DE197060C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- M 197060 CLASS 7Aa. GROUP

is driven.

Patented in the German Empire on April 5, 1907 .

The invention relates to an electric signal bell, the clapper of two Electromagnets (or solenoids) are driven, each for one direction of oscillation acts and the shifting device adjusted by the oscillating parts alternately in action be set.

The invention aims at this

ίο to regulate the activity of the magnets so that the change of which coincides as far as possible with the reversal of movement of the clapper regardless of the speed of the The clapper oscillation takes place so quickly that the direction of movement with the Clapper-connected magnet armature counteracting attractive forces are avoided. For this purpose, the switching device is connected to a tensioning mechanism that is operated by tensioned in both directions of rotation and during the movement of the bobbin by means of a locking device also activated by the lace factory in the cocked state State held, but is triggered in the end positions of the clapper. This makes it possible to use the switch in the appropriate Moment regardless of the slowed movement of the when changing direction To change the lacework at great speed and such a sudden change to bring about the magnets.

In the drawing, an embodiment of the invention is at four different Positions of the drive device shown.

Inside the bell 1, a housing 2 is arranged that the drive device for the clapper 3 encloses (Fig. 1). The clapper can swing around a shaft 4 and connected to a double-armed lever 5. In the lower part of the housing 2 there are two solenoids 6 and 7, whose movable anchor cores 8 and 9 by rods 10 and 11 with the ends of the double-armed Lever 5 are articulated. The anchor cores 8 and 9 are so to the Solenoids 6 and 7 arranged so that they are drawn into the latter from below. Above of the lever 5 is arranged a shift lever 13 rotatable about the axis 12, which is connected to its upper, free end carries a contact spring 14 and according to its two directions of rotation through tension springs 15 and 16 with the corresponding arms of the Lever 5 is resiliently connected. A locking rail 17 is also attached to the shift lever 13 hingedly connected in their bearings 18 and 19 according to the two directions of rotation of the shift lever 13 is linearly displaceable.

The anchor rod 11 is extended upwards beyond the point of application of the lever 5 to approximately the level of the locking rail 17 and carries a locking piece 20, against which a locking piece 21 seated on the rail 17 rests. Both locking pieces are attached to their rods and designed in such a way that they move in the directions of their rods, unimpeded by them, with their two

side surfaces can yorbeibeschommen each other. To in case of inaccurate location of the locking piece 21 to prevent the up and down movement of the rod i 1 avoid, are the upper and lower edges of both locking pieces, as shown in Fig. 1 to 4 can be seen, beveled parallel to each other, so that the locking piece 21 from the locking piece 20 is always pushed into the correct end position '.

This also ensures that contact is always made reliably. . : '. .

The line 22 coming from one pole of the power source is connected to the. Gear lever 13 connected, while the line 23 leading to the other pole, each with one end of the two solenoids 6 and 7 is connected. The other end of the solenoid 6 is standing through a line 24 with a contact piece 25, the corresponding end of the solenoid 7 through a line 26 with a contact piece 27 in connection. The contact pieces 25 and 27 are on both sides the contact spring 14, such that when the shift lever 13 swings back and forth are alternately touched by the contact spring 14.

The mode of operation of the device described is as follows:

If the bell is in the rest position shown by Fig. the external circuit is closed, the current flows from the line 22 via the Shift lever 1.3, the contact spring 14, the contact piece 25 and the line 24 through the solenoid 6 and the line 23 back to the power source, whereby the solenoid 6 its anchor core 8 upwards into itself-

. pulls, as shown in Fig. 2, while the armature core 9 of the electroless solenoid 7 is lowers. As a result, the double-armed lever 5 is rotated clockwise, and the clapper 3 swings to the left. This is done using levers 5 and 13 attached tension spring 16 tensioned, which now seeks to pull the shift lever 13 to the right. However, the latter is prevented from this movement in that the locking piece 21 of the with it connected rail 17 lays against the locking piece 20 of the rods. At the However, if the rod 11 connected to the armature core 9 falls, the locking piece slides 20 down on the locking piece 21, and as soon as the contact between the two locking pieces stops, the spring 16 can pull the shift lever 13 to the right, as shown in FIG. Through this if the contact spring 14 is brought into contact with the contact piece 27, so

· - ■ * that now the line 26 and the solenoid 7 be switched on in said circuit while the solenoid 6 is de-energized has become. As a result, the armature core 9 is drawn into the solenoid 7 and the drive device for the clapper in the opposite sense, the. clapper itself so .moves to the right. These processes take place shortly before the clapper Bell mantle touched. Therefore, at the moment of the attack, he is already under the pulling it back so that it is quickly withdrawn from the bell mantle. As a result, a short stop is achieved even with slow clapper movement.

As soon as the back oscillation of the clapper occurs (FIG. 3), the locking piece 20 is lifted again and finally guided in front of the rear surface of the locking piece 21. Here, the switching lever 13 and the locking bar 17 are under the tensile force of the spring 16 until the double-armed lever 5 has reached its horizontal central position. As soon as it exceeds this, the spring 15 is tensioned. However, since the locking piece 20 has in the meantime stepped in front of the locking piece 21, the locking rail 17 and thus the switching lever 13 are prevented from following the tensile force of the spring 15. This can only happen when the locking piece 20 has slid up past the locking piece 21, that is to say to the right shortly before the end of the clapper oscillation, as shown in FIG. 4. Then the switching lever 13 flips over to the left, whereby the solenoid 6 is switched on again in the circuit, the solenoid 7, on the other hand, is de-energized, and the entire process described is now repeated.

As can be seen, the springs form 15 and 16 together with the locking pieces 20 and 21, a tensioning mechanism that prevents the current during sustains the entire period of oscillation of the clapper and shortly before the Vibration reversal is a quick flip of the shift lever and thus a sudden one Switching the solenoids. causes.

Instead of solenoids, electromagnets with a fixed iron core can also be used. Likewise, the number of electromagnets located on each side can be arbitrary be. So z. B. horseshoe magnets or corresponding pairs of solenoids can be selected.

Claims (3)

Patent Claims: I. Electric signal bell, whose '-clapper powered by two electromagnets or solenoids, each of which acts for one direction of oscillation and that through one of the back and forth vibrating parts adjusted switching device alternately put into action are, characterized in that the switching device is operated by a pulled tensioning mechanism is converted, which is also carried out by the lacework in Activity set locking device held in the tensioned state during the clapper oscillation, in the end positions of the lacework is triggered. 2. Electrical signal bell according to claim I, characterized in that the changeover switch (13, 14) by two tension springs (15 and 16) with a double-armed The lever (5) of the lacework is flexible and connected in an articulated manner to a longitudinally displaceable locking bar (17), which the latter carries a locking piece (21) that is connected to the bobbin lace mechanism and alternately by this locking piece (20) which is moved back and forth is blocked on both sides until the end of the respective clapper oscillation. 3. embodiment of the electrical signal bell according to claim 1 and 2, characterized characterized in that the locking pieces (20, 21) on their mutually movable Edges beveled like a wedge in the sense of their respective direction of movement are, for the purpose of avoiding a mutual hindrance of the locking pieces and to ensure reliable contact formation. 1 sheet of drawings.