Power Systems, Reactors, And Synchronism
Visual topic gallery
Power Systems, Reactors, And Synchronism
Visual routes through system sections, reactors, synchronizing current, power-limiting reactance, apparatus, and industrial engineering decisions.
0
original crops
scan images routed into this topic12
modern guide diagrams
reconstructions, not historical evidence228
figure candidates
OCR/PDF-text leads needing crop review1212
formula candidates
math leads needing transcription reviewLayer rule: original crops, figure candidates, modern redraws, and formula candidates are separated. Use this page to browse visually, then verify in the linked source text and workbench.
Source Routes
Section titled “Source Routes”Commonwealth Edison Generating System Trouble
Visual mapCommonwealth Edison Generating System Trouble
Formula mapTheory Calculation Electric Circuits
Visual mapTheory Calculation Electric Circuits
Formula mapTheory Calculation Electric Apparatus
Visual mapTheory Calculation Electric Apparatus
Formula mapGeneral Lectures Electrical Engineering
Visual mapGeneral Lectures Electrical Engineering
Formula map
Original Scan Crops
Section titled “Original Scan Crops”No promoted original scan crops are currently routed to this topic. Use the candidate figure leads below to pick the next crops for extraction.
Modern Guide Diagrams
Section titled “Modern Guide Diagrams”
Rotating Magnetic Field From Quadrature Fluxes
Modern reading aid for induction-machine field language in AC and Theoretical Elements sources.
symbolic-method, magnetism, phase, induction-motor
Distributed Constants Of A Transmission Line
Modern reading aid for line capacity, inductance, leakage, waves, and transients.
distributed-constants, capacity, inductance, waves
Impulse Surge And Reflection
Modern reading aid for lightning, impulses, discharges, and traveling waves.
lightning-surges, impulse-current, traveling-wave
Equivalent Sine Waves And Harmonics
Modern reading aid for wave-shape analysis and higher harmonics.
harmonics, wave-shape, fourier-analysis
Reactors And Synchronizing Power
Modern reading aid for the Commonwealth Edison report and system-stability mathematics.
synchronizing-power, power-limiting-reactors, reactance
Engineering Number Plane
Modern reading aid for number, direction, and symbolic calculation in Engineering Mathematics.
complex-quantities, number, symbolic-method
AC Symbolic Method Redraw Sheet
Modern redraw sheet for rectangular components, resultant addition, and quarter-period j rotation.
symbolic-method, complex-quantities, phasor, operator-j
Phasor And Symbolic Method
Modern reading aid for vector and complex-number representation of alternating quantities.
symbolic-method, complex-quantities, phase, phasor
Hysteresis Loop
Modern guide for magnetic lag, loop area, and energy loss per cycle.
hysteresis, magnetism, magnetic-loss, effective-resistance
Field Wave Line
Modern reading aid for distributed constants, standing waves, traveling waves, and surge propagation.
electric-waves, distributed-constants, traveling-wave, lightning-surges
Impedance And Reactance Triangle
Modern guide for resistance, reactance, impedance, phase angle, and symbolic quantities.
impedance, reactance, power-factor, symbolic-method
Commonwealth Edison System Reactor Map
Modern reading aid for station sections, power-limiting reactors, tie cables, and synchronism.
power-limiting-reactors, synchronizing-power, reactance, power-systems
Candidate Figure Leads
Section titled “Candidate Figure Leads”| Candidate | Caption lead | Source section | Routes |
|---|---|---|---|
radiation-light-and-illumination-fig-012Fig. 12 | They are used in wireless telegraphy, etc. I here connect (Fig. 12) FIG. 12. the condenser C of the apparatus which I used for operating the ultra-violet arc, to a spark gap Gv of which the one side is con- | Radiation, Light and Illumination Lecture 1: Nature And Different Forms Of Radiation | source research review |
radiation-light-and-illumination-fig-014Fig. 14 | as far as possible when producing light, as they consume power FIG. 14. and so lower the efficiency; the ultra-violet rays are of importance in medicine as germ killers. They are more or less destructive | Radiation, Light and Illumination Lecture 1: Nature And Different Forms Of Radiation | source research review |
radiation-light-and-illumination-fig-021Fig. 21 | VIOLET FIG. 21. in the ultra-red and ultra-violet, where no power of radiation can produce visibility. It thus varies about as indicated in Fig. 22. | Radiation, Light and Illumination Lecture 3: Physiological Effects Of Radiation | source research review |
radiation-light-and-illumination-fig-024Fig. 24 | \ FIG. 24. (1 meter-candle is the illumination produced by 1 candle power | Radiation, Light and Illumination Lecture 3: Physiological Effects Of Radiation | source research review |
radiation-light-and-illumination-fig-025Fig. 25 | S FIG. 25. 62 for high intensities and changes in approximately the same range of intensities in which lwo changes; ks is also plotted in | Radiation, Light and Illumination Lecture 3: Physiological Effects Of Radiation | source research review |
radiation-light-and-illumination-fig-027Fig. 27 | fore, increase enormously with the increase of temperature. FIG. 27. With bodies in a vacuum, the radiation power is the power input and this above law can be used to calculate the tempera- | Radiation, Light and Illumination Lecture 5: Temperature Radiation | source research review |
radiation-light-and-illumination-fig-028Fig. 28 | weight, exhibit a periodicity in their properties which permits FIG. 28. a systematic study of their properties. In diagram Fig. 28 the | Radiation, Light and Illumination Lecture 5: Temperature Radiation | source research review |
radiation-light-and-illumination-fig-029Fig. 29 | \ FIG. 29. power required to maintain the temperature is correspondingly less, hence the efficiency is the same and merely a larger radiator | Radiation, Light and Illumination Lecture 5: Temperature Radiation | source research review |
radiation-light-and-illumination-fig-031Fig. 31 | one, the other from the other terminal. They are stationary FIG. 31. only if the gas pressure is perfectly constant, but separate and contract with the slightest change of pressure, hence are almost | Radiation, Light and Illumination Lecture 6: Luminescence | source research review |
radiation-light-and-illumination-fig-059Fig. 59 | Fig. 59, is the distribution curve in one meridian, it is the same FIG. 59. in every other meridian, and for photometric test of the illumi- nant it is sufficient to measure the light intensities in one merid- | Radiation, Light and Illumination Lecture 9: Measurement Of Light And Radiation | source research review |
radiation-light-and-illumination-fig-100Fig. 100 | candle power: FIG. 100. I. The direct-current enclosed carbon arc, with clear inner | Radiation, Light and Illumination Lecture 11: Light Intensity And Illumination | source research review |
radiation-light-and-illumination-fig-125Fig. 125 | FIG. 124. FIG. 125. In some respects the action of the two separate flux densities | Radiation, Light and Illumination Lecture 13: Physiological Problems Of Illuminating Engineering | source research review |
elementary-lectures-electric-discharges-waves-impulses-fig-003Fig. 3 | permanent condition corresponding to the closed switch can occur, Fig. 3. the stored energy has to be supplied from the source of power; that is, for a short time power, in supplying the stored energy, flows… | Elementary Lectures on Electric Discharges, Waves and Impulses, and Other Transients Lecture 1: Nature And Origin Of Transients | source research review |
elementary-lectures-electric-discharges-waves-impulses-fig-025Fig. 25 | frequency, and as the result an increase of voltage and a distor- tion of the quadrature phase occurs, as shown in the oscillogram Fig. 25. Various momentary short-circuit phenomena are illustrated by the os… | Elementary Lectures on Electric Discharges, Waves and Impulses, and Other Transients Lecture 4: Single-Energy Transients In Alternating Current Circuits | source research review |
elementary-lectures-electric-discharges-waves-impulses-fig-040Fig. 40 | Line Fig. 40. former, the high-tension switches are opened at the generator end of the transmission line. The energy stored magnetically and | Elementary Lectures on Electric Discharges, Waves and Impulses, and Other Transients Lecture 8: Traveling Waves | source research review |
elementary-lectures-electric-discharges-waves-impulses-fig-054Fig. 54 | which it can draw in supplying power. In permanent condition the line could not add to the power, but must consume, that is, the permanent power-transmission diagram must always be like Fig. 54. Not so, as s… | Elementary Lectures on Electric Discharges, Waves and Impulses, and Other Transients Lecture 9: Oscillations Of The Compound Circuit | source research review |
elementary-lectures-electric-discharges-waves-impulses-fig-056Fig. 56 | Line Fig. 56. The diagram of the power of the two waves of opposite direc- tions, and of the resultant power, is shown in Fig. 57, assuming | Elementary Lectures on Electric Discharges, Waves and Impulses, and Other Transients Lecture 9: Oscillations Of The Compound Circuit | source research review |
engineering-mathematics-fig-047Fig. 47 | able to supply the charging current of the line, due to the Fig. 47. wave shape distortion, more than two generators are required. | Engineering Mathematics: A Series of Lectures Delivered at Union College Chapter 3: Trigonometric Series | source research review |
theory-calculation-alternating-current-phenomena-fig-034Fig. 34 | 90” LAG Fig. 34. and generator currents, /i”, 72°, I^, over the topographical char- | Theory and Calculation of Alternating Current Phenomena Chapter 6: Topographic Method | source research review |
theory-calculation-alternating-current-phenomena-fig-051Fig. 51 | Eo E Fig. 51. M | Theory and Calculation of Alternating Current Phenomena Chapter 9: Circuits Containing Resistance, Inductive Reactance, And Condensive Reactance | source research review |
theory-calculation-alternating-current-phenomena-fig-052Fig. 52 | Eo Fig. 52. Fig. 53. | Theory and Calculation of Alternating Current Phenomena Chapter 9: Circuits Containing Resistance, Inductive Reactance, And Condensive Reactance | source research review |
theory-calculation-alternating-current-phenomena-fig-053Fig. 53 | Fig. 52. Fig. 53. 2. Reactance in Series with a Circuit | Theory and Calculation of Alternating Current Phenomena Chapter 9: Circuits Containing Resistance, Inductive Reactance, And Condensive Reactance | source research review |
theory-calculation-alternating-current-phenomena-fig-054Fig. 54 | ohms inductance-’— reactance-^condensance Fig. 54. E^, are shown for various conditions of a receiver circuit and | Theory and Calculation of Alternating Current Phenomena Chapter 9: Circuits Containing Resistance, Inductive Reactance, And Condensive Reactance | source research review |
theory-calculation-alternating-current-phenomena-fig-055Fig. 55 | 0 Fig. 55. Fig. 56. | Theory and Calculation of Alternating Current Phenomena Chapter 9: Circuits Containing Resistance, Inductive Reactance, And Condensive Reactance | source research review |
Formula Leads That Pair With The Visual Topic
Section titled “Formula Leads That Pair With The Visual Topic”| Candidate | OCR/PDF text | Source section | Routes |
|---|---|---|---|
theory-calculation-alternating-current-phenomena-eq-candidate-0294symbolic-ac | is r - j {x + Xo) = r = 0.6, x -{- Xo = 0, and tan do = 0; that | Theory and Calculation of Alternating Current Phenomena Chapter 9: Circuits Containing Resistance, Inductive Reactance, And Condensive Reactance | source research review |
theory-calculation-electric-apparatus-eq-candidate-0028symbolic-ac | = - J = (tan a - j) (7) | Theory and Calculation of Electric Apparatus Chapter 1: Speed Control Of Induction Motors | source research review |
theoretical-elements-electrical-engineering-eq-candidate-0132symbolic-ac | If an alternating current i = I0 sin 6 passes through a resist- | Theoretical Elements of Electrical Engineering Theory Section 4: Power and Effective Values | source research review |
theory-calculation-alternating-current-phenomena-1900-eq-candidate-0156apparatus-systems | E.M.F. of the generator OE°, where Z0 = r0 - jx0 = inter- | Theory and Calculation of Alternating Current Phenomena Chapter 6: Topographic Method | source research review |
theoretical-elements-electrical-engineering-eq-candidate-0138symbolic-ac | e.m.f., e = EQ sin 6. | Theoretical Elements of Electrical Engineering Theory Section 4: Power and Effective Values | source research review |
general-lectures-electrical-engineering-eq-candidate-0026symbolic-ac | copper of No. 5, or j of ;j = ^: Cu. = ^ | General Lectures on Electrical Engineering Lecture 3: Light And Power Distribution | source research review |
commonwealth-edison-generating-system-trouble-eq-sync-emfs-0001apparatus-systems | e1 = E cos(…); e2 = E cos(…), OCR candidate | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-candidate-0007apparatus-systems | ei = E cos (0 | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-resultant-voltage-0002apparatus-systems | e = e1 - e2 = 2E sin(…) sin(…), OCR candidate | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-interchange-current-0003apparatus-systems | i = (2E / z) sin(…) sin(…), OCR candidate | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-impedance-angle-0004apparatus-systems | z = sqrt(r^2 + x^2); tan a = x / r, OCR candidate | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-candidate-0024apparatus-systems | p’Y=-!|cos(2a>-a) | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-candidate-0027apparatus-systems | P=- sin a sin 2co | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-candidate-0039apparatus-systems | W= ^-sin a (1-cos 2 Wo ) | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
commonwealth-edison-generating-system-trouble-eq-candidate-0105apparatus-systems | 2Eo sin wo = I (2xx+x) | Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. Mathematical Appendix 5: Appendix: Synchronous Operation | source research review |
theoretical-elements-electrical-engineering-eq-candidate-0133symbolic-ac | i*r = 702r sin2 0 = ^r C1 ~ cos 2 0), | Theoretical Elements of Electrical Engineering Theory Section 4: Power and Effective Values | source research review |
theoretical-elements-electrical-engineering-eq-candidate-0168symbolic-ac | e = E0 sin (0 - 0i) = 273 sin (0 - 0i) ; | Theoretical Elements of Electrical Engineering Theory Section 4: Power and Effective Values | source research review |
theoretical-elements-electrical-engineering-eq-candidate-0170symbolic-ac | e = 273 sin 210 (t - h). | Theoretical Elements of Electrical Engineering Theory Section 4: Power and Effective Values | source research review |
Editorial Use
Section titled “Editorial Use”This gallery is meant for discovery, not final citation. The strongest current source distribution is: Theory and Calculation of Electric Circuits (337), Theory and Calculation of Electric Apparatus (313), Theory and Calculation of Alternating Current Phenomena (291), Investigation of Some Trouble in the Generating System of the Commonwealth Edison Co. (221). Promote a diagram or formula only after the scan, page label, exact caption, and mathematical notation are checked.