DE212197C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVe 212197- CLASS 74 c. GROUP

Patented in Germany from October 24th, 1907.

The present invention relates to a method and an apparatus for transmitting Signs, electrical currents, closing and opening circuits and the like under Use of two or more electromagnets. .

Electromagnetic signaling, calling and transmission devices have now become known in which electromagnets are also used. In these known devices, the electromagnets, which in an uninterrupted sequence - that is, without one being overturned ^: - are excited by means of a transmitter of currents that follow one another with periodically recurring differences or in some other way, serve to create an armature of any kind, which also similar to how the armature in simple electric motors or the like can have different poles, i.e. a magnetic north and south pole, to set them in rotating motion and to hold them at any point with one or between two electromagnets. As a result, the number of possible positions of the armature will correspond to the number of electromagnets or be as large again.

The essence of the present invention is that * that any electromagnets individually, be switched on, on, off or toggled together and one after the other, so that a cone-like pendulum suspended anchor a straight

• linear movement is issued from the rest position, ie it is attracted by a magnet is going to make a rectilinear movement from its normal position towards the center of attraction to be carried out, which is followed by a second at an angle to the first, which is achieved by switching on, off or toggling the electromagnet is produced. This increases the number of movement options and thus the number of positions of the anchor has increased considerably, since each is self-contained simple straight movement add two angular movements. On the The field of electrical engineering is the possibility of application because of the simplicity. Equity ■ and expediency an unlimited.

In the drawing is a device for performing the method in several Embodiments and an application are shown. It shows

Fig. Ι a front view,

Fig. 2 is a side view,

3 is a view from below of the first embodiment,

4 shows a diagram for the possible contact positions in which the armature is brought can be and which can be achieved by means of the device shown in Figs can,

Fig. 5 is a diagram for the various circuits of the electromagnets through which the positions indicated in Fig. 4 can be achieved. (The characters of this scheme can can also be used as telegraphic characters like Morse code.)

FIG. 6 shows a wiring and contact diagram which is illustrated in FIG. 5 Circuits enables

Fig. 7 is a view of a contact bit from above, '

8 is a view of the same from below, in which the contact pieces indicated in FIG are replaced by movable tongues,

9 shows a view of a further embodiment,

Fig. 10 is a section along line I-I the device according to FIG. 9,

11 shows a section along line H-II.

12 shows a device to be used as a line selector, switch or the like, partly in view, partly in the cut and

Fig. 13 is a plan view of the right part of the switch according to FIG. 12 and the bottom view of the right part rotated by 180 ° on the left.

In the embodiment shown in Fig. 1 to 3, a polarized armature 1 is suspended in a cardanic bearing 2 like a pendulum cone and held in an open ring of the central plate 3, so that 'it can move freely in any direction in a straight line and at an angle. The plate 3 made of soft iron forms part of the magnetic circuit. The electromagnets 4, 4 ^a and 5, $ ^a are arranged so that the planes which are laid by the axis of the armature and the axes of the electromagnets enclose a right angle, as indicated by the dash-dotted lines in FIG. However, this right angle is only present if the armature is held in its rest position when the magnet is not excited. The windings of the two magnets 4, / \ ^a and also those of the magnets 5, 5 "are connected in series!

The electromagnets 4 and 4 ^Λ are grounded through one line and the electromagnets 5 and $ ^a through another line. The turns of the electromagnets 4 and 4 ° connected in series are directed opposite to one another, so that when a current flows through them, a north pole is generated at the pole end \ ^b and also at the pole end \ ^c . (The south poles are in the middle of plate 3.) Similarly, turns 5 and 5 ^{a are} wound one behind the other in opposite directions. Since the armature 1 is polarized, its end is attracted by * 4, while 4 ^C repels the other end. Since the magnets 4 and 4 ^a are wound similar or similar to the pairs 5 and 5 ^fl , 4 is wound in the same direction as 5 and 4 ^a in the same direction as 5 ^a . The pole pieces \ ^b , 4 ^C and 5 * and 5 ^C consist of curved plates of soft iron, which are held on the ends of the cores by means of screws. The pole pieces are extended towards the armature and bent at right angles near it. The cores are screwed into the middle plate 3. The armature is held in its central position by an adjustable spring 6 and returned to the same after the electromagnet has been deactivated. At the other end of the cores, an end frame 10 having a central opening 11 is attached, into which the end of the anchor protrudes with a pin. A rotatable ring 12 is mounted in the opening and has an arm 13 to which a contact 14 is attached. The end frame 10 is isolated from the core by an insulation plate 15 and an insulation liner 16 through which the fastening screws pass. The armature carries at its end an outwardly projecting pin 17 through which contact with the contact piece 14 can be made when the armature is deflected in the appropriate direction. The pin 17 also carries a loose wheel 18 which is held on the partially threaded pin by a small nut 19. This wheel should prevent the armature from touching the magnetized poles and at the same time serve to reduce the friction that causes a rigid connection. When the armature is deflected by the electromagnets, the wheel rests against the inner surface of the ring 12 and rides on the same in the case of the pendulum-like suspension.

From Figs. 1 and 2 it can be seen that the Spring 6 is not directly connected to the adjusting screw, but by a loosely guided in a longitudinal bore of the screw 7 pin 21. This pin is on a its ends equipped with a hook 22 on which the spring engages while it has a head 25 at its other end, the diameter of which is greater than that of the hole going through the screw. This arrangement is a tensioning of the Spring completely excluded by twisting.

Instead of the one contact point, 24 can be provided with which the pin 17 can be brought into contact (see embodiment FIGS. 7 and 8), or it can but also the contact piece 14 by rotating the ring 12 in each of the 24 positions are brought, which are represented by the, scheme (Fig. 4).

First, the way in which the armature moves should be briefly described and the pen is achieved. The one made of soft iron, for example

When the electromagnets 4 and 5 are excited individually, the armature is attracted in the direction of the same, when both are excited at the same time in the direction of the resultant of the two from Forces exerted by the individual magnets. This will make three straight movements generated. If now, after the two magnets excited at the same time, the armature is in have brought the middle between the two magnets, one or the other magnet switched off or off, the armature is removed from it by the magnet that remains excited Position after a radial movement to one side or the other in tangential Direction distracted. The anchor describes the sequence of magnetic effects an angled path. So far, five different movements have been created. If further 4 a

ao switched and a little later 5 added, the armature initially moves to 4 and then after 5, since the force of 4 is added to that of 5. This will again creates an angular movement of the armature. When the magnet 5 and When the magnet 4 is subsequently switched on, the armature of 5 is first attracted and then distracted after 4. So it is when using two magnets and one non-polarized anchor made of soft iron 7 different movements possible.

In FIG. 4, the points labeled b represent the stops K according to the embodiment of FIGS. 7 and 8 and the points α and c represent the contacts which can be achieved by the tongues L (FIG. 7).

Taking into account the scheme according to FIG. 4, the

1. Movement by energizing the electromagnet 4. The non-magnetized armature Soft iron is thereby attracted by 4 and moves to 30 *. the

2. Movement of the armature takes place by energizing the magnet 5, whereby the armature 17 is moved to 28 *. The .

3. Movement takes place by energizing the electromagnets 4 and 5, whereby the armature 17 is moved to 29 *. the

4. Movement takes place by energizing the two electromagnets 4 and 5, whereby the Armature is moved to 29 *, whereupon the magnet 4 is switched off, so that only the magnet 5 remains in action. Through this the anchor is moved from 29 * to 29 ^. the

5. Movement takes place in that the two electric magnets 4 and 5 are excited, whereby the armature 17 is moved to 29 *, whereupon the electromagnet 5 is switched off and only the electromagnet 4 remains in action. The anchor has "covered the path 17, 29 *, 29 ^C. The

6. Movement takes place by exciting the magnet 4, whereby the armature 17 is moved to 30 *, whereupon the electromagnet 5 is also excited, whereby the armature is moved from 30 * to 3O ^a . the

7. Movement takes place by energizing the electromagnet 5, whereby the armature 17 is moved to 28 *. Then the electromagnet 4 is still excited, whereby the armature 28 * is moved to 28 ^C.

So there are three straight movements from 17 to 28 *, 29 * and 30 ⁶ and four angular movements from 17 to 28 ^C , 29 ", 29 ^C and 30 ^a . The anchor thus leads to three straight and four angular movements, i.e. together seven different movements. '

However, these seven movements can also be achieved with the use of four electromagnets can be increased to 24. If the anchor is polarized, combinations of the forces of attraction and repulsion the magnets, which are created by diverting the current with one and the same pole of the magnets 24 movements are also possible. This should also be on hand 4 will be explained.

In the diagram, the lines 25 *, 25V 25 ° etc. to 32 ^C on the circular disk 24 indicate the 24 positions in which the pin 17 is to be moved and in which contacts according to the embodiment of FIGS. 7 and 8 are located.

It is assumed, however, that the adjustable contact 14 is used for the explanation. The same should be located at point 2, j ^a , after which the armature is to be moved with the pin 17. For this purpose, such a current is first sent through the lines that the pole 4 * of the magnet 4 repels the armature and the pole 5 * of the magnet 5, which is also excited, attracts the armature. But since the magnets 4 and 4 "as well as 5 and 5 ^Λ are wound in such a way that poles of the same kind appear on the pole pieces \ ^b , 4 ^C and 5 *, 5 ^C , the upper part of the armature 1 is held by the magnet 4" attracted and repelled by the magnet 5 ' ^1. Various forces then act on the armature tending to move the armature and the pin 17 firstly in the direction of the arrow χ - by repelling the magnet 4 and attracting the magnet \ ^α - and secondly in the direction y - by the Attracting magnet 5 and repelling magnet $ ^a - to move. Since two forces act on it, the anchor is moved in the direction of the resultant, i.e. its lower end in the direction of the arrow ζ to point 27 *. The pen must take this direction because the forces acting on the lower end and the

forces acting on the upper end are equal to each other. The attraction force of the magnet 5 on the lower end of the armature for movement in the direction y corresponds to the attraction force of the magnet \ ^a on the upper end of the armature in the opposite direction of the arrow ■%. The repulsive force of the magnet 4 acting in the direction of this arrow χ on the lower end of the armature is also equal to the repulsive force of the magnet 5 'on the upper end of the armature in the direction opposite to the arrow y. If the magnet 5 no longer remains excited, i.e. is switched off, the armature is no longer attracted by 5, so that the armature is now only influenced by the force of the magnet 4: The armature will therefore move from point 27 * move in a parallel or approximately parallel direction to the arrow χ , whereby it comes into contact with the contact piece located at 27 ". In the explanation of the movement according to 27" it was shown by the way how the pin is brought into position 27 *, namely through Exciting the magnets 4 and 5 in such a way that 4 repels the armature, while 5 attracts the same.

If the contact 14 is at 28 ^, then ' to make contact at this point, magnet 5 is excited so that pole 5 * attracts, while the magnet 4 remains de-energized. This causes the pen to follow immediately brought the contact piece.

When the permanent contact is at 28 ^C , the pin is brought to point 28 * in the manner already mentioned, whereupon the magnet 4 is excited so that pole 4 ^{b is also} attracted. The magnet remains 5 * like. so far excited. Two forces then act on the pin or anchor, one in the direction of the arrow y, the other in the direction of the arrow v. The pin will move in the direction of the resultant of these two forces, ie w in the direction of the arrow, thereby bringing it 28 ^C in contact with the contact.

Similarly, if contact is to be made at 28 ^Λ , the pin is first brought to point 28 * by exciting 5 to attract, while magnet 4 initially remains de-excited, whereupon pole 4 * is excited to repel and pole 5 * still remains excited to attract, whereby the pin 17 is brought to the contact 28 ^a .

When the contact piece is at 25 *, both poles 4 *, 5 * are excited to repel, so the poles 4 ^C and 5 ^C exert an attractive force, so that the pen moves to the desired point.

When the contact is at 25 ^, will. the pen, as just described, brought to point 25 * and then switched off 4, i.e. the effect of the magnet is canceled. If the pin is then influenced by the magnet 5 alone, it is moved to the contact 25 ^a .

If the contact were at 32 *, then 5 * is excited to repel while 4 remains unexcited. This brings the pin to contact 32 *. If the contact is to be at 32 ° ^C , the pin is moved after point 32 * in the manner already mentioned, whereupon 4 is excited to repel, while 5 remains excited to repel, so that the pin is forced to move to 32 ^ to move. These examples should make it perfectly clear how the pen can be brought into any of the 24 positions shown.

In the above explanation only the magnets 4 and 5 and not 4 ^a and 5 ^{a are} mentioned; However, these serve to support and supplement the effect of magnets 4 and 5.

A line leads from the insulation frame 10, which carries the contact piece 14 after a connector. A second connector is with the metallic frame connected to the device, whereby the electrical connection to the pin 17 is established will. The ends of the circuit, which includes a local battery and the instrument, are routed to the two terminals. which is to be influenced contains.

The switch shown schematically in FIGS. 5, 6 and illustrated in FIGS. 12 and 13 is used to implement the various circuits of the magnets. The poles of the battery B are connected to the parts C ¹ , C ² , C ³ , C ⁴ and D ¹ , D ² , D ³ , D ¹ , which are intended to be fixed in the scheme, but in the embodiment of the switch according to FIG 12, 13 are movable. Movable springs F ¹ , F ² , F ³ , F * are provided between the four switch plates A ¹ , A ² , A ³ , A * and parts C and D , which are connected to parts E ¹ , E ^% , E ³ , E ^{1 of} a switch E, are conductively connected. The device with the armature suspended in the manner of a conical pendulum is connected to the terminals G ¹ and G ² by means of the wires α and b , the turns of which are connected in series are earthed at a suitable point. The battery is also connected to earth in the middle. On the switch plates A ¹ to A ⁴ , approaches made of insulating material i are on both sides, through which the spring contact pieces F ¹ to F ⁴ with the contacts C ¹ to C * and D ¹ to Z) ⁴ in Beruh-. tion can be brought. The contact is brought about by the bored switching plates A ¹ to A ⁴ · by a pin 5, which is guided through a fixed plate P provided with bores B ¹ , to the positive or negative side.

be pushed, since the bores of the switch plates are partly to the right and partly to the left from the center axes of the bores S ^{1 of} the plate P , while a part lies in the center axes.

By the scheme shown in Fig. 5 are

i. the positions of the holes in the various panels A ¹ to A ^{1 are} determined,

2. The order and direction of the currents to be sent into the electromagnets or their polarity is determined and

3. Illustrated the movements of the anchor.

From the diagram of FIG. 5 it can be seen that the 24 characters provided with -f and - are not identical to one another and consequently also provide 24 different current sequences or current patterns which are possible through the bores after the plugging has taken place. The single image or characters 1 to 24 is divided into four parts by the x and y axes, so that the parts form the four quadrants of a circle, so to speak. The first row from 1 to 12 corresponds to the four upper rows of holes c, d, e, f of the switch plates A ¹ to A ¹ and the second row from 13 to 24 corresponds to the lower rows of holes g, h, i, k of the switch plates A ¹ to A. ⁱ . If there is a line in one of the quadrants, this means that the switching hole has been shifted from the central axis of the fixed plate P. The sign - \ - or - indicates the side to which the hole must be shifted. If a quadrant is empty, it can be seen that the switching hole has not been shifted. The characters above the λ; -axis correspond to the bores of row c and d, those below those of row e and f, those on the left of the y- axis belong to rows c and e, while those on the right belong to rows Rows d, f belong. The character 1 is z. B. expressed that the holes in rows c and d must be shifted to the right in the sheets A ¹ and A ² to connect the contacts on the positive side C ¹ and C ² , while the holes in Α ^Ά and A ^A (Fig. 6) must be in the middle, since under the # axis at 1 (Fig. 5) there are no details (heavy lines), so the quadrants are empty. After inserting the plug S through the hole 1 of the fixed plate P , the sheet A ¹ with A ² is shifted to the left by the plug 5, whereby contact is made at F ¹ , C ¹ and F ² , C ² , while A ³ and A * remain in their normal position, as the holes e, f are in the middle at 1. No contact is made with the sheets A ³ and A *. Correspondingly, position 6 shows: A ¹ not shifted, while the other three sheets make the positive connection. Therefore the hole in A ^{1 is} in the middle and in 4 ² to A ^ shifted to the right.

Position 21 means: In the lower four rows g, h, i, k there is a hole in A ¹ to the side of the sheet metal giving the positive contacts, i.e. shifted to the right, in A ² in the middle and in ^ ³ and A ¹ shifted to the left so that contact is made on the negative side after stopping.

The plus and minus signs indicate the polarity or the direction of the current to be sent into lines a, b , while the longer and shorter lines represent the sequence of the individual currents when switching the switch / on and off.

The upper row of lines, i.e. the line χ above the dash-dotted line, represents the current directions to be given with the contacts E ¹ , E ² , while the lower row shows the current directions to be given with the contacts E ⁸ and Zs ⁴ . The four quadrants therefore correspond directly to the contact fields E ¹ , E *, E ³ , E * of switch I.

From these considerations it can be concluded that the rows of holes

c and g in A ¹ for E ¹ ,

d and h in A ² for E ² , ■ β and i in A ³ for E ³ and
/ and k in A ⁴ · for E ¹ .

From the representation of position 1 (Fig. 5) it can be seen that first of all, the metal sheets A ^λ and A ^{2 are} moved to the left by the plug inserted into the bore 1 and thus contact between F ¹ and C ¹ and between -F ² and C ^{2 is} produced while the sheets A ³ and A * remain in their central position, since no information is given below the x- axis for offsetting the bores or current pulses. If the changeover switch / the current of the battery B is switched on, E ^{1 is} conductively connected to G ¹ and a positive current is sent through the line α (there is a plus sign in the quadrant E ¹ , FIG. 5), while no through the line δ Current goes because below the x- axis and to the left of the y- axis, i.e. in quadrant E ^3, no current pulse is recorded and A ^{3 has} not brought any contacts into contact on either side due to the central position of hole e ¹ . The current course is as follows: Battery B, pole P ¹ , positive main line, contacts C ¹ , F ¹ , line a ¹ , contact Έ \ sliding terminal G ¹ , line a, winding W ¹ , W ² , earth via pole P ² back to the battery. Then ■ the switch I is thrown so that the sliding clamps on the contacts 2? ² and ⁴ pounds on meet. The course of the current and the currents

direction remain the same in the «line, while line b remains de-energized. So it is in the current sequence after position ι of FIG. 5 a straight movement

■ 5 movement of the armature achieved from the center directly after the axis of the electromagnet.

According to position 2 (Fig. 5), when the current is switched on through the switch I, while it is on E ¹ and E ³ , a positive current is first sent through the line «, whereupon after the switch is switched to E ² and Z? ⁴ a positive current is also sent through the line b , while the positive current continues to flow through the line, since the connection of the battery is established through the contact piece £ ⁴ and the switching device. In this circuit, a straight movement is first generated from the central axis of the armature to the central axis of the electromagnets Tf ¹ , Tf ² , since a force is exerted on the armature, whereupon the armature is switched on by connecting the electromagnets Tf ³ , W ⁱ it is already on the periphery of the guide ring, executes a tangential movement, since in addition to the action of the first pair of electromagnets, a second pair of electromagnets also exerts its force on the armature. The following contacts are connected by plugging 2: C ¹ with F ¹ , C ² with F ² · and C ⁴ with i " ⁴ .

I. Current curve after switching on:

1. Line «connected through E ¹ , P ¹ , positive line, C ¹ , F \ a ¹ , E ¹ , G ¹ , a, Tf ¹ , Tf ² , earth, P ² , battery,

2. Line b de-energized.

II. Current curve after switching:

i. for the α-line as under 1 after switching on remained,

2. P ¹ , positive lead, C ⁴ , F \ b ² , E ¹ , G ² , Tf ⁴ , W ³ via earth and pole P ^{2 back} to battery B.

From position 16 it follows that all four superimposed metal sheets A ¹ to A ⁱ are pushed to the right by plugging, so that all of the right contacts F ¹ to i ^{74 are} connected to the negative contacts D ¹ to D ⁴ and the battery B. are. After switching on the switch I , the contact pieces E ¹ , E ³ are first connected to the lines a, b by the slip spring G ¹ , G ² . So it works

I. after switching on a current
i. from pole P ² of battery B via earth to W ² , Tf ¹ , a, G \ E \ a \ F \ D \ P ³ , battery.

At the same time a strem also goes through the line b, and it runs as follows:

2. P ² , earth, Tf ³ , Tf ⁴ , b, G ² , E ³ , b ¹ , F ³ , D ³ , negative lead, P ³ , battery.

II. After flipping the switch is through the contacts E ² , E ^ and the connections of the contacts D ² , Z) ⁴ with the contacts F ² , F * the current in the same way through the lines α and b and thus also through the Sent electromagnet, so that there is no further movement of the armature, since the effect of both magnets on the armature remains the same.

Through the interaction of two magnets the armature will make a movement, which is the resulting of the two individual movements.

The position 21 accordingly means that a positive current first passes through the wire, while a negative current is sent through the wire b and then, after switching over, the current in is switched off while it remains in b.

After plugging the holes 21 namely the switching plate A ^{1 is} moved to the left, so that the spring F ^{1 is} connected to C ¹ . Switching plate A ² remains in its position, so it does not connect the contacts. The switch plates A ^s and A ⁱ are shifted to the right, thus making contact between F ³ and F ⁱ and the negative contact ^{pieces D 3} and Z) ^{4 of} the battery. After switching on, the current curve is as follows: ■ ·

I. After switching on:

1st line: P ¹ , positive lead, C ¹ , F ¹ , a ¹ , E ¹ , G ¹ ,, Tf ¹ , Tf ² , earth, P ² , battery.

2. Line b: Pole P ² , earth, Tf ³ , Tf ⁴ , b, G ² , E ³ , b ¹ , F ³ , D ³ , P ³ , battery.

With this circuit, the current does not run through earth, but through the four windings Tf ¹ to Tf ^{4 connected in series} .

II. After switching:

1. Line «de-energized, as no contact is made ^{through sheet metal 2.}

2. Line b current course as under 2 before switching.

When the magnet is switched off, the armature is drawn towards the magnet that is still working. It therefore first finds a movement of the anchor from the central position to the center between two magnets, whereupon after switching off the armature after the still acting Magnet is attracted. This creates the angular movement.

The characters 1 to 24 clearly show which movement makes the anchor in the individual circuits. A single long one or two long ones Lines indicate a straight line movement, with a single line tracing the movement the electromagnet, while the double lines of equal length indicate the straight line resulting motion between two

Claims (6)

Indicate electromagnet. The remaining characters, which contain short dashes, represent angular movements, either from the electromagnets or from the resulting position. For the first movement, there is a sign in the first or third quadrant, while there is a sign in each of the second and fourth quadrants. In the second type of movement, the position of the ίο characters in the quadrants is reversed. The embodiment of the switch shown in FIGS. 12 and 13 is used to produce the twenty-four possible deflections of the armature shown in FIG also makes the necessary circuits. After turning the switch lever, the current is sent through the windings for the second movement of the armature in the required direction, or it does not change after moving the switch if only a straight movement is to be generated. From FIGS. 12 and 13, the explanations relating to FIGS. 5 and 6 and the reference symbols, the construction of the switch can be clearly seen. In Fig. 7 and 8, a contactor is shown, in the middle of which the pin 17 of the device is in the rest position. If current is now sent through the electromagnet, the armature with the pin 17 moves either in a straight line to the contact points K or to the movable tongues L, which by the second movement of the armature, which forms an angle with the first, in contact with the Contact pieces M are brought. The individual local circuits are connected to the contacts K, M. If more than twenty-four positions are to be achieved, when two of these electromagnetic devices according to the present invention cooperate, 24 * 24 = 576 and when three devices interact, 13824 different positions are possible. The method of the present invention can be used in ordinary and wireless telegraphy and telephony, in the transmission of characters (typewriters, shorthand), in signals and the like. 9, 10 and 11 show a further embodiment of the device for carrying out the method in which the pairs of electromagnets are offset by 90 ° from one another, the poles of one pair of electromagnets always being in the vicinity of the magnetic connection of the cores of the other pair lie. By shifting the electromagnets against each other, the two force line fields that occur are better used, since the armature can now be suspended in the middle between the four electromagnets like a pendulum cone. Godfather ν τ claims: 1. Method for either displaying or making contact by means of two or more Electromagnets or pairs of electromagnets, characterized in that one cone-like pendulum suspended armature by energizing one of the electromagnets or electromagnet pairs or joint excitation of several of the same a straight movement and then after moving in, out or switching the current as a result of inoder disabling certain electromagnets or electromagnet pairs are given a second movement forming an angle with the first. 2. Embodiment of the method according to claim 1, characterized in that the gimbal-mounted, polarized armature by the excited electromagnets or electromagnet pairs in the radial direction only tightened or initially tightened radially and then repelled tangentially or attracted or initially radially repelled and tangentially attracted or repelled, so that by combining or successions of single or compound magnetic effects either a simple straight line or a compound angular motion can be performed with the armature can. 3. device for carrying out the method according to claim 1, characterized in that that an anchor (1) is cardanic in its center or in its center of gravity is stored and that the electromagnets or electromagnet pairs grouped around the same are connected in series and are wound in such a way that the free poles of the common core of each pair of magnets are homopolar when energized are. 4. Device for carrying out the method according to claim i, characterized in that that horseshoe-like electromagnets, offset from one another by 90 °, ι to one cardanic in the common central axis surrounded by mounted, polarized armature and are located in such a way that the poles of a horseshoe magnet are one end of the armature and the poles of the other electromagnet affect the second end of the armature. 5. Embodiment of a contact device for carrying out the method according to claim 1 and 2, characterized in that on a disc between fixed contacts movable tongues lying, which moves to one side or the other due to the action of the anchor making contact with the connection line or closing a local circuit. 6. Embodiment of a switch for switching the current for the method according to claim ι and 2, characterized in that several in a known manner Sheet metal lying one on top of the other and equipped with partially offset holes after plugging and the resulting displacement establish such connections, that the switched-on current remains the same after the switch is flipped or moved further, or that currents are added or be switched off or switched, for the purpose of the anchor according to claim ι and 2 of a single one or of two successive simple or compound ones To influence currents and so a simple rectilinear and a compound achieve angular movement. For this purpose ι sheet of drawings.