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Reeds Vol 7: Advanced Electrotechnology for Marine Engineers [Minkštas viršelis]

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, (Britannia Royal Naval College, UK)
  • Formatas: Paperback / softback, 544 pages, aukštis x plotis x storis: 234x156x32 mm, weight: 840 g
  • Serija: Reeds Marine Engineering and Technology Series
  • Išleidimo metai: 23-Oct-2014
  • Leidėjas: Thomas Reed Publications
  • ISBN-10: 1408176033
  • ISBN-13: 9781408176030
Kitos knygos pagal šią temą:
Reeds Vol 7: Advanced Electrotechnology for Marine EngineersDidesnis paveikslėlis
  • Formatas: Paperback / softback, 544 pages, aukštis x plotis x storis: 234x156x32 mm, weight: 840 g
  • Serija: Reeds Marine Engineering and Technology Series
  • Išleidimo metai: 23-Oct-2014
  • Leidėjas: Thomas Reed Publications
  • ISBN-10: 1408176033
  • ISBN-13: 9781408176030
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781408176030.html

Essential text for all marine
engineers and ETO officers, covering advanced electrotechnology theory.



This book is a companion to Reeds Vol. 6: Basic Electrotechnology for Marine Engineers and covers aspects of theory beyond the scope of Volume 6. The book will cover the more advanced topics in electrotechnology for professional trainees studying Merchant Navy Marine Engineering Certificates of Competency (CoC) as well as the syllabi in electrotechnology for undergraduates studying for BSc, BEng and MEng degrees in marine engineering and electrical engineering.

The new edition will provide worked examples and test exam questions, corresponding to current Merchant Navy Qualifications. Other revisions will include new material on emerging technology areas such as image intensifiers (photoelectric effect, secondary emission), thermal imaging cameras, radar, increased maritime use of LEDs, various semiconductor physics devices including the laser, as well as discussions of binary or digital theory.

Daugiau informacijos

Essential text for all marine engineers and ETO officers, covering advanced electrotechnology theory.
Preface xi
Acknowledgements xiii
The S.I. System xiv
1 Transformer Operation
1(24)
Brief Early History of the Transformer
2(1)
Principle of Operation
2(3)
The e.m.f. Equation
5(2)
The Transformer on No Load
7(4)
Primary phasor diagram
7(1)
Secondary phasor diagram
8(1)
Combined phasor diagram
9(1)
Voltage and turns relationship
10(1)
The Transformer on Load
11(7)
On-load phasor diagram
12(3)
On-load voltage diagram
15(3)
Referred Values of Resistance, Reactance and Impedance
18(2)
Transformer Efficiency
20(5)
Efficiency
21(4)
2 The Transformer (Testing And Efficiency)
25(25)
The Combined Phasor Diagram
26(3)
The Equivalent Circuit
29(1)
Voltage Regulation
30(5)
Internal Voltage-Drop Formula (For Approximation)
35(3)
Transformer Testing
38(5)
The open-circuit test
38(2)
The short-circuit test
40(2)
Direct-Loading Test (Sumpner's Test)
42(1)
Percentage Resistance, Reactance and Impedance
43(1)
Efficiency
44(6)
Conditions for maximum efficiency
45(1)
Conditions for all-day efficiency
46(4)
3 The Transformer Applications
50(32)
Instrument Transformers
50(8)
The current transformer (C.T.)
51(6)
The voltage transformer (V.T.)
57(1)
The Auto-Transformer
58(10)
Fixed ratio type
58(3)
Variable ratio type
61(2)
Three-phase transformation
63(2)
Methods of connection
65(3)
The Saturable Reactor
68(10)
The transductor
70(1)
The magnetic amplifier
70(8)
Solid-State Transformers
78(4)
4 D.C. Machines
82(37)
Testing of D.C. Machines
82(16)
Output
83(1)
Efficiency
84(1)
Losses
84(3)
Testing methods
87(11)
D.C. Generators in Parallel
98(6)
Parallel operation
98(3)
Load sharing
101(3)
Commutation and Armature Reaction
104(11)
Commutation
104(6)
Armature reaction
110(5)
Special D.C. Machines
115(4)
The rotary transformer
115(1)
The rotary converter
116(1)
The rotating amplifier
116(3)
5 D.C. Rectification
119(32)
Electromagnetic Induction
120(1)
Inductance
120(1)
The Direct Current LR Circuit
121(9)
Growth of current
122(4)
Decay of current
126(2)
The field switch and discharge resistor
128(2)
The Direct Current CR Circuit
130(5)
Growth of current
131(2)
Discharge conditions
133(2)
The Alternating Currents LR and CR Circuit
135(2)
Current asymmetry
135(2)
Rectification
137(14)
Terms
137(1)
Rectifier arrangements
137(11)
Battery charging by rectifier
148(3)
6 The A.C. Generation
151(34)
The A.C. Generator
152(4)
Rotating-armature type
152(1)
Rotating-field type
153(3)
Excitation Arrangements
156(6)
Rotary excitation systems
157(2)
Static excitation systems
159(3)
The Speed-Frequency Equation
162(13)
E.M.F. equation
163(6)
Waveform of generated e.m.f.
169(6)
Stator Windings
175(4)
Types of windings
176(3)
The Alternator on Load
179(6)
7 The Marine Alternator
185(26)
The Rotating Magnetic Field
186(25)
Armature reaction
193(2)
The phasor diagram (continued)
195(4)
Prediction of voltage regulation
199(4)
Synchronising torque
203(8)
8 The Induction Motor
211(29)
Principle of Operation
212(16)
Rotor to stator relationships
214(3)
Relation between rotor loss, rotor input power and rotor output
217(1)
Torque conditions
218(7)
The phasor diagram
225(3)
The Circle Diagram
228(12)
Explanation of the circle diagram
230(1)
Testing procedure
231(1)
Construction of the circle diagram
232(8)
9 A.C. Machines - Operation
240(32)
A.C. Generators
240(15)
A.C. generators in parallel
241(1)
The synchroscope
242(1)
Parallel operation
243(7)
Load sharing
250(5)
The Synchronous Motor
255(5)
Operating action
255(3)
Starting
258(2)
Induction Motors
260(12)
Starting
260(4)
Speed and torque control
264(4)
Speed adjustment
268(4)
10 Electronic Emission Processes And Devices
272(26)
Electron Emission
273(1)
Thermionic Emission
274(1)
The Vacuum Diode
274(9)
Static characteristics
277(3)
Dynamic characteristics -- load line
280(3)
The Vacuum Triode
283(6)
Static characteristics
284(2)
Valve parameters
286(1)
Parameter relationships
287(2)
Ionisation
289(3)
The hot-cathode discharge lamp (low pressure)
290(1)
The hot-cathode discharge lamp (high pressure)
291(1)
The Cathode Ray Oscilloscope
292(6)
Image intensifies
293(1)
Image intensifier device operation
294(4)
11 Solid-State Electronics: The Diode
298(26)
Semiconductors
298(6)
Basic theory
300(2)
Conduction control
302(2)
The P-N Junction
304(8)
The junction diode
306(3)
Rectifier operation
309(3)
Rectifier Circuits
312(4)
Half-wave
312(1)
Full-wave
313(3)
Filter Circuit
316(1)
Voltage Doubler Circuit
317(2)
Stabilised power supplies
317(1)
The zener diode
318(1)
Series Stabilisation
319(5)
12 Solid-State Electronics: The Transistor
324(28)
The Transistor
324(28)
The junction transistor
325(5)
Transistor characteristics
330(12)
Load lines
342(1)
Leakage current
343(1)
The practical amplifier
343(1)
The transistor as a switch
344(2)
The thyristor
346(6)
13 Electronic AIDS To Navigation
352(30)
Radar
353(8)
Maritime radar applications
354(3)
Maximum Detection Range (MDR) and Radar Cross Section (RCS)
357(2)
Antennas
359(2)
Signal Processing
361(1)
Clutter
361(1)
Noise
361(1)
Environmental effects
362(1)
Lasers
362(4)
Lasers for marine applications
362(1)
Stimulated emission
363(1)
Laser safety
364(1)
Laser range finding and maintaining ships' proximity in RAS
364(1)
Automatic Radar Plotting Aid (ARPA)
365(1)
Electronic Chart Displays
366(1)
Electronic Chart Display and Information System (ECDIS)
366(1)
War-fighting ECDIS
366(1)
Radio Navigation Aids
367(1)
Interference-based navigation-related sensors
367(1)
LORAN-C
367(2)
Limitations of LORAN
368(1)
Global Positioning Systems
369(7)
NAVSTAR
372(1)
GLONASS
372(1)
GALILEO
373(1)
Global Maritime Distress Safety System (GMDSS)
373(1)
Automatic Identification System (AIS)
374(2)
Emergency Beacons
376(6)
How a typical beacon operates
376(1)
Activation
377(1)
Hydrostatic Release Unit
377(1)
GPS beacon operation
377(1)
High-precision registered beacon operation
378(1)
Non-GPS Doppler location
378(1)
Satellites
379(1)
Search and rescue response
379(3)
14 Display Devices
382(32)
Cathode Ray Tube
382(5)
Production of displays
384(1)
Oscilloscope CRTs
385(1)
CRT advantages
386(1)
CRT disadvantages
386(1)
Liquid Crystal Displays
387(14)
A brief history of liquid crystals
388(3)
Liquid crystal phases
391(2)
Switching speeds
393(2)
Liquid crystal alignment
395(1)
Liquid crystal technology
396(5)
The Plasma Display Device
401(3)
History
401(1)
Plasma display advantages
402(1)
Plasma display disadvantages
402(1)
Screen burn-out
403(1)
ElectroLuminescent Displays
404(4)
History
405(3)
Material fabrication technologies
408(1)
Polymer Light Emitting Diodes
408(3)
Phosphorescent materials
408(1)
Device structure: Bottom or top emission?
409(1)
Fabrication
409(1)
OLED advantages
410(1)
OLED disadvantages
410(1)
Outdoor performance
410(1)
Power consumption
410(1)
Holographic Displays
411(3)
Solutions To Practice Examples 414(79)
Selection Of Typical Examination Questions 493(5)
Solutions To Typical Examination Questions 498(23)
Index 521
Christopher Lavers is a lecturer in Marine Engineering and has taught Maritime and Remote Sensing topics at Britannia Royal Naval College since 1993. He is Subject Matter Expert (Radar and Telecommunications) at Britannia Royal Naval College, Dartmouth, UK.