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<h2> CHAPTER XVII </h2>
<h3> OTHER EARLY STATIONS—THE METER </h3>
<p>WE have now seen the Edison lighting system given a complete, convincing
demonstration in Paris, London, and New York; and have noted steps taken
for its introduction elsewhere on both sides of the Atlantic. The Paris
plant, like that at the Crystal Palace, was a temporary exhibit. The
London plant was less temporary, but not permanent, supplying before it
was torn out no fewer than three thousand lamps in hotels, churches,
stores, and dwellings in the vicinity of Holborn Viaduct. There Messrs.
Johnson and Hammer put into practice many of the ideas now standard in the
art, and secured much useful data for the work in New York, of which the
story has just been told.</p>
<p>As a matter of fact the first Edison commercial station to be operated in
this country was that at Appleton, Wisconsin, but its only serious claim
to notice is that it was the initial one of the system driven by
water-power. It went into service August 15, 1882, about three weeks
before the Pearl Street station. It consisted of one small dynamo of a
capacity of two hundred and eighty lights of 10 c.p. each, and was housed
in an unpretentious wooden shed. The dynamo-electric machine, though
small, was robust, for under all the varying speeds of water-power, and
the vicissitudes of the plant to which it, belonged, it continued in
active use until 1899—seventeen years.</p>
<p>Edison was from the first deeply impressed with the possibilities of
water-power, and, as this incident shows, was prompt to seize such a very
early opportunity. But his attention was in reality concentrated closely
on the supply of great centres of population, a task which he then felt
might well occupy his lifetime; and except in regard to furnishing
isolated plants he did not pursue further the development of
hydro-electric stations. That was left to others, and to the application
of the alternating current, which has enabled engineers to harness remote
powers, and, within thoroughly economical limits, transmit thousands of
horse-power as much as two hundred miles at pressures of 80,000 and
100,000 volts. Owing to his insistence on low pressure, direct current for
use in densely populated districts, as the only safe and truly universal,
profitable way of delivering electrical energy to the consumers, Edison
has been frequently spoken of as an opponent of the alternating current.
This does him an injustice. At the time a measure was before the Virginia
legislature, in 1890, to limit the permissible pressures of current so as
to render it safe, he said: "You want to allow high pressure wherever the
conditions are such that by no possible accident could that pressure get
into the houses of the consumers; you want to give them all the latitude
you can." In explaining this he added: "Suppose you want to take the falls
down at Richmond, and want to put up a water-power? Why, if we erect a
station at the falls, it is a great economy to get it up to the city. By
digging a cheap trench and putting in an insulated cable, and connecting
such station with the central part of Richmond, having the end of the
cable come up into the station from the earth and there connected with
motors, the power of the falls would be transmitted to these motors. If
now the motors were made to run dynamos conveying low-pressure currents to
the public, there is no possible way whereby this high-pressure current
could get to the public." In other words, Edison made the sharp
fundamental distinction between high pressure alternating current for
transmission and low pressure direct current for distribution; and this is
exactly the practice that has been adopted in all the great cities of the
country to-day. There seems no good reason for believing that it will
change. It might perhaps have been altogether better for Edison, from the
financial standpoint, if he had not identified himself so completely with
one kind of current, but that made no difference to him, as it was a
matter of conviction; and Edison's convictions are granitic. Moreover,
this controversy over the two currents, alternating and direct, which has
become historical in the field of electricity—and is something like
the "irrepressible conflict" we heard of years ago in national affairs—illustrates
another aspect of Edison's character. Broad as the prairies and free in
thought as the winds that sweep them, he is idiosyncratically opposed to
loose and wasteful methods, to plans of empire that neglect the poor at
the gate. Everything he has done has been aimed at the conservation of
energy, the contraction of space, the intensification of culture. Burbank
and his tribe represent in the vegetable world, Edison in the mechanical.
Not only has he developed distinctly new species, but he has elucidated
the intensive art of getting $1200 out of an electrical acre instead of
$12—a manured market-garden inside London and a ten-bushel exhausted
wheat farm outside Lawrence, Kansas, being the antipodes of productivity—yet
very far short of exemplifying the difference of electrical yield between
an acre of territory in Edison's "first New York district" and an acre in
some small town.</p>
<p>Edison's lighting work furnished an excellent basis—in fact, the
only one—for the development of the alternating current now so
generally employed in central-station work in America; and in the McGraw
Electrical Directory of April, 1909, no fewer than 4164 stations out of
5780 reported its use. When the alternating current was introduced for
practical purposes it was not needed for arc lighting, the circuit for
which, from a single dynamo, would often be twenty or thirty miles in
length, its current having a pressure of not less than five or six
thousand volts. For some years it was not found feasible to operate motors
on alternating-current circuits, and that reason was often urged against
it seriously. It could not be used for electroplating or deposition, nor
could it charge storage batteries, all of which are easily within the
ability of the direct current. But when it came to be a question of
lighting a scattered suburb, a group of dwellings on the outskirts, a
remote country residence or a farm-house, the alternating current, in all
elements save its danger, was and is ideal. Its thin wires can be carried
cheaply over vast areas, and at each local point of consumption the
transformer of size exactly proportioned to its local task takes the
high-voltage transmission current and lowers its potential at a ratio of
20 or 40 to 1, for use in distribution and consumption circuits. This
evolution has been quite distinct, with its own inventors like Gaulard and
Gibbs and Stanley, but came subsequent to the work of supplying small,
dense areas of population; the art thus growing from within, and using
each new gain as a means for further achievement.</p>
<p>Nor was the effect of such great advances as those made by Edison limited
to the electrical field. Every department of mechanics was stimulated and
benefited to an extraordinary degree. Copper for the circuits was more
highly refined than ever before to secure the best conductivity, and
purity was insisted on in every kind of insulation. Edison was intolerant
of sham and shoddy, and nothing would satisfy him that could not stand
cross-examination by microscope, test-tube, and galvanometer. It was,
perhaps, the steam-engine on which the deepest imprint for good was made,
referred to already in the remarks of Mr. F. J. Sprague in the preceding
chapter, but best illustrated in the perfection of the modern high-speed
engine of the Armington & Sims type. Unless he could secure an engine
of smoother running and more exactly governed and regulated than those
available for his dynamo and lamp, Edison realized that he would find it
almost impossible to give a steady light. He did not want his customers to
count the heart-beats of the engine in the flicker of the lamp. Not a
single engine was even within gunshot of the standard thus set up, but the
emergency called forth its man in Gardiner C. Sims, a talented draughtsman
and designer who had been engaged in locomotive construction and in the
engineering department of the United States Navy. He may be quoted as to
what happened: "The deep interest, financial and moral, and friendly
backing I received from Mr. Edison, together with valuable suggestions,
enabled me to bring out the engine; as I was quite alone in the world—poor—I
had found a friend who knew what he wanted and explained it clearly. Mr.
Edison was a leader far ahead of the time. He compelled the design of the
successful engine.</p>
<p>"Our first engine compelled the inventing and making of a suitable engine
indicator to indicate it—the Tabor. He obtained the desired speed
and load with a friction brake; also regulator of speed; but waited for an
indicator to verify it. Then again there was no known way to lubricate an
engine for continuous running, and Mr. Edison informed me that as a marine
engine started before the ship left New York and continued running until
it reached its home port, so an engine for his purposes must produce light
at all times. That was a poser to me, for a five-hours' run was about all
that had been required up to that time.</p>
<p>"A day or two later Mr. Edison inquired: 'How far is it from here to
Lawrence; it is a long walk, isn't it?' 'Yes, rather.' He said: 'Of course
you will understand I meant without oil.' To say I was deeply perplexed
does not express my feelings. We were at the machine works, Goerck Street.
I started for the oil-room, when, about entering, I saw a small funnel
lying on the floor. It had been stepped on and flattened. I took it up,
and it had solved the engine-oiling problem—and my walk to Lawrence
like a tramp actor's was off! The eccentric strap had a round glass
oil-cup with a brass base that screwed into the strap. I took it off, and
making a sketch, went to Dave Cunningham, having the funnel in my hand to
illustrate what I wanted made. I requested him to make a sheet-brass
oil-cup and solder it to the base I had. He did so. I then had a standard
made to hold another oil-cup, so as to see and regulate the drop-feed. On
this combination I obtained a patent which is now universally used."</p>
<p>It is needless to say that in due course the engine builders of the United
States developed a variety of excellent prime movers for electric-light
and power plants, and were grateful to the art from which such a stimulus
came to their industry; but for many years one never saw an Edison
installation without expecting to find one or more Armington & Sims
high-speed engines part of it. Though the type has gone out of existence,
like so many other things that are useful in their day and generation, it
was once a very vital part of the art, and one more illustration of that
intimate manner in which the advances in different fields of progress
interact and co-operate.</p>
<p>Edison had installed his historic first great central-station system in
New York on the multiple arc system covered by his feeder and main
invention, which resulted in a notable saving in the cost of conductors as
against a straight two-wire system throughout of the "tree" kind. He soon
foresaw that still greater economy would be necessary for commercial
success not alone for the larger territory opening, but for the compact
districts of large cities. Being firmly convinced that there was a way
out, he pushed aside a mass of other work, and settled down to this
problem, with the result that on November 20, 1882, only two months after
current had been sent out from Pearl Street, he executed an application
for a patent covering what is now known as the "three-wire system." It has
been universally recognized as one of the most valuable inventions in the
history of the lighting art. [13] Its use resulted in a saving of over 60
per cent. of copper in conductors, figured on the most favorable basis
previously known, inclusive of those calculated under his own feeder and
main system. Such economy of outlay being effected in one of the heaviest
items of expense in central-station construction, it was now made possible
to establish plants in towns where the large investment would otherwise
have been quite prohibitive. The invention is in universal use today,
alike for direct and for alternating current, and as well in the equipment
of large buildings as in the distribution system of the most extensive
central-station networks. One cannot imagine the art without it.</p>
<p>[Footnote 13: For technical description and illustration of<br/>
this invention, see Appendix.]<br/></p>
<p>The strong position held by the Edison system, under the strenuous
competition that was already springing up, was enormously improved by the
introduction of the three-wire system; and it gave an immediate impetus to
incandescent lighting. Desiring to put this new system into practical use
promptly, and receiving applications for licenses from all over the
country, Edison selected Brockton, Massachusetts, and Sunbury,
Pennsylvania, as the two towns for the trial. Of these two Brockton
required the larger plant, but with the conductors placed underground. It
was the first to complete its arrangements and close its contract. Mr.
Henry Villard, it will be remembered, had married the daughter of
Garrison, the famous abolitionist, and it was through his relationship
with the Garrison family that Brockton came to have the honor of
exemplifying so soon the principles of an entirely new art. Sunbury,
however, was a much smaller installation, employed overhead conductors,
and hence was the first to "cross the tape." It was specially suited for a
trial plant also, in the early days when a yield of six or eight lamps to
the horse-power was considered subject for congratulation. The town being
situated in the coal region of Pennsylvania, good coal could then be
obtained there at seventy-five cents a ton.</p>
<p>The Sunbury generating plant consisted of an Armington & Sims engine
driving two small Edison dynamos having a total capacity of about four
hundred lamps of 16 c.p. The indicating instruments were of the crudest
construction, consisting of two voltmeters connected by "pressure wires"
to the centre of electrical distribution. One ammeter, for measuring the
quantity of current output, was interpolated in the "neutral bus" or
third-wire return circuit to indicate when the load on the two machines
was out of balance. The circuits were opened and closed by means of about
half a dozen roughly made plug-switches. [14] The "bus-bars" to receive
the current from the dynamos were made of No. 000 copper line wire,
straightened out and fastened to the wooden sheathing of the station by
iron staples without any presence to insulation. Commenting upon this Mr.
W. S. Andrews, detailed from the central staff, says: "The interior
winding of the Sunbury station, including the running of two three-wire
feeders the entire length of the building from back to front, the wiring
up of the dynamos and switchboard and all instruments, together with
bus-bars, etc.—in fact, all labor and material used in the
electrical wiring installation—amounted to the sum of $90. I
received a rather sharp letter from the New York office expostulating for
this EXTRAVAGANT EXPENDITURE, and stating that great economy must be
observed in future!" The street conductors were of the overhead pole-line
construction, and were installed by the construction company that had been
organized by Edison to build and equip central stations. A special type of
street pole had been devised by him for the three-wire system.</p>
<p>[Footnote 14: By reason of the experience gained at this<br/>
station through the use of these crude plug-switches, Mr.<br/>
Edison started a competition among a few of his assistants<br/>
to devise something better. The result was the invention of<br/>
a "breakdown" switch by Mr. W. S. Andrews, which was<br/>
accepted by Mr. Edison as the best of the devices suggested,<br/>
and was developed and used for a great many years<br/>
afterward.]<br/></p>
<p>Supplementing the story of Mr. Andrews is that of Lieut. F. J. Sprague,
who also gives a curious glimpse of the glorious uncertainties and
vicissitudes of that formative period. Mr. Sprague served on the jury at
the Crystal Palace Exhibition with Darwin's son—the present Sir
Horace—and after the tests were ended left the Navy and entered
Edison's service at the suggestion of Mr. E. H. Johnson, who was Edison's
shrewd recruiting sergeant in those days: "I resigned sooner than Johnson
expected, and he had me on his hands. Meanwhile he had called upon me to
make a report of the three-wire system, known in England as the Hopkinson,
both Dr. John Hopkinson and Mr. Edison being independent inventors at
practically the same time. I reported on that, left London, and landed in
New York on the day of the opening of the Brooklyn Bridge in 1883—May
24—with a year's leave of absence.</p>
<p>"I reported at the office of Mr. Edison on Fifth Avenue and told him I had
seen Johnson. He looked me over and said: 'What did he promise you?' I
replied: 'Twenty-five hundred dollars a year.' He did not say much, but
looked it. About that time Mr. Andrews and I came together. On July 2d of
that year we were ordered to Sunbury, and to be ready to start the station
on the fourth. The electrical work had to be done in forty-eight hours!
Having travelled around the world, I had cultivated an indifference to any
special difficulties of that kind. Mr. Andrews and I worked in
collaboration until the night of the third. I think he was perhaps more
appreciative than I was of the discipline of the Edison Construction
Department, and thought it would be well for us to wait until the morning
of the fourth before we started up. I said we were sent over to get going,
and insisted on starting up on the night of the third. We had an Armington
& Sims engine with sight-feed oiler. I had never seen one, and did not
know how it worked, with the result that we soon burned up the babbitt
metal in the bearings and spent a good part of the night getting them in
order. The next day Mr. Edison, Mr. Insull, and the chief engineer of the
construction department appeared on the scene and wanted to know what had
happened. They found an engine somewhat loose in the bearings, and there
followed remarks which would not look well in print. Andrews skipped from
under; he obeyed orders; I did not. But the plant ran, and it was the
first three-wire station in this country."</p>
<p>Seen from yet another angle, the worries of this early work were not
merely those of the men on the "firing line." Mr. Insull, in speaking of
this period, says: "When it was found difficult to push the
central-station business owing to the lack of confidence in its financial
success, Edison decided to go into the business of promoting and
constructing central-station plants, and he formed what was known as the
Thomas A. Edison Construction Department, which he put me in charge of.
The organization was crude, the steam-engineering talent poor, and owing
to the impossibility of getting any considerable capital subscribed, the
plants were put in as cheaply as possible. I believe that this
construction department was unkindly named the 'Destruction Department.'
It served its purpose; never made any money; and I had the unpleasant task
of presiding at its obsequies."</p>
<p>On July 4th the Sunbury plant was put into commercial operation by Edison,
and he remained a week studying its conditions and watching for any
unforeseen difficulty that might arise. Nothing happened, however, to
interfere with the successful running of the station, and for twenty years
thereafter the same two dynamos continued to furnish light in Sunbury.
They were later used as reserve machines, and finally, with the engine,
retired from service as part of the "Collection of Edisonia"; but they
remain in practically as good condition as when installed in 1883.</p>
<p>Sunbury was also provided with the first electro-chemical meters used in
the United States outside New York City, so that it served also to
accentuate electrical practice in a most vital respect—namely, the
measurement of the electrical energy supplied to customers. At this time
and long after, all arc lighting was done on a "flat rate" basis. The arc
lamp installed outside a customer's premises, or in a circuit for public
street lighting, burned so many hours nightly, so many nights in the
month; and was paid for at that rate, subject to rebate for hours when the
lamp might be out through accident. The early arc lamps were rated to
require 9 to 10 amperes of current, at 45 volts pressure each, receiving
which they were estimated to give 2000 c.p., which was arrived at by
adding together the light found at four different positions, so that in
reality the actual light was about 500 c.p. Few of these data were ever
actually used, however; and it was all more or less a matter of guesswork,
although the central-station manager, aiming to give good service, would
naturally see that the dynamos were so operated as to maintain as steadily
as possible the normal potential and current. The same loose methods
applied to the early attempts to use electric motors on arc-lighting
circuits, and contracts were made based on the size of the motor, the
width of the connecting belt, or the amount of power the customer thought
he used—never on the measurement of the electrical energy furnished
him.</p>
<p>Here again Edison laid the foundation of standard practice. It is true
that even down to the present time the flat rate is applied to a great
deal of incandescent lighting, each lamp being charged for individually
according to its probable consumption during each month. This may answer,
perhaps, in a small place where the manager can gauge pretty closely from
actual observation what each customer does; but even then there are
elements of risk and waste; and obviously in a large city such a method
would soon be likely to result in financial disaster to the plant. Edison
held that the electricity sold must be measured just like gas or water,
and he proceeded to develop a meter. There was infinite scepticism around
him on the subject, and while other inventors were also giving the subject
their thought, the public took it for granted that anything so utterly
intangible as electricity, that could not be seen or weighed, and only
gave secondary evidence of itself at the exact point of use, could not be
brought to accurate registration. The general attitude of doubt was
exemplified by the incident in Mr. J. P. Morgan's office, noted in the
last chapter. Edison, however, had satisfied himself that there were
various ways of accomplishing the task, and had determined that the
current should be measured on the premises of every consumer. His
electrolytic meter was very successful, and was of widespread use in
America and in Europe until the perfection of mechanical meters by Elihu
Thomson and others brought that type into general acceptance. Hence the
Edison electrolytic meter is no longer used, despite its excellent
qualities. Houston & Kennelly in their Electricity in Everyday Life
sum the matter up as follows: "The Edison chemical meter is capable of
giving fair measurements of the amount of current passing. By reason,
however, of dissatisfaction caused from the inability of customers to read
the indications of the meter, it has in later years, to a great extent,
been replaced by registering meters that can be read by the customer."</p>
<p>The principle employed in the Edison electrolytic meter is that which
exemplifies the power of electricity to decompose a chemical substance. In
other words it is a deposition bath, consisting of a glass cell in which
two plates of chemically pure zinc are dipped in a solution of zinc
sulphate. When the lights or motors in the circuit are turned on, and a
certain definite small portion of the current is diverted to flow through
the meter, from the positive plate to the negative plate, the latter
increases in weight by receiving a deposit of metallic zinc; the positive
plate meantime losing in weight by the metal thus carried away from it.
This difference in weight is a very exact measure of the quantity of
electricity, or number of ampere-hours, that have, so to speak, passed
through the cell, and hence of the whole consumption in the circuit. The
amount thus due from the customer is ascertained by removing the cell,
washing and drying the plates, and weighing them in a chemical balance.
Associated with this simple form of apparatus were various ingenious
details and refinements to secure regularity of operation, freedom from
inaccuracy, and immunity from such tampering as would permit theft of
current or damage. As the freezing of the zinc sulphate solution in cold
weather would check its operation, Edison introduced, for example, into
the meter an incandescent lamp and a thermostat so arranged that when the
temperature fell to a certain point, or rose above another point, it was
cut in or out; and in this manner the meter could be kept from freezing.
The standard Edison meter practice was to remove the cells once a month to
the meter-room of the central-station company for examination, another set
being substituted. The meter was cheap to manufacture and install, and not
at all liable to get out of order.</p>
<p>In December, 1888, Mr. W. J. Jenks read an interesting paper before the
American Institute of Electrical Engineers on the six years of practical
experience had up to that time with the meter, then more generally in use
than any other. It appears from the paper that twenty-three Edison
stations were then equipped with 5187 meters, which were relied upon for
billing the monthly current consumption of 87,856 lamps and 350 motors of
1000 horse-power total. This represented about 75 per cent. of the entire
lamp capacity of the stations. There was an average cost per lamp for
meter operation of twenty-two cents a year, and each meter took care of an
average of seventeen lamps. It is worthy of note, as to the promptness
with which the Edison stations became paying properties, that four of the
metered stations were earning upward of 15 per cent. on their capital
stock; three others between 8 and 10 per cent.; eight between 5 and 8 per
cent.; the others having been in operation too short a time to show
definite results, although they also went quickly to a dividend basis.
Reports made in the discussion at the meeting by engineers showed the
simplicity and success of the meter. Mr. C. L. Edgar, of the Boston Edison
system, stated that he had 800 of the meters in service cared for by two
men and three boys, the latter employed in collecting the meter cells; the
total cost being perhaps $2500 a year. Mr. J. W. Lieb wrote from Milan,
Italy, that he had in use on the Edison system there 360 meters ranging
from 350 ampere-hours per month up to 30,000.</p>
<p>In this connection it should be mentioned that the Association of Edison
Illuminating Companies in the same year adopted resolutions unanimously to
the effect that the Edison meter was accurate, and that its use was not
expensive for stations above one thousand lights; and that the best
financial results were invariably secured in a station selling current by
meter. Before the same association, at its meeting in September, 1898, at
Sault Ste. Marie, Mr. C. S. Shepard read a paper on the meter practice of
the New York Edison Company, giving data as to the large number of Edison
meters in use and the transition to other types, of which to-day the
company has several on its circuits: "Until October, 1896, the New York
Edison Company metered its current in consumer's premises exclusively by
the old-style chemical meters, of which there were connected on that date
8109. It was then determined to purchase no more." Mr. Shepard went on to
state that the chemical meters were gradually displaced, and that on
September 1, 1898, there were on the system 5619 mechanical and 4874
chemical. The meter continued in general service during 1899, and probably
up to the close of the century.</p>
<p>Mr. Andrews relates a rather humorous meter story of those early days:
"The meter man at Sunbury was a firm and enthusiastic believer in the
correctness of the Edison meter, having personally verified its reading
many times by actual comparison of lamp-hours. One day, on making out a
customer's bill, his confidence received a severe shock, for the meter
reading showed a consumption calling for a charge of over $200, whereas he
knew that the light actually used should not cost more than one-quarter of
that amount. He weighed and reweighed the meter plates, and pursued every
line of investigation imaginable, but all in vain. He felt he was up
against it, and that perhaps another kind of a job would suit him better.
Once again he went to the customer's meter to look around, when a small
piece of thick wire on the floor caught his eye. The problem was solved.
He suddenly remembered that after weighing the plates he went and put them
in the customer's meter; but the wire attached to one of the plates was
too long to go in the meter, and he had cut it off. He picked up the piece
of wire, took it to the station, weighed it carefully, and found that it
accounted for about $150 worth of electricity, which was the amount of the
difference."</p>
<p>Edison himself is, however, the best repertory of stories when it comes to
the difficulties of that early period, in connection with metering the
current and charging for it. He may be quoted at length as follows: "When
we started the station at Pearl Street, in September, 1882, we were not
very commercial. We put many customers on, but did not make out many
bills. We were more interested in the technical condition of the station
than in the commercial part. We had meters in which there were two bottles
of liquid. To prevent these electrolytes from freezing we had in each
meter a strip of metal. When it got very cold the metal would contract and
close a circuit, and throw a lamp into circuit inside the meter. The heat
from this lamp would prevent the liquid from freezing, so that the meter
could go on doing its duty. The first cold day after starting the station,
people began to come in from their offices, especially down in Front
Street and Water Street, saying the meter was on fire. We received
numerous telephone messages about it. Some had poured water on it, and
others said: 'Send a man right up to put it out.'</p>
<p>"After the station had been running several months and was technically a
success, we began to look after the financial part. We started to collect
some bills; but we found that our books were kept badly, and that the
person in charge, who was no business man, had neglected that part of it.
In fact, he did not know anything about the station, anyway. So I got the
directors to permit me to hire a man to run the station. This was Mr.
Chinnock, who was then superintendent of the Metropolitan Telephone
Company of New York. I knew Chinnock to be square and of good business
ability, and induced him to leave his job. I made him a personal
guarantee, that if he would take hold of the station and put it on a
commercial basis, and pay 5 per cent. on $600,000, I would give him
$10,000 out of my own pocket. He took hold, performed the feat, and I paid
him the $10,000. I might remark in this connection that years afterward I
applied to the Edison Electric Light Company asking them if they would not
like to pay me this money, as it was spent when I was very hard up and
made the company a success, and was the foundation of their present
prosperity. They said they 'were sorry'—that is, 'Wall Street sorry'—and
refused to pay it. This shows what a nice, genial, generous lot of people
they have over in Wall Street.</p>
<p>"Chinnock had a great deal of trouble getting the customers straightened
out. I remember one man who had a saloon on Nassau Street. He had had his
lights burning for two or three months. It was in June, and Chinnock put
in a bill for $20; July for $20; August about $28; September about $35. Of
course the nights were getting longer. October about $40; November about
$45. Then the man called Chinnock up. He said: 'I want to see you about my
electric-light bill.' Chinnock went up to see him. He said: 'Are you the
manager of this electric-light plant?' Chinnock said: 'I have the honor.'
'Well,' he said, my bill has gone from $20 up to $28, $35, $45. I want you
to understand, young fellow, that my limit is $60.'</p>
<p>"After Chinnock had had all this trouble due to the incompetency of the
previous superintendent, a man came in and said to him: 'Did Mr. Blank
have charge of this station?' 'Yes.' 'Did he know anything about running a
station like this?' Chinnock said: 'Does he KNOW anything about running a
station like this? No, sir. He doesn't even suspect anything.'</p>
<p>"One day Chinnock came to me and said: 'I have a new customer.' I said:
'What is it?' He said: 'I have a fellow who is going to take two hundred
and fifty lights.' I said: 'What for?' 'He has a place down here in a top
loft, and has got two hundred and fifty barrels of "rotgut" whiskey. He
puts a light down in the barrel and lights it up, and it ages the
whiskey.' I met Chinnock several weeks after, and said: 'How is the
whiskey man getting along?' 'It's all right; he is paying his bill. It
fixes the whiskey and takes the shudder right out of it.' Somebody went
and took out a patent on this idea later.</p>
<p>"In the second year we put the Stock Exchange on the circuits of the
station, but were very fearful that there would be a combination of heavy
demand and a dark day, and that there would be an overloaded station. We
had an index like a steam-gauge, called an ampere-meter, to indicate the
amount of current going out. I was up at 65 Fifth Avenue one afternoon. A
sudden black cloud came up, and I telephoned to Chinnock and asked him
about the load. He said: 'We are up to the muzzle, and everything is
running all right.' By-and-by it became so thick we could not see across
the street. I telephoned again, and felt something would happen, but
fortunately it did not. I said to Chinnock: 'How is it now?' He replied:
'Everything is red-hot, and the ampere-meter has made seventeen
revolutions.'"</p>
<p>In 1883 no such fittings as "fixture insulators" were known. It was the
common practice to twine the electric wires around the disused
gas-fixtures, fasten them with tape or string, and connect them to
lamp-sockets screwed into attachments under the gas-burners—elaborated
later into what was known as the "combination fixture." As a result it was
no uncommon thing to see bright sparks snapping between the chandelier and
the lighting wires during a sharp thunder-storm. A startling manifestation
of this kind happened at Sunbury, when the vivid display drove nervous
guests of the hotel out into the street, and the providential storm led
Mr. Luther Stieringer to invent the "insulating joint." This separated the
two lighting systems thoroughly, went into immediate service, and is
universally used to-day.</p>
<p>Returning to the more specific subject of pioneer plants of importance,
that at Brockton must be considered for a moment, chiefly for the reason
that the city was the first in the world to possess an Edison station
distributing current through an underground three-wire network of
conductors—the essentially modern contemporaneous practice, standard
twenty-five years later. It was proposed to employ pole-line construction
with overhead wires, and a party of Edison engineers drove about the town
in an open barouche with a blue-print of the circuits and streets spread
out on their knees, to determine how much tree-trimming would be
necessary. When they came to some heavily shaded spots, the fine trees
were marked "T" to indicate that the work in getting through them would be
"tough." Where the trees were sparse and the foliage was thin, the same
cheerful band of vandals marked the spots "E" to indicate that there it
would be "easy" to run the wires. In those days public opinion was not so
alive as now to the desirability of preserving shade-trees, and of
enhancing the beauty of a city instead of destroying it. Brockton had a
good deal of pride in its fine trees, and a strong sentiment was very soon
aroused against the mutilation proposed so thoughtlessly. The investors in
the enterprise were ready and anxious to meet the extra cost of putting
the wires underground. Edison's own wishes were altogether for the use of
the methods he had so carefully devised; and hence that bustling home of
shoe manufacture was spared this infliction of more overhead wires.</p>
<p>The station equipment at Brockton consisted at first of three dynamos, one
of which was so arranged as to supply both sides of the system during
light loads by a breakdown switch connection. This arrangement interfered
with correct meter registration, as the meters on one side of the system
registered backward during the hours in which the combination was
employed. Hence, after supplying an all-night customer whose lamps were on
one side of the circuits, the company might be found to owe him some thing
substantial in the morning. Soon after the station went into operation
this ingenious plan was changed, and the third dynamo was replaced by two
others. The Edison construction department took entire charge of the
installation of the plant, and the formal opening was attended on October
1, 1883, by Mr. Edison, who then remained a week in ceaseless study and
consultation over the conditions developed by this initial three-wire
underground plant. Some idea of the confidence inspired by the fame of
Edison at this period is shown by the fact that the first theatre ever
lighted from a central station by incandescent lamps was designed this
year, and opened in 1884 at Brockton with an equipment of three hundred
lamps. The theatre was never piped for gas! It was also from the Brockton
central station that current was first supplied to a fire-engine house—another
display of remarkably early belief in the trustworthiness of the service,
under conditions where continuity of lighting was vital. The building was
equipped in such a manner that the striking of the fire-alarm would light
every lamp in the house automatically and liberate the horses. It was at
this central station that Lieutenant Sprague began his historic work on
the electric motor; and here that another distinguished engineer and
inventor, Mr. H. Ward Leonard, installed the meters and became meter man,
in order that he might study in every intimate detail the improvements and
refinements necessary in that branch of the industry.</p>
<p>The authors are indebted for these facts and some other data embodied in
this book to Mr. W. J. Jenks, who as manager of this plant here made his
debut in the Edison ranks. He had been connected with local telephone
interests, but resigned to take active charge of this plant, imbibing
quickly the traditional Edison spirit, working hard all day and sleeping
in the station at night on a cot brought there for that purpose. It was a
time of uninterrupted watchfulness. The difficulty of obtaining engineers
in those days to run the high-speed engines (three hundred and fifty
revolutions per minute) is well illustrated by an amusing incident in the
very early history of the station. A locomotive engineer had been engaged,
as it was supposed he would not be afraid of anything. One evening there
came a sudden flash of fire and a spluttering, sizzling noise. There had
been a short-circuit on the copper mains in the station. The fireman hid
behind the boiler and the engineer jumped out of the window. Mr. Sprague
realized the trouble, quickly threw off the current and stopped the
engine.</p>
<p>Mr. Jenks relates another humorous incident in connection with this plant:
"One night I heard a knock at the office door, and on opening it saw two
well-dressed ladies, who asked if they might be shown through. I invited
them in, taking them first to the boiler-room, where I showed them the
coal-pile, explaining that this was used to generate steam in the boiler.
We then went to the dynamo-room, where I pointed out the machines
converting the steam-power into electricity, appearing later in the form
of light in the lamps. After that they were shown the meters by which the
consumption of current was measured. They appeared to be interested, and I
proceeded to enter upon a comparison of coal made into gas or burned under
a boiler to be converted into electricity. The ladies thanked me
effusively and brought their visit to a close. As they were about to go
through the door, one of them turned to me and said: 'We have enjoyed this
visit very much, but there is one question we would like to ask: What is
it that you make here?'"</p>
<p>The Brockton station was for a long time a show plant of the Edison
company, and had many distinguished visitors, among them being Prof. Elihu
Thomson, who was present at the opening, and Sir W. H. Preece, of London.
The engineering methods pursued formed the basis of similar installations
in Lawrence, Massachusetts, in November, 1883; in Fall River,
Massachusetts, in December, 1883; and in Newburgh, New York, the following
spring.</p>
<p>Another important plant of this period deserves special mention, as it was
the pioneer in the lighting of large spaces by incandescent lamps. This
installation of five thousand lamps on the three-wire system was made to
illuminate the buildings at the Louisville, Kentucky, Exposition in 1883,
and, owing to the careful surveys, calculations, and preparations of H. M.
Byllesby and the late Luther Stieringer, was completed and in operation
within six weeks after the placing of the order. The Jury of Awards, in
presenting four medals to the Edison company, took occasion to pay a high
compliment to the efficiency of the system. It has been thought by many
that the magnificent success of this plant did more to stimulate the
growth of the incandescent lighting business than any other event in the
history of the Edison company. It was literally the beginning of the
electrical illumination of American Expositions, carried later to such
splendid displays as those of the Chicago World's Fair in 1893, Buffalo in
1901, and St. Louis in 1904.</p>
<p>Thus the art was set going in the United States under many difficulties,
but with every sign of coming triumph. Reference has already been made to
the work abroad in Paris and London. The first permanent Edison station in
Europe was that at Milan, Italy, for which the order was given as early as
May, 1882, by an enterprising syndicate. Less than a year later, March 3,
1883, the installation was ready and was put in operation, the Theatre
Santa Radegonda having been pulled down and a new central-station building
erected in its place—probably the first edifice constructed in
Europe for the specific purpose of incandescent lighting. Here "Jumbos"
were installed from time to time, until at last there were no fewer than
ten of them; and current was furnished to customers with a total of nearly
ten thousand lamps connected to the mains. This pioneer system was
operated continuously until February 9, 1900, or for a period of about
seventeen years, when the sturdy old machines, still in excellent
condition, were put out of service, so that a larger plant could be
installed to meet the demand. This new plant takes high-tension polyphase
current from a water-power thirty or forty miles away at Paderno, on the
river Adda, flowing from the Apennines; but delivers low-tension direct
current for distribution to the regular Edison three-wire system
throughout Milan.</p>
<p>About the same time that southern Europe was thus opened up to the new
system, South America came into line, and the first Edison central station
there was installed at Santiago, Chile, in the summer of 1883, under the
supervision of Mr. W. N. Stewart. This was the result of the success
obtained with small isolated plants, leading to the formation of an Edison
company. It can readily be conceived that at such an extreme distance from
the source of supply of apparatus the plant was subject to many peculiar
difficulties from the outset, of which Mr. Stewart speaks as follows: "I
made an exhibition of the 'Jumbo' in the theatre at Santiago, and on the
first evening, when it was filled with the aristocracy of the city, I
discovered to my horror that the binding wire around the armature was
slowly stripping off and going to pieces. We had no means of boring out
the field magnets, and we cut grooves in them. I think the machine is
still running (1907). The station went into operation soon after with an
equipment of eight Edison 'K' dynamos with certain conditions inimical to
efficiency, but which have not hindered the splendid expansion of the
local system. With those eight dynamos we had four belts between each
engine and the dynamo. The steam pressure was limited to seventy-five
pounds per square inch. We had two-wire underground feeders, sent without
any plans or specifications for their installation. The station had
neither voltmeter nor ammeter. The current pressure was regulated by a
galvanometer. We were using coal costing $12 a ton, and were paid for our
light in currency worth fifty cents on the dollar. The only thing I can be
proud of in connection with the plant is the fact that I did not design
it, that once in a while we made out to pay its operating expenses, and
that occasionally we could run it for three months without a total
breakdown."</p>
<p>It was not until 1885 that the first Edison station in Germany was
established; but the art was still very young, and the plant represented
pioneer lighting practice in the Empire. The station at Berlin comprised
five boilers, and six vertical steam-engines driving by belts twelve
Edison dynamos, each of about fifty-five horse-power capacity. A model of
this station is preserved in the Deutschen Museum at Munich. In the
bulletin of the Berlin Electricity Works for May, 1908, it is said with
regard to the events that led up to the creation of the system, as noted
already at the Rathenau celebration: "The year 1881 was a mile-stone in
the history of the Allgemeine Elektricitaets Gesellschaft. The
International Electrical Exposition at Paris was intended to place before
the eyes of the civilized world the achievements of the century. Among the
exhibits of that Exposition was the Edison system of incandescent
lighting. IT BECAME THE BASIS OF MODERN HEAVY CURRENT TECHNICS." The last
phrase is italicized as being a happy and authoritative description, as
well as a tribute.</p>
<p>This chapter would not be complete if it failed to include some reference
to a few of the earlier isolated plants of a historic character. Note has
already been made of the first Edison plants afloat on the Jeannette and
Columbia, and the first commercial plant in the New York lithographic
establishment. The first mill plant was placed in the woollen factory of
James Harrison at Newburgh, New York, about September 15, 1881. A year
later, Mr. Harrison wrote with some pride: "I believe my mill was the
first lighted with your electric light, and therefore may be called No. 1.
Besides being job No. 1 it is a No. 1 job, and a No. 1 light, being better
and cheaper than gas and absolutely safe as to fire." The first
steam-yacht lighted by incandescent lamps was James Gordon Bennett's
Namouna, equipped early in 1882 with a plant for one hundred and twenty
lamps of eight candlepower, which remained in use there many years
afterward.</p>
<p>The first Edison plant in a hotel was started in October, 1881, at the
Blue Mountain House in the Adirondacks, and consisted of two "Z" dynamos
with a complement of eight and sixteen candle lamps. The hotel is situated
at an elevation of thirty-five hundred feet above the sea, and was at that
time forty miles from the railroad. The machinery was taken up in pieces
on the backs of mules from the foot of the mountain. The boilers were
fired by wood, as the economical transportation of coal was a physical
impossibility. For a six-hour run of the plant one-quarter of a cord of
wood was required, at a cost of twenty-five cents per cord.</p>
<p>The first theatre in the United States to be lighted by an Edison isolated
plant was the Bijou Theatre, Boston. The installation of boilers, engines,
dynamos, wiring, switches, fixtures, three stage regulators, and six
hundred and fifty lamps, was completed in eleven days after receipt of the
order, and the plant was successfully operated at the opening of the
theatre, on December 12, 1882.</p>
<p>The first plant to be placed on a United States steamship was the one
consisting of an Edison "Z" dynamo and one hundred and twenty eight-candle
lamps installed on the Fish Commission's steamer Albatross in 1883. The
most interesting feature of this installation was the employment of
special deep-sea lamps, supplied with current through a cable nine hundred
and forty feet in length, for the purpose of alluring fish. By means of
the brilliancy of the lamps marine animals in the lower depths were
attracted and then easily ensnared.</p>
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