Antonio d'Angelo -- Inter-Atomic Ion Motor -- NY Times
article & US Patent # 2021177

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**Antonio d'ANGELO**

**Inter-Atomic Ion Motor**

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***New York Times* (Wednesday, March 7,
1928)**

> **Priest
> Has Motor Run By 'Ion Energy'**

***Jesuit Inventor From
Brazil Is Here To market Product, Now Undergoing Patent
Tests ~ Not A Fuelless Machine ~ "Inter-Atomic" Force
Increases Electric Battery power, He Says -- Discounts
Hendershot Claims***

An Italian Jesuit priest
from Brazil announced here yesterday that he had invented a
motor that makes use of "interatomic" energy to generate many
times the power it receives originally from an electric
battery. The motor is now at Washington, where it is
undergoing the Patent Office investigation.

The priest is the Rev.
Antonio dAngelo, S.J., a stocky, earnest little man who
combines missionary work in Brazil with tinkering in his own
electrical laboratory. He speaks no English, but told of his
machine through his brother, Biagio dAngelo of 1475 LeLand
Ave., the Bronx.

Father dAngelo became
interested in electricity 20 years ago when he was a student
at a Jesuit seminary in Naples. A year and a half ago he was
sent out by his Order to Brazil to carry on missionary work at
Ribeirao Preto among the Italian emigrants. He had to get a
special dispensation from Bishop Alberto Gonzales of Ribeirao
Preto to visit the United States where, so his brother had
written him, fortune comes more easily to the man with a
money-saving device. He came here in November 1927, and has
urged his Bishop to extend his leave of six months.

The missionary priest does
not believe in the Hendershot "fuelless motor".

"I challenge anyone", he
said yesterday, "to use the magnetic field of the earth for
running a motor. The energy from that would be too small".

His motor, he said, could be
used in the home to supply electric lighting cheaply, and even
heating. He said that it could be used to run trains,
airplanes and automobiles.

Father dAngelo had a plan
of his motor with him yesterday. He showed how it started to
develop energy from an electric battery, and how this original
impulse worked on the machine to generate many times its power
through the "electricity produced by the inter-atomic energy
of the ions".

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> ---
>
>
>
> ![](angelo.jpg)
>
> ***Popular Science
> Monthly* (July 1928, p. 26)**
>
> ---
>
> **US Patent # 2,021,177**
>
> **Motor Generator & Other Transformer**
>
> **Antonio d'Angelo**
>
> **[ [PDF Format](us2021177.pdf) -- 1.3 MB ]**
>
> ![](abstr.jpg)
>
> Nov. 19, 1935,   
>   
> This invention relates to means for transforming electrical
> energy into electrical energy of a different type, or into
> mechanical energy. The invention refers more particularly to
> electrical machines provided with a stationary or rotary
> pole-armature and to a new method of winding the primary and
> secondary circuits carried by said armature.  
>   
> An object of the present invention is the provision of
> inexpensive, durable and reliable machines for transforming
> direct or alternating current into a single-phase or
> multi-phase alternating current or direct current of any
> desired voltage.  
>   
> Another object is the adaptation of a machine provided with
> a pole-armature carrying a primary circuit and a secondary
> circuit for transforming direct current into a direct
> current of any desired voltage.  
>   
> A further object is the provision of a new method for
> winding the secondary circuit on the pole-armature of a
> machine, said method resulting in an increase in
> electromotive forces developed in the secondary circuit.  
>   
> The above and other objects of this invention may be
> realized through the provision of a secondary winding
> carried by the pole-armature and having a pitch which is
> different from that of the primary winding; preferably at
> least some of the turns of the secondary winding are wound
> in such a way that each of the last-mentioned turns
> encircles two, three or more poles of the pole armature.  
>   
> The invention will appear more clearly from the following
> detailed description when taken in connection with the
> accompanying drawings, showing by way of example only, some
> of the preferred embodiments of the inventive idea.  
> **In the drawings:****- Figure I shows a motor-generator partly in side
> elevation and partly in a longitudinal vertical section.****- Figure II shows the motor-generator illustrated in
> Figure I in a transverse vertical section.****- Figure III is a front view of the iron sheets
> forming the armature of the motor-generator illustrated in
> Figures I and II.****- Figure IV shows diagrammatically the windings of
> the primary circuit carried by the armature.****- Figure V shows diagrammatically the windings of the
> primary and secondary circuits crried by the armature.****- Figures Va, Vb and Vc are diagrams representing the
> changes in the magnetic flux and the electromotive forces
> of the machine illustrated in Figures I to V****- Figue VI shows diagrammatically the primary and
> secondary circuits of a machine for transforming direct
> current into a direct current of a low voltage.****- Figure VII shows diagrammatically a machine for
> producing direct current of a high voltage.****- Figure VIII shows diagrammatically another machine
> having rotor-pole windings, which are connected with the
> windings of the stator poles.****- Figure IX shows diagrammatically a machine for
> transforming alternating current into direct current.****- Figure X is a transverse vertical section through a
> motor-generator provided with a revolving armature.****- Figure XI shows diagrammatically the primary and
> secondary circuits of the motor-generator illustrated in
> Figure X.****- Figure XII and XIII are diagrams illustrating two
> different modifications of the machine illustrated in
> Figures X and XI.- Figure XIV shows diagrammatically
> another modification of the motor-generator having a
> revolving armature****- Figure XV shows a stationary transformer provided
> with a secondary winding having a different pitch from
> that of the primary winding.**
>
> ![](fig1.jpg)![](fig2.jpg)
>
> ![](fig3.jpg)![](fig4.jpg)
>
> ![](fig5.jpg)![](fig5abc.jpg)
>
> ![](fig6.jpg)![](fig7.jpg)
>
> ![](fig8.jpg)![](fig9.jpg)
>
> ![](fig10.jpg)![](fig11.jpg)

![](fig12.jpg)![](fig13.jpg)

![](fig14.jpg)![](fig15.jpg)

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**The motor-generator illustrated in Figures I to V of
the drawings is used for transforming direct current into a
two-phase alternating current;** it consists of a
stationary armature, or stator, having eight long and narrow
poles and a rotor provided with four poles. Obviously, the
number of poles may be varied at will. The stationary
pole-armature is formed of insulated sheets 20 of soft iron,
as shown in Figure III. The sheets 20 are carried by bolts 21
(Fig.II) passing through holes 1 (Fig.III). The stator is
assembled in the usual manner. The space 3 between two
adjacent stator poles 23 (Fig.III) should be wide enough to
permit the insertion of the windings of the primary circuit 8
and of the secondary circuit 4.  
  
The rotor 17 of the **motor-generator** is illustrated in**Figures I and II** of the drawings, and is provided with
four poles 16. The rotor 17 is mounted on a shaft 18 and is
rotatable along with this shaft. A pair of insulated
slip-rings 14 are also mounted on the shaft 18, and rotate
together with this shaft. The slip-rings 14 are rotatably
connected at b with the pole winding 7 of the rotor 17. In the
modification illustrated in the drawings, the pole windings 7
of the rotor 17 are connected in parallel with the primary
windings 6 of the stator. Obviously, the windings 6 and 7 may
be connected to different sources of energy or interconnected
in series or in compound.  
  
A source 22 of direct current shown diagrammatically in Figure
I is connected by conductors 11 with a pair of stationary
brushes 15, which press against the two rotary slip-rings 14.
Thus an electrical current is sent from the source 22 to the
pole windings 7 of the rotor, so that the poles 16 become
magnetized, and produce a magnetic field, the lines of which
pass through the primary circuit 6 and the secondary circuit 4
of the stator.  
  
A stationary commutator 9 surrounds the shaft 18 and is
provided with a number of conducting segments, which are
insulated from each other. A rotary brush carrier 19 is
rigidly mounted on the shaft 18 and is rotatable along with
said shaft. The brush carrier 19 is provided with a plurality
of revolving brushes 12, which bear against the segments of
the stationary commutator 9. The brushes 12 are connected at a
with the slip-rings 13. Stationary brushes 10, the ends of
which press against the stationary slip-rings 13, are
connected with the source 22 of direct current by conductors
2.  
  
The direct current is thus sent from the source 22 through the
conductors 2 and the stationary brushes 10 into the revolving
slip-rings 13. From the slip-rings 13 the current passes
through conductors a and the revolving brushes 12 into the
stationary commutator 9. Conductors 8 connect the stationary
commutator 9 with the primary windings 5 of the stator.  
  
As shown more clearly in **Figure IV of the drawings, the
primary windings, or the primary circuit 6, carried by the
poles 23 of the stator consists of a number of coils 24,
which are situated one above the other and at a certain
distance from each other. Each coil 24 has two ends 8
connected to separate segments of the commutator 9.****The primary circuit 6 is wound in the following manner:**  
  
One end of a coil 24 is joined to a segment of the commutator
9. The other end of the same coil 24 is joined to an adjacent
segment of the commutator 9. An end of an adjacent coil, which
coil is situated either immediately below or above the
first-mentioned coil on the same pole, is joined to the same
segment, to which the nearest end of the first-mentioned coil
is connected. This arrangement is repeated until the winding
of the primary circuit 6 is completed. Segments of the
commutator 9 which are connected with coils carried by one
pole, are situated at a predetermined distance from
corresponding segments connected with the coils carried by an
adjacent pole, said **distance being proportional to the
angle between these two pole**s. After the winding of one
pole has been completed, the end of the first coil of the
adjacent pole is connected with that segment, which is also
connected with the nearest end of one the coils carried by the
first-mentioned pole. Thus all the coils 24 carried by the
pole 23 are interconnected in series. **Due to this
arrangement a great part of the effects of self-induction is
avoided and sparking is eliminated to a remarkable extent.**  
  
The coils 24 are wound in such a manner that groups of poles
are formed, which have the same sign. In the modification
illustrated in **Figure IV,** two adjacent poles have the
same sign, but the next two poles have the opposite sign. The
poles 23 of the stator are thus divided into pairs of poles,
each pair having a different sign from that of the adjacent
pair. The direction of the current flowing through the primary
winding 6 is illustrated by arrows in Figure IV. The magnetic
poles 23 attract the adjacent poles 16 of the rotor 17 thus
causing a rotation of the rotor 17. Since the brush carrier 10
and the slip-rings 13 and 14 are rigidly mounted on the shaft
18, they will rotate along with said shaft, so that the
brushes 12 will rotate along with the rotor 17 and will slide
with respect to the stationary commutator 9. While the brushes
12 pass by the segmants of the commutator, they will reverse
the polarity of the poles 23 of the stationary armature. Due
to this arrangement the rotor 17 and the field of the
stationary armature will revolve with a predetermined speed.  
  
The arrangement of the windings of the secondary circuit 4 is
diagrammatically illustrated in **Figure V** of the
drawings. As shown in that figure, **the pitch of the
secondary windings is much greater than the pitch of the
primary windings. The secondaty circuit 4 consists of
windings divided onto a plurality of coils, the turns of
which encircle or surround two of the poles 23. In the
illustrated modification the winding is wound twice around a
pair of poles.** Each turn of a coil surrounds both poles,
and an adjacent pair of poles is surrounded by another turn of
the same winding. Since a two-phase alternating current is
required at the secondary side of the machine, the secondary
circuit 4 consists of two separate windings, one winding being
situated at a distance of one pole from the other winding. The
windings of the primary circuit 6, which is connected by
conductors 8 with the stationary commutator 9, have a smaller
pitch than that of the secondary windings, since the coils of
the primary circuit 6 surround each pole 23.  
  
While the magnetic field of the rotor 17 is revolving, the
lines of forces of that field cut the windings of the
secondary circuit 4 with the results that an electromotive
force is produced in the secondary circuit 4. Another
electromotive force is created in the secondary circuit 4 by
the revolving magnetic field of the stator. The total
electromotive force induced in the secondary circuit 4 is thus
created firstly by the changing of the signs of the poles 23
of the stationary armature, and secondly, by the revolving
magnetic field of the poles 16 of the rotor 17.  
  
Since each turn of the secondary winding 4 encircles two poles
23 of the stationary armature, and since these windings fill
in the space 3 between the poles 23, one coil of the secondary
winding 4 is subjected to four variations of the magnetic flux
in one half cycle. This is due to the fact that the poles,
which are encircled by the coils of the secondary circuit 4,
form a pair, the polarity of which is reversed twice during
one-half cycle: once the sign of one of the poles, forming the
pair is reversed, and the second time the sign of the other
pole of the pair is reversed. Consequently, the entire
electromotive force caused by the continuous changing of the
signs of the poles 23 of the armature, is induced four times
in each coil of the secondary circuit 4 during one complete
revolution of the rotor.  
  
**Figure Va** illustrate diagrammatically the changes in
the electromotive forces induced in the motor-generator
illustrated in Figures I to V of the drawings. The
electromotive force induced by the magnetic field of the rotor
is represented by the outer circle: the magnetic flux varies
between a positive maximum value and a negative maximum value.
The values of the electromotive force created by the changes
of sign of two poles encircled by a turn of the secondary
winding, are represented in Figure Va by four inner circles.
It should be noted that the last-mentioned electromotive force
is changed twice to a positive value and twice to a negative
value.  
  
**Figure Vb** is a diagram of the electromotive forces,
showing changes of the values thereof in the course of one
revolution of the rotor. The broken curve 26 represents the
electromotive force or voltage developed in the primary
circuit 6. The electromotive force induced by the magnetic
field of the rotor 17 in the secondary circuit 4 is
represented by a sinusoidal curve 27.  
  
The curve 27 would have represented the entire electromotive
force if the machine had no primary circuit 6 at all, so that
it would operate only as a dynamo. However, due to the fact
that the poles 23 of the stator produce a revolving magnetic
field, another electromotive force is developed within the
secondary circuit 4, which is represented by the curve 28 in
Figure Vb. As illustrated in that Figure, the values of the
electromotive force represented by the curve 28 vary from zero
to a maximum value, then to zero, then again to the maximum
and then again to zero, while the values of the electromotive
force represented by the curve 27 vary once, from zero to a
maximum and then again to zero.  
  
**These curves illustrate that the electromotive force
induced by the changing of the signs of the poles 23 of the
stationary armature is not reversed in the course of
one-half cycle. This is caused by the fact that one and the
same turn of the secondary winding is subjected to another
inductive action during the same half-cycle, due to the
change of the sign of the second pole of the pair of poles
encircled by the turn: this sign is changed at a time when
the electromotive force induced by the first pole is
reversed. The combined inductive action caused by the
reversal of the signs of the poles 23 is represented by the
curve 28 illustrated in Figure Vb.****Due to this feature, the induced electromotive force
developed in the secondary circuit is greater than that of
the primary circuit, although the secondary circuit has a
smaller number of conductors and turns. Another reason for
the increase in voltage is that the pitch of the primary
winding is much shorter than the pitch of the secondary
winding. In order to enable the primary winding to develop
its normal counter-electromotive force, the rotor will make
more revolution than would have to be made if a full-pitch
winding were used, provided that the machine runs on direct
current. A quickly rotating rotor will cut more lines of
force and this will contribute to the increase of the
voltage in the secondary winding. Obviously, if the machine
runs on alternating current, the magnetic field must be
strangthened in order to develop its normal
counter-electromotive force, and this will contribute to the
increase of the secondary voltage.**  
  
The diagram illustrated in **Figure Vc** of the drawings,
is based on the generally known principles that the average
voltage is proportional to the sine of the angle, through
which the coil has turned from the position in which it lay
across the field, and that the total amount of voltage is
proportional to the rectangular area, which is equal to the
sum of the areas limited by the sinuous curves, the total
amount of voltage being therefore proportional to the average
height of the points along that curve.  
  
In Figure Vc the line a' b' represents the average voltage of
the direct current flowing in the primary circuit 6. The
rectangular area a' l d e is equal to the area limited by the
positive portion of the curve 27 representing the positive
electromotive force induced by the magnetic field of the rotor
17. The rectangular area ***a' c h d*** is the sum of
the areas limited by the positive portion of the curve 28,
representing the positive electromotive forces induced through
the changing of the sign of a pair of stator poles 23
encircled by turns of the secondary winding.  
  
The rectangular area ***l c h e*** is the sum of the
above-mentioned two areas. Consequently, the line c l
represents the average positive electromotive force.  
  
In the same manner, the area ***l b' g f*** is equal
to the area limited by the negative portion of the curve 27
representing the negative electromotive force induced by the
rotor 17. the area b' d i g is the sum of the areas limited by
the curve 28 representing the negative electromotive force
induced by the change of the sign of a pair of poles 23. The
area ***l d i f*** is the sum of the two-above areas,
and the line l d represents the average negative electromotive
force. The line ***c d*** is, therefore, proportional
to the difference of potentials of a phase current generated
during one cycle.  
  
Assuming that both the primary and secondary circuits have an
equal number of turns and neglecting the energy losses in the
armature, the average increase in the voltage of the secondary
circuit as compared to the voltage of the primary circuit, is
given by substrating the line ***a' b'*** from the
line ***c d.*** Since the windings of the secondary
circuit 4 for all phases are exactly alike, a similar current
will be generated in each phase winding; and since the two
systems of windings are placed one-half cycle apart from each
other, the generated current will be the usual two-phase
current.  
  
If a single-phase alternating current is desired, the second
phase may be left open; it is also possible to connect the two
phase windings in series.  
  
The direction of the current flowing in the primary and
secondary circuits is illustrated by arrows in **Figure V**
of the drawings. It will be noted that at a certain time, the
conductors carrying the current of one phase will have no
demagnetizing effect on the poles of the armature. This takes
place when the induced current flows between adjacent poles
having the same polarity. This effect with those already
described increases the efficiency of the described
motor-generator.  
  
The efficiency of the motor-generator may be further increased
by increasing the length of the armature, since the
counter-electromotive force is produced mainly by
self-induction, and self-induction is proportional to the
square of the number of turns.  
  
The device illustrated in **Figure I to V** is used for t**ransforming
direct current into a two-phase alternating current.**   
  
The modifications shown in **Figures VI and VII** of the
drawings illustrate a **motor-generator transforming direct
current into a direct current of a different voltage and
amperage.** For that purpose **two different stationary
commutators are used, one of which sends the incoming
current into the primary winding of the stationary armature.
The second commutator is connected with the secondary
winding and is used for collecting the secondary current.**  
  
**Figure VI i**llustrates diagrammatically the windings of
a machine used for the production of a **direct current of a
low voltage**; it comprises a stationary armature having
poles 32, carrying the primary circuit 33 and the secondary
circuit 34. The rotor is diagrammatically represented by the
rotary poles 29. The direct current is supplied by a source of
energy not shown in the drawings, and flows through stationary
brushes 39, which are pressed against rotary slip-rings 38.
The slip-rings 38 are rigidly mounted on the rotor shaft,
which is not shown in the drawings. The rotary slip-rings 38
are connected by conductors 37 with the rotary brushes 35
pressing against the segments of the stationary commutator 36.
The ends of the primary circuit 33 are connected with the
segments of the stationary commutator 36.  
  
The **primary circuit 33** is wound in the following
manner:  
  
**The two ends of a coil surrounding one pole 32, are
connected to adjacent segments. An adjacent end of a coil
wound around the nearest pole is connected to the same
segment, to which the nearest end of the coil carried by the
first-mentioned pole is connected. This arrangement is
repeated, so that the coils carried by the poles 32 and
forming the primary circuit 33, are interconnected in
series.****The secondary circuit 34 is wound in the following
manner:****One end of a wire is connected to a segment of a second
stationary commutator 30. Then the wire is led around two
poles back to the commutator 30 and is connected to the
adjacent segment of that commutator. Another wire is
connected to the second-mentioned segment of the commutator
30, and is again led around two poles. It will be noted that
each turn of the secondary winding encircles two poles 32.
However, each turn is situated at a distance equal to one
pole from the adjacent turn. Due to this arrangement the
beginning of one turn and the end of another turn are passed
along two sides of the same pole.**  
Rotary brushes 40 press against the segments of the stationary
commutator 30 and are connected by conductors 41 with the
rotary slip-rings 42. Stationary brushes 48 press against
rotary slip-rings 42, and are used for collecting the
secondary current.The device illustrated in **Figure VI is
used for producing a direct current having a low voltage**.
The device illustrated in Figure VII may be used when the
secondary direct current should have a higher voltage. The
same parts are indicated by the same numerals in the figures.  
  
It will be noted that the secondary circuit 44 shown in Figure
VI is wound in such a way that **each turn or coil
surrounding a pair of adjacent poles is connected to two
adjacent segments of the commutator 30. This done, because
if the voltage is small the self-induction will not have a
serious disturbing effect during the commutation of the
current.**  
  
**Figure VII** shows diagrammatically the system of **secondary
windings for generating a** **high voltage direct
current**. To prevent sparking, the commutator 46 is
divided into a large number of segments. The secondary circuit
44, consists of a number of windings surrounding a pair of
adjacent poles, each winding being subdivided into a plurality
of separate turns, the turns of the same windings surrounding
the same pair of poles. As shown in Figure VII the adjacent
ends 45 of the turns forming one winding, are **connected to
separate adjacent segments of the commutator** 46. If, for
instance, a winding surrounding two adjacent poles consists of
three separate turns, then one turn of that winding is
connected to the first and third segments of the commutator
46. The second turn of the same winding is then connected to
the second and fourth segments of the commutator 46. The third
turn of the same winding is connected to the third and fifth
segments of the commutator 46.  
  
This arrangement is repeated until all the turns of the
secondary winding are connected with the commutator 46. The
machine operates in substantially the same manner as that
illustrated in Figure VI.  
  
**Figure VIII** illustrates an arrangement used when a
series-wound field is desired. The rotor of a machine is
provided with a number of poles 47 having a pole-winding 48.
The shaft of the rotor, which is not shown in the drawings,
carries a pair of slip-rings 49 and 50, which are rotatable
along with this shaft. The machine is also provided with two
rotary brushes 51 and 52. The rotary brush 61 is electrically
connected with the slip-ring 49, while the rotary brush 52 is
electrically connected with the end 53 of the rotor-pole
winding 48. The other end 54 of the rotor-pole winding 48 is
connected with the rotary slip-ring 50. Stationary brushes 55
press against the slip-rings 49 and 50.  
  
The stationary armature comprises a number of poles 57
carrying the primary circuit 56, which consists of a number of
coils, each one of which surrounds a separate pole 57. The
adjacent ends of two adjacent coils are connected to the same
segment of a commutator 95. The secondary circuit 58 consists
of two phase-windings, each one of which comprise a number of
turns encircling adjacent poles 57. One turn, surrounding a
pair of poles forms a continuation of another turn surrounding
a pair of adjacent poles. It will be noted that the
pole-winding 48 of the rotor 47 is connected in series with
the pole-winding 56 of the stator.  
  
It is obvious that a **compound winding** may also be used
by **combining this winding in series with the winding****in parallel** described in connection with the machine
illustrated in **Figures I to V** of the drawings.  
  
This machine may be used as an **ordinary electric motor,
irrespective as to whether the windings creating the
magnetic field are excited separately or are wound in
parallel, or in series, or are compound wound. To use the
machine as a motor, the secondary circuit may be left open,
or it may be omitted altogether. The torque of this motor is
due to the magnetic pull between the poles of the stator and
the poles of the rotor.**  
  
**Figure IX** illustrates a **rotary transformer used for
transforming a two-phase alternating current into a direct
current.** The pole winding 58, which transmits the
primary alternating current, is carried by the poles 60 of the
stationary armature; two coils carried by separate poles are
connected with each other and the ends of these coils are
joined to a source of current not shown in the drawings. The
coils are wound in uniform layers, each coil having the same
number of turns. One coil carried by one of the poles 60 is
connected with another coil carried by a pole which is
situated at a distance of one-half cycle from the
first-mentioned pole.  
  
The secondary winding 61 consists of turns, each one of which
encircles two adjacent poles. The turns are connected to
segments of a commutator 62, in such a way that all turns
appear to be interconnected in series. Rotary brushes 65 are
connected with rotary slip-rings 64 carried by the rotor
shaft, which is not shown in the drawings. Stationary brushes
63 press against the slip-rings 64 and collect the direct
current passing through these slip-rings.  
  
The primary alternating current creates a revolving magnetic
field, which will attract or repulse the poles 96 of the
rotor, so that the rotor will be caused to rotate. The rotary
field of the stationary armature and the magnetic of the rotor
will produce an electromotive force in the secondary circuit
with the result that an alternating current will flow through
these windings and will be transformed into a direct current
by the commutator 62.  
  
Due to this arrangement **alternating current of a very high
voltage, for instance 12,000 volts, may be transformed into
direct current of a very low voltage, for instance 25 volts,
without the necessity of using any auxiliary devices.**  
  
The machine illustrated in Figure IX may be used as a
synchronous alternating current motor. This is accomplished by
leaving the secondary circuit open, or by omitting the
secondary circuit altogether.  
  
Instead of providing a stationary armature and a rotating
magnetic field, it is obviously possible to construct a**rotary armature and stationary magnets**. This arrangement
is illustrated in modifications described in **Figures X to
XIV.**  
  
**Figures X and XI** show a motor-generator provided with a
rotating armature carrying the primary and secondary circuits
and used for generating a three phase alternating current. The
stator 66 is provided with four elongated poles 97 carrying a
pole winding 68. The rotor carries twelve long and narrow
poles 67 provided with a pole winding 69. The winding 69 is
arranged in such a manner that the twelve poles 67 of the
rotor are divided into groups of three poles each, poles of
the same group having the same sign, although this sign is
different from that of the poles of the adjacent groups.  
  
Obviously, the number of the poles of the stator and the rotor
may be varied at will.  
  
A commutator 70, consisting of a number of segments, is
mounted on the shaft of the rotor and is rotated along with
that shaft. The pole winding 68 of the stator poles 97 may be
excited separately or may be interconnected in any suitable
manner. The primary circuit 69 carried by the rotor poles 67
is connected with the segments of the rotary commutator 70
(Fig. XI).  
  
The end of each coil, carried by a separate pole 67, is
connected to the same segment, to which the adjacent end of
the coil carried by the adjacent pole is connected. The
winding of the primary circuit 69 is substantially the same as
that of the machine illustrated in Figures I to V of the
drawings.  
  
The direct current is supplied by a source of energy not shown
in the drawings. The stationary brushes 71, press against the
segments of the rotary commutator 70. The current flowing
through the rotor-pole winding or primary winding 69, creates
a magnetic field, which will cut the lines of the magnetic
field created by the poles 97 of the stator. The resulting
repulsion or attraction will cause the rotation of the
armature.  
  
The polarity of the poles 67 of the rotor will be reversed
when the stationary brushes 71 will come in contact with other
segments of the commutator 70. Thus the rotor will be driven
steadily and continuously by the magnetic forces.  
  
The secondary circuit, carried by the rotor consists of three
separate windings 72, 73, and 74. In the course of the
rotation of the rotor, these windings will cut the lines of
the magnetic field created by the stationary poles 97, with
the result that an electromotive force will be induced in
these windings. The electromotive force will be increased by
other electromotive forces caused by the continuous changing
of the polarity of the poles 67 of the armature.  
  
Since the windings of the secondary circuit consist of three
groups situated at a distance of one third of a cycle from
each other, the current flowing through them will be the usual
three-phase alternating current. The three-phase windings 72,
73, and 74 may be joined at 76, to form a star-connection. The
current flowing through the secondary circuit is collected by
stationary brushes 98 pressing against the rotating slip-rings
75 ( **Fig.X** ), which are mounted on the shaft of the
rotor. As shown in Figure XI, each secondary winding is formed
by passing a wire twice around a group of three poles 67 and
then winding it twice around the adjacent group of three
poles. Obviously each phase winding may consist of any desired
number of turns.  
  
The electromotive forces induced in the secondary circuit are
substantially similar to those developed in the secondary
circuit of the machine illustrated in Figure I to V of the
drawings. The two electromotive forces produced by the
magnetic field of the rotor 66 and by reversing the polarity
of the rotor poles 67 are added to each other. In this machine
also there is a time, during which the electric current
flowing through the secondary circuit will have no
demagnetizing effect on the pole winding 69. This occurs when
the secondary current is flowing between poles having the same
polarity as shown by arrows in **Figure XI.**  
  
Figure XII showa a modified form of the machine illustrated in
**Figure X and XI** of the drawings. The machine shown in **FIgure
XII may be used for transforming a direct current into
another direct current of any desired voltage and amperage.**
The direct current on the primary side is supplied by a source
of energy not shown in the drawings, to a pair of stationary
brushes 80. The brushes 80 are in contact with the segments of
a rotary commutator 81. The revolving armature of this machine
is provided with a number of poles 83 carrying a pole winding
82. The pole winding 82 is divided into a number of coils,
each coil being carried by a separate pole 83. The end of each
coil is connected to that segment of the commutator 81, to
which the adjacent end of the coil carried by the adjacent
pole is connected. Due to this arrangement, the various coils
forming the primary circuit 82 are connected in series with
each other.  
  
The secondary circuit 78 consists of a number of windings
joined to the segments of another revolving commutator 79. In
the modification illustrated in **Figure XII**, **each
turn of the secondary winding encircles three poles** 83.
One end of a turn is connected to one segment of the
commutator 79, while the other end of the same turn is
connected to the second-mentioned segment of the commutator
79, while the other end of that turn is connected to the third
segment of the commutator. Stationary brushes 98 press against
the segments of the commutator 79 and are used for collecting
the secondary current. The stationary magnetic field is
indicated diagrammatically by the two poles 99.  
  
The machine illustrated in **Figure XIII is used for
generating a current of a high voltage**. This machine is
somewhat similar to that shown in Figure XII, the main
difference consisting in the use of a secondary circuit 84
wound in a different way, and in the provision of a rotary
commutator 85 having a large number of segments. The secondary
circuit 84 consists of a large number of segments. The
secondary circuit 84 consists of a large number of separate
windings, each turn of a winding encircling a group of three
poles, is joined to one segment of the commutator 85, while
the other end of the same turn is joined to the adjacent
segment of the commutator 85, while the other end of the same
turn is joined to the adjacent segment of the commutator 85.
The adjacent end of a second turn is joined to the
second-mentioned segment of the commutator 85 and then the
wire is wound around the same poles around which the
first-mentioned turn was wound. The other end of the
second-mentioned turn is joined to the third segment of the
commutator 85. The next two turns are wound around a group of
three poles, two of which are the poles belonging to the
first-mentioned group.  
  
The machine operates in substantially the same manner as that
illustrated in figure XII. The direct current of the primary
circuit passes through stationary brushes 80 and through the
rotary commutator 81 into the pole winding 82. Due to the
rotation of the commutator 81, the direction of the current
will be reversed in the course of the rotation of the
armature, with the result that an electromotive force will be
induced in the secondary circuit 84. The magnetic field
created by the stationary poles 99 will produce another
electromotive force in the secondary circuit 84, and the two
electromotive forces will be added to each other. The
secondary current will be collected from the commutator 85 by
the stationary brushes 98.  
  
**Figure XIV** shows a secondary circuit 87 consisting of
windings encircling **groups of four poles.** After one end
of a turn has been joined to a segment of the commutator 79,
the wire is passed around four poles and the other end of this
turn is joined to the adjacent segment of the commutator 79.
The end of the next turn is joined to the third segment of the
commutator 79. Then this wire is passed around four poles,
three of which were surrounded by the first-mentioned turn,
and the other end of the second-mentioned turn is joined to
the fourth segment of the commutator 79.  
  
The primary direct current is supplied from a source of energy
not shown in the drawings to stationary brushes 80, which
press against the rotary commutator 81. The current passes
through the primary winding 83 and the direction of the
current is reversed in the course of rotation of the
commutator 81. The secondary current is induced in the
secondary circuit 87 by the stationary magnetic field 99 and
the continuous reversal of the signs of the poles 86. The
secondary current is collected by the brushes 98 pressing
against the segments of the rotary commutator 79.  
  
The above-described machine may be used as an ordinary motor
by leaving open the secondary circuit, or by omitting this
secondary circuit altogether.  
  
**Figure XV** shows diagrammatically a stationary
transformer constructed in accordance with the principles of
this invention and used for **transforming a two-phase
alternating current.** This transformer is formed of
insulated soft-iron sheets 88 provided with concentric
projections or poles 89, which project towards the center of
the device. The primary circuit 90 is formed of a plurality of
uniform layers of conductors wound on each of the poles 89 and
connected in such a way that one end 91 of a coil is connected
with the end of a coil carried by a pole situated in the
opposite quadrant. The space between the poles 89 is filled by
a central part 92, which consists of laminated iron and which
fits snugly between the ends of the poles 89.  
  
The secondary circuit consists of two separate windings 93 and
94, each of said windings encircling two poles of the
transformer. The end 95 of one winding is connected with the
end of a winding situated on the opposite side of the
transformer.  
  
**Due to this arrangement, each of the secondary windings is
subjected to the variations of the magnetic flux produced by
the two-phase alternating current supplied to the primary
winding 90. Each winding is subjected to two inductive
actions of the phases. Consequently, there are four
inductions for each winding in one cycle. The efficiency of
this transformer is quite high, and this is caused
particularly by the joint effect of the overlapping
electromotive forces.**

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