Handbook of Large Hydro Generators. Geoff Klempner
which was the model for this book.
The authors would like to give special recognition to Sungsoo Kim for writing Chapter 6 (Generator Protection); his patience and contribution has produced a magnificent compilation of his expertise. The authors would also like to thank Tim Maricic and Wayne Martin for their gracious contributions to Chapter 2. The authors are privileged to have had two very patient technical reviewers, John Linn and Richard Huber, who painstakingly went through the manuscript and contributed useful ideas. The authors are also very grateful to the individuals who kindly supplied the many pictures and information that make up this handbook.
The authors wish to thank Ontario Power Generation for the incredibly large volume of pictures that form part of this book, without this support, this book would not have been possible. Unless otherwise indicated, all pictures in the book are courtesy of Ontario Power Generation.
Special thanks to Victoria Bomben and Paolo Bomben for their assistance with the design of the front cover, and to Voith for the picture.
The authors are most indebted to the IEEE Press for supporting its publication.
The authors also would like to thank the members of the editorial departments of the IEEE Press and Wiley, the reviewers, and all others involved in the publication of this book for their support in making its publication possible.
Finally, but certainly most intensely, the authors wish to thank their immediate families for their continuous support and encouragement while we played with big machines around the world.
CHAPTER 1 Principles of Operation of Synchronous Machines
The synchronous generator belongs to the family of electric rotating machines. Other members of the family are the direct‐current (DC) motor or generator, the induction motor or generator, and a number of derivatives of these three. What is common to all the members of this family is the basic physical process involved in their operation, which is the conversion of electromagnetic energy to mechanical energy, and vice versa. Therefore, to gain an understanding of the physical principles governing the operation of electric rotating machines, one has to understand some rudiments of electrical and mechanical engineering.
Chapter 1 is for those who are involved in operating, maintaining, and trouble‐shooting electrical generators. Specifically, those who want to acquire a better understanding of the principles governing the machines' design and operation, but lack an electrical engineering background. The chapter starts by introducing the rudiments of electricity and magnetism, quickly building up to a description of the basic laws of physics governing the operation of the synchronous electric machine, which is the type of machine to which all salient pole hydro generators belong.
1.1 Introduction to Basic Notions on Electric Power
1.1.1 Magnetism and Electromagnetism
Certain materials found in nature exhibit a characteristic to attract or repel each other. These materials, called magnets, are also called ferromagnetic because they include the element iron as one of their constituent elements. Magnets always have two poles: one called north, the other called south. Two north poles will repel each other, as will two south poles. However, north and south poles will attract each other. A magnetic field is defined as a physical field established between two poles. Its intensity and direction determine the forces of attraction or repulsion existing between the two magnets.
Figures 1.1-1 and 1.1-2 are typical representations of two interacting magnetic poles and the magnetic field established between them.
Figure 1.1-1 Representation of two magnetic poles of opposite polarity, with the magnetic field between them shown as “lines of force.”
Magnets are found in nature in all sorts of shapes and chemical constitution. Magnets used in industry are artificially made. Magnets that sustain their magnetism for long periods of time are denominated “permanent magnets.” The magnetic field produced by the north and the south pole of a permanent magnet is directional from north to south as shown in Figure 1.1-3. These are widely used in several types of electric rotating machines, including synchronous machines. However, due to mechanical as well as operational reasons, permanent magnets in synchronous machines are restricted to those with ratings much lower than large hydraulic (“hydro”) turbine‐driven generators, which is the subject of this book. Hydro generators take advantage of the fact that magnetic fields can be created by the flow of electric currents in conductors, see Figure 1.1-4.
The direction of the lines of force is given by the “law of the screwdriver”: mentally follow the movement of a screw as it is screwed in the same direction as that of the current; the lines of force will then follow the circular direction of the head of the screw. The magnetic lines of force are perpendicular to the direction of current. A very useful phenomenon is that forming the conductor into the shape of a coil can augment the intensity of the magnetic field created by the flow of current through the conductor. In this manner, as more turns are added to the coil, the same current produces larger and larger magnetic fields. For practical reasons, all magnetic fields created by current in a machine are generated in coils as shown in Figure 1.1-5.
Figure 1.1-2 Representation of two north poles and the magnetic field between them. South poles will create similar field patterns, but the lines of force will point toward the poles.
Figure 1.1-3 Representation of a “permanent magnet” showing the north and south poles and the magnetic field between them flowing from north to south outside the magnet.
Figure 1.1-4 Representation of a magnetic field created by the flow of current in a conductor.
The use of coils to amplify the magnetic field intensity requires them to be constructed in a very specific manner so that the resulting flux is produced in an effective way. When the coil is operating in air, the magnetic field direction, shape, and intensity depends on the number of turns in the coil, the size of the coil, and the direction of electric current flow in the coil winding. The flux produced is basically divided into two types. One is the effective flux that links the entire coil and does the useful work, and the other is the leakage flux which is a more