. the Stirling Cycle you see on the right side.

Question & Answers on Steam Turbines

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Question & Answers on Steam Turbines
  1. What is a stage in a steam turbine?
  2. Answer: In an impulse turbine, the stage is a set of moving blades behind the nozzle. In a reaction turbine, each row of blades is called a "stage." A single Curtis stage may consist of two or more rows of moving blades.
  3. What is a diaphragm?
  4. Answer: Partitions between pressure stages in a turbine's casing are called diaphragms. They hold the vane-shaped nozzles and seals between the stages. Usually labyrinth-type seals are used. One-half of the diaphragm is fitted into the top of the casing, the other half into the bottom.
  5. What is a radial-flow turbine?
  6. Answer: In a radial-flow turbine, steam flows outward from the shaft to the casing. The unit is usually a reaction unit, having both fixed and moving blades. They are used for special jobs and are more common to European manufacturers, such as Sta-Laval (now ABB).
  7. What are four types of turbine seals?
  8. Answers:
    1. Carbon rings fitted in segments around the shaft and held together by garter or retainer springs.
    2. Labyrinth mated with shaft serration’s or shaft seal strips.
    3. Water seals where a shaft runner acts as a pump to create a ring of water around the shaft. Use only treated water to avoid shaft pitting.
    4. Stuffing box using woven or soft packing rings that are compressed with a gland to prevent leakage along the shaft.
  9. In which turbine is tip leakage a problem?
  10. Answer: Tip leakage is a problem in reaction turbines. Here, each vane forms a nozzle; steam must flow through the moving nozzle to the fixed nozzle. Steam escaping across the tips of the blades represents a loss of work. Therefore, tip seals are used prevent this.
  11. What are two types of clearance in a turbine?
  12. Answer:
    1. Radial
    2. - clearance at the tips of the rotor and casing.
    3. Axial - the fore-and-aft clearance, at the sides of the rotor and the casing.
  13. What are four types of thrust hearings?
  14. Answer:
    1. Babbitt-faced collar bearings.
    2. Tilting pivotal pads.
    3. Tapered land bearings.
    4. Rolling-contact (roller or ball) bearings.
  15. What is the function of a thrust bearing?
  16. Answer: Thrust bearings keep the rotor in its correct axial position.
  17. What is a balance piston?
  18. Answer: Reaction turbines have axial thrust because pressure on the entering side is greater than pressure on the leaving side of each stage. To counteract this force, steam is admitted to a dummy (balance) piston chamber at the low-pressure end of the rotor. Some designers also use a balance piston on impulse turbines that have a high thrust. Instead of piston, seal strips are also used to duplicate a piston's counter force.
  19. Why should a steam or moisture separator be installed in the steam line next to a steam turbine?
  20. Answer: All multistage turbines, low-pressure turbines, and turbines operating at high pressure with saturated steam should have a moisture separator in order to prevent rapid blade wear from water erosion.
  21. What are some conditions that may prevent a turbine from developing full power?
  22. Answers:
    1. The machine is overloaded.
    2. The initial steam pressure and temperature are not up to design conditions.
    3. The exhaust pressure is too high.
    4. The governor is set too low.
    5. The steam strainer is clogged.
    6. Turbine nozzles are clogged with deposits.
    7. Internal wear on nozzles and blades.
  23. Why is it necessary to open casing drains and drains on the steam line going to the turbine when a turbine is to be started?
  24. Answers: To avoid slugging nozzles and blades inside the turbine with condensate on start-up; this can break these components from impact. The blades were designed to handle steam, not water.
  25. What is steam rate as applied to turbo-generators?
  26. Answer: The steam rate is the pounds of steam that must be supplied per kilowatt-hour of generator output at the steam turbine inlet.
  27. What are the two basic types of steam turbines?
  28. Answers:
    1. Impulse type.
    2. Reaction type.
  29. What is the operating principle of an impulse turbine?
  30. Answer: The basic idea of an impulse turbine is that a jet of steam from a fixed nozzle pushes against the rotor blades and impels them forward. The velocity of the steam is about twice as fast as the velocity of the blades. Only turbines utilizing fixed nozzles are classified as impulse turbines.
  31. What is the operating principle of a reaction turbine?
  32. Answer: A reaction turbine utilizes a jet of steam that flows from a nozzle on the rotor. Actually, the steam is directed into the moving blades by fixed blades designed to expand the steam. The result is a small increase in velocity over that of the moving blades. These blades form a wall of moving nozzles that further expand the steam. The steam flow is partially reversed by the moving blades, producing a reaction on the blades. Since the pressure drop is small across each row of nozzles (blades), the speed is comparatively low. Therefore, more rows of moving blades are needed than in an impulse turbine.
  33. What are topping and superposed turbines?
  34. Answer: Topping and superposed turbines arc high-pressure, non-condensing units that can be added to an older, moderate-pressure plant. Topping turbines receive high-pressure steam from new high-pressure boilers. The exhaust steam of the new turbine has the same pressure as the old boilers and is used to supply the old turbines.
  35. What is an extraction turbine?
  36. Answer: In an extraction turbine, steam is withdrawn from one or more stages, at one or more pressures, for heating, plant process, or feedwater heater needs. They are often called "bleeder turbines."
  37. What is a combination thrust and radial bearing?
  38. Answer: This unit has the ends of the babbitt bearing extended radially over the end of the shell. Collars on the rotor face these thrust pads, and the journal is supported in the bearing between the thrust collars.
  39. What is a tapered-land thrust bearing?
  40. Answer: The babbitt face of a tapered-land thrust bearing has a series of fixed pads divided by radial slots. The leading edge of each sector is tapered, allowing an oil wedge to build up and carry the thrust between the collar and pad.
  41. What is important to remember about radial bearings?
  42. Answer: A turbine rotor is supported by two radial bearings, one on each end of the steam cylinder. These bearings must be accurately aligned to maintain the close clearance between the shaft and the shaft seals, and between the rotor and the casing. If excessive bearing wear lowers the he rotor, great harm can be done to the turbine.
  43. How many governors are needed for safe turbine operation? Why?
  44. Answer: Two independent governors are needed for safe turbine operation. One is an overspeed or emergency trip that shuts off the steam at 10 percent above running speed (maximum speed). The second, or main governor, usually controls speed at a constant rate; however, many applications have variable speed control.
  45. How is a flyball governor used with a hydraulic control?
  46. Answer: As the turbine speeds up, the weights are moved outward by centrifugal force, causing linkage to open a pilot valve that admits and releases oil on either side of a piston or on one side of a spring-loaded piston. The movement of the piston controls the steam valves.
  47. What is a multi-port governor valve? Why is it used?
  48. Answer: In large turbines, a valve controls steam flow to groups of nozzles. The number of open valves controls the number of nozzles in use according to the load. A bar-lift or cam arrangement operated by the governor opens and closes these valves in sequence. Such a device is a multi-port valve. Using nozzles at full steam pressure is more efficient than throttling the steam.
  49. What is meant by critical speed?
  50. Answer: It is the speed at which the machine vibrates most violently. It is due to many causes, such as imbalance or harmonic vibrations set up by the entire machine. To minimize damage, the turbine should be hurried through the known critical speed as rapidly as possible. (Caution, be sure the vibration is caused by critical speed and not by some other trouble).
  51. How is oil pressure maintained when starting or stopping a medium-sized turbine?
  52. Answer: An auxiliary pump is provided to maintain oil pressure. Some auxiliary pumps are turned by a hand crank; others are motor-driven. This pump is used when the integral pump is running too slowly to provide pressure, as when starting or securing a medium-sized turbine.
  53. Besides lubrication, which are two functions of lubricating oil in some turbines?
  54. Answer: In large units, lube oil cools the bearings by carrying off heat to the oil coolers. Lube oil in some turbines also acts as a hydraulic fluid to operate the governor speed-control system.
  55. What is meant by the water rite of a turbine?
  56. Answer:
  57. What is the difference between partial and full arc admission?
  58. Answer: In multi-valve turbine inlets, partial arc ad mission allows the steam to enter per valve opening in a sequential manner, so as load is increased, more valves open to admit steam. This can cause uneven heating on the high-pressure annulus as the valves are individually opened with load increase. In full-arc admission, all regulating valves open but only at a percentage of their full opening. With load increase, they all open more fully. This provides more uniform heating around the high-pressure part of the turbine. Most modern controls start with full-arc and switch to partial arc to reduce throttling losses through the valves.
  59. At what points does corrosion fatigue does show up?
  60. Answer: It attacks trailing edges, near the base of the foil and also the blade-root serration’s.
  61. Besides lubrication, what are two functions of lubricating oil in some turbines?
  62. Answer: In larger units, lube oil cools the bearings by carrying off heat to the oil coolers. Lube oil in some turbines also acts as a hydraulic fluid to operate the governor speed-control system.
  63. But despite these preventive measures, damage due to moisture impingement has been found, in certain cases, in the shield and beyond. Why?
  64. Answers:
    1. Shields are designed and fabricated on the basis of predicted range of steam/water quantities impacting the blades at specific angles.
    2. Now if the operating conditions deviate significantly from design parameters then the erosion damage will occur. And in some cases it may go beyond nominal erosion wear and warrant repair.
    3. Also the corrosion of casing can occur due to blockage/clogging of water drains or extraction thereby forcing the water back into the casing. If this condensate water is carried over to steam path and impacts the blade, thermal-fatigue failure can occur within a short period.
  65. By monitoring the exhaust steam temperature, how can the blade deposition be predicted?
  66. Answers:
    1. Immediately after the 1st commissioning, the different values of exhaust temperature for different steam flow rates are precisely determined and plotted against steam flow. This will produce the first actual graph. This is for a clean turbine.
    2. Similar graphs are to be drawn at later periods for comparing with the initial graph.
    3. A rise in exhaust steam temperature under the same conditions refers to deposit formation.
    4. An increase of exhaust steam temperature by more than 10% in the range of 70 to l00% steam flow, indicates inadmissible blade depositions. Shutdown is to be taken and blades are to be washed off deposits.
  67. Do the radial axial-bore cracks occur in the LP rotor/shaft alone?
  68. Answer: These are also known to occur in the HP as well as HP rotors.
  69. Do you stop cooling-water flow through a steam condenser as soon as the turbine is slopped?
  70. Answer: You should keep the cooling water circulating for about 15 mill or more so that the condenser has a chance to cool down gradually and evenly. Be sure to have cooling water flowing through the condenser before starting up in order to prevent live steam from entering the condenser unless it is cooled. Overheating can cause severe leaks and other headaches.
  71. Do you think that turbine blade failure is the only cause of unreliability of steam turbines? Does upgrading of turbine means replacement of blades and/or improvement of blade design?
  72. Answers:
    1. Like the blades, the steam-turbine rotors are highly stressed components. They are subject to cracking by a variety of failure mechanisms. Rotor failures do occur. And when they occur the result is catastrophic with the complete destruction of the unit and the total loss of generating capacity.
    2. Therefore, special attention should be given to rotor upgrading and repairing techniques.
  73. FACTORS BLADE FAILURES
  74. Unknown 26% Stress-Corrosion Cracking 22% High-Cycle Fatigue 20% Corrosion-Fatigue Cracking 7% Temperature Creep Rupture 6% Low-Cycle Fatigue 5% Corrosion 4% Other causes 10%
    TOTAL 100%
    1. Besides, many damage mechanisms operate in combination of
    1. poor steam/water chemistry,
    2. certain blade design factors that vary from one turbine manufacture to other,
    3. system operating parameters,
  1. How can damaged tenons be repaired?
  2. Answers: By adopting modern welding techniques, tenons can be rebuilt This in some cases results in extended blade life.
  3. How can problems of "excessive vibration or noise" due to piping strain be avoided on steam turbines?
  4. Answers:
    1. The inlet as well as exhaust steam lines should be firmly supported to avoid strains from being imposed on the turbine.
    2. Adequate allowance should be made for expansion of steam pipes due to heat.
  5. How can steam turbines be classified?
  6. Answers: By the action of steam:
    1. Impulse.
    2. Reaction.
    3. Impulse and reaction combined.
    4. The number of step reductions involved:
    5. Single stage.
    6. Multi-stage.
    7. Whether there is one or more revolving vanes separated by stationary reversing vanes.
    8. The direction of steam flow:
    9. Axial.
    10. Radial.
    11. Mixed.
    12. Tangential.
    13. Helical.
    14. Reentry.
    15. The inlet steam pressure:
    16. High pressure.
    17. Medium pressure.
    18. Low pressure.
    19. The final pressure:
    20. Condensing.
    21. Non-condensing.
    22. The source of steam:
    23. Extraction.
    24. Accumulator.
  7. How can the deposits be removed?
  8. Answers:
    1. Water soluble
    2. deposits may be washed off with condensate or wet steam.
    3. Water insoluble deposits are removed mechanically after dismantling the turbine.
    4. Experience shows that water soluble deposits are embedded in layers of water-insoluble deposits. And when the washing process is carried out, water soluble parts of the deposit dissolve away leaving a loose, friable skeleton of water-insoluble deposits which then break loose and wash away.
  9. How can the detection of deposits in a turbine be made during operation?
  10. Answers:
    1. Pressure monitoring.
    2. Internal efficiency monitoring.
    3. Monitoring exhaust steam temperature.
    4. Monitoring specific steam consumption.
  11. How can the disadvantages of the impulse turbine question 7 be overcome?
  12. Answers:
    1. Velocity compounding
    2. Pressure compounding
    3. Pressure-Velocity compounding.
  13. How can the fatigue damage on high-pressure blades be corrected?
  14. Answers: Fatigue-damage on high-pressure blades arises due to vibration induced by partial-arc admission. This can be corrected by switching over to full arc admission technique.
  15. How can the misalignment be rectified?
  16. Answer: The bolts holding the flanges together are to be tightened. The coupling is to be checked for squareness between the bore and the face. At the same time axial clearance is to be checked. Using gauge block and feeler gauges, the gap between coupling faces 1800 apart is to be measured. After rotating the coupling-half 1800, the gap at the same points is to be measured. After this, the other coupling is to be rotated 1800 and the gap at the same points is to be re-measured. These measures should come within a few thousands of an inch. Dividing the coupling faces into four intervals, the distance between the coupling faces at this intervals is to be measured with the aid of a gauge block and feeler gauges. These gap measurements should come within 0.005 inch for proper angular shaft alignment. After proper alignment at room temperature, the two halves of the coupling are to be connected.
  17. How can the problem of excessive speed variation due to throttle assembly friction be overcome?
  18. Answer: The throttle should be dismantled. Moving parts should be checked for free and smooth movement. Using very fine-grained emery paper, the throttle valve seats and valve steam should be polished.
  19. How can the speed variation be reduced by making a governor droop adjustment?
  20. Answer: If the internal droop setting is increased, the speed variation will reduce.
  21. How do the problems of vibration and fatigue arise with steam turbine blades?
  22. Answers:
    1. These arise due to flow irregularities introduced because of manufacturing defects, e.g. lack of control over tolerances.
    2. System operating parameter, e.g. low flow may excite various modes of vibration in the blades.
  23. How does deposit formation on turbine blades affect turbine efficiency?
  24. Answer: About 500 g of deposits distributed more or less evenly all over the blading section can bring down turbine efficiency by 1%.
  25. How does improper governor lubrication arise and
  26. Answers:
    1. In the event of low governor oil level or if the oil is dirty or foamy, it will cause improper governor lubrication.
    2. What is the remedy to it?
    3. The dirty or foamy lube oil should be drained off, governor should be flushed and refilled with a fresh charge of proper oil.
    4. In the event of low level, the level should be built up by make- up lube oil.
  27. How does pressure monitoring ensure detection of turbine deposits?
  28. Answers:
    1. Pressure of steam expanding in the turbine is measured at characteristic points, i.e., at the wheel chamber, points of pass-out, inlet/outlet of HP, IP and LP stages of the turbine.
    2. The turbine manufacturer provides the pressure characteristics in the form of graphs.
    3. At 1st commissioning, the user supplements these theoretical curves with those derived from actual measurements. These are actual pressure characteristics for a clean turbine. Now these pressure characteristics are compared with those obtained during operation in the later period.
    4. Under identical conditions, an increase in pressure shows the formation of deposits.
    5. For a steam throughput in the range 70-100%, an increase in wheel chamber pressure of more than 10% indicates severe blade depositions.
  29. How does solid-particle erosion occur?
  30. Answer: Solid-particle erosion, i.e. SPE occurs in the high-pressure blades. And it takes place when hard particles of iron exfoliated by steam from superheater tubes, reheater tubes, steam headers and steam leads strike on the surface of turbine blades.
  31. How does the damage to turbine-blades tell upon the efficiency of the unit?
  32. Answer: The damage to blade profiles changes the geometry of steam flow path and thereby reducing the efficiency of the unit.
  33. How does the dirty safety trip valve trip the safety trip at normal speed?
  34. Answers: Dirt may find its way to the safety trip valve and get deposited around the spring end cap end. This will block the clearance between the safety trip valve and the spring end cap. As a result the steam pressure in the spring cap gets lowered allowing the valve to close. What is the remedy to it? The spring end cap as well as safety trip valve should be cleaned.
  35. How does the foreign-particle damage of turbine blades arise?
  36. Answer: It occurs due to impact on blades by foreign particles (debris) left in the system following outages and become steam-borne later.
  37. How does the internal efficiency monitoring lead to the detection of turbine deposits?
  38. Answers:
    1. Process heat drop.
    2. Adiabatic heat drop.
    3. The process heat drop and adiabatic heat drop are obtained from a Mollier-Chart for the corresponding values of steam parameters - pressure and temperature - at initial and final conditions.
  39. How does this modification reduce the vibration fatigue damage?
  40. Answers:
    1. Joining the blade segments together at the shroud band increases the length of the arc-to a maximum of 360° that alters the natural frequency of the blade grouping from the operating vibration mode.
    2. This design has gained considerable success in commercial service.
  41. How is a flyball governor used with a hydraulic control?
  42. Answer: As the turbine speeds up, the weights are moved outward by centrifugal force, causing linkage to open a pilot valve that admits and releases oil on either side of a piston or on one side of a spring-loaded piston. The movement of the piston controls the steam valves.
  43. How is oil pressure maintained when starting or stopping a medium-sized turbine?
  44. Answer: An auxiliary pump is provided to maintain oil pressure. Some auxiliary pumps are turned by a hand crank; others are motor-driven. This pump is used when the integral pump is running too slowly to provide pressure, as when starting or securing a medium-sized turbine.
  45. How is pressure compounding accomplished?
  46. Answers:
    1. This is accomplished by an arrangement with alternate rows of nozzles and moving blades.
    2. Steam enters the 1st row of nozzles where it suffers a partial drop of pressure and in lieu of that its velocity gets increased. The high velocity steam passes on to the 1st row of moving blades where its velocity is reduced.
    3. The steam then passes into the 2nd row of nozzles where its pressure is again partially reduced and velocity is again increased. This high velocity steam passes from the nozzles to the 2nd row of blades where its velocity is again reduced.
    4. Thus pressure drop takes place in successive stages. Since a partial pressure drop takes place in each stage, the steam velocities will not be so high with the effect that the turbine will run slower.
  47. How is pressure-velocity compounding accomplished?
  48. Answers:
    1. It is a combination of pressure compounding and velocity compounding.
    2. Steam is expanded partially in a row of nozzles whereupon its velocity gets increased. This high velocity steam then enters a few rows of velocity compounding whereupon its velocity gets successively reduced. (Fig. 5)
    3. The velocity of the steam is again increased in the subsequent row of nozzles and then again it is allowed to pass onto another set of velocity compounding that brings about a stage-wise reduction of velocity of the steam.
    4. This system is continued.
  49. How is the washing of turbine blades carried out with the condensate?
  50. Answers:
    1. The washing is carried out with the condensate at 100°C.
    2. The turbine is cooled or heated up to 100°C and filled with the condensate via a turbine drain.
    3. The rotor is turned or barred by hand and the condensate is drained after 2 to 4 hours.
    4. It is then again filled with the condensate at 100°C (but up to the rotor center-level), the rotor is rotated and the condensate is drained after sometime. This process is repeated several times.
  51. How is turbine blade washing with wet steam carried out?
  52. Answers:
    1. Wet steam produced usually by injecting cold condensate into the superheated steam, is introduced to the turbine which is kept on running at about 20% of nominal speed.
    2. For backpressure turbine the exhaust steam is let out into the open air through a gate valve. For a condensing turbine, the vacuum pump is kept out of service while cooling water is running, with the effect that the entering cooling steam is condensed. The condensate is drained off.
    3. The washing steam condition is gradually adjusted to a final wetness of 0.9 to 0.95.
    4. Note, it is important:
    5. not to change washing steam temperature by 10°C/min,
    6. to keep all turbine cylinder drains open.
  53. How is velocity compounding accomplished?
  54. Answers:
    1. This is accomplished by an arrangement with alternate rows of fixed blades and moving blades. The mounted on the casing while the moving blades are keyed in series on a common shaft. The function of the fixed blades is to correct the direction of entry of steam to the next row of moving blades.
    2. The high velocity steam leaving the nozzles passes on to the 1st row of moving blades where it suffers a partial velocity drop.
    3. Its direction is then corrected by the next row of fixed blades and then it enters the 2nd row of moving blades. Here the steam velocity is again partially reduced. Since only part of the velocity of the steam is used up in each row of the moving blades, a slower turbine results. This is how velocity compounding works.
  55. How many governors are needed for safe turbine operation? Why?
  56. Answer: Two independent governors are needed for safe turbine operation:
    1. One is an overspeed or emergency trip that shuts off the steam at 10 percent above running speed (maximum speed).
    2. The second, or main governor, usually controls speed at a constant rate; however, many applications have variable speed control.
  57. How many types of particle-impact damage occur in turbine blades?
  58. Answers:
    1. Erosion/corrosion.
    2. Foreign-particle impacts.
    3. Solid-particle erosion.
    4. Water damage.
  59. How to prevent turbine deposition?
  60. Answers: By upgrading the quality of steam. That is by ensuring proper:
    1. Boiler feedwater quality.
    2. Steam boiler model.
    3. Boiler design.
    4. Boiler operation.
  61. How will you detect that misalignment is the probable cause of excessive vibration?
  62. Answers:
    1. Coupling to the driven machine is to be disconnected.
    2. The turbine is to be run alone.
    3. If the turbine runs smoothly, either misalignment, worn coupling or the driven equipment is the cause of the trouble.
  63. How would you slop a leaky tube in a condenser that was contaminating the feed-water?
  64. Answer: To stop a leaky tube from contaminating the feedwater, shut down, remove the water-box covers, and fill the steam space with water. By observing the tube ends you can find the leaky tube. An alternate method is to put a few pounds of air pressure in the steam space, flood the water boxes to the top inspection plate, and observe any air bubbles. Once you have found the leaky tube, drive a tapered bronze plug (coated with white lead) into each end of the tube to cut it out of service. This allows you to use the condenser since the tubes need not be renewed until about 10 percent of the tubes are plugged.
  65. How would you stop air from leaking into a condenser?
  66. Answer: First, find the leak by passing a flame over the suspected part while the condenser is under vacuum. Leaks in the flange joints or porous castings can be stopped with asphalt paint or shellac. Tallow or heavy grease will stop leaks around the valve stems. Small leaks around the porous castings, flange nuts, or valve stems can always be found by the flame test. So, you might have to put the condenser under a few pounds of air pressure and apply soapsuds to the suspected trouble parts.
  67. In how many patterns are tie wires used?
  68. Answers:
    1. In one design, tie wire is passed through the blade vane.
    2. In another design, an integral stub is jointed by welding/brazing.
  69. In some weld-repair cases, it has been found that the Stellite survived while the filler material eroded away. Why?
  70. Answers: If Inconel is used as the filler material, it has the inferior resistance to erosion in comparison to the Stellite insert. So filler material erodes away underneath.
  71. In steam turbines, is there any alternative to the shrunk-on-disc design?
  72. Answers: Two designs are available at present:
    1. Welded rotor in which each individual disc is welded, instead of shrunk, onto the main shaft.
    2. Monobloc rotor in which the entire shaft and blade assembly is manufactured from a single forging.
  73. In which case does upgrading imply life extension of steam turbines?
  74. Answer: For a capital-short electric utility plant, upgrading comes to mean extending the life of that plant scheduled for retirement.
  75. In which cases does erosion corrosion damage appear?
  76. Answer: It is commonly encountered in nuclear steam turbines and old fossil-fuel-fired units that employ lower steam temperatures and pressures.
  77. In which cases does moisture-impingement and washing erosion occur?
  78. Answers:
    1. These are encountered in the wet sections of the steam turbine.
    2. For nuclear power plants, these wet sections can involve parts of high-pressure cylinder.
  79. In which cases does upgrading mean up-rating the turbine capacity?
  80. Answer: For an electric utility system facing uncertain load growth, upgrading is chiefly up-rating. It is an inexpensive way to add capacity in small increments.
  81. In which part of the steam turbine does corrosion fatigue occur?
  82. Answer: In the wet stages of the LP cylinder.
  83. In which part of the steam turbine does stress corrosion cracking (SCC) occur?
  84. Answer: In the wet stages of the low-pressure turbine.
  85. In which section of the steam-turbine rotors is the problem of rotor failure mostly prevalent?
  86. Answers: Rotor failures occur mostly on the large low-pressure rotors. Basic causes of the problems are:
    1. Normal wear.
    2. Fatigue failure due to high stress.
    3. Design deficiency.
    4. Aggressive operating environment
  87. In which turbine is this pressure compounding used?
  88. Answer: In the Rateau turbine.
  89. In which turbine is tip leakage a problem?
  90. Answer: Tip leakage is a problem in reaction turbines. Here, each vane forms a nozzle; steam must how through the moving nozzle to the fixed nozzle. Steam escaping across the tips of the blades represents a loss of work. Therefore, tip seals are used to prevent this.
  91. In which turbine is velocity compounding utilized?
  92. Answer: In the Curtis turbine.
  93. In which turbines, is this pressure-velocity compounding principle employed?
  94. Answer: In the Curtis turbine.
  95. In which zone of steam turbines has temperature-creep rupture been observed?
  96. Answer: Damage due to creep is encountered in high temperature (exceeding 455°C) zones. That is, it has been found to occur in the control stages of the high-pressure and intermediate-pressure turbines where steam temperature sometimes exceed 540°C. In the reheat stage, it has been observed that creep has caused complete lifting of the blade shroud bands.
  97. Is there any adverse effect off full-arc admission operation?
  98. Answer: At low loads, this results in a heat-rate penalty, due to throttling over the admission valves.
  99. Is there any alternative to the shrunk-on-disc design?
  100. Answers: Two designs are available at present:
    1. Welded rotor in which each individual discs are welded, instead of shrunk, onto the main shaft.
    2. Monobloc rotor in which the entire shaft and blade assembly is manufactured from a single forging.
  101. Is there any factor other than corrodents and erodents that contributes to turbine blade failure?
  102. Answers:
    1. Turbine blade damage and failures can be effected by vibration and fatigue.
    1. These arise due to flow irregularities introduced because of manufacturing defects, e.g. lack of control over tolerances.
    2. System operating parameter, e.g. low flow may excite various modes of vibration in the blades.
  1. Is there any other type of racking occurring in HP/IP rotors and causing rotor failures?
  2. Answers:
    1. Blade-groove-wall cracking.
    2. Rotor-surface cracking.
  3. Of all the factors that contribute to the unreliability of steam turbines, which one is the most prominent?
  4. Answer: It is the problem of turbine blade failures that chiefly contribute to the unreliability of steam turbines.
  5. Rim cracking continues to be a problem of shrunk-on-disc type rotors in utility steam turbines. Where does it occur?
  6. Answer: Cracking has been located at the outer corners of tile grooves where the blade root attaches to the rotor.
  7. So can you recommend this technique as a permanent measure?
  8. Answer: No, this can be recommended in extreme cases or at best temporarily.
  9. So what should be the more sound approach?
  10. Answers:
    1. The more reasonable and better approach is to replace the damaged blades with new ones that are stiffened by:
    1. Serrating the interface surface of individual blades so they interlock, or
    2. Welding the blades together.
    3. In some cases, a single monolithic block is machined out to manufacture the blades in a group.
    4. In some other cases, blades themselves are directly welded into the rotor.
  1. Steam blowing from a turbine gland is wasteful. Why else should it be avoided?
  2. Answer: It should be avoided because the steam usually blows into the bearing, destroying the lube oil in the main bearing. Steam blowing from a turbine gland also creates condensate, causing undue moisture in plant equipment.
  3. The consequences of turbine depositions have three effects?
  4. Answers:
    1. Economic Effect:
    1. Reduction in turbine output
    2. Decrease in efficiency requiring higher steam consumption.
    1. Effect of Overloading and Decreasing Reliability in Operation:
    1. Pressure characteristic in the turbine gets disturbed with the effect that thrust and overloading of thrust bearing increase.
    2. Blades are subjected to higher bending stresses.
    3. Natural vibrations of the blading are affected.
    4. Vibration due to uneven deposition on turbine blading.
    5. Valve jamming due to deposits on valve stems.
    1. Corrosion Effect:
    1. Fatigue corrosion.
    2. Pitting corrosion.
    3. Stress corrosion.
  1. Usually it has been found that SCC attack takes place particularly at keyways of shrunk-on-disc rotors of low-pressure turbines. Why are keyways prone to SCC attack?
  2. Answers:
    1. Keyways shrunk-fit each disc onto tile rotor shaft. They improve the rigidity of the connection between the disc and the central shaft However, key ways are subjected to abnormal centrifugal forces due to high overspeed, that reduce the amount of shrink. Tangential stresses tend to gravitate at the keyway connection and steam tends to condense.
    2. It is a one-piece-construction, and thus has inherent rigidity.
    3. Advanced steel making techniques enable building of monobloc rotors almost free from non-metallic inclusions and gas bubbles. Even large monobloc rotors of clean steel are being manufactured today.
    4. It exhibits lower inherent stresses.
    5. The chance of disc loosening during operation is eliminated.
    6. Highly stressed keyway is eliminated.
  3. What are four types of thrust bearings?
  4. Answers:
    1. babbitt-faced collar bearings
    2. tilting pivotal pads
    3. tapered land bearings
    4. rolling-contact (roller or ball) bearings
  5. What are four types of turbine seals?
  6. Answer:
    1. Carbon rings fitted in segments around the shaft and held together by garter or retainer springs.
    2. Labyrinths mated with shaft serrations or shaft seal strips.
    3. Water seals where a shaft runner acts as a pump to create a ring of water around the shaft. Use only treated water to avoid shaft pitting.
    4. Stuffing box using woven or soft packing rings that are compressed with a gland to prevent leakage along the shaft.
  7. What are some common troubles in surface-condenser operation?
  8. Answer: The greatest headache to the operator is loss of vacuum caused by air leaking into the surface condenser through the joints or packing glands. Another trouble spot is cooling water leaking into the steam space through the ends of the tubes or through tiny holes in the tubes. The tubes may also become plugged with mud, shells, debris, slime, or algae, thus cutting down on the cooling-water supply, or the tubes may get coated with lube oil from the reciprocating machinery. Corrosion and dezincification of the tube metal are common surface-condenser troubles. Corrosion may be uniform, or it may occur in small holes or pits. Dezincification changes the nature of the metal and causes it to become brittle and weak.
  9. What are the advantages of steam turbines over reciprocating steam engines?
  10. Answers:
    1. Steam turbine has higher thermal efficiency than reciprocating steam engines.
    2. The brake horsepower of steam turbines can range from a few HP to several hundred thousand HP in single units. Hence they are quite suitable for large thermal power stations.
    3. Unlike reciprocating engines, the turbines do not need any flywheel, as the power delivered by the turbine is uniform.
    4. Steam turbines are perfectly balanced and hence present minimum vibrational problem.
    5. High rpm l8000 - 24000 can be developed in steam turbines but such a high speed generation is not possible in the case of reciprocating steam engines.
    6. Some amount of input energy of steam is lost as the reciprocating motion of the piston is converted to circular motion.
    7. Unlike reciprocating steam engines, no internal lubrication is required for steam turbines due to the absence of rubbing parts.
    8. Steam turbines, if well designed and properly maintained, are more reliable and durable prime movers than steam engines.
  11. What are the advantages of velocity compounding?
  12. Answers:
    1. The velocity compounding system is easy to operate and operation is more reliable.
    2. Only two or three stages are required. Therefore, first cost is less.
    3. Since the total pressure drop takes place only in nozzles and not in the blades, the turbine casing need not be heavily built. Hence the economy in material and money.
    4. Less floor space is required.
  13. What are the advantages of welded rotors?
  14. Answers:
    1. Welded rotor is a composed body built up by welding the individual segments. So the limitations on forgings capacity do not apply.
    2. Welding discs together results in a lower stress level. Therefore, more ductile materials can be chosen to resist SCC attack.
    3. There are no keyways. So regions of high stress concentrations are eliminated.
  15. What are the basic causes of the problem of rotor failure?
  16. Answers:
    1. Normal wear.
    2. Fatigue failure due to high stress.
    3. Design deficiency.
    4. Aggressive operating environment
  17. What are the causes of radial axial-bore cracks on HP/IP rotors/shafts?
  18. Answers:
    1. The predominant cause is creep, which may act with or without low cycle fatigue.
    2. Also the cracks result due to poor creep ductility due to faulty heat treatment process.
  19. What are the differences between impulse and reaction turbines?
  20. Answers:
    1. The impulse turbine is characterized by the fact that it requires nozzles and that the pressure drop of steam takes place in the nozzles.
    2. The reaction turbine, unlike the impulse turbines has no nozzles, as such. It consists of a row of blades mounted on a drum. The drum blades are separated by rows of fixed blades mounted in the turbine casing. These fixed blades serve as nozzles as well as the means of correcting the direction of steam onto the moving blades.
    3. In the case of reaction turbines, the pressure drop of steam takes place over the blades. This pressure drop produces a reaction and hence cause the motion of the rotor.
  21. What are the disadvantages of velocity compounding?
  22. Answers:
    1. Steam velocity is too high and that is responsible for appreciable friction losses.
    2. Blade efficiency decreases with the increase of the number of stages.
    3. With the increase of the number of rows, the power developed in successive rows of blade decreases. For as much as, the same space and material are required for each stage, it means, therefore, that all stages are not economically efficient.
  23. What are the factors that contribute to bearing failure in a steam turbine?
  24. Answers:
    1. Improper lubrication. Only the recommended lubricant should be used.
    2. Inadequate water-cooling.
    1. The jacket temperature should be maintained in the range of 37-60°C
    2. The flow of cooling water should be adjusted accordingly.
    1. Misalignment. It is desirable that ball bearings should fit on the turbine shaft with a light press fit. If the fitting is too tight, it will cause cramping. On the other hand, if the fitting is too loose it will cause the inner race to turn on the shaft. Both conditions are undesirable. They result in wear, excessive vibration and overheating. And bearing failure becomes the ultimate result.
    2. Bearing fit.
    3. Excessive thrust.
    4. Unbalance.
    5. Rusting of bearing.
  1. What are the losses in steam turbines?
  2. Answers:
    1. Residual Velocity Loss
    2. - This is equal to the absolute velocity of the steam at the blade exit.
    3. Loss due to Friction - Friction loss occurs in the nozzles, turbine blades and between the steam and rotating discs. This loss is about 10%.
    4. Leakage Loss.
    5. Loss due to Mechanical Friction - Accounts for the loss due to friction between the shaft and bearing.
    6. Radiation Loss - Though this loss is negligible, as turbine casings are insulated, it occurs due to heat leakage from turbine to ambient air which is at a much lower temperature than the turbine.
    7. Loss due to Moisture - In the lower stages of the turbine, the steam may become wet as the velocity of water particles is lower than that of steam. So a part of the kinetic energy of steam is lost to drag the water particles along with it.
  3. What are the main causes of turbine vibration?
  4. Answer:
    1. unbalanced parts
    2. poor alignment of parts
    3. loose parts
    4. rubbing parts
    5. lubrication troubles
    6. steam troubles
    7. foundation troubles
    8. cracked or excessively worn parts
  5. What are the points of SCC attack?
  6. Answers:
    1. SCC attack predominates where corrodents deposit and build up i.e. in those blading areas where flowing steam cannot provide a washing effect.
    2. What are these points in particular?
    1. Tie wires.
    2. Tie wire holes.
    3. Brazings.
    4. Blade covers.
    5. Tenon holes.
    1. At what points does corrosion fatigue does show up?
It attacks trailing edges, near the base of the foil and also the blade-root serration’s.
  1. What are the possible causes for the turbine not running at rated speed?
  2. Answers:
    1. The possible causes are:
    1. too many hand valves closed,
    2. oil relay governor set too low,
    3. inlet steam pressure too low or exhaust pressure too high,
    4. load higher than turbine rating,
    5. throttle valve not opening fully,
    6. safety trip valve not opening properly,
    7. nozzles plugged,
    8. steam strainer choked.
  1. What are the possible causes of a governor not operating?
  2. Answers:
    1. Restriction of throttle valve reflex.
    2. Failure of governor control on start-up.
    If it is found that after start-up, the speed increases continuously and the governor is not closing the throttle valve, it may be that the governor pump has been installed in the wrong direction.
  3. What are the possible causes of excessive vibration or noise in a steam turbine?
  4. Answers:
    1. Misalignment.
    2. Worn bearings.
    3. Worn coupling to driven machine.
    4. Unbalanced coupling to driven machine.
    5. Unbalanced wheel.
    6. Piping strain.
    7. Bent shaft.
  5. What are the possible causes of the speed of the turbine rotor increasing excessively as the load is decreased?
  6. Answers:
    1. Throttle valve not closing fully.
    2. Wearing of throttle valve seats.
  7. What are the stresses to which a steam turbine rotor is subjected during its service life?
  8. Answers:
    1. Mechanical stress
    2. - The factors that contribute to mechanical stress in the shaft are the centrifugal forces and torque’s generated due to revolving motion of the shaft as well as bending arising during steady-state operation.
    3. Thermal stress - Transient operating phases i.e. startup and shutdown the genesis of thermal stress induced to the turbine shaft.
    4. Electrically induced stress - They originate due to short circuits and faulty synchronization.
  9. What are these points in particular?
  10. Answers:
    1. Tie wires.
    2. Tie wire holes.
    3. Brazings.
    4. Blade covers.
    5. Tenon holes.
  11. What are three types of condensers?
  12. Answer:
    1. surface (shell-and-tube)
    2. jet
    3. barometric.
  13. What are topping and superposed turbines?
  14. Answer: Topping and superposed turbines are high-pressure, non-condensing units that can be added to an older, moderate-pressure plant. Topping turbines receive high-pressure steam from new high-pressure boilers. The exhaust steam of the new turbine is at the same pressure as the old boilers and is used to supply the old turbines.
  15. What are two types of clearance in a turbine?
  16. Answers:
    1. radial - the clearance at the tips of the rotor and casing
    2. axial - the fore-and-aft clearance, at the sides of the rotor and the casing
  17. What design modification is adopted to reduce susceptibility of last low-pressure stages to fatigue failure?
  18. Answer: One modification is to join the blade segments together at the shroud band.
  19. What does "upgrading" generally means in the context of steam turbines?
  20. Answer: Upgrading is a most widely used tern. It encompasses a variety of meanings verses life extension, modernization and up-rating of steam turbines.
  21. What does the term "ramp rat" mean?
  22. Answer: Ramp rate is used in bringing a turbine up to operating temperature and is the degrees Fahrenheit rise per hour that metal surfaces are exposed to when bringing a machine to rated conditions. Manufactures specify ramp rates for their machines in order to avoid thermal stresses. Thermocouples are used in measuring metal temperatures.
  23. What factors are responsible for turbine-blade failures?
  24. Answers:
    1. In the high pressure cylinder, the turbine blades are mostly affected by:
    1. solid-particle erosion (SPE),
    2. high cycle fatigue,
    1. Whereas in the last few stages of the low-pressure cylinder, the blade damage is mainly afflicted by:
    1. erosion,
    2. corrosion,
    3. stress/fatigue damage mechanism.
    4. According to EPRI (Electric Power Research Institute, USA) data stress-corrosion cracking and fatigue are the chief exponents for turbine-blade failures in utility industries.
  1. What factors cause excessive steam leakage under carbon rings?
  2. Answers:
    1. Dirt under rings. - steam borne scale or dirt foul up the rings if steam is leaking under the carbon rings.
    2. Shaft scored.
    3. Worn or broken carbon rings.
    These should be replaced with a new set of carbon rings. The complete ring is to be replaced.
  3. What factors contribute to excessive speed variation of the turbine?
  4. Answers:
    1. Improper governor droop adjustment.
    2. Improper governor lubrication.
    3. Throttle assembly friction.
    4. Friction in stuffing box.
    5. High inlet steam pressure and light load.
    6. Rapidly varying load.
  5. What is a balance piston?
  6. Answer: Reaction turbines have axial thrust because pressure on the entering side is greater than pressure on the leaving side of each stage. To counteract this force, steam is admitted to a dummy (balance) piston chamber at the low-pressure end of the rotor. Some designers also use a balance piston on impulse turbines that have a high thrust. Instead of pistons, seal strips are also used to duplicate a piston's counter force.
  7. What is a combination thrust and radial bearing?
  8. Answer: This unit has the ends of the babbitt bearing extended radially over the end of the shell. Collars on the rotor face these thrust pads, and the journal is supported in the bearing between the thrust collars.
  9. What is a diaphragm (turbine)?
  10. Answer: Partitions between pressure stages in a turbine's casing are called diaphragms. They hold the vane-shaped nozzles and seals between the stages. Usually labyrinth-type seals are used. One-half of the diaphragms are fitted into the top of the casing, the other half into the bottom.
  11. What is a multiport governor valve? Why is it used?
  12. Answer: In large turbines, a valve controls steam flow to groups of nozzles. The number of open valves controls the number of nozzles in use according to the load. A bar-lift or cam arrangement operated by the governor, opens and close the valves in sequence. Such a device is a multiport valve. Using nozzles at full steam pressure is more efficient than throttling the steam.
  13. What is a radial-flow turbine?
  14. Answer: In a radial-flow turbine, steam flows outward from the shaft to the casing. The unit is usually a reaction unit, having both fixed and moving blades. They are used for special jobs and are more common to European manufacturers.
  15. What is a shrunk-on-disc rotor?
  16. Answer: These are built by heat expanding the discs, so that upon cooling they shrink on the main rotor forging.
  17. What is a stage in a steam turbine?
  18. Answer: In an impulse turbine, the stage is a set of moving blades behind the nozzle. In a reaction turbine, each row of blades is called a "stage." A single Curtis stage may consist of two or more rows of moving blades.
  19. What is a tapered-land thrust bearing?
  20. Answer: The babbitt face of a tapered-land thrust bearing has a series of fixed pads divided by radial slots. The leading edge of each sector is tapered, allowing an oil wedge to build up and carry the thrust between the collar and pad.
  21. What is an air ejector?
  22. Answer: An air ejector is a steam siphon that removes non-condensable gases from the condenser.
  23. What is an extraction turbine?
  24. Answer: In an extraction turbine, steam is withdrawn from one or more stages, at one or more pressures, for heating, plant process, or feedwater heater needs. They are often called "bleeder turbines."
  25. What is combined-cycle cogeneration?
  26. Answer: A combined cycle using a gas turbine or diesel, usually driving a generator in which the exhaust gases are directed to a waste heat-recovery boiler or heat-recovery steam generator (HRSG). The steam from the HRSG is then directed to a steam turbo-generator for additional electric power production. The use of the exhaust heat from a gas turbine improves the overall thermal efficiency. In cogeneration, electric power is produced, but part of the steam from the HRSG or from extraction from the steam turbine is used for process heat, hence the term cogeneration-the simultaneous production of electric power and process heat steam.
  27. What is done when cracks due to SCC or corrosion-fatigue are found?
  28. Answer: The damaged blade is usually replaced, as repairing is difficult.
  29. What is gland-sealing steam?
  30. Answer: Low-pressure steam is led to a sealing gland. The steam seals the gland, which may be a carbon ring or of the labyrinth type, against air at the vacuum end of the shaft.
  31. What is important to remember about radial bearings?
  32. Answer: A turbine rotor is supported by two radial bearings, one on each end of the steam cylinder. These bearings must be accurately aligned to maintain the close clearances between the shaft and the shaft seals, and between the rotor and the casing. lf excessive bearing wear lowers the rotor, great harm can be done to the turbine.
  33. What is meant by critical speed?
  34. Answer: It is the speed at, which the machine vibrates most violently. It is due to many causes, such as imbalance or harmonic vibrations set up by the entire machine. To minimize damage, the turbine should be hurried through the known critical speed as rapidly as possible. Caution: Be sure the vibration is caused by critical speed and not by some other trouble.
  35. What is meant by the water rate of a turbine?
  36. Answer: It is the amount of water (steam) used by the turbine in pounds per horsepower per hour or kilowatts per hour.
  37. What is the cause of axial-bore cracks?
  38. Answer: Inadequate toughness of rotor steel and transient thermal stresses.
  39. What is the cause of circumferential cracking?
  40. Answer: High cycle fatigue with or without corrosion.
  41. What is the cause of turbine deposits?
  42. Answers: The turbine deposits are steam-born foreign matters settled on turbine blades. Substances dissolved in the BFW transfer partly from the water to steam, during the process of evaporation. They get dissolved in the steam and are carried into the steam turbine.
  43. What is the definition of a steam turbine?
  44. Answers: A steam turbine is a prime mover that derives its energy of rotation due to conversion of the heat energy of steam into kinetic energy as it expands through a series of nozzles mounted on the casing or produced by the fixed blades.
    1. Neilson defines it: The turbine is a machine in which a rotary motion is obtained by the gradual change of the momentum of the fluid.
    2. Graham's definition: The turbine is a prime mover in which a rotary motion is obtained by the centrifugal force brought into action by changing the direction of a jet of a fluid (steam) escaping from the nozzle at high velocity.
  45. What is the difference between partial and full arc admission?
  46. Answer: In multi-valve turbine inlets, partial arc admission allows the steam to enter per valve opening in a sequential manner, so as load is increased, more valves open to admit steam. This can cause uneven heating on the high-pressure annulus as the valves are individually opened with load increase. In full-arc admission, all regulating valves open but only at a percentage of their full opening. With load increase, they all open more fully. This provides more uniform heating around the high-pressure part of the turbine. Most modern controls start with full-arc and switch to partial arc to reduce throttling losses through the valves.
  47. What is the essential distinguishing feature between a steam turbine and reciprocating steam engine?
  48. Answers:
    1. In a steam turbine, the heat energy of steam is converted into kinetic energy by allowing it to expand through a series of nozzles and this kinetic energy of steam is then imparted to the turbine blades mounted on a shaft free to rotate to drive this prime mover.
    2. In a reciprocating steam engine, the pressure energy of steam is directly utilized to overcome the external resistance. Here, the utilization of the KE of input steam is negligibly small.
  49. What is the function of a gland drain?
  50. Answer: The function of a gland drain is to draw off water from sealing-gland cavities created by the condensation of the sealing steam. Drains are led to either the condenser air-ejector tube nest or the feedwater heaters. Often, gland drains are led to a low-pressure stage of the turbine to extract more work from the gland-sealing steam.
  51. What is the function of a thrust bearing?
  52. Answer: Thrust bearings keep the rotor in its correct axial position.
  53. What is the harm if the rotor is oversped?
  54. Answer: Overspeed rotor grows radially causing heavy rub in the casing and the seal system. As a result, considerable amount of shroud-band and tenon-rivet head damage occurs.
  55. What is the nature of circumferential cracking in shrunk-on-disc rotors in steam turbines?
  56. Answer: Regions of high stress concentration give birth to this type of cracking. It begins in corrosion pits and propagates towards the bore by high-cycle fatigue. It may culminate in a catastrophe, if it penetrates the bore (happily this usually does not occur).
  57. What is the nature of rotor surface cracks in steam turbines?
  58. Answer: They are shallow in depth and have been located in heat grooves and other small radii at labyrinth-seal areas along the rotor.
  59. What is the operating principle of a reaction turbine?
  60. Answer: A reaction turbine utilizes a jet of steam that flows from a nozzle on the rotor. Actually, the steam is directed into the moving blades by fixed blades designed to expand the steam. The result is a small increase in velocity over that of the moving blades. These blades form a wall of moving nozzles that further expand the steam. The steam flow is partially reversed by the moving blades, producing a reaction on the blades. Since the pressure drop is small across each row of nozzles (blades), the speed is comparatively low. Therefore, more rows of moving blades are needed than in an impulse turbine.
  61. What is the possible cause of slow start up of a steam turbine?
  62. Answer: This may be due to high starting torque required by the driven equipment.
  63. What is the potential problem of shrunk-on-disc type rotor?
  64. Answers:
    1. It is the failure due to circumferential cracks, which are not limited to old rotors of early models (1960), but they also take place on present-day rotors.
    2. As a result corrodent impurities like chlorides concentrate at key ways. This factor coupled with high stress concentration lead to SCC attack on keyway areas.
  65. What is the principle of a steam turbine?
  66. Answers:
    1. If high-velocity steam is allowed to blow on to a curved blade, the steam will suffer a change in direction as it passes across the blade, and leaves it as shown.
    2. As a result of its change in direction across the blade, the steam will impart a force to the blade. This force will act in the direction shown.
    3. Now if the blade were free in the direction of force as depicted. if, therefore, a number of blades were fixed on the circumference of a disc which is free to rotate on a shaft, then steam blown across the blades in the way described, would cause the disc to rotate. This is the working principle of a steam turbine.
  67. What is the purpose of a turning gear?
  68. Answer: Heat must be prevented from warping the rotors of large turbines or high-temperature turbines of 400°C or more. When the turbine is being shut down, a motor-driven turning gear is engaged to the turbine to rotate the spindle and allow uniform cooling.
  69. What is the remedy for a bent steam turbine shaft causing excessive vibration?
  70. Answers:
    1. The run-out of the shaft near the center as well as the shaft extension should be checked.
    2. If the run-out is excessive, the shaft is to be replaced.
  71. What is the remedy for rotor-surface cracking?
  72. Answer: Current rotor/shaft should be machined off (skin-peeling).
  73. What is the remedy of the damage to blade profiles?
  74. Answers:
    1. Upgrading the turbine and depending on the extent of damage, upgrading may involve:
    1. weld repair of affected zones of the blade,
    2. replacement of damaged blades by new ones and of new design,
    3. replacement of base material,
    4. application of protective coatings to guard against corrosion and erosion damage.
    1. What are the remedies to this failure?
    2. Answers:
    3. For existing rotor, weld repair may be a choice; otherwise retire it.
    4. For new rotors, materials with improved pitting resistance should be used.
  1. What is the safe maximum tripping speed of a turbine operating at 2500 rpm?
  2. Answer: The rule is to trip at 10 percent overspeed. Therefore, 2500 x 1.10 = 2750 rpm.
  3. What is the solution to the problem of SCC/corrosion fatigue of steam turbine blades?
  4. Answer: It involves changing the blade material as well as minimizing the presence of corrodents in steam to a permissible level.
  5. What is to be done for erosion-induced damage on high-and low-pressure stage blading?
  6. Answers:
    1. In such cases welding repair can be a good solution and this can be carried out during a normal maintenance outage without removing the blade. Using oxyacetylene torch, Stellite is generally deposited onto the damaged site. Following this, the weld is subjected to stress-relieving and re-profiling.
    2. In case of erosion penetrating the erosion shield and extending to the base material, a filler material of consistent or identical composition of blade material is used.
    3. In some cases use is made of Inconel alloy to build up the metal base. Therefore, using welding or brazing technique, a new shield can be attached to the blade. If brazing technique is followed, the rebuilt section is stress-relieved prior to the attachment of shield to it. If, on the other hand, the shield is attached by welding, then they are stress-relieved together.
  7. What is to be done in case of cracks originating at the lacing-wire holes?
  8. Answers:
    1. These are to be weld-repaired. However the following factors must be considered:
    1. The length of the crack that appears on the pressure and/or suction face.
    2. Whether the cracks propagate towards inlet end, discharge end and or both.
  1. What maybe the possible causes for the safety trip to trip at normal speed?
  2. Answers:
    1. Excessive vibration.
    2. Leakage in the pilot valve.
    3. Deposition of dirt in the safety trip valve.
  3. What maybe the possible causes for the safety trip tripping during load variation?
  4. Answers:
    1. Light load and high inlet steam pressure.
    2. Safety trip set very close to the operating speed of turbine.
  5. What other parts of the steam turbine blades suffer from damage?
  6. Answers:
    1. Blade roots.
    2. Shroud band.
  7. What provisions in the layout of a combined-cycle should be considered?
  8. Answer: It is important to consider the use of a bypass stack that will permit operating the gas turbo-generator in case of a forced outage on the HRSG or steam turbo-generator. However, in certain states, such as California, also to be considered are NO limits that require steam injection and loading to limit the exhaust temperature coming out of the simple-cycle gas turbine so that they do not exceed jurisdictional limits.
  9. What remedial measures you can suggest to cope with radial axial-bore cracks?
  10. Answer: For new rotors, modified heat treatment process is recommended while for existing rotors de-rating the turbine or replacement of the rotor may be a solution.
  11. What should be done if excessive vibration is due to an unbalanced turbine wheel?
  12. Answers:
    1. The turbine wheel is to be checked if it became unbalanced due to overspeeding.
    2. The turbine wheel must be re-balanced or replaced.
    3. What should be the remedial action?
    4. Answers:
    5. For new rotors, control cleanliness of the steel.
    6. i.e. inclusion and segregates free and more homogeneous steel shaft is required.
    7. For current rotors, replace the rotor, grind and overbore.
  13. What should be the remedial actions for blade-groove-wall cracking?
  14. Answers:
    1. Modified heat treatment of new rotors is a sound and lasting remedy.
    2. For current rotors, cracks should be machined off and lighter blades should be installed. Better, retire the cracked shaft.
  15. What should you do if you lost vacuum while operating a condensing turbine plant?
  16. Answer: If vacuum is lost shut down immediately. The condenser cannot stand steam pressure; the condenser tubes may leak from excessive temperature. Excessive pressure will also damage the shell, the exhaust, and the low-pressure parts of the turbine.
  17. What steps are taken to minimize damage from moisture on steam turbine blades?
  18. Answers:
    The following measures are employed at the design stage:
    1. Stellite inserts.
    2. Hardening of the base metal.
    3. Moisture-removal devices to combat impingement corrosion due to moisture.
  19. What steps are taken to minimize damage from moisture?
  20. Answers:
    1. Stellite inserts.
    2. Hardening of the base metal.
    3. Moisture-removal devices to combat impingement corrosion due to moisture.
  21. What steps/modifications should be implemented to curtail the damage from moisture impingement on steam turbine blades?
  22. Answers:
    1. The drainage system should be redesigned. Larger drains are to be provided.
    2. More effective water-catchers are to be in-stalled.
    3. Radial seals are to be eliminated to remove water before it can chance upon the blades.
    4. Nozzle trailing edges are to be thinned to promote the formation of smaller and less harmful droplets.
  23. What steps/modifications should be implemented to curtail the damage from moisture impingement?
  24. Answers:
    1. The drainage system should be redesigned. Larger drains are to be provided.
    2. More effective water-catchers are to be in-stalled.
    3. Radial seals are to be eliminated to remove water before it can chance upon the blades.
    4. Nozzle trailing edges are to be thinned to promote the formation of smaller and less harmful droplets.
  25. What type of deposits are formed on steam turbine blading?
  26. Answers:
    1. Water-soluble deposits.
    1. NaCl, Na2SO4, NaOH and Na3PO4
    1. Water-insoluble deposits.
    1. SiO2 (mainly).
  1. What types of cracking occur in the LP rotor shaft?
  2. Answers:
    1. Radial axial-bore cracks.
    2. Circumferential cracks.
  3. When "stall flutter" occurs?
  4. Answers: This problem is encountered when operating limits are exceeded i.e., when turbine exhaust pressure exceeds the value what the manufacturer has recommended. Stall flutter induces stress in the blades
  5. When does SPE damage usually occur on steam turbine blades?
  6. Answer: It occurs usually during startup or abrupt load change.
  7. When does SPE damage usually occur?
  8. Answer: It occurs usually during startup or abrupt load change.
  9. When does upgrading mean modernization of utility industry?
  10. Answer: Upgrading is really modernization to all those units other than those facing uncertain load growth and low-capital utility system. It involves replacement of damaged parts/components by state-of-the-art components without scrapping the entire machine.
  11. Where are velocity compounded steam turbines mostly employed?
  12. Answers:
    1. They are chiefly used as the prime mover for:
    1. Centrifugal pumps.
    2. Centrifugal compressors.
    3. Low capacity turbo-generators.
    4. Feed pumps of high capacity power plants.
  1. Where do water-soluble deposits prevail?
  2. Answer: In the high-and intermediate-pressure sections of steam turbines.
  3. Where is pitting corrosion mostly prevalent?
  4. Answer: Upstream of LP stages as well as wet stages of LP cylinder.
  5. Where would you look for a fault if the air ejector did not raise enough vacuum?
  6. Answer: In this case, the trouble is usually in the nozzle. You will probably find that:
    1. the nozzle is eroded
    2. the strainer protecting the nozzle is clogged
    3. the steam pressure to the nozzle is too low
  7. Which factors affect the extent of an upgrading program?
  8. Answers:
    1. Age of the unit.
    2. How it has been operated.
    Note: Turbines less than quarter of a century old can simply be upgraded to their original design conditions.
  9. Why are free-standing blades in the last low-pressure stage favored more, in some cases, than those that are coupled and shrouded together?
  10. Answers:
    1. These free-standing blades are known to provide good and adequate protection against stresses and aggressive environment.
    2. They eliminate all areas viz. shroud/tenon interface and tie-wire/hole area where corrodents can collect
  11. Why are simple impulse turbines not so common?
  12. Answers:
    1. Since the whole pressure drop from boiler to condenser pressure takes place in a single row of nozzles, the velocity of the steam entering the turbine is very high. If some of this velocity is used up in a single row of turbine blading, as in the de Laval turbine, the speed of the rotation of the wheel will be too high to be blades are be useful for practical purposes, as there is the danger of structural failures due to excessive centrifugal stresses.
    2. Steam exits from the turbine with a sufficiently high velocity, meaning a considerable loss of kinetic energy.
  13. Why are some groups of steam turbine blades, particularly the first or control stages more prone to fatigue failures than others?
  14. Answer: Blades in the first or control stages are under partial-arc admission that forces the blades to move into and out of the steam flow causing alternating high-and low-impact forces. This periodic change of impact forces imparts fatigue stress that makes such groups of blades susceptible to fatigue failure.
  15. Why could a turbine wheel become unbalanced?
  16. Answer: If the turbine is kept idle for a long spell without complete drainage of exhaust casing, the solid matter can deposit in the lower half of the wheel causing unbalance.
  17. Why do blade roots suffer from damage?
  18. Answers:
    1. Fatigue is the common cause to the effect of blade root damage. Also a generic type of fault often assists this factor in design or manufacturer.
    2. Moreover, the root-fillet radii are subjected to a high degree of stress concentration with the effect that they crack relatively easily.
  19. Why do electrically induced stresses occur in steam turbine rotors occur?
  20. Answer: They originate due to short circuits and faulty synchronization.
   
 

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