George Piggott -- Electro-Gravitation (Electrical
Experimenter, July 1920)

![](0logo.gif)  
**[rexresearch.com](../index.htm)**

---

**George PIGGOTT**

**Electro-Gravitation**

---

***Electrical Experimenter* (July 1920)**   
(Reprinted in **Richard A. Ford: *Homemade Lightning --
Creative Experiments in Electricity***; McGraw-Hill;
ISBN 0-07-137323-3)

**Overcoming Gravitation**

by **George Piggott**

For some time past there has been quite a controversy going on
regarding the subject of interplanetary communication by means
of electric waves. I have been very much interested in the above
on account of experiments which I have made and data collected
pertaining to gravitation effects on high frequency oscillations
and electronic discharges in general. A series of experiments
which I conducted during the year 1904, caused me to formulate
the theory that interplanetary transmission of electrical
impulses was an impossibility on account of the suns resisting
and absorbing influence which virtually isolates our planet from
all other electrical vibrations of a lesser tension or power.

**Gravitation Suspended in Experiments**

The above theorem was arrived at after I had succeeded in
sustaining a metallic object in space by means of a
counter-gravitational effect produced through the action of an
electric field upon the above object. A strong electric field
was produced by means of a special form of generator and when
the metallic object was held within its influence it drew up to
approximately a distance of 1 mm from the center of the field,
then was repelled backward toward an earthed contact, going
within 10 cm of the same when it was again attracted toward the
fields center but this time getting no nearer than 5 cm from
the polar nucleus. This backward and forward movement contained
for some time until the metallic object at last came to a
comparatively stable position, about 25 cm from the fields
center where it remained until the power was shut off. While the
metallic object was suspended, I was able to study the effect of
the surrounding field and found by means of a powerful
microscope, assisted by the insertion of a vacuum tube within
the field, that the metallic object (having of course a certain
electrical capacity) became fully charged and gave off part of
said charge to and against the surrounding field which tended to
hold said object in space, apparently without any other
sustaining influence. Around the outside of the metallic object
and extending to a distance of about 1/2 cm was a completely
dark belt or space in which there appeared to be no electrical
agitation due, possibly, to neutralization caused by the contact
of the large incoming energy supply from the fields center of
with the small oscillating radiations from metallic object. The
ever-changing action of attraction and repulsion resulted in the
overcoming of gravitation. Going farther I will state that the
dark belt above mentioned after many tests gave no sign of
electrification, inasmuch as its width was but 1/2 cm. In fact,
a dark line was shown in the vacuum tube when it was introduced
between metallic object and center of field. It is my firm
conviction that somewhere on the outer confines of our planet
there exists a similar counteracting belt through which naught
but the gravitational vibrations of the sun penetrate, and these
vibrations absolutely annihilate or absorb all other less
powerful ones.

Therefore, after making many experiments to ascertain as nearly
as possible the absolute facts and conditions as they exist, I
have come to the conclusion that all electrical disturbances not
due to our own radio oscillations, on this globe are due to the
suns electrical activities in semi-inductional contact with our
polar extremities.

**Details of Defying Gravity**

The illustrations 1 to 4 will possibly give a fair idea of the
apparatus used, and the manner in which the experiments were
carried on.

Figure 1 shows the general scheme of arrangement of devices. In
the lower left hand corner is shown the ground contact, which
can be turned around and placed in any position found necessary;
in fact, when a metallic object is in suspension, this ground
can be entirely eliminated.

I have found that any substance within the limits of my
experiments can he held in suspension, viz: water globules,
metallic objects, and insulators being among those tried. Some
materials such as cork and wood exhibit peculiar properties when
suspended; a piece of green maple would not rest in one position
in the field, but oscillated backward and forward, continuously,
going to the fields center, then back to ground

Heated materials exhibited equally peculiar characteristics: A
silver ball 11 mm in diameter when heated, remained farther away
from the fields center than when at normal temperature; upon
cooling it gradually drew up to the position it would occupy if
unheated.

Figure 2 shows a generator of the Wimhurst type (improved), the
generating or collecting units being entirely enclosed in an
insulating case and operated under a pressure of 3 atmospheres;
completely dry air only, enters the case through the drying
device attached to the air pump shown in Figure 1. Interior
parts of the generator will retain quite a powerful charge for a
long period of time.

Figure 3 illustrates suspension stand and field producing
electrode. The latter can be revolved in any direction by means
of a spring motor shown on the upper section of the stand.

The small apertures seen in electrode, which is hollow, are
there for the purpose of ascertaining the action of the reduced
field tension at these points, and are also made use of to hold
different sized metallic discs, which are cemented to insulating
plates, forming condensers, the function of which is to create
weak opposite polarities at these points and thus show a
reaction on the suspended object and also a greater ocular
effect in the vacuum tube.

Figure 4 is a detailed drawing of the vacuum tube principally
used; this is of the spectrum type, without sealed-in electrodes
and when introduced into the electrical fields, flows very
brightly at its extremities, especially giving a sharp line
bordering the dark space around the metallic object. A very high
vacuum is sustained in the tube and it is found necessary to
build it of a very perfect insulating glass; the bulb must be
kept absolutely dry on its outer surface.

Different tubes have been used beside the above; corrugated
spherical, cone shaped, and cylindrical, with various results.

The electric field produced for suspension  experiments is
very powerful and intense, being detectable with a vacuum tube
at a distance of over 6 meters (19.68 ft).

In conjunction with the above and drawing an analogy between
the same, I am of the opinion that cometary motion is
undoubtedly due to the activity of its compositional elements
and their susceptibility t changes of polarity which, when the
comet is far distant from the sun, would be opposite in sign to
that of the latter, or when in close proximity to the ventral
orb, would be of the same sign and therefore repelled.

All bodies in process of formation possibly have their cometary
stage, and doubtless future experiments will reveal this fact.

**Actual Effects Achieved by Mr Piggott**

The total power required to operate the generator, which was
run by an electric motor, was about 1/4 KW; the machine voltage
was in the neighborhood of 500,000 when the electrodes were
separated beyond sparking distance. The electrostatic charge
left on the suspension electrode retained the average object in
space for a short length of time, about 1-1/4 seconds after the
machine ceased rotating.

Some objects such as copper and silver balls, which are of
course good electrical conductors, and very nearly homogeneous,
when falling toward the earth, after power had been shut off,
seemed to slow down when they neared same, and hovered about 2
cm above contact for approximately 1 second of time before
striking same; this was due no doubt to the inductional change
in polarity which was imparted to balls almost at the instant of
earth contact.

The aura, shown in Figure 3, near suspended balls (which in
this experiment were made of silver) extended outward to a
distance of about 1 cm and covered about one-half of the upper
hemisphere and a trifle more of the lower hemisphere.

This bluish emanation appeared to be made up of numerous
infinitesimal dots or darting particle, each apparently
separated from the other by a very narrow, glowless belt.
Wverything was, however, in a constant state of agitation and it
was quite impossible to get an absolutely perfect view
microscopically, of an individual particle. Different substances
have different auras both in length and breadth, and also in
luminosity.

The silver balls used in these experiments had an actual
gravitational weight of 1-3/10 gram (nearly 0.05 oz.,
avoirdupois) and were the heaviest objects suspended at this
time, their diameter being 11 mm as before mentioned in another
part of this article.

The largest object suspended was a cork cylinder 10 cm long by
4 cm diameter (approximately 4 by 1-9/16 inches) which had a
copper wire pushed through its center, and extending beyond its
ends to a distance of 3 mm. The weight of the above cylinder was
3/4 grams (0.002645 oz., avoirdupois).

The behavior of metal spheres used in the above experiments was
a most interesting spectacle; silver and copper balls floated
very steadily on one position and when suspending electrode was
revolved, would follows and turn slightly axially, but would not
revolve entirely around same, there being a peculiar slipping
effect not entirely accounted for.

**Figure 1** --- This picture shows Mr George Piggott, the
author, and his laboratory with the powerful electrical
apparatus used, whereby he was enabled to carry on successful
experiments in nullifying the effects of gravitation. In other
words, he was able to suspend small balls and other objects in
the manner shown, the silver balls actually used having weighed
1.3 grams. The diameter of the balls was 11 mm.

![](fig1.jpg)

**Figure 2** --- Special electrostatic machine used by Mr
Piggott in his gravitation nullifying experiments, the which was
enclosed in a heavy airtight compartment, so that it could be
operated under several atmospheres of pressure.

![](fig2.jpg)

**Figure 3** --- A close-up view of the charged metal sphere
mounted on a pedestal together with a spring driving motor,
whereby the electrode or charged ball could be rotated. The two
smaller silver balls are shown as suspended in mid-air, the
earths gravitational pull having been nullified.

![](fig3.jpg)

**Figure 4** --- Close-up view of vacuum tube of the
spectrum type used in studying the aura surrounding the
suspended silver balls, while they remained suspended in space.

![](fig4.jpg)

---

  
**http://www.hbci.com/~wenonah/history/brown.htm****PIGGOT**  
  
George S. Piggot (July 1920) designed, built, and utilized a
fantastically potent electrostatic machine with which he observed
powerful electrogravitic effects. The device was heavily encased
and "dried out" with high-pressure carbon dioxide gas. With this
dramatically dehumified static generator, Mr. Piggot observed a
strange electro-gravitational effect. It was first seen, the
result of accidental occurrences while performing unrelated
electrical experiments.  
  
Mr. Piggot was able to suspend heavy silver beads (112 inch in
diameter) and other materials in the air space between a charged
sphere and a concave ground plate when his generator was fully
charged at 500,000 electrostatic volts. The levitational feat was
only observed when the charged sphere was electropositive.  
  
The Piggot effect was clearly not a purely electrical phenomenon.
If it were, then the presence of the grounded plate would have
destroyed the effect. The very instant in which a discharged
passed to ground, every suspended object would have come crashing
down. But, without the ground counterpoise, the levitational
effect was not observed. Mr. Piggot believed that he was modifying
the local gravitational field in some inexplicable manner, the
effect being the result of interaction between the static field
generator and some other agency the ground.  
  
Piggot further stated that heated metal marbles fell further away
from the field center than cold ones. These suspended marbles
remained in the flotation space for at least 1.25 seconds even
after the static generator ceased rotating. The marbles fell very
slowly after the field was completely removed; a noticeable
departure from normal gravitational behavior.  
  
Mr. Piggot stated that suspended objects were surrounded by a
radiant "black belt". The surrounding space was filled with the
ephemeral electric blue lumination common with very powerful
electrostatic machines. Many academicians explained such phenomena
away. Employing electro-induction theories, it was stated that the
effects were "simple outcomes of highly charged conditions in
conductive media". The suspension of matter in Piggot's experiment
was explained by academes to be the simple result of charge
attraction and gravitational balance. Accordingly, charged metal
balls would achieve their own balancing positions as long as the
field was operating.  
  
Piggot stated that tiny blue spots could be seen running all over
the suspended metal marbles, evidence of electrical discharging
into the air. This being the case, no net attractive charge could
ever develop, simply leaking away with every second into the
surrounding air. Considering that the intense field was "grounded"
to a concave electrode plate, no consistent charge condition could
develop in such a space. Obvious similarities are noted when
considering all these cases, the electrogravitic action being
stimulated by intense electrostatic fields. Effects developed by
Piggot were entirely similar to those observed by Nikola Tesla,
who employed high voltage electrostatic impulses.  
  
The Piggot device certainly discharged its tremendous charge in a
rapid staccato-like fashion to the ground plate. The rate of this
disruptive unidirectional field would be determined by considering
the parameters of the sphere and the concave ground plate. Judging
from the actual capacities involved, and the sizable free air
space, certainly it was a very rapid impulse rate.   
  


---

  

**US1006786**  
 **SPACE TELEGRAPHY  
  
[ [PDF](US1006786A.pdf) ]**

  
1911-10-24       
  
To all whom it may concern:  
  
Be it known that I, George S. Piggott, a citizen of the United
States, and a resident of Chicago, county of Cook, and State of 5
Illinois, have invented certain new and useful Improvements in
Space Telegraphy, of which the following is declared to be a full,
clear, and exact description.  
  
The invention relates to signaling systems 10 in which radiant
electric energy transmitted from suitable sparking apparatus, is
employed to effect suitable detectors at the receiving stations.  
  
The present improvement employs sparking or discharge terminals
connected to the poles of a static electric machine and seeks to
provide an effective form of that type of machine, together with
signaling means for controlling the discharge between the sparking
terminals.  
  
Other objects of the invention are to provide an effective form of
detecting or receiving apparatus for use in connection with such a
transmitting device. To provide 25 means whereby the transmitting
and receiving apparatus may be synchronized and to provide an
effective system of space, telegraphy which will be certain and
rapid in operation which may be readily syntonized and 30 with
which aerial wires or ground connections are not necessary,
although both may be employed with the present improved system if
desired.  
  
With these objects in view, the invention 35 consists in the
improved arrangements and combinations set forth in the following
description, illustrated in the accompanying drawings and more
particularly pointed out in the appended claims.  
  
In the drawings  
  
**Figure 1 is a sectional elevation of the improved transmitter
or radiant electrical generator.** 

![](figa1.jpg)

 **Fig. 2 is a vertical section on line 22 of Fig. 1.**

![](figa2.jpg)

 **Fig. 3 is a horizontal section on line 33 of Fig. 1**   
 **Fig. 4 is a detail plan view of the signaling instrument,
parts being shown in section.**   

![](figa3.jpg)

**Fig. 5 is a sectional view thereof on the line 55 of Fig. 4.** **Fig. 6 is a detail elevation of part of the transmitting
apparatus.** 

![](figa4.jpg)

 **Fig. 7 is a diagrammatic view of the transmitting apparatus.**  **Fig. 8 is a plan view of the detector or receiving
apparatus.** 

![](figa5.jpg)

 **Fig. 9 is a sectional elevation thereof.** 

![](figa6.jpg)

 **Fig. 10 is a longitudinal section through the variable 55
resistance or coherer.**  **Fig. 11 is a diagram of the detector circuits.**  **Fig. 12 is a detail section on the line 1212 of Fig. 8.**   
  

![](figa7.jpg)

 **Fig. 13 is a detail view of parts shown in Fig. 12.**   
The radiant electrical generator or transmitter preferably
comprises a suitable inclosing casing 15, which is made of
insulating material and is preferably shellacked inside and
outside and which is mounted upon insulating blocks 16 of hard
rubber or other suitable substance. Within the casing 15 are
mounted a pair of uprights 17 of hard rubber or other suitable
insulating material which are secured rigidly to the bottom of the
casing. Between the upper ends of uprights or standards 17 is
fixed a 70 shaft 18, preferably of steel upon which are mounted
the revoluble disks 19. Disks 19 are arranged, as shown in pairs,
any number of which may be employed in accordance with the desired
capacity of the machine and 75 the separate disks of each pair are
driven by suitable gearing in opposite directions. Each disk is
preferably mounted (see Fig. 3) upon a hub 20 of hard rubber
having a tubular brass core and is clamped in position 80 thereon
between disks 21 of hard rubber which are securely fastened to the
hubs 20 by right and left hand screw threads. Upon the outer end
of each hub is threaded a beveled gear 22 which is preferably
formed 85 of raw hide and, as shown, the gears connected to each
pair of disks 19 face in opposite directions.    "  
  
The disks 19 are rotated from a main drive shaft 23 suitably
journaled between 90 the lower ends of the uprights 17. This shaft
is preferably driven through gears 24 by a small electric motor 24
mounted inside and upon the base of the casing 15 and the metallic
parts of which are well insulated. Main drive beveled gears 25
fixed upon shaft 23 mesh with beveled pinions 26 fixed upon the
lower ends of vertically disposed counter-shafts 27, and beveled
pinions 28 and the upper ends of the counter-shafts 27 engage the
beveled, pinions 22 connected, as above described, to the disks
19. Gears 25, 26, 28 and 22 are, for the sake of perfect
insulation, preferably made of raw hide. Counter-shafts 27 are
preferably formed of 105 hard brass and are journaled in hard
brass bearings 29 fixed to the end uprights 17 and to an
intermediate upright or uprights 30 (see Fig. 1).  
      
of which may be employed in accordance with the desired capacity
of the machine and 75 the separate disks of each pair are driven
by suitable gearing in opposite directions. Each disk is
preferably mounted (see Fig. 3) upon a hub 20 of hard rubber
having a tubular brass core and is clamped in position 80 thereon
between disks 21 of hard rubber which are securely fastened to the
hubs 20 by right and left hand screw threads. Upon the outer end
of each hub is threaded a beveled gear 22 which is preferably
formed 85 of raw hide and, as shown, the gears connected to each
pair of disks 19 face in opposite directions.  
  
The disks 19 are rotated from a main drive shaft 23 suitably
journaled between 90 the lower ends of the uprights 17. This shaft
is preferably driven through gears 24 by a small electric motor 24
mounted inside and upon the base of the casing 15 and the metallic
parts of which are well insulated. 95 Main drive beveled gears 25
fixed upon shaft 23 mesh with beveled pinions 26 fixed upon the
lower ends of vertically disposed counter-shafts 27, and beveled
pinions 28 and the upper ends of the counter-shafts 27 engage the
beveled, pinions 22 connected, as above described, to the disks
19. Gears 25, 26, 28 and 22 are, for the sake of perfect
insulation, preferably made of raw hide.  Counter-shafts 27
are preferably formed of 105 hard brass and are journaled in hard
brass bearings 29 fixed to the end uprights 17 and to an
intermediate upright or uprights 30 (see Fig. 1).  
  
As above stated, any number or pairs of disks 19 may be employed
(two sets being shown in the drawings) and by the gearing
described, the disks of each pair or set will be driven in
opposite directions. The disks 19 are formed of suitable
dielectric material, such as glass or hard rubber, but preferably
of the former and these disks are preferably provided with a
coating of shellac. Thin metal contact plates or sectors 31 are
cemented to the outer faces of each set of disks 19 by shellac or
other suitable adhesive. These contact plates are preferably
formed of aluminum and are preferably divided into two or more
parts, the sectors shown in 15 the drawings being divided into two
parts.  
  
Separate sets of contact brush holders 32 extend through the top
and bottom of the casing and outside of each set of disks 19.
These brush holders are, as shown in Figs. 1 20, and 2, arranged
at diametrically opposite points and extend radially toward the
center of the disks 19 and at an angle of about 70 degrees to the
horizontal. Each holder 32 is provided with two or more contact
brushes 33 of aluminum wire which are adapted to contact with the
faces of disks 19 and with the sections of the divided contact
plates 31. The brush holders 32 are formed of brass or aluminum
rods and are held in 30 place by soft rubber plugs. 34 inserted in
openings in the top and bottom of the casing 15 and snugly fitted
in such openings to prevent leakage of air.  
  
It is desirable to maintain dry air under 35 pressure within the
casing 15 and for that reason the brush holders 32 and other parts
which extend through the casing, are suitably sealed so. that the
casing may be substantially air tight Brush holders 32 are 40
provided at their outer ends with slotted metal balls so that the
upper and lower sets may be electrically connected by a metal rod
35 set within the slotted balls and held in place by screws 3 6.
The upper and lower 45 rods 35, connected respectively to the
upper and lower sets of contact brush holders, are electrically
connected by coiled insulating conductors 37. To hold the brush
holders 32 securely in place against the outward pressure of the
air within the casing 15, the soft rubber plugs 34 are preferably
provided with flanges 34 which engage the inner face of the top
and bottom of the casing.  
  
Condenser brush holders 38 are arranged. 55 in a horizontal plane
extending through the center of the disks 19 and at diametrically
opposite points. These holders are formed of aluminum or brass
tubing and at each side are threaded into a common metal support
39 having a central shouldered projection 40 which extends through
the end of the casing and which is firmly held in place by a ball
41, preferably of brass, which is threaded upon the end of the
projection 40. 65 A Washer 42 between the ball 41 and the casing
renders the joint practically air tight. The brush holders 38 are
arranged in pairs on the outside of each pair of oppositely
rotating disks 19 and are provided with brushes 38a of fine
aluminum wire which extend toward, but do not contact with the
disks.  
  
To each support 39 for the condenser brushes, is threaded or
otherwise suitably fixed, a tubular rod 43 of aluminum which 75
extends upwardly through the top of the casing. The upper end of
the tubular rod is plugged to prevent leakage of air and is
connected by a short piece of metal tubing with a brass ball 45. A
hard rubber so thimble 46 and a washer'47 between the ball and the
top of the casing seals this joint. A metal rod or tube 49 is
mounted to slide horizontally through a bore in the ball 45 and
may be held firmly in any adjusted position therein by a screw 50.
A similar rod 49 is connected in a similar manner to the other
side of the machine and the inner ends of these rods are provided
with sparking or discharge terminals or balls 51, while the 90
outer ends of the rods are provided with handles 52 which may be
grasped to adjust the position, of the sparking terminals and
which are of hard rubber, preferably corrugated as shown. Between
the sparking terminals or balls 51 and in line therewith, is
preferably located a large metal discharge ball 53 preferably of
brass which is secured to the top of the casing.  
  
A short circuit connects the opposite sides 100 or poles of the
machine and consists of bent pieces 54 (see Fig, 3) of brass or
aluminum which are secured to the balls 41 at the ends of the
machine. The bent pieces 54 are preferably covered with insulating
material 105 and the end balls or terminals 55 of the shunt
circuit are inclosed in receptacles 56 of hard rubber or other
suitable material. The receptacles 56 are mounted upon a bracket
57, preferably of insulating material secured to the casing 15,
and the opposing faces of the receptacles 56 are provided with
small openings 58 in line with which normally extends a shiftable
conductor con-nected to the signaling key.  
  
The signaling key 59, preferably formed of brass, is pivoted
between a pair of bearing pins 60 and is normally held in uplifted
position with its inner end against an adjustable stop 62 by a
cushion spring 63 120 which is interposed between the outer end of
the key and the shelf or support 57. The inner end 64 of the key
is connected to the main body thereof by an insulating section 65.
The shiftable conductor is formed of of separate pieces of brass
or aluminum tubing 66 fitted to adjustably slide one within the
other and adjustably held in place upon the end of the key by a
screw 67. Each of the tubular sections 66 is fitted at its end
with a pointed steel plug 68 and, in normal position, the
conducting sections 66 and points 68 extend in line with the
openings 58 in the receptacles 56.  
  
When the electric generator described, is operated the condenser
brushes and sparking terminal upon one side or pole of the
ma-chine will become charged with positive and those upon the
other side or'pole of the machine will become charged with
negative electricity! A part of the charge however will leak
across from the short circuit terminals 55 through the shiftable
conductor or switch 66, the points of which are in line 15 with
the openings 58 in the receptacles 56 which inclose the short
circuit terminals. A sufficient amount of the charge will thus,
leak from one side or pole of the machine to the other to prevent
any disruptive discharge 20 or spark between the discharge
terminals 51. When however, the sparking terminals are properly
adjusted and the key is depressed, a disruptive discharge or
single spark at once occurs between'the discharge terminals, 25
since the conductor or switch 66 is by the depression of the key
moved out of line of the openings 58 in the receptacles 56. The
leakage of current between the poles of the machine is thus
interrupted so that a heavy 30 spark at once takes place between
the discharge terminals.  
  
Numerous advantages are incident to the employment of such a
static machine as a transmitter for space telegraphy. At each 35
quick depression of the signal key a single strong heavy spark
having little heat occurs between the positive and negative
terminals instead of a series of sparks having considerable heat
such as occur at the spark gap 40 when a coil is employed for the
production of a high tension current. Moreover, the sparking
terminals are always ready to discharge at the instant the signal
key is depressed and there is no magnetic lag to overcome as is
the case with a sparking coil, thereby increasing the speed of
transmission. With the present improved transmitter a single spark
or discharge is employed to represent a " dot" while two sparks or
discharges 50 in quick succession represent a "'dash" so that
signals may be rapidly and accurately transmitted. The machine
moreover, can be readily, adjusted for selective signaling as
hereinafter explained and does not require 55 the employment of an
aerial wire or ground connection, although either or both may be
employed if desired for transmission of signals over long
distances.  
  
The discharge balls 51 and 53 may be of 60 any suitable size, but
good results have been obtained with the discharge terminals 51 of
about an inch and a half in diameter and with the intermediate
discharge ball of three to four inches in diameter. When a signal
is to be transmitted the negative terminal 51 is preferably
adjusted to a position quite close to the intermediate discharge
ball 58 while the positive discharge terminal 51 is placed about
an inch away from the center discharge ball so that a heavy strong
spark yo occurs between the positive sparking terminal and the
center discharge ball. The sections of the shifting conductor or
switch 66 may be readily adjusted to correct position to prevent a
discharge between the terminals 75 until the signal key 59 is
depressed.  
  
To prevent leakage between the condenser brushes and the central
steel shaft of the machine, the ends of the brush holders 38 are
preferably provided with blocks 38b of g(r) insulating material.  
  
The efficiency of the machine is found to be considerably
increased by maintaining air under pressure within the
substantially air-tight casing 15 which incloses the generator
disks, plates and brushes and preferably the air within the casing
is maintained as dry and as free from moisture as possible. For
this purpose a small air pump 69. (see Fig. 6, the oscillating
type of pump being illustrated in the drawings) is driven from a
suitable electric or other motor 70 and supplies air under
pressure to the upper end of a casing 71 through a flexible pipe
72. The casing 71, which is preferably upwardly flaring is shown,
is provided with a grating 73 at its lower end upon which is
superposed a layer 74 of cotton wool which serves to filter the
air. Above the layer of cotton wool is placed a layer 75 of
anhydrous 100 calcium chloride which removes all moisture from the
air. The lower end of the casing 71 is provided with a drain cock
76. A valved outlet nozzle 77 near the lower end of the casing is
provided with a screen and 105 is connected by a flexible pipe 78
with an inlet valve 79 (see Fig. 2) on one side of the machine
casing 15. An outlet valve 80 is provided on the opposite side of
the casing and is set to maintain a pressure of about 110 thirty
pounds within the same. By thus maintaining dry air under pressure
within the machine, the efficiency of the latter is found to be
considerably increased and the machine is not atfected by the
varying atmospheric conditions. The sides 81 (see Fig. 2) of the
casing 15 are preferably removably held in place by screws 82,
rubber packing being provided between the sides and the edges of
the casing to produce a 120 tight joint.  
  
The transmitter may be readily syntonized for selectively
signaling a series of stations by providing a series of discharge
terminals 51a, 51b, 51c, etc. (see Diagram Fig. 7) and 125 by
providing a series of intermediate dis-charge balls 53a, 53b,
'53c, etc., the size of which terminals and balls is varied to
vary the capacity and thus vary the intensity, length and
thickness of the sparks transmitted. The signals are transmitted
from the desired set of terminals by properly adjusting that set
while the others are withdrawn as indicated in Fig. 7. The
efficiency of the transmitter is increased and it may be further
syntonized by providing condensers of varying capacity on one or
both sides of the machine. In Fig. these condensers are indicated
in the form 10 of Leyden jars 88 having their poles 84 arranged
adjacent the balls 41 on opposite sides from the machine. A series
of such condensers may be employed if desired. Moreover, if
desired for transmitting, signals over long distances, the
positive side of the machine may be connected to an aerial wire 85
and too, if desirable, the condenser, or capacity arranged
adjacent the positive side of the machine may be Connected to the
20 ground by a wire 86.  
  
The detector or receiving device at the receiving stations
comprises a suitable inclosing casing 87 preferably of wood,
thoroughly shellacked and mounted upon insulating feet 88. A plate
89 of hard rubber or other suitable insulating material upon the
upper face of the casing, carries an upright 90 also of hard
rubber, to which is fixed the lower section of a hinged clamp 91
the members of which are also formed of hard rubber. The curved
open ends of the clamp embrace and rigidly support in horizontal
position the coherer or variable resistance apparatus, the latter
being securely held in 35 place by a thumb screw 92 extending
between the hinged members of the clamp.  
      
The coherer or variable resistance apparatus comprises a tubular
casing 93 preferably of hard rubber within opposite ends 40 of
which are threaded hollow plugs 94 also of hard rubber. The inner
ends of the plugs 94 abut, as shown within the casing 93 and they
are securely, held and clamped in position by lock nuts 95 of hard
rubber. The 45 conducting plugs 96 are adjustably threaded through
the hollow plugs 94 and are provided on their ends with thumb nuts
97 by which suitable conductors may be connected thereto. The
conducting plugs 96 are preferably formed of silver 500 to 600
fine and partly of nickel. The inner end of one of the plugs is
provided with a cylindrical extension 98, while the inner, end of
the opposite plug is provided with a cylindrical depression or
recess 99 slightly larger in diameter than the extension 98. The
filings 100 intermediate the ends of the conducting plugs are
preferably of soft iron, medium fine, mixed with about two per
cent, of platinum filings. Preferably, to increase the
sensitiveness of the coherer, the soft iron filings are first
placed under magnetic influence or tension before they are put
into position between the conducting plugs 96.  
  
The arrangement described has been found extremely sensitive in
operation. The hollow supporting plugs 94 of hard rubber and the
conducting plugs 96 carried thereby may be removed and threaded
back into position without disturbing the adjustment between the
ends of the conducting plugs. By forming the parts of hard rubber
they are bound very tightly together and the adjustment of the
conducting plugs is not readily displaced. The hard rubber 75
parts are preferably shellacked and highly polished so that the
filings will not become tarnished by the sulfur or other component
parts of the rubber.  
  
The coils 101 of a polarized relay, are in 80 circuit with the
coherer, as indicated in Fig. 11. In order that the operation of
the relay may not interfere with the operation of the coherer and
in order that the relay contacts may be kept free from dust, such
85 relay is preferably mounted within the casing 87 and preferably
upon a series of insulating blocks 102. The relay coils 101 are
mounted upon one pole of a permanent horse shoe magnet 103, the
cores of the coils being 90 in electrical connection with such
pole of the permanent magnet. A metal upright 104, fixed to the
other pole of the permanent magnet 103, pivotally supports the
horizontally disposed armature 105 which is arranged to vibrate
between the poles of the relay. A binding post 106 is fixed to the
upper end of upright 104 and a leaf spring 107 is connected to the
binding post and its free end engages the vibrating armature 105
in line with its pivot, thus maintaining a secure electric contact
therewith. The circuit tnrough the relay, armature and contact may
be traced in Fig. 11 from battery 108. to binding post 106,
contact spring 107, 105 armature 105, relay contact 109, tapper
actuating magnet 110 and through oppositely wound coils 111 upon
the members of the permanent magnet 103 and fro m thence back to
battery. By thus directing the circuit 110 from battery 108
through oppositely wound coils on the members of the permanent
magnet 103, any loss of magnetism in the latter is compensated for
and the full strength of the magnet maintained.  
  
To adjust the sensitiveness of the relay, an armature 112 (see
Fig. 11) is provided in line with the poles of the magnet 103 and
is adjustable to and from such poles. A screw threaded extension
113 upon the armature extends through guides upon a suitable
support 114 and lock nuts 115 threaded on the extension serve to
hold the armature in adjusted position at any desired distance
from the poles of magnet 103.  
  
The tapper actuating magnet 110 is mounted, upon a suitable
support 116 upon the upper portion of the casing with its poles
facing upwardly. Its armature 117 is pivoted to a suitable upright
118 on the top of the casing and its outer end extends in
substantially horizontal direction over the upwardly facing poles
of the magnet 110. A leaf spring 119 is fixed to the outer end of
the armature and extends inwardly over its pivot. The inner
upwardly bent free end of spring 119 is engaged by an adjusting
screw 120 threaded through a suitable projection upon the support
118 and 10 normally holds the inner end of the armature against an
adjusting screw 121 also threaded through an extension fixed to
the support 118. The tapper 122 fixed to the inner end of the
armature extends downwardly and inwardly beneath the end of the
coherer supporting clamp 91 in position to strike the clamp when
the magnet 110 is energized. Since the signals are transmitted
from the improved generator by single or individual disruptive
discharges or sparks instead of a series of such discharges or
sparks, the tapper actuating magnet 110 is non-self-interrupting,
that is, the operating circuit therefor extends directly through
its 25 coil and not through an intermediate contact controlled bv
the vibration of its armature. In operation a single blow of the
tapper against the coherer clamp represents a dot and two blows in
quick succession reprsent a dash. Other similar codes could of
course be employed if desired. When the tapper strikes the coherer
clamp a clear resonant sound is emitted and the signal may be
easily read. Other means may of 35 course be employed for reading
the signal as for example, a telephone interposed in the coherer
circuit. By properly adjusting the screws 120 and 121, the
operation of the tapper magnet may be rendered extremely 40
sensitive.  
  
The coherer circuit (see Fig. 11) derives current from a small
battery 123 and in this circuit is also interposed a variable
resistance or rheostat 124 for regulating the 45 amount of
current. This rheostat is convenient mounted, as shown, upon one
end of the casing. An intensifier 125 of improved construction, is
also interposed in the coherer circuit as indicated in Fig. 11. 50
The intensifier (see Figs. 12 and 13) comprises a suitable casing
provided with bind-ing posts 126 to which the conductors of the
coherer circuit are conveniently attached. Binding posts 126 are
in turn connected to 55 a pair of binding posts 127 by conductors
128. A contact disk 129 is rotatably mounted between the binding
posts 127 and a pair of brush holders 130, upon the outer ends of
the binding posts, are each provided with 39 a series of line wire
brushes 131 One of which upon each brush holder is bent to contact
with the rotating disk. 129. If one of the fine brushes is injured
or burned another may he employed. Coiled springs 132 extend
between shoulders on the binding posts 127 and the brush holders
130 and adjusting nuts 133 threaded upon the outer ends of the
binding posts engage the outer faces of the brush holders 130 and
serve to accurately adjust the same in desired position.  
  
In operation the contact disk 129 is driven by a spring actuated
clock train 134a, 134b, 134c, 134d, 134e and 134f. A suitable
escapement mechanism 135a, 135b and 135c is employed to maintain
the speed of the rotating disk uniform. Any suitable form of motor
and any suitable form of escapement mechanism may be employed in
connection with the rotating contact disk 129. That illustrated is
an ordinary form of clock 80 train and need not be more fully
described. A spring-held plunger 136 extends through the casing of
the intensifier adjacent the escapement mechanism so that the
rotation of the contact disk may be started and stopped 85 as
desired.  
  
The employment of the rotatable contact intensifier in the coherer
circuit materially increases the sensitiveness of the latter and
renders the transmission of the signals accurate and certain.  
  
In order to properly adjust the detectors or receiving instruments
at various stations the intensifiers at such stations are set to
rotate at different speeds and a condenser 95 137 (see Fig. 11) or
other suitable capacity which may be varied, is connected to the
coherer circuit and the opposite side of the condenser or capacity
may be, if desired, connected to ground. The ground connection
however has not been found necessary over short distances. This
form of receiver having the peculiar intensifier, as described is
specially and peculiarly applicable for use in connection with an
influence machine transmitter. It has been found in practice that
by changing the length and thickness of the sparks generated by
the static machine transmitter, by varying the speed of the
intensifying disk at different stations and by 110 properly
arranging the capacity areas at the transmission station and at
the different receiving stations, the selective transmission of
signals may be accurately effected. By running the disk of the
intensifier at high 115 speed and using a small capacity area, the
receiver will respond only to heavy discharges of the influence
machine transmitter and by running the disk at low speed and
increasing the capacity area the receiver 120 will respond only to
light sparks sent out by the transmitter.  
  
It is obvious that numerous changes may be made in the details of
structure and arrangement of parts without departure from 125 the
essentials of the invention.  
  
Having described my invention what I claim as new and desire to
secure by Letters Patent is:...  
  


---