Chapter 30: Efficiency Of Systems

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Source Metadata

Field	Value
Source	Theory and Calculation of Alternating Current Phenomena
Year	1900
Section ID	`theory-calculation-alternating-current-phenomena-1900-chapter-30`
Location	lines 25136-25597
Status	candidate
Word Count	2745
Equation Candidates In Section	0
Figure Candidates In Section	0
Quote Candidates In Section	0

Opening Source Excerpt

CHAPTER XXX. EFFICIENCY OF SYSTEMS. 288. In electric power transmission and distribution, wherever the place of consumption of the electric energy is distant from the place of production, the conductors which transfer the current are a sufficiently large item to require consideration, when deciding which system and •what potential is to be used. In general, in transmitting a given amount of power at a given loss over a given distance, other things being equal, the amount of copper required in the conductors is inversely proportional to the square of the potential used. Since the total power transmitted is proportional to the product of current and E.M.F., at a given power, the current will vary inversely proportional to the E.M.F., and therefore, since the loss is proportional to the product of current- square and resistance, to

Source-Located Theme Snippets

Alternating current

CHAPTER XXX. EFFICIENCY OF SYSTEMS. 288. In electric power transmission and distribution, wherever the place of consumption of the electric energy is distant from the place of production, the conductors which transfer the current are a sufficiently large item to require consideration, when deciding which system and •what potential is to be used. In general, in transmitting a given ...

Dielectricity / capacity

... maximum potential only, but where the limitation of potential depends upon the problem of insulating the conductors against disruptive discharge, the proper comparison is on the basis of equality of the maximum difference of potential in the system ; that is, •equal maximum dielectric strain on the insulation. The same consideration holds in moderate potential power circuits, in considering the danger to life from live wires entering human habitations. Thus the comparison of different systems of long-dis- tance transmission at high potential or power d ...

Radiation / light

... comparison of different systems of long-dis- tance transmission at high potential or power distribution for motors is to be made on the basis of equality of the maximum difference of potential existing in the system. The comparison of low potential distribution circuits for lighting on the basis of equality of the minimum difference of potential between any pair of wires connected to the receiving apparatus. 289. 1st. Comparison on the basis of equality of the minimum difference of potential, in low potential lighting circuits : 4TO ALTERNATING- ...

Complex quantities

... lamps between the neutral wire and the three outside wires — that is, in Y con- nection— the potential between the outside wires or delta potential will be = e X V3, since the Y potential = e, and the potential of the system is raised thereby from e to e V3 ; that is, only J as much copper is required in the out- side wires as before — that is \ as much copper as in the single-phase two-wire system. Making the neutral of the same cross-section as the outside wires, requires \ more copper, or \ = 33.3 per cent of the copper of the single- phase sy ...

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Modern Engineering Reading Prompts

Alternating current: Compare Steinmetz’s AC language with modern sinusoidal steady-state analysis, RMS quantities, phase, and phasor notation.
Dielectricity / capacity: Check whether the passage treats capacity, condensers, displacement, or dielectric stress as field storage rather than only circuit algebra.
Radiation / light: Compare the chapter’s radiation vocabulary with modern electromagnetic radiation, spectral frequency, wavelength, absorption, and illumination engineering.
Complex quantities: Track how Steinmetz preserves geometric rotation and quadrature while translating the same operation into symbolic form.

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Dielectricity / capacity: A Wheeler-style reading may emphasize dielectric compression, field stress, and stored potential, but this page treats that as interpretation unless Steinmetz explicitly says it.
Radiation / light: Radiation and wave language can invite ether-field comparison, but source wording, modern radiation theory, and speculative synthesis must stay separated.

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