DE261278C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 261278 CLASS 2Oi. GROUP .30.

SIEMENS & HALSKE AKT.-GES. in Berlin.

for railway signal systems.

Patented in the German Empire on December 15, 1911.

In the case of railway signal systems with mercury contact and insulated rails, the vehicle is driven on the insulated rail through the mercury contact the circuit for a relay closed, which in turn prepares the circuit for a second relay. This second Relay receives power when the last axis has left the isolated rail and releases then a switching process off (e.g. free -

ίο would give a block key). To be sure achieve that the second relay receives power only when a larger number of power surges is released, the relay influenced by the mercury contact becomes a multi-leaf relay Given anchor, which is switched jerkily by the current surges of the mercury contact is, so that he only after a large number of current surges in the contact position for the circuit of the second relay

ao is coming. This working method of the multi-leaf anchor, of which always two wings before two Magnetic poles are, is achieved according to the invention in that the two in the rest state Magnetic poles are excited by a permanent magnet in such a way that one acts more strongly on the armature than the other and attracts it, while by closing an electric current at the mercury contact the both magnetic poles are magnetized so that one is weakened and the other attracts the anchor, whereby the anchor again "assumes the relative starting position and at Interrupting the current through the permanent magnet is switched on again.

In a frame (Fig. 1 to 3) four magnets I to IV are attached, between their Poles a star consisting of six lamellas is rotatably arranged. The left, through The hatched side of the frame is a permanent steel magnet that is attached to the May have south magnetism at the lower end and north magnetism at the upper end. He could go through too a constantly energized electromagnet can be replaced. The remaining parts of the frame as well as the magnetic poles, and the star are made of soft iron. The lower side of the The frame has an incision at 1.

The magnetic poles I to IV are designed so that they oppose a lower resistance at the ends e β to the magnetic lines of force passing through the star than at the tips ss (FIG. 1).

The whole system is initially de-energized, which should be indicated by opening the mercury contact 6 in the circuit of the battery α , and the star should assume the position shown in FIG. Due to the permanent magnetism of the rod 2, magnet II becomes a strong south magnet, magnet I a weaker north magnet as a result of the long iron path; likewise magnets III and IV become weak

North magnets. The polarities of the magnets are indicated by the letters N and S in FIG.

Under the influence of the magnetic effect, the lamella 3 (Fig. 1) moves Star from the tip 4 to the end 5 of the pole I and goes into the one shown in FIG Above, because in this the lines of force on their way have the lowest magnetic resistance Find.

If the mercury contact 6 is closed, then by the dropwise flow of Mercury caused direct current surges. Such a surge of electricity may just happen when the star is in the position shown in FIG.

The magnets I and II are wound so that in the assumed direction of the Direct current generated at magnetic pole I, south magnetism, at magnetic pole II, north magnetism will. So at the moment of the current connection it becomes the only weak north magnetic one Magnet I a south magnet, while the magnetism at magnet II is canceled, i.e. = 0 is. Magnets III and IV retain north magnetism. The polarities are in Fig. 2 specified.

As a result, the lamella 7 moves from the tip 8 to the end 9 of the pole shoe I. At the same time, the lamella 10 comes to the tip 11 of the pole shoe II and assumes the ready position of the lamella 3 shown in FIG The effect of the permanent magnet results in a further rotation of the star by ¹ ^ _{2 of} its circumference in the clockwise direction. As a result of this further movement when the current is interrupted, the readiness position shown in FIG. 2 for the current surge that now follows is reached again for the next lamella. When the contact 6 is alternately opened and closed, the star rotates continuously in the clockwise direction until a contact is closed by the star for a relay to release the block button after a large amount of power surges. The star can be connected to a colored disk and its rotation can be limited by a stop.

The rotation of the star back to its original position can initially take place on any Way done mechanically. But it can also be done electrically by alternating current, that by the windings of the magnets, which are also wound in different directions III and IV is sent. The movement of such a system with alternating current is known per se; However, it is only possible if there are two opposite PoI pairs same name, d. H. for the present case, if I and II south poles and III and IV Are north poles. This equivalency is created according to the invention by the fact that during the flow of the alternating current is an auxiliary current (direct current) solely through the magnet I. is sent (Fig. 3). The polarities shown in FIG. 3 then arise.

If the block button 12 (Fig. 3) is pressed down and the inductor 13 is rotated, alternating current flows from the inductor 13 via the push rod contact 14, the windings 15 of the block magnet into the turns of the magnets III and IV and from there via the long-distance line at any point back to earth or to the negative pole of the inductor. At the same time, a direct current flows from the battery α through the windings of the magnet I via the connection 16 to the push rod contact 17 and to earth. This auxiliary current generates the required south magnetism in pole I, so that the alternating current enables the star to rotate counterclockwise. . ■

Instead of releasing a block key, you can also z. B. interrupt the current in the signal dome magnet and thereby stop the signal place. In general, the circuit arrangement can always be used when a magnet give a signal or a switching operation only after a large number of power surges should trigger.

Claims (4)

Patent Claims: 1. Device for jerky switching of a multi-wing magnet armature in the case of railway signal systems with mercury contact and insulated rail, of which two wings are always in front of two magnetic poles stand, characterized in that of the rest by a permanent magnet If both magnetic poles are excited, one acts more strongly on the armature than the other and attracts it until through Close an electric current at the mercury contact, the two magnetic poles be remagnetized, d. H. one is weakened and the other attracts the anchor, so that the anchor again the assumes relative initial position and is advanced again by the permanent magnet when the current is interrupted. 2. Device according to claim 1, there- • characterized in that the permanent magnet forms a yoke on two opposite sides carries magnetic poles and on one side between two Magnet poles is interrupted. 3. Device according to claim 1 with switching back the armature by alternating current, characterized in that the a part of the magnetic poles is excited by alternating current and always changing gets the same polarity, while the other part is partly due to the permanent magnet, is partly excited by direct current and also only has a single polarity. 4. Device according to claim 3, characterized in that by pressing down the block rod of an electrical block field the alternating current and at the same time also the auxiliary direct current closed will. 1 sheet of drawings.