DE63481C - Electric device for generating movement - Google Patents

Description

IMPERIAL

PATENT OFFICE.

The patent no. 54089 protected device is based on its fundamental nature on the following phenomena:

1. A magnetic needle is pushed through one in the direction from the South Pole to the North Pole is influenced by the current flowing through it in such a way that the north pole of the needle turns to the left, the south pole moved to the right (Fig. 1 of the accompanying drawing). The left side of the live wire is thus south polar and 'the right north polar.

2. If the current flows from the center of the needle to both sides through a conductor arranged above the needle (Fig. 2 of the accompanying drawing), the current tends to deflect the north pole to the left. The half of the wire towards the south pole is north polar on the left and south polar on the right. If the magnetic needle can be rotated about an axis χ χ running in the same direction as it, it will be shifted to the left.

. ,. Ah '' the direction of movement described Nothing is changed now when the current goes over the two poles and against the Flows back in the middle of the needle (Fig. 3). It is sufficient here if the electricity only has the surrounds one pole of the needle in the specified manner.

The same movement will also occur if there is a current path between two with

a common axis of rotation connected magnetic needles, which have their unlike one another Turn the poles (Fig. 4). If you arrange several wires next to each other that: are all traversed by the current in the same sense, they produce in theirs Overall effect of poles on the two outer wires.

If you now put a pole formed in this way to the pole of the same name of a freely movable one Opposite the magnetic needle, the latter is repelled by it and through the wire layers attracted through it by the pole of the same name on the wire layers (Fig. 5). Here you can have a number of concurrently next to Replace the wires lying on top of one another with a conductor with an approximately rectangular cross-section.

Fig. 6 shows that the above-described current paths, which the Nordbezw. Influence the south poles of a magnetic needle, consider them to be parts of three solenoids can. These solenoids, which can consist of one or more turns, have the same polarity as the corresponding current paths considered above and therefore work individually or together in the same way on a magnetic needle. In the way it works nothing is changed if the three solenoids merge into a single one, which is the one in the lower half of Fig. 6 has the shape shown.

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What has been said about magnetic needles in the foregoing naturally applies to exactly the same In the way of electromagnets or solenoids, which replace the magnetic needles.

One could also arrange that the magnets and the current paths are fixed move without changing the essence of the present invention.

If you now put together a number of current paths on a circle and they are based on a system of solenoids or electromagnets with a common axis of rotation works, one can see a constant rotation of the solenoid or electromagnet system reach. However, since several wires arranged close to one another only generate poles on the two outermost wires, so must the individual current paths through which currents flow in the same direction be arranged at a certain distance from each other so that free poles can arise.

Such devices have been shown in FIGS. 7-10. Figures 7 and 8 show the same in view, while FIGS. 9 and 10 show the devices in section demonstrate. In Fig. 7 and 8 only one half of the current paths has been shown.

In Fig. 7 and 9, a number of the described current paths through which the current flows in the same direction α respectively. of the corresponding solenoids in a circular arrangement and at certain distances from one another and continuously connected to one another. In this way, a number of free poles η s, η s, and one on its circumference with one of the number of current paths respectively. of the solenoids the same number of electromagnets e occupied disk r is sleichnamiser respectively by the repulsion.

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Attracting dissimilar poles rotated up the dissimilar poles by electromagnets and current paths respectively. Solenoids face each other.

Through this rotation a second system of electromagnets e attached to the disk r is switched on in such a way that poles of the same name of electromagnets and current paths are opposite each other, while the previously active system of electromagnets is switched off.

The solenoids or electromagnets of one system are midway between those of the other system. Both systems always receive electricity alternately, and this can be done by means of any commutator. As soon as the second electromagnetic system is switched on in the circuit, the magnet wheel r is again caused to rotate. As a result, however, the first electromagnetic system is switched on again in the circuit, and by repeating the same game, a continuous rotation of the electromagnetic wheel is brought about. When using solenoid current paths through which the current flows in the same sense, it does not matter whether the poles acting on an electromagnetic pole in the same direction of rotation belong to the same or to two neighboring solenoids. When using such solenoid current paths, the direction of rotation of the wheel r depends on whether the total width of the current paths is more or less than half the circumference of the circle described by the electromagnet. In FIGS. 8 and 10 a very similar device is shown as in FIGS. 7 and 9. The difference, however, is that here the adjacent current paths are traversed by the current in different ways. In this case, a series of poles ns, ns ... In order to achieve a continuous rotation, the two systems of electromagnets respectively. Solenoids that alternately bezw. the corresponding solenoids are compared to change their polarity from current path to current path. This can be achieved in a very simple manner by means of a suitable commutator, by means of which the direction of the current in the electromagnet windings is changed from current path to current path. However, if four electromagnetic systems are arranged, which come into effect one after the other, it is not necessary to change the polarity of the electromagnets belonging to a system.

Of course, in FIGS. 4, 7 and 8, two or more solenoids can also be used at the same time respectively Electromagnets of two or more systems influenced by the same current path will.

Is the device described as an electricity meter are used, an electromagnetic brake can be used on the same in the. In a way that one can

ι. When using a disk with magnet systems without changing poles, the upper and lower halves or even only one of these two halves of the electromagnet are surrounded on one or both sides by a closed copper cylinder k and thus a damping of the rotation of the wheel r is achieved by induction currents (here the two Copper cylinders connected above or below the magnetic poles and covered on the outside with iron jackets), or

2. when using a double row of electromagnets, which are unlike one another Turning the pole, attaching a metal cylinder between the double row, or

Claims (1)

3 · when using electromagnetic systems with pole change resp. Electromagnetic systems acting alternately in a four-stroke cycle, the electromagnets (or solenoids) surrounded by metal cylinders m, Fig. 8, the circumference of which is cut open so that the resulting electromotive forces of induction add up. The inhibition produced by the arrangement of the metal masses described is different from the previously known inhibitions very substantially; in the latter there is a part of the lines of force generated by the magnet only to produce movement and the other part is used only for the inhibition. In contrast, in the present case, each line of force acts both moving and at the same time inhibiting. By the rotating electromagnets in the fixed metal cylinders The eddy currents generated cause the speed of rotation of the magnetic wheel becomes proportional to the respective current. Godfathers τ-claims ρ ρ odor: i. The patent no. 54089 protected electrical device for generating movement in the special embodiment that the current paths (a) are arranged in a circle at a certain distance from each other, the same on two, three or four sides of the solenoids respectively. Electromagnets (e) with a common axis of rotation (b) can act and the current flows through them as individual or group windings in such a way that the direction of the current in the currents acting on the north poles is opposite to that in the currents acting on the south poles.
The patent no. 54089 protected electrical device for generating movement in the special embodiment that paired solenoids or electromagnets face each other with their unlike poles, and that between these solenoids or electromagnets there are the current paths starting from their indifferent zones or running in the same direction (Fig. 4 ). The patent no. 54089 protected electrical device for generating movement in the special embodiment, that the solenoids respectively set in rotation by electromagnetic interaction. Electromagnets themselves generate eddy currents in neighboring fixed metal masses without the aid of special electro or permanent magnets, which have an inhibiting effect on the movement caused by the electromagnetic interaction. 1 sheet of drawings.