To obtain a clear idea of the Gary Magnetic Motor, it is necessary firstto comprehend thoroughly the principle underlying it -- the existence ofthe neutral line and the change in polarity,which Mr. Gary demonstratesby his horseshoe magnet, his bit of soft iron, and his common shingle-nail.
This is illustrated in Figure 1. 
By pressing the finger on the lever at D the iron is raised above theneutral line. Now let the nail be applied to the end of the induced magnetat E; it clings to it, and the point is turned inward toward the pole ofthe magnet directly below, thus indicating that the induced magnet is ofopposite polarity from the permanent one.
Now let the iron be g
r
adually lowered toward the magnet; the nail dropsoff at the neutral line, but it clings again when the iron is lowered belowthe line, and now its point is turned outward, or away from the magneticpole below.
In this way Mr. Gary proves that the polarity of an induced magnet ischanged by passing over the neutral line without coming in contact. Inthe experiment strips of paper are placed under the soft iron, or inducedmagnet, as shown in the figure, to prevent contact.
The neutral line is shown to extend completely around the magnet; anda piece of soft iron placed upon this line will entirely cut off the attractionof the magnet from any thing beyond. The action of this cutoff is illustratedin Fig. 2. 
The letters A and B represent the one a balanced magnet and the othera stationary magnet. The magnet A is balanced on a joint, and the two magnetsare placed with opposite poles facing each other.
The letter C is a piece of thin or sheet iron, as the case may be, madefast to a lever with a joint in the centre, and so adjusted that the ironwill move on the neutral line in front of the poles of the stationary magnet.
By pressing the finger on the lever at D the iron is raised, thus withdrawingthe cut-off so that the magnet A is attracted and drawn upward by the magnetB. Remove the finger, and the cut-off drops between the poles, and, inconsequence, the magnet A drops again.
The same movement of magnets can be obtained by placing a piece of ironacross the poles of the magnet B after the magnet A has been drawn nearto it.
The magnet A will thereupon immediately fall away; but the iron canonly be balanced, and the balance not disturbed, by the action of the magnetsupon each other when the iron is on the neutral line, and does not movenearer or farther away from the magnet B.
It may not be found easy to demonstrate these principles at the firsttrials. But it should be borne in mind that it took the inventor himselffour years after he had discovered the principle to adjust the delicatebalance so as to get a machine which would go.
Now, however, that he has thought out the entire problem, and franklytells the world how he has solved it, any person at all skillful and patient,and with a little knowledge of mechanics, may soon succeed in demonstratingit for himself.
The principle underlying the motor and the method by which a motionis obtained now being explained, let us examine the inventor's workingmodels.
The beam movement is the simplest, and by it, it is claimed, the mostpower can be obtained from the magnets. This is illustrated in Fig. 3.
The letter A represents a stationarymagnet, and B the soft iron, or induced magnet, fastened to a lever witha joint in the centre, and so balanced that the stationary magnet willnot quite draw it over the neutral line.
The letter C represents a beam constructed of double magnet, clampedtogether in the centre and balanced on a joint. One end is set oppositethe stationary magnet, with like poles facing each other.
The beam is so balanced that when the soft iron B on the magnet A isbelow the neutral line, it (the beam) is repelled down to the lower dottedline indicated by the letter D. The beam strikes the lever E with the pinF attached, and drives it (the Lever) against the pin G, which is attachedto the soft iron B, which is thus driven above the neutral line, whereits polarity changes.
The soft iron now attracts the beam magnet C to the upper dotted line,whereupon it (the soft iron) is again drawn down over the neutral line,and its polarity again changing, the beam magnet C is again repelled tothe lower line, continuing so to move until it is stopped or worn out.
This simply illustrates the beam movement. To gain a large amount ofpower the inventor would place groups of compound stationary magnets aboveand below the beam at each side, and the soft iron induced magnets, inthis case four in number, connected by rods passing down between the polesof the stationary magnets.
A "Pittman" connecting the beam with a fly-wheel to changethe reciprocating into a rotary motion would be the means of transmittingthe power. With magnets of great size an enormous power, he claims, couldbe obtained in this way.
One of the daintiest and prettiest of Mr. Gary's models is that illustratingthe action of a rotary motor. There is a peculiar fascination in watchingthe action of this neat little contrivance. 
It is shown in Fig. 4. The letter A represents an upright magnet hungon a perpendicular shaft; B, the horizontal magnets; C, the soft iron whichis fastened to the lever D; E, the pivoted joint on which lever is balanced;and F, the thumb-screw for adjusting the movement of the soft iron.
This soft iron is so balanced that as the north pole of the uprightmagnet A swings around opposite and above the south pole of the horizontalmagnets B, it drops below the neutral line and changes its polarity.
As the magnet A turns around until its north pole is opposite and abovethe north pole of the magnets B, the soft iron is drawn upward and overthe neutral line, so that its polarity is changed again. At this pointthe polarity in the soft iron C is like that of the permanent magnets Aand B.
To start the engine the magnet A is turned around to the last-namedposition, the poles opposite like poles of the magnets B; then one poleof the magnet A is pushed a little forward and over the soft iron.
This rotary magnet is repelled by the magnets B, and also by the softiron; it turns around until the unlike poles of the permanent magnets becomeopposite; as they attract each other the soft iron drops below the neutralline, the polarity changes and becomes opposite to that of the magnetsB and like that of the magnet A; the momentum gained carries the pole ofA a little forward of B and over the soft iron, which, now being of likepolarity, repels it around to the starting-point, completing the revolution.
The magnets A and B now compound or unit their forces, and the softiron is again drawn up over the neutral line; its polarity is changed,and another revolution is made without any other force applied than theforce of the magnets. The motion will continue until some outside forceis applied to stop it, or until the machine is worn out.
The result is the same as would be obtained were the magnets B removedand the soft iron coiled with wire, and battery force applied sufficientto give it the same power that it gets from the magnets B, and a current-changerapplied to change the polarity.
The power required to work the current-changer in this case would bein excess of the power demanded to move the soft iron over the neutralline, since no power is required from the revolving magnet under thesecircumstances, it being moved by the magnets compounding when like polesare opposite each other, three magnets thus attracting the iron.
When opposite poles are near together, they attract each other and letthe iron drop below the line. The soft iron, with its lever, is finelybalanced at the joint, and has small springs applied and adjusted so asto balance it against the power of the magnets. In this working model thesoft iron vibrates less than a fiftieth of an inch.
This rotary motion is intended for use in small engines where lightpower is required, such as propelling sewing-machines, for dental work,show windows, etc..
When Wesley Gary was a boy of nine years, the electric telegraph wasin its infancy and the marvel of the day; and his father, who was a clergymanin Cortland County, New York, used to take up matters of general interestand make them the subject of an occasional lecture, among other things,giving much attention to the explanation of this new invention.
To illustrate his remarks on the subject he employed an electro-magneticmachine. This and his father's talk naturally excited the boy's curiosity,and he used to ponder much on the
relations of electricity and magnetism,until he formed a shadowy idea that somehow they must become a great powerin the world.
He never lost his interest in the subject, though his crude experimentswere interrupted for a while by the work of his young manhood. When thechoice of a calling was demanded, he at first had a vague feeling thathe would like to be an artist.
"But," he says, "my friends would have thought that almostas useless and impractical as to seek for perpetual motion." At lasthe went into the woods a-lumbering, and took contracts to clear large tractsof woodland in Western and Central New York, floating the timber down thecanals to Troy.
He followed this business for several years, when he was forced to abandonit by a serious attack of inflammatory rheumatism, brought about throughexposure in the woods. And this, unfortunate as it must have seemed atthe time, proved the turning-point in his life.
His family physician insisted that he must look for some other meansof livelihood than lumbering. To the query, "What shall I do?"it was suggested that he might take to preaching, following in the footstepsof his father, and of a brother who had adopted the profession.
But this he said he could never do: he would do his best to practice,but he couldn't preach. "Invent something, then, "said the doctor."There is no doubt in my mind that your were meant for an inventor."This was really said in all seriousness, and Mr. Gary was at length persuadedthat the doctor knew him better than he did himself.
His thoughts naturally recurring to the experiments and the dreams ofhis youth, he determined to devote all his energies to the problem. Hefelt more and more confident, as he dwelt on the matter, that a great forcelay imprisoned within the magnet; that some time it must be unlocked andset to doing the world's work; that the key was hidden somewhere, and thathe might find it as well as some one else.
At Huntingdon, Pennsylvania, Mr. Gary made his first practical demonstration,and allowed his discovery to be examined and the fact published. He hadlong been satisfied, from his experiments, that if he could devise a "cut-off,"the means of neutralizing the attractive power of a stationary magnet onanother raised above it and adjusted on a pivot, unlike poles opposite,and so arrange this cut-off as to work automatically, he could producemotion in a balanced magnet.
To this end he persistently experimented, and it was only about fouryears ago that he made the discovery, the key to his problem, which isthe basis of his present motor, and upsets our philosophy.
In experimenting one day with a piece of soft iron upon a magnet hemade the discovery of the neutral line and the change of polarity. At firsthe gave little attention to the discovery of the change of polarity, notthen recognizing its significance, being absorbed entirely by the possibilitiesthe discovery of the neutral line opened up to him. Here was the pointfor his cut-off.
For a while he experimented entirely with batteries, but in September,1874, he succeeded in obtaining a movement independent of the battery.This was done on the principle illustrated in Fig. 2.
The balanced magnet, with opposite poles to the stationary magnet, wasweighted so that the poles would fall down when not attracted by the stationarymagnet.
When it was attracted up to the stationary magnet, a spring was touchedby the movement, and thus the lever with the soft iron was made to descendbetween the two magnets on the neutral line, and so cutting off the mutualattraction.
Then the balanced magnet, responding to the force of gravitation, descended,and, when down, struck an other spring, by means of which the cut-off waslifted back to its original position, and consequently the force of attractionbetween the magnets was again brought into play.
In June, the following year, Mr. Gary exhibited this continuous movementto a number of gentlemen, protecting himself by covering the cut-off withcopper, so as to disguise the real material used, and prevent any one fromrobbing him of his discovery.
The publication in the local newspaper of the performance of the littlemachine, which was copied far and wide, excited much interest. But theinventor was by no means satisfied. He had succeeded in securing a continuousmotion, but not a practical motor.
He had invented a unique plaything, but not a machine that would doman's work. So he made further experiments in one direction and another,using for a long time the battery; and it was not until some time afterhe moved to Boston (which was about two years ago) that he was convincedthat the points in the change of polarity, with which he was so littleimpressed when he first hit upon them along with his discovery of the neutralline, were the true ones to work upon.
Thereafter his progress was most rapid, and in a little while he hadconstructed working models, not only to his own satisfaction, but to thatof those experts who had the fairness to give them a critical and thoroughexamination, clearly demonstrating his ability to secure motion and power,as they had never before been secured, from self-feeding and self-actingmachines.
His claim, as he formally puts it, is this: "I have discoveredthat a straight piece of iron placed across the poles of magnet, and nearto their end, changes its polarity while in the magnetic field and beforeit comes in contact with the magnet, the fact being, however, that actualcontact is guarded against.
The conditions are that the thickness of the iron must be proportionedto the power of the magnet, and that the neutral line, or line of changein the polarity of the iron, is nearer or more distant from the magnetaccording to the power of the latter and the thickness of the former.
(The following illustrations come from Westley's Canadian patent forhis generator shown in fig. 5, this drawing is not in the Harpers articlebut aids understanding. TV )
My whole discovery is based upon this change of polarity in the iron,with or without a battery."
Power can be increased to any extent, or diminished, by the additionor withdrawal of magnets.
Mr. Gary is forty-one years old, having been born in 1837. During theyears devoted to working out his problem he has sustained himself by theproceeds from the sale of a few useful inventions made from time to timewhen he was forced to turn aside from his experiments to raise funds.
From the sale of one these inventions -- a simple little thing -- herealized something like ten thousand dollars.
The announcement of the invention of the magnetic motor came at a momentwhen the electric light excitement was at its height. The holders of gasstocks were in a state of anxiety, and those who had given attention tothe study of the principle of the new light expressed the belief that itwas only the question of the cost of power used to generate the electricityfor the light that stood in the way of its general introduction and substitutionfor gas.
A prominent electrician, who was one day examining Mr. Gary's principle,asked if in the change of polarity he had obtained electric sparks. Hesaid that he had, and the former then suggested that the principle be usedin the construction of a magneto-electric machine, and that it might turnout to be superior to anything then in use.
Acting on this suggestion, Mr. Gary set to work, and within a week hadperfected a machine which apparently proved a marvel of efficiency andsimplicity.
In all previous machines electricity is generated by revolving a pieceof soft iron in front of the poles of a permanent magnet. But to do thisat a rate of speed high enough to produce sparks in such rapid successionas to keep up a steady current of electricity suitable for the light, considerablepower is required.
In Mr. Gary's machine, however
, the piece of soft iron, or armature,coiled with wire, has only to be moved across the neutral line to securethe same result.
Every time it crosses the line it changes it polarity, and every timethe polarity changes, a spark is produced. The slightest vibration is enoughto secure this, and with each vibration two sparks are produced, just aswith each revolution in the other method. An enormous volume can be securedwith an expenditure of force so diminutive that a caged squirrel mightfurnish it. (fig. 5: This also does not appear in the Harpers article butcome from Gary's Canadian Patent.)
With the employment of one of the smallest of the magnetic motors, powermay be supplied and electricity generated at no expense beyond the costof the machine.
The announcement of the invention of the magnetic motor was naturallyreceived with incredulity, although the recent achievements in mechanicalscience had prepared the public for almost anything, and it could not bevery much astonished at whatever might come next.
Some admitted that there might be something in it; others shrugged theirshoulders and said, "Wait and see;" while the scientific referredall questioners to the laws of magnetic science; and all believers in bookauthority responded, "It can't be so, because the law says it can't."
A few scientists, however, came forward, curious to see, and examinedMr. Gary's models; and when reports went out of the conversion of two orthree of the most eminent among them, interest generally was awakened,and professors from Harvard and from the Massachusetts Institute of Technologycalled, examined, and were impressed.
More promptly than the scientists, capitalists moved; and before sciencehad openly acknowledged the discovery and the principle of the invention,men of money were after Mr. Gary for the right to use the motor for variouspurposes: one wished to use it for clocks, another for sewing-machines,others for dental engines, and son on.
It is as yet too soon to speculate upon what may result from the discovery;but since it produces power in two ways, both directly by magnets and indirectlyby the generation of unlimited electricity, it would seem that it reallymight become available in time for all purposes to which electricity mightlong ago have been devoted except for the great expense involved.
Within one year after the invention of the telephone it was in practicaluse all over the world, from the United States to Japan.
And it is not incredible that in 1880 one may be holding a magneticmotor in his pocket, running the watch which requires no winding up, and,seated in a railway car, be whirling across the continent behind a locomotiveimpelled by the same agency.
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Harper's New Monthly Magazine - March 1879 pages 601-605 Text retyping courtesy of John Draper
HTML and image enhancement by Tim Vaughan
