US717065A - Distributing electric currents. - Google Patents
Distributing electric currents. Download PDFInfo
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- US717065A US717065A US4163000A US1900041630A US717065A US 717065 A US717065 A US 717065A US 4163000 A US4163000 A US 4163000A US 1900041630 A US1900041630 A US 1900041630A US 717065 A US717065 A US 717065A
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- phase
- current
- currents
- superposed
- transformers
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04B—TRANSMISSION
- H04B3/00—Line transmission systems
- H04B3/54—Systems for transmission via power distribution lines
- H04B3/56—Circuits for coupling, blocking, or by-passing of signals
Definitions
- phases and periods of different numbers are most suitable in relation to the separate objects.
- phases and periods of different numbers are most suitable in relation to the separate objects.
- the principle of our invention consists, in brief, in the simultaneous transformation and introduction or further transmission of alternating currents ofdifferentnumbersofperiod and phase over the conductors of a motorcircuit by means of the employment of transformers having two different kinds of inductive primary windings, which in certain circumstances can be reduced to one, and hav- 6o ing only one induced, secondary winding, and in the simultaneous transformation and withdrawal of the currents of the transformers with a primary and two secondary windings. Because the currents must be of differcut frequency and because the drop of potential of any one of the superposed currents in the conductors and transformers is independent of the drop of pote ntialof any other superposed current such a description of system for conducting may be entitled An independent polycyclic system of distribution.
- the simultaneous transformation besides lessening the cost of plant has this further advantage that however increased the total output may be the maximum in duction in the transformers can by means of a suitable choice of the superposed currents be reduced, and because of this the hysteresis loss is also reduced.
- the transformers will be correspondingly smaller.
- Figure 1 illustrates the simultaneous transformation of a three-phase current and of a superposed single'phase current by a three-phase trans- 8 5 former with magnetic return.
- Figs. 3to 5, inclusive illustrate the introduction and withdrawing and simultaneous transformation of a superposed alternating current by the transformers of the main system.
- a represents the three main conductors, and b the neutral conductor, of a three-phase system.
- the conductors a carry a superposed single-phase alternating current, the returnwire of which is formed byb.
- the four-core transformer 0, its iron frame beingshown in Fig. 2, serves for the simultaneous transformation of the three-phase current and of the superposed single-phase alternating current.
- a fourth core is necessary as a return for the fluxes produced by the superposed current.
- the three secondary conductors e serve simultaneously to carry away the transformed three-phase current and for leading out the transformed alternating current which flows back through the neutral conductor (Z. If the ratio of transformation of the three-phase current be determined beforehand, then it is made possible to make the ratio for the single-phase alternating current as large as may be desired by the insertion of windings in the neutral conductor. These windings are wound on the fourth core of the transformer.
- Fig. 3 illustrates the employment of the three one-phase transformers of a three-phase system serving as main system for simultaneous transformation and introduction of a superposed single-phase alternating current.
- fde notes the three-phase generator for the generation of the three-phase current.
- g g g are the three single-phase transformers, each of which possesses two primary and one secondary winding. Three of these primary windings, each of which belong to a transformer, are star-connected and serve to receive the three-phase current, while the three remaining primary windings are series-con nected and serve to receive a single-phase alternating current generated in the generator h.
- one 00- phase transformer which provides a magnetic return for the magnetic fluxes excited by the superposed alternating current may also be used.
- On the iron core serving as return a primary as well as a secondary winding can be wound in which flow only the superposed currents.
- Fig. 4t illustrates an employment of a fourwire three-phase system Z as main system.
- m is the four-core three-phase transformer shown in Fig. 2.
- the transformer m serves for simultaneous transformation and delivery of two currents, of which the main current serves for feeding the threephase motor 72 and the alternating current for feeding the lighting-circuit 0.
- the fourth core ofthe transformer is furnished with a primary and with a secondary winding.
- the taking off and transforming can be performed as follows: 1. By the use of four single-phase transformers. 2. By the use of two two-phase transformers with magnetic return. 3. By the use of a fourphase transformer. The lastarrangement, 3, is represented in Fig. 5. From a four-phase generator of the generating-station come the conductorst and t, which serve simultaneously as the outgoing and return conductors for the superposed alternating current. to is the four-phase transformer, 12 is supposed to be a three-wire alternating-current circuit, and 10 represents a four-phase motor.
- the secondary windings for taking off the maincurrent may each by itself be star-connected, as shown in Fig. 5. They can as well all be connected in one four-phase star; but in this case the two windings of the four-phase motor, which are displaced ninety degrees, must not be so connected as to form a neutral point.
- a suchlike star as a double two-phase star wherewith to show that to form a proper four-phase current the two two-phase stars must remain unconnected either in the transformer or in the motors.
- the taking off and transforming can be done as follows: 1. By the use of six single-phase transformers. 2. By the use of two three-phase transformers with magnetic return. Thus these must have at least four cores. 3. By the use of one six-phase transformer.
- the secondary station is by means of simple inversion made available in the primary stations for the transforming and introduction of the superposed currents, and reversely. What before was secondary then becomes primary.
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Description
Patented Dec; 30, I902.
DISTRIBUTING ELECTRIC CURRENT-S.
(Application filed. necjal, 1906.
Fig. I.
(No Model.)
Fig.3.
UNITED STATES P TENT OFFICE.
ENGELBERT ARNOLD, OLE SIVERT BRAGSTAD, AND J ENS LASSEN LA COUR, OF KARLSRUHE, GERMANY.
DESTRIBUTING ELECTRIC CURRENTS.
SPECIFICATION forming part of Letters Patent No. 717,065, dated December 30, 1902.
Application filed December 31, 1900. Serial No. 41,630. (No mod l.)
To aZZ whom it may concern.-
Be it known that we, ENGELBERT ARNOLD, a subject of the Emperor of Germany, OLE SIvER'r BRAGSTAD, a subject of the King of Sweden and Norway, and J ENS LAssEN LA COUR, a subject of the King of Denmark,
all residents of Karlsruhe, Germany, have in- Vented certain new and useful Improvements in Distributing Electric Currents, of which I0 the following is a specification.
For the different applications of electric alternating currents, phases and periods of different numbers are most suitable in relation to the separate objects. As examples,
for driving motors a multiphase current of low frequency is best. For arc-lamps and incandescent lighting a single-phase current of higher frequency is most advantageous. Frederick Bedell has already shown how these advantages are gained by means of superposing alternating currents of different frequency, while currents of different character can be introduced and withdrawn at points of equal potential of a motor-circuit, his invention being protected by Letters Patent of the United States, Nos. 645,907 and 647,741. These arrangements of Bedell by which the direct current or superposed alternating current is introduced at points of the winding of go the generators, motors, transformers, or choking-coils of the main system have the disadvantage with alternating currents that the alternating current introduced into the windings of transformers or choking-coils sustains 5 a great drop of potential on account of the self-induction of such current if the windings are not arranged without self-induction.
The method hereinafter described will serve to obviate above disadvantages without the employment of non-inductive windings,
because electric currents of different character are not introduced in one and the same wire by means of conduction, but by means of induction. This is effected by means of the superposition of magnetic fluxes in one and the same transformer. Hereby not only is the immediate end gained, but the additional advantage that the same transformer can be used for simultaneously transforming the superposed alternating current of different character.
The principle of our invention consists, in brief, in the simultaneous transformation and introduction or further transmission of alternating currents ofdifferentnumbersofperiod and phase over the conductors of a motorcircuit by means of the employment of transformers having two different kinds of inductive primary windings, which in certain circumstances can be reduced to one, and hav- 6o ing only one induced, secondary winding, and in the simultaneous transformation and withdrawal of the currents of the transformers with a primary and two secondary windings. Because the currents must be of differcut frequency and because the drop of potential of any one of the superposed currents in the conductors and transformers is independent of the drop of pote ntialof any other superposed current such a description of system for conducting may be entitled An independent polycyclic system of distribution. The simultaneous transformation besides lessening the cost of plant has this further advantage that however increased the total output may be the maximum in duction in the transformers can by means of a suitable choice of the superposed currents be reduced, and because of this the hysteresis loss is also reduced. The transformers will be correspondingly smaller.
In the accompanying drawings, Figure 1 illustrates the simultaneous transformation of a three-phase current and of a superposed single'phase current by a three-phase trans- 8 5 former with magnetic return. Figs. 3to 5, inclusive, illustrate the introduction and withdrawing and simultaneous transformation of a superposed alternating current by the transformers of the main system. 0
In Fig. 1, a represents the three main conductors, and b the neutral conductor, of a three-phase system. Besides the three-phase current the conductors a carry a superposed single-phase alternating current, the returnwire of which is formed byb. The four-core transformer 0, its iron frame beingshown in Fig. 2, serves for the simultaneous transformation of the three-phase current and of the superposed single-phase alternating current. As the alternating current flows similarly through the three primary windings, and thus produces a magnetic force which flows similarlyin the three cores, a fourth core is necessary as a return for the fluxes produced by the superposed current. The three secondary conductors e serve simultaneously to carry away the transformed three-phase current and for leading out the transformed alternating current which flows back through the neutral conductor (Z. If the ratio of transformation of the three-phase current be determined beforehand, then it is made possible to make the ratio for the single-phase alternating current as large as may be desired by the insertion of windings in the neutral conductor. These windings are wound on the fourth core of the transformer.
Fig. 3 illustrates the employment of the three one-phase transformers of a three-phase system serving as main system for simultaneous transformation and introduction of a superposed single-phase alternating current. fdenotes the three-phase generator for the generation of the three-phase current. g g g are the three single-phase transformers, each of which possesses two primary and one secondary winding. Three of these primary windings, each of which belong to a transformer, are star-connected and serve to receive the three-phase current, while the three remaining primary windings are series-con nected and serve to receive a single-phase alternating current generated in the generator h.
In the star-connected secondary windings of the transformers a three-phase and a single-phase current are simultaneously induced. Oontrariwise the two primary windings have no inductive action on each other. 1) represents the three main conductors of the three-phase motor-circuit, while 71", denotes the neutral conductor of same, which serves as return-wire for the superposed one-phase alternating current. This arrangement can be applied to a main system with whatever number of phasesfor example, 0cmay be desired, while at separate star-connected transformers are employed.
Instead of a: separate transformers one 00- phase transformer which provides a magnetic return for the magnetic fluxes excited by the superposed alternating current may also be used. On the iron core serving as return a primary as well as a secondary winding can be wound in which flow only the superposed currents.
Fig. 4t illustrates an employment of a fourwire three-phase system Z as main system. m is the four-core three-phase transformer shown in Fig. 2. In this case the transformer m serves for simultaneous transformation and delivery of two currents, of which the main current serves for feeding the threephase motor 72 and the alternating current for feeding the lighting-circuit 0.
It is here considered that the fourth core ofthe transformer is furnished with a primary and with a secondary winding.
With the two halves of a four-phase system used as main system the taking off and transforming can be performed as follows: 1. By the use of four single-phase transformers. 2. By the use of two two-phase transformers with magnetic return. 3. By the use of a fourphase transformer. The lastarrangement, 3, is represented in Fig. 5. From a four-phase generator of the generating-station come the conductorst and t, which serve simultaneously as the outgoing and return conductors for the superposed alternating current. to is the four-phase transformer, 12 is supposed to be a three-wire alternating-current circuit, and 10 represents a four-phase motor.
The secondary windings for taking off the maincurrent may each by itself be star-connected, as shown in Fig. 5. They can as well all be connected in one four-phase star; but in this case the two windings of the four-phase motor, which are displaced ninety degrees, must not be so connected as to form a neutral point. We designate in what follows a suchlike star as a double two-phase star wherewith to show that to form a proper four-phase current the two two-phase stars must remain unconnected either in the transformer or in the motors.
If in place of the two halves of a four-phase system two symmetrical three-phase systems which form together a symmetrical six-phase system are used as main system, then, similar to the foregoing, the taking off and transforming can be done as follows: 1. By the use of six single-phase transformers. 2. By the use of two three-phase transformers with magnetic return. Thus these must have at least four cores. 3. By the use of one six-phase transformer.
The method of transformation detailed for.
the secondary station is by means of simple inversion made available in the primary stations for the transforming and introduction of the superposed currents, and reversely. What before was secondary then becomes primary.
The described principle can of course be extended and include any number of systems superposed one above the other.
What we claim as our invention, and desire to secure by'Letters Patent, is-
1. In a system of electrical distribution for the simultaneous transmission of alternating currents of different character by the simultaneous transformation of alternating currents of different numbers of periods and phases, the method of winding the common conductors of the different currents on the transformer-cores so that the different currents generate independent magnetic fluxes superposed one above another which said fluxes again induce in the secondary windings independent currents of different character which currents can be transmitted farther.
2. In a system of electrical distribution for the simultaneous transmission of alternating currents of difierent character, by the simultaneous transformation of a single-phase current and of an n-phase current, the method of winding the common primary and the com mon secondary windings on the cores of n single-phase transformers and connecting in star, whereby both superposed currents can be transmitted together.
3. In a system of electrical distribution for the simultaneous transmission of alternating currents of different character by the simultaneous transformation of a single-phase current and of an "rt-phase current, the method of winding the common primary and the common secondary windings on the n-iron core of an (n+1)-core n-phase transformer and connecting in star, whereby both the superposed currents can be transmitted together.
4. In a system of electrical distribution for the simultaneous transmission of alternating currents of different character by the simultaneous transformation and superposing or division of a single-phase current and of an 'n-phase current, the method of winding the common primary windings and the secondary windings for receiving the 'n-phase current on the cores of n single-phase transformers and connecting in star, and connecting in series the secondary windings of all transformers for receiving the superposed alternating current.
5. In a system of electrical distribution for the simultaneous transmission of alternating currents of different character by the simultaneous transformation and superposing or division of a single-phase current and of an n-phase current, the method of winding the common primary windings and the secondary windings for receiving of the n-phase current on n-iron core of an (n+1)-core n-phasetransformer and connecting in star, and connecting in series the secondary windings of all cores for reception of the superposed alternating current.
In testimony whereof We have signed our names to this specification in the presence of two subscribing witnesses.
ENGELBERT ARNOLD. OLE SIVERT BRAGSTAD. JENS LASSEN LA COUR.
Witnesses FRANZ HASSLACHER, MICHAEL VoLK.
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US4163000A US717065A (en) | 1900-12-31 | 1900-12-31 | Distributing electric currents. |
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US4163000A US717065A (en) | 1900-12-31 | 1900-12-31 | Distributing electric currents. |
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US4163000A Expired - Lifetime US717065A (en) | 1900-12-31 | 1900-12-31 | Distributing electric currents. |
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