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AT the present writing, when, after the
phenomenally rapid electrical development of
thirty years, we find on the market a great
variety of modern forms of efficient current
generators advertised under the names of
different inventors (none, however, bearing
the name of Edison), a young electrical
engineer of the present generation might well
inquire whether the great inventor had ever
contributed anything to the art beyond a mere
TYPE of machine formerly made and bearing his
name, but not now marketed except second hand.
For adequate information he might search in vain
the books usually regarded as authorities on the
subject of dynamo-electric machinery, for with
slight exceptions there has been a singular
unanimity in the omission of writers to give
Edison credit for his great and basic
contributions to heavy-current technics,
although they have been universally acknowledged
by scientific and practical men to have laid the
foundation for the efficiency of, and to be
embodied in all modern generators of current.
It might naturally be expected that the
essential facts of Edison's work would appear
on the face of his numerous patents on
dynamo-electric machinery, but such is not
necessarily the case, unless they are carefully
studied in the light of the state of the art as
it existed at the time. While some of these
patents (especially the earlier ones) cover
specific devices embodying fundamental principles
that not only survive to the present day, but
actually lie at the foundation of the art as it
now exists, there is no revelation therein of
Edison's preceding studies of magnets, which
extended over many years, nor of his later
systematic investigations and deductions.
Dynamo-electric machines of a primitive kind
had been invented and were in use to a very
limited extent for arc lighting and
electroplating for some years prior to the summer
of 1819, when Edison, with an embryonic
lighting SYSTEM in mind, cast about for a
type of machine technically and commercially
suitable for the successful carrying out of his
plans. He found absolutely none. On the
contrary, all of the few types then obtainable
were uneconomical, indeed wasteful, in regard
to efficiency. The art, if indeed there can be
said to have been an art at that time, was in
chaotic confusion, and only because of
Edison's many years' study of the magnet was
he enabled to conclude that insufficiency in
quantity of iron in the magnets of such
machines, together with poor surface contacts,
rendered the cost of magnetization abnormally
high. The heating of solid armatures, the only
kind then known, and poor insulation in the
commutators, also gave rise to serious losses.
But perhaps the most serious drawback lay in the
high-resistance armature, based upon the
highest scientific dictum of the time that in
order to obtain the maximum amount of work from a
machine, the internal resistance of the armature
must equal the resistance of the exterior
circuit, although the application of this
principle entailed the useless expenditure of at
least 50 per cent. of the applied energy.
It seems almost incredible that only a little
over thirty years ago the sum of scientific
knowledge in regard to dynamo- electric machines
was so meagre that the experts of the period
should settle upon such a dictum as this, but
such was the fact, as will presently appear.
Mechanical generators of electricity were
comparatively new at that time; their theory and
practice were very imperfectly understood;
indeed, it is quite within the bounds of truth
to say that the correct principles were befogged
by reason of the lack of practical knowledge of
their actual use. Electricians and scientists
of the period had been accustomed for many years
past to look to the chemical battery as the
source from which to obtain electrical energy;
and in the practical application of such energy
to telegraphy and kindred uses, much thought and
ingenuity had been expended in studying
combinations of connecting such cells so as to
get the best results. In the text-books of the
period it was stated as a settled principle
that, in order to obtain the maximum work out of
a set of batteries, the internal resistance must
approximately equal the resistance of the
exterior circuit. This principle and its
application in practice were quite correct as
regards chemical batteries, but not as regards
dynamo machines. Both were generators of
electrical current, but so different in
construction and operation, that rules
applicable to the practical use of the one did
not apply with proper commercial efficiency to
the other. At the period under consideration,
which may be said to have been just before dawn
of the day of electric light, the philosophy of
the dynamo was seen only in mysterious, hazy
outlines-- just emerging from the darkness of
departing night. Perhaps it is not surprising,
then, that the dynamo was loosely regarded by
electricians as the practical equivalent of a
chemical battery; that many of the
characteristics of performance of the chemical
cell were also attributed to it, and that if the
maximum work could be gotten out of a set of
batteries when the internal and external
resistances were equal (and this was
commercially the best thing to do), so must it
be also with a dynamo.
It was by no miracle that Edison was far and
away ahead of his time when he undertook to
improve the dynamo. He was possessed of
absolute KNOWLEDGE far beyond that of
his contemporaries. This he ad acquired by the
hardest kind of work and incessant experiment
with magnets of all kinds during several years
preceding, particularly in connection with his
study of automatic telegraphy. His knowledge of
magnets was tremendous. He had studied and
experimented with electromagnets in enormous
variety, and knew their peculiarities in charge
and discharge, lag, self- induction, static
effects, condenser effects, and the various
other phenomena connected therewith. He had
also made collateral studies of iron, steel,
and copper, insulation, winding, etc.
Hence, by reason of this extensive work and
knowledge, Edison was naturally in a position
to realize the utter commercial impossibility of
the then best dynamo machine in existence, which
had an efficiency of only about 40 per cent.,
and was constructed on the "cut-and-try"
principle.
He was also naturally in a position to assume
the task he set out to accomplish, of
undertaking to plan and-build an improved type
of machine that should be commercial in hav- ing
an efficiency of at least 90 per cent. Truly
a prodigious undertaking in those dark days,
when from the standpoint of Edison's large
experience the most practical and correct
electrical treatise was contained in the
Encyclopaedia Britannica, and in a German
publication which Mr. Upton had brought with
him after he had finished his studies with the
illustrious Helmholtz. It was at this period
that Mr. Upton commenced his association with
Edison, bringing to the great work the very
latest scientific views and the assistance of the
higher mathematics, to which he had devoted his
attention for several years previously.
As some account of Edison's investigations in
this connection has already been given in
Chapter XII of the narrative, we shall not
enlarge upon them here, but quote from An
Historical Review, by Charles L. Clarke,
Laboratory Assistant at Menlo Park,
1880-81; Chief Engineer of the Edison
Electric Light Company, 1881-84:
"In June, 1879, was published the
account of the Edison dynamo-electric machine
that survived in the art. This machine went
into extensive commercial use, and was notable
for its very massive and powerful field-magnets
and armature of extremely low resistance as
compared with the combined external resistance of
the supply-mains and lamps. By means of the
large masses of iron in the field-magnets, and
closely fitted joints between the several parts
thereof, the magnetic resistance (reluctance)
of the iron parts of the magnetic circuit was
reduced to a minimum, and the required
magnetization effected with the maximum economy.
At the same time Mr. Edison announced the
commercial necessity of having the armature of
the dynamo of low resistance, as compared with
the external resistance, in order that a large
percentage of the electrical energy developed
should be utilized in the lamps, and only a
small percentage lost in the armature, albeit
this procedure reduced the total generating
capacity of the machine. He also proposed to
make the resistance of the supply-mains small,
as compared with the combined resistance of the
lamps in multiple arc, in order to still further
increase the percentage of energy utilized in the
lamps. And likewise to this end the combined
resistance of the generator armatures in multiple
arc was kept relatively small by adjusting the
number of generators operating in multiple at any
time to the number of lamps then in use. The
field-magnet circuits of the dynamos were
connected in multiple with a separate energizing
source; and the field-current; and strength of
field, were regulated to maintain the required
amount of electromotive force upon the
supply-mains under all conditions of load from
the maximum to the minimum number of lamps in
use, and to keep the electromotive force of all
machines alike."
Among the earliest of Edison's dynamo
experiments were those relating to the core of
the armature. He realized at once that the heat
generated in a solid core was a prolific source
of loss. He experimented with bundles of iron
wires variously insulated, also with sheet-iron
rolled cylindrically and covered with iron wire
wound concentrically. These experiments and
many others were tried in a great variety of
ways, until, as the result of all this work,
Edison arrived at the principle which has
remained in the art to this day. He split up
the iron core of the armature into thin
laminations, separated by paper, thus
practically suppressing Foucault currents
therein and resulting heating effect. It was in
his machine also that mica was used for the first
time as an insulating medium in a
commutator.[27]
Elementary as these principles will appear to
the modern student or engineer, they were
denounced as nothing short of absurdity at the
time of their promulgation--especially so with
regard to Edison's proposal to upset the then
settled dictum that the armature resistance
should be equal to the external resistance. His
proposition was derided in the technical press of
the period, both at home and abroad. As public
opinion can be best illustrated by actual
quotation, we shall present a characteristic
instance.
In the Scientific American of October 18,
1879, there appeared an illustrated article
by Mr. Upton on Edison's dynamo machine, in
which Edison's views and claims were set
forth. A subsequent issue contained a somewhat
acri- monious letter of criticism by a
well-known maker of dynamo machines. At the
risk of being lengthy, we must quote nearly all
this letter: "I can scarcely conceive it as
possible that the article on the above subject
"(Edison's Electric Generator)" in last
week's Scientific American could have been
written from statements derived from Mr.
Edison himself, inasmuch as so many of the
advantages claimed for the machine described and
statements of the results obtained are so
manifestly absurd as to indicate on the part of
both writer and prompter a positive want of
knowledge of the electric circuit and the
principles governing the construction and
operation of electric machines.
"It is not my intention to criticise the design
or construction of the machine (not because they
are not open to criticism), as I am now and
have been for many years engaged in the
manufacture of electric machines, but rather to
call attention to the impossibility of obtaining
the described results without destroying the
doctrine of the conservation and correlation of
forces.
. . . . .
"It is stated that `the internal resistance of
the armature' of this machine `is only 1/2
ohm.' On this fact and the disproportion
between this resistance and that of the external
circuit, the theory of the alleged efficiency of
the machine is stated to be based, for we are
informed that, `while this generator in general
principle is the same as in the best well-known
forms, still there is an all-important
difference, which is that it will convert and
deliver for useful work nearly double the number
of foot-pounds that any other machine will under
like conditions.' " The writer of this
critical letter then proceeds to quote Mr.
Upton's statement of this efficiency: "`Now
the energy converted is distributed over the
whole resistance, hence if the resistance of the
machine be represented by 1 and the exterior
circuit by 9, then of the total energy
converted nine-tenths will be useful, as it is
outside of the machine, and one-tenth is lost
in the resistance of the machine.'"
After this the critic goes on to say:
"How any one acquainted with the laws of the
electric circuit can make such statements is what
I cannot understand. The statement last quoted
is mathematically absurd. It implies either
that the machine is CAPABLE OF
INCREASING ITS OWN
ELECTROMOTIVE FORCE NINE
TIMES WITHOUT AN INCREASED
EXPENDITURE OF POWER, or that
external resistance is NOT resistance to the
current induced in the Edison machine.
"Does Mr. Edison, or any one for him, mean
to say that r/n enables him to obtain nE, and
that C IS NOT = E / (r/n + R)? If
so Mr. Edison has discovered something
MORE than perpetual motion, and Mr. Keely
had better retire from the field.
"Further on the writer (Mr. Upton) gives
us another example of this mode of reasoning
when, emboldened and satisfied with the absurd
theory above exposed, he endeavors to prove the
cause of the inefficiency of the Siemens and
other machines. Couldn't the writer of the
article see that since C = E/(r + R) that
by R/n or by making R = r, the machine
would, according to his theory, have returned
more useful current to the circuit than could be
due to the power employed (and in the ratio
indicated), so that there would actually be a
creation of force! . . . . . . .
"In conclusion allow me to say that if Mr
Edison thinks he has accomplished so much by the
REDUCTION OF THE INTERNAL
RESISTANCE of his machine, that he has
much more to do in this direction before his
machine will equal IN THIS RESPECT
others already in the market."
Another participant in the controversy on
Edison's generator was a scientific gentleman,
who in a long article published in the
Scientific American, in November, 1879,
gravely undertook to instruct Edison in the A
B C of electrical principles, and then
proceeded to demonstrate mathematically the
IMPOSSIBILITY of doing WHAT
EDISON HAD ACTUALLY DONE.
This critic concludes with a gentle rebuke to
the inventor for ill- timed jesting, and a
suggestion to furnish AUTHENTIC
information!
In the light of facts, as they were and are,
this article is so full of humor that we shall
indulge in a few quotations It commences in A
B C fashion as follows: "Electric machines
convert mechanical into electrical energy....
The ratio of yield to consumption is the
expression of the efficiency of the
machine.... How many foot-pounds of elec-
tricity can be got out of 100 foot-pounds of
mechanical energy? Certainly not more than
100: certainly less.... The facts and
laws of physics, with the assistance of
mathematical logic, never fail to furnish
precious answers to such questions."
The would-be critic then goes on to tabulate
tests of certain other dynamo machines by a
committee of the Franklin Institute in
1879, the results of which showed that these
machines returned about 50 per cent. of the
applied mechanical energy, ingenuously
remarking: "Why is it that when we have
produced the electricity, half of it must slip
away? Some persons will be content if they are
told simply that it is a way which electricity
has of behaving. But there is a satisfactory
rational explanation which I believe can be made
plain to persons of ordinary intelligence. It
ought to be known to all those who are making or
using machines. I am grieved to observe that
many persons who talk and write glibly about
electricity do not understand it; some even
ignore or deny the fact to be explained."
Here follows HIS explanation, after which he
goes on to say: "At this point plausibly comes
in a suggestion that the internal part of the
circuit be made very small and the external part
very large. Why not (say) make the internal
part 1 and the external 9, thus saving
nine-tenths and losing only one-tenth?
Unfortunately, the suggestion is not
practical; a fallacy is concealed in it."
He then goes on to prove his case
mathematically, to his own satisfaction,
following it sadly by condoling with and a
warning to Edison: "But about Edison's
electric generator! . . . No one capable of
making the improvements in the telegraph and
telephone, for which we are indebted to Mr.
Edison, could be other than an accomplished
electrician. His reputation as a scientist,
indeed, is smirched by the newspaper
exaggerations, and no doubt he will be more
careful in future. But there is a danger nearer
home, indeed, among his own friends and in his
very household.
". . . The writer of page 242" (the
original article) "is probably a friend of
Mr. Edison, but possibly, alas! a wicked
partner. Why does he say such things as these?
`Mr. Edison claims that he realizes 90 per
cent. of the power applied to this machine in
external work.' . . . Perhaps the writer is
a humorist, and had in his mind Colonel
Sellers, etc., which he could not keep out of
a serious discussion; but such jests are not
good.
"Mr. Edison has built a very interesting
machine, and he has the opportunity of making a
valuable contribution to the electrical arts by
furnishing authentic accounts of its
capabilities."
The foregoing extracts are unavoidably lengthy,
but, viewed in the light of facts, serve to
illustrate most clearly that Edison's
conceptions and work were far and away ahead of
the comprehension of his contemporaries in the
art, and that his achievements in the line of
efficient dynamo design and construction were
indeed truly fundamental and revolutionary in
character. Much more of similar nature to the
above could be quoted from other articles
published elsewhere, but the foregoing will
serve as instances generally representing all.
In the controversy which appeared in the columns
of the Scientific American, Mr. Upton,
Edison's mathematician, took up the question
on his side, and answered the critics by further
elucidations of the principles on which Edison
had founded such remarkable and radical
improvements in the art. The type of Edison's
first dynamo- electric machine, the description
of which gave rise to the above controversy, is
shown in Fig. 1.
Any account of Edison's work on the dynamo
would be incomplete did it omit to relate his
conception and construction of the great
direct-connected steam-driven generator that
was the prototype of the colossal units which are
used throughout the world to-day.
In the demonstrating plant installed and
operated by him at Menlo Park in 1880 ten
dynamos of eight horse-power each were driven by
a slow-speed engine through a complicated system
of counter-shafting, and, to quote from Mr.
Clarke's Historical Review, "it was found
that a considerable percentage of the power of
the engine was necessarily wasted in friction by
this method of driving, and to prevent this
waste and thus increase the economy of his
system, Mr. Edison conceived the idea of
substituting a single large dynamo for the
several small dynamos, and directly coupling it
with the driving engine, and at the same time
preserve the requisite high armature speed by
using an engine of the high- speed type. He
also expected to realize still further gains in
economy from the use of a large dynamo in place
of several small machines by a more than
correspondingly lower armature resistance, less
energy for magnetizing the field, and for other
minor reasons. To the same end, he intended to
supply steam to the engine under a much higher
boiler pressure than was customary in
stationary-engine driving at that time."
The construction of the first one of these large
machines was commenced late in the year
1880. Early in 1881 it was completed
and tested, but some radical defects in armature
construction were developed, and it was also
demonstrated that a rate of engine speed too high
for continuously safe and economical operation
had been chosen. The machine was laid aside.
An accurate illustration of this machine, as it
stood in the engine-room at Menlo Park, is
given in Van Nostrand's Engineering
Magazine, Vol. XXV, opposite page
439, and a brief description is given on page
450.
With the experience thus gained, Edison
began, in the spring of 1881, at the
Edison Machine Works, Goerck Street, New
York City, the construction of the first
successful machine of this type. This was the
great machine known as "Jumbo No. 1,"
which is referred to in the narrative as having
been exhibited at the Paris International
Electrical Exposition, where it was regarded
as the wonder of the electrical world. An
intimation of some of the tremendous difficulties
encountered in the construction of this machine
has already been given in preceding pages, hence
we shall not now enlarge on the subject, except
to note in passing that the terribly destructive
effects of the spark of self-induction and the
arcing following it were first manifested in this
powerful machine, but were finally overcome by
Edison after a strenuous application of his
powers to the solution of the problem.
It may be of interest, however, to mention
some of its dimensions and electrical
characteristics, quoting again from Mr.
Clarke: "The field-magnet had eight solid
cylindrical cores, 8 inches in diameter and
57 inches long, upon each of which was wound
an exciting-coil of 3.2 ohms resistance,
consisting of 2184 turns of No. 10 B.
W. G. insulated copper wire, disposed in six
layers. The laminated iron core of the
armature, formed of thin iron disks, was 33
3/4 inches long, and had an internal diameter
of 12 1/2 inches, and an external diameter
of 26 7/16 inches. It was mounted on a
6-inch shaft. The field-poles were 33
3/4 inches long, and 27 1/2 inches
inside diameter The armature winding consisted
of 146 copper bars on the face of the core,
connected into a closed-coil winding by means of
73 copper disks at each end of the core. The
cross-sectional area of each bar was 0.2
square inch their average length was 42.7
inches, and the copper end- disks were
0.065 inch thick. The commutator had 73
sec- tions. The armature resistance was
0.0092 ohm,[28] of which 0.0055
ohm was in the armature bars and 0.0037 ohm
in the end-disks." An illustration of the
next latest type of this machine is presented in
Fig. 2.
The student may find it interesting to look up
Edison's United States Patents Nos.
242,898, 263,133,
263,146, and 246,647, bearing
upon the construction of the "Jumbo"; also
illustrated articles in the technical journals of
the time, among which may be mentioned:
Scientific American, Vol. XLV, page
367; Engineering, London, Vol.
XXXII, pages 409 and 419, The
Telegraphic Journal and Electrical Review,
London, Vol. IX, pages 431-433,
436-446; La Nature, Paris, 9th
year, Part II, pages 408-409;
Zeitschrift fur Angewandte
Elektricitaatslehre, Munich and Leipsic,
Vol. IV, pages 4-14; and Dredge's
Electric Illumination, 1882, Vol. I,
page 261.
The further development of these great machines
later on, and their extensive practical use,
are well known and need no further comment,
except in passing it may be noted that subsequent
machines had each a capacity of 1200 lamps of
16 candle-power, and that the armature
resistance was still further reduced to
0.0039 ohm.
Edison's clear insight into the future, as
illustrated by his persistent advocacy of large
direct-connected generating units, is
abundantly vindicated by present-day practice.
His Jumbo machines, of 175 horse-power,
so enormous for their time, have served as
prototypes, and have been succeeded by
generators which have constantly grown in size
and capacity until at this time (1910) it
is not uncommon to employ such generating units
of a capacity of 14,000 kilowatts, or
about 18,666 horse-power.
We have not entered into specific descriptions
of the many other forms of dynamo machines
invented by Edison, such as the multipolar,
the disk dynamo, and the armature with two
windings, for sub-station distribution;
indeed, it is not possible within our limited
space to present even a brief digest of
Edison's great and comprehensive work on the
dynamo-electric machine, as embodied in his
extensive ex- periments and in over one hundred
patents granted to him. We have, therefore,
confined ourselves to the indication of a few
salient and basic features, leaving it to the
interested student to examine the patents and the
technical literature of the long period of time
over which Edison's labors were extended.
Although he has not given any attention to the
subject of generators for many years, an
interesting instance of his incisive method of
overcoming minor difficulties occurred while the
present volumes were under preparation
(1909). Carbon for commutator brushes has
been superseded by graphite in some cases, the
latter material being found much more
advantageous, electrically. Trouble
developed, however, for the reason that while
carbon was hard and would wear away the mica
insulation simultaneously with the copper,
graphite, being softer, would wear away only
the copper, leaving ridges of mica and thus
causing sparking through unequal contact. At
this point Edison was asked to diagnose the
trouble and provide a remedy. He suggested the
cutting out of the mica pieces almost to the
bottom, leaving the commutator bars separated by
air-spaces. This scheme was objected to on the
ground that particles of graphite would fill
these air-spaces and cause a short- circuit.
His answer was that the air-spaces constituted
the value of his plan, as the particles of
graphite falling into them would be thrown out by
the action of centrifugal force as the commutator
revolved. And thus it occurred as a matter of
fact, and the trouble was remedied. This idea
was subsequently adopted by a great manufacturer
of generators.
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