DE695013C - Arrangement for receiving alternating current surges in telecommunication systems, in particular telephone systems - Google Patents

Description

Arrangement for receiving alternating current surges in telecommunications systems, in particular telephone systems The invention relates to an arrangement for Reception of alternating current surges in telecommunications systems, in particular telephone systems, by means of a polarized receiving relay, whose armature is in the rhythm of the frequency the incoming alternating current surges oscillate.

The invention seeks the usual polarized relays as AC receiving relays avoid as these relays are expensive to manufacture. It is therefore according to Invention as a polarized alternating current receiving relay, an alternating current alarm clock used, which has the advantage of being cheap over the usual polarized relays Has.

Arrangements have already become known in which alternating current alarm clocks are designed as polarized receiving relays. In these arrangements takes place the actuation of the contacts by additional flywheels, which are from the alarm clock anchor or be pushed by the clapper in a specific end position. Thereby occurs a unilateral actuation of the contacts, which has the disadvantage that the alarm clock anchor unbalanced and thus the sensitivity of the alarm clock is reduced. Furthermore, due to the indeterminate rest position of the armature in such arrangements the relay contacts are closed continuously even after the end of the alternating current surge remain, causing incorrect switching operations. The invention avoids these disadvantages in that as a means for receiving the alternating current surges the magnet system of a conventional alternating current alarm clock is used on its magnet In addition, contact springs are arranged symmetrically to the armature axis, their Contacts alternately closed with the help of the alarm anchor when the alarm clock is activated will.

The accompanying Fig. 3 shows an example of the structural design an AC alarm clock as an AC relay. Figures r, a, q. to show 7 Examples of the use of the alternating current alarm clock as an alternating current receiving relay, namely, Figs. z, 4 to 7 a solution in which the The transmission relay controlled by the receiving relay is excited by means of direct current is, while according to Fig. a, the transmission relay is operated by alternating current.

As FIG. 3 shows, the construction of the alternating current alarm clock the same as the well-known AC alarm clocks. The two each on one Coils Sp of the alarm clock arranged in the core are connected to one another by a yoke G. On the yoke G is a permanent steel magnet in the middle between the two coils M fastened by a screw. At the upper end of the magnet M is an anchor A im Points c rotatably mounted. The armature A is given a certain by the magnet M Polarity: The opposite pole is formed in the cores of the coil Sp. The two coils Sp are connected to one another in such a way that current flows through them in series will. In this circuit of the coils, a flowing through the coils is made Alternating current alternately weakened the pole in the one coil in a known manner and reinforced in the other coil. The consequence of this is that the anchor A at each Period of alternating current attracted alternately by one coil and by the others are repelled.

According to the invention are now on the magnet M by insulating washers S arranged against the magnet and against each other insulated contact springs f, and f2. The springs are held in place on the magnet by a screw R; she are symmetrical to the axis of the alarm clock anchor over the anchor and are pretensioned so that in one position of the armature the one spring, e.g. B. f1, with the one repelled Armature arm makes contact while the contact is out of contact with the other spring the other tightened anchor arm remains. The contact is in the position shown w1 of the spring f1 in contact with the left arm of the alarm clock anchor during the contact w2 of the spring f2 is out of contact with the right alarm clock arm. When the alarm clock anchor kills; so contact w1 is opened and contact w2 is closed. Through this arrangement without giving up the indefinite rest position of the alarm clock, d. H. without impairment the sensitivity of the relay, a symmetrical loading of the alarm clock anchor is achieved. There is no preload on one of the two armature arms: because the contacts w1 and w2 are always closed only in the end position of the alarm clock arms, whereby the contact pressure occurring, indifferent; in which position the anchor is, in repulsive, d. H. beneficial sense. Furthermore, this arrangement enables a considerably higher contact pressure than with the usual AC relays. Of the Contact pressure can be made as large as that of a normal DC relay.

As FIG. I shows, an AC alarm clock according to FIG. 3, the armature of which has no particular rest position, is located at the incoming end of a line FL sealed off by a transformer as a polarized receiving relay in a bridge between the line wires. Let it be B. in the rest position, the contact w1 is closed. This creates the following charging circuit for the capacitor Co: earth, capacitor Co, contact w1, winding I of relay H, battery Bt, earth. Relay H is not energized during this condition. When the alarm clock W is excited by alternating current or by inductive current surges in alternating directions, it alternately flips its armature. If the contact w2 is closed, the capacitor Co discharges through the winding II of the relay H. The relay H responds to the discharge surge. As soon as contact w2 opens and contact w1 closes again; the winding I of the relay H is excited by the now occurring surge of the capacitor Co. The two windings of the relay H are switched in opposite directions so that both the discharge surge and the charging surge of the capacitor, which have opposite directions, always generate a magnetic field in the same direction in the relay; due to the alternating excitation of the two windings, the relay H remains that way. excited for a long time as the alternating current arriving via the line FL acts on the alarm clock W.

According to Fig. A, the relay H is not operated by direct current, but by alternating current. The arrangement is shown in the rest position, in which, for example, contact w1 may be closed again. An alternating current flow from the alternating current source WQ via the winding I of the relay H is prevented by the fact that in addition to the capacitor Co in series with the winding I of the relay H there is a rectifier GL1 in the circuit. The rectifier blocks one half-wave of the alternating current, sä that only rectified current in the. Circuit via alternating current source WQ, capacitor Co, contact w1, rectifier GLl, 'winding I of the relay H; AC power source WQ can flow. This direct current flow is blocked by the capacitor Co. However, due to the rectified current, the capacitor is charged with current in a specific direction.

If, when alternating current arrives via line FL, alarm clock W responds and changes its anchor and thereby closes contact w2, then since the rectifier GL2 in series with winding II of relay H is the opposite I-IaJbwelle des - alternating current blocks, the capacitor Co is initially charged and then charged in the opposite sense. The winding II of the relay H is excited by this current surge. As soon as contact w2 opens and contact w1 closes, the charged capacitor Co is discharged via the rectifier GLi and the winding I of the relay H and charged again in the opposite direction. This current impulse has the opposite direction as the current impulse running via contact w2. Since the winding I is switched in the opposite direction to the winding II of the relay H, the same magnetic field is always generated in the relay H by the alternating excitation of the two windings. The relay therefore remains energized as long as the incoming alternating current acts on the receiving relay P.

One . further circuit, - in which. the alarm clock can be used according to the invention, is shown in FIG. q. If the alarm clock is excited by alternating currents sent over the line; so a winding of the relay H is energized alternately by the two alarm clock contacts w1 and w2. The capacitor Co - is in the idle state. charged in the following circuit: earth, capacitor Co, point c, contact w1, point a, winding I of relay H, 'battery, earth. If the incoming alternating current closes the contact w2, the capacitor Co discharges through the winding II of the relay H. The winding II of the relay H is wound in the opposite direction as the winding I, so that the discharge surge of the capacitor has the opposite direction like the burst, generates a magnetic field in the same direction as the burst. The relay responds to the discharge surge. As soon as contact w2 opens and contact w1 closes when the alarm armature is turned over, the relay H is kept excited by the charging surge via winding I. This game is repeated as long as the alarm clock is excited by the incoming alternating current. The relay H remains continuously energized during this time.

In Fig: q. In contrast to Fig. r, the relay H is a delay relay shown. However, this arrangement does not have the purpose here of the current breaks during to bridge the throwing of the alarm anchor and thereby the drop of the relay to prevent, but it should through the applied 'copper ring' the inductivity of the relay are reduced so that the relay winding and capacitor do not form one tuned oscillation circuit, which when changing the frequency under. Circumstances must be changed. The arrangement according to Fig. Q. is thereby up to a certain conscience Degree independent of frequency. If this point of view is left out of consideration, then so An ordinary relay is also sufficient, as shown in FIG. One of those too Relay remains even at a frequency of 2o Hertz during the recording of the Alternating current is constantly excited, provided that the winding sense of the two Windings I and II are opposite; for also the falling times of an ordinary one Bridge relay. the short pauses.-during the passage of the alternating current through the zero point.

Fig. 5 shows a further circuit application of the invention. The relay H has only a single winding in the charging circuit of the capacitor via contact w1 of the alarm clock W; in the discharge circuit of the capacitor via contact w2 there is only one resistance Wi. By some 'known arrangement, such as. B. copper ring or short-circuit winding, the fall of the. Relay H is delayed. , The relay H is excited by the charging surge of the capacitor via contact w1. The capacitor Co is discharged via contact w2. - As soon as w2 opens and w1 again 'closes, relay H is again energized by the charging surge. As a result of the dropout delay, which the relay possesses will be those which occur during the opening of the contact w1 Power interruptions bridged.

6 shows the application of the invention for setting step switch mechanisms in time with the frequency picked up by the alarm clock. As the figure shows, the capacitor Co is discharged through the contact w2 and the resistor Lhi. As soon as contact w2 opens and contact w1 closes, the rotary magnet DM responds through the charging surge of the capacitor. When the contact w1 opens, the rotary magnet DM is de-energized. The 'capacitor Co discharges again via contact w2 and resistor' Wi. The game is repeated until the alternating current arriving via the line has ended. Of the. The rotary magnet responds in the cycle of the recorded frequency.

Finally- shows' the prop. 7 shows an application of the invention in which the relay H actuated via contacts w1 and w2 at twice the frequency of the absorbed alternating current responds. The relay H lies between the connection point c and the capacitor Co. As soon as the contact is closed, the relay H responds by the discharge surge of the capacitor Co. Will contact If w2 is open and contact w1 is closed, the opposite is done first directional charging surge of the capacitor, the relay H is thrown off, but speaks immediately due to the burst of charging. If now, conversely, w1 is opened and w2 is closed, so by the opposite direction of discharge the: relay becomes first again thrown off and then aroused again. This arrangement can be changed in any way use for frequency doubling:

Claims (7)

PATENT REQUIREMENTS: i. Arrangement for receiving alternating current surges in telecommunications systems, in particular telephone systems, by means of a polarized receiving relay, the armature of which oscillates in the rhythm of the frequency of the incoming alternating current surges, characterized in that the magnet system of a conventional alternating current alarm clock (W) is used as the device for receiving the alternating current surges Magnet additionally symmetrically to the armature axis of which contact springs (f 1, f2) are arranged, the contacts (w1, w2) of which are alternately closed with the help of the alarm armature when the alarm clock is activated (Fig. 3). 2. Arrangement according to claim z, characterized in that each arm of the magnet (M) of the alarm clock is rotatable mounted armature each a contact spring (f1, f2) is arranged on the magnet. 3. Arrangement according to claim 2, characterized in that a contact closure in each case between the rejected arm. of the anchor and the overlaid, whipped spring takes place. 4th Arrangement according to Claim 2, characterized in that the contact springs (f1, f2) on the permanent magnet (M) of the alarm clock by insulating washers (S) against each other and are stored isolated from the magnet. 5. Circuit arrangement according to Claim r, characterized in that the alarm clock (W) by means of one contact (w2) one winding (II) of the transmission relay (H) in the discharge circuit of a capacitor (Co) switches on and by means of the other contact (w1) the second winding (I) the transfer relay (H) in the charging circuit of this capacitor (Fig. t, 2, 4). 6; Circuit arrangement according to Claim 5, characterized in that the windings (I, II) of the transmission relay (H) are switched in the opposite sense, so that despite the different directions of the loading or Discharge surge of the capacitor (Co) always rectified magnetic fields in the relay (H) can be generated (Fig. Z, 2, 4). 7. Circuit arrangement according to Claim 5, characterized in that the charging and discharging surges of the capacitor (Co) which excite the windings of the transmission relay (H) are generated by a direct current source (Bt) (Fig.i, 4). B. Circuit arrangement according to claim 5 and 6; characterized in that the charging and discharging surges of the capacitor (Co) which excite the windings of the transmission relay (H) are generated by alternating current (WQ) whose half-waves - via the capacitor (Co) - as a result of rectifiers in series with the windings of the auxiliary relay (GL1, GI-2) different directional effects run over one winding in the one direction and over the other winding in the opposite direction (Fig. 2). G. Circuit arrangement according to Claim i, characterized in that the alarm clock (W) by means of one contact (wl) - the transmission relay (H) in the charging circuit of a capacitor (Co) and a resistor in the discharging circuit of this capacitor by means of the other contact (w2) (Wal switches on (Fig. 5). Io. Circuit arrangement according to claim z, characterized in that the alarm clock (W) by means of the one contact (w1) in the charging circuit of a capacitor (Co) the working magnet (DIM) of a stepping mechanism and by means of the other contact (w2) switches on a resistor (W ) in the discharge circuit of the capacitor (Fig. 6). For a circuit arrangement according to claim 5, characterized in that the alarm clock (W) alternates when it is actuated the transmission relay provided with only one winding (H) switches on in the discharge circuit or in the charge circuit of a capacitor (Co) (Fig. 7).