DE1025930B - Circuit for relay-controlled turnouts and signals in electrical signal boxes, especially in track diagram signal boxes - Google Patents

Description

Circuit for relay-controlled turnouts and signals in electrical Signal boxes, especially in track diagram signal boxes For the electrical operation of relay-controlled Turnouts and signals are known to be used with three-phase motors, whereby all actuating and monitoring processes are handled via four cable cores and the three-phase motor in its start-up position as a two-phase motor (T circuit), on the other hand in the intermediate position is operated as a three-phase motor (star connection).

This circuit has the disadvantage that the torque of the motor worsened with two-phase start-up and run-down compared to three-phase operation and this circuit is also not suitable for three-phase motors with low operating voltages suitable because then very strong field currents are required and the drive contacts or the contacts of the relays for the voltage cut-off due to such strong currents become overloaded. The disadvantage of one would also be undesirable result in a high voltage drop in the cables from the interlocking to the drive, as it is well known that the voltage drop is not only due to the alternating current resistance of the line, but is also determined by the strength of the current flow.

According to the invention, all of the aforementioned disadvantages are eliminated by a circuit eliminated, the main characteristic of which is that. a three-phase motor for the drive is used in a continuously resolved star connection by one on or in the drive provided symmetrical three-phase transformer is fed, its primary windings through drive contacts in the end positions of the drive two-phase and in the The intermediate position of the drive can be switched in three phases.

This measure has the advantage that on the one hand the Actuating and monitoring operation of a three-phase drive is handled via four cable cores and every voltage drop can be stepped up again in a simple manner and on the other hand also three-phase motors for small and strong operating voltages Field currents can be used.

Another feature of the invention is that instead of one symmetrical three-phase transformer three alternating current transformers in symmetry circuit be used. This measure can accommodate the transformers can be carried out more easily if there is insufficient space in the drive.

Another feature of the invention is that the star connection the primary windings of the three-phase transformer or the alternating current transformers is separated in the drive end positions that of three windings each two windings are connected in series and the third winding to the zero point the three-phase network is performed.

With these features, the three-phase transformer or the alternating current transformers can be switched in two or three phases as required.

Another feature of the invention is that the monitoring current both via all four cable cores and via all three primary windings of the three-phase transformer or the AC transformers are connected in series. Through this Measure are all cable cores and all primary windings of the transformer (s) constantly checked for operational readiness.

Another feature of the invention is that each secondary winding the three-phase transformer or the alternating current transformer, each with one field winding of the three-phase motor connected in series and the star point of these windings constantly is dissolved.

Another feature of the invention is that three-phase motors can be used for low-voltage voltages and high currents. By this measure the three-phase motor can be wound more easily.

The circuits of Figs. 1 and 2 show two embodiments the invention. Fig. 1 shows a circuit for three-phase control operation and direct current monitoring; which in its mode of operation almost corresponds to the circuit in Fig. The second embodiment differs from the first embodiment only in that on Instead of direct current monitoring, use alternating current monitoring of two additional AC transformers Trq and Ty, is provided, wherein these transformers are only used to generate the correct relay voltage and this relay voltage is rectified in a manner known per se by blocking cells will. In this embodiment, a three-phase transformer is also used three alternating current transformers F, -F, ', F, -F ,, F3 F3 provided in symmetry circuit, their accommodation in the drive, even with a lack of space, not difficult should be. Regarding the circuit of the alternating current monitoring it should be said that this is traversed by the single-phase current S = 0 of the three-phase network.

Explanation of the individual position of the switch according to Fig. 1: When the switch is positioned individually, first the contacts WTl-WT3 of the switch button and the contact WG of the group button relay are actuated, whereby the auxiliary relay P receives power and picks up its armature. Due to the closed armature contact p1, the positive monitor U is short-circuited with its high-resistance coil and the flow of current in the steeplevel detector A is increased so that it attracts its armature and the armature of the positive monitor U drops. Due to the fallen anchor of the plus monitor U , its contact aa; closed, and the switch relay SR receives power, whereby its armature is briefly attracted. This relay is designed in such a way that it changes the position of its contact rod with each brief armature tightening and switches it either from the plus to the minus position or, conversely, from the minus to the plus position. During this actuation, the voltage changer S, whose contact rod rests loosely on the armature plate of the point setting relay SR, is raised from the released basic position to the active position and held in place by a self-closing current in the coil S during the turnout circuit. With each brief armature pickup of the turnout relay SR as described above, all sv contacts and s contacts are switched over, so that four different current flows are formed in connection with the switching over of all a contacts. The first current flow is formed by the self-closing of the voltage changer S via its own contact s and holds the contact rod of the voltage changer with all of its contacts. The second current flow is formed by the contact s $ of the voltage changer S and slowly charges the capacitor C of the delay coil V of the trip relay LV via the series resistor Rv. However, this current flow causes the armature of the trigger relay LV to switch off the voltage changer S only after 6 seconds, ie whenever the normal changeover time of the drive of 3 seconds is exceeded by the same amount of time. This circuit part is a so-called motor protection circuit in which the drive motor is also switched off from the high-voltage network if the switch cannot reach the end position due to a mechanical inhibition.

The third current flow of the switch circuit is formed by the contacts s3, sy2, a4 and s4 via the primary windings F2 and F3 of the transformer Tr, one of the primary windings of the transformer Tyl for the alarm A from the phase current ST (current curve S-s3 -sy2 -Ader 3 - F2 -m2 - F3 - Vein 4 - a4 -Trl -s4 -T) . The fourth current flow is through the contacts s2, a2, syl, a1 and s5 via the primary winding F1 of the transformer Ty. formed, whereby the second primary winding of the transformer Tr, for the steep detector A from a single-phase alternating current R = 0M (current course R -s2-Tyl-a2-svl-Ader 1-Fl-ml-Ader 2-al-sS-O: IM) is traversed. The third and fourth current flow in the primary windings F1, F2, F3 of the transformer Ty3 now induce in their secondary windings F, ', F2', F, ', each with the associated field windings F1 ", F2", F, "of the three-phase motor M. are connected in series, phase currents of the same type, so that a rotating field arises in the turnout drive motor during steep operation and it starts up and in the third winding (secondary winding) of the transformer Tr, of the position indicator A, a holding voltage is induced for the position indicator A, so that its armature is induced for the time being cannot fall off.

In the first switching movement of the drive, the drive contact changes its position, so that the three-phase transformer Tr is properly connected in star and the three-phase motor is connected in three-phase operation in a resolved star connection. In this position, the two primary windings of the alternating current transformer Tr for the position indicator A are flowed through by the two phase currents R and T (current curve R- s ..- Tvl - a2- srl-wire, 1- F1 - IM, - F2 - wire 3 - sv2 -s. - S or T- s4 -Tyl - @ _ @ -Ader 4-F, -in. -F2- Core 3 -sv. - s3 - S), so that despite the oppositely wound primary windings the holding voltage remains for the steep detector A in the secondary winding, so it remains attracted. In the second switching movement of the drive, the drive contact also changes. its position, so that the star connection of the primary windings Fl, F2, F ", of the three-phase transformer Tr, is broken up again and these and their secondary windings F1 ', F,', F3 are again operated in two phases. In this position, the two oppositely wound primary windings of the Only one phase current R- T flows through the transformer Trl for the steep detector A (current course R - s ;; - Tr, - a2-srl-wire 1-Fl-inl-F3-wire 4- «4-Trl-s4-T ), so that in the secondary winding there is no longer any holding voltage for the alarm signal A. Due to its subsequent armature drop and the switching of all a-contacts, a current flow for the primary windings of the transformers Tyl and Tr2 (current curve S - s3 - sr2 - wire 3- F2 - fn2 - wire 2 -tr. - a5 - s7 - a4-Trl - s4 - T) so that the coil Lof the tripping relay is excited e of the voltage changer S drops out and switches all s-contacts over, so that the monitoring current from -} - via the position indicator A -sr2 - cable wire 3-7n2 -Kabelader2 -Minusmonitorer U - srl - cable core 1- in, - cable core 4 - choke Dr - comes about to the negative monitoring pole. Position indicator A cannot attract its armature due to the current weakened by the upstream minus monitor, whereas the winding of the minus monitor is dimensioned so that its armature is still attracted. The contacts f1 and f2 are route contacts and, when they are actuated, cause the same switching operations for the electrical switch position as the actuation of the contacts WT2 and WG for the individual switch position.

In the circuit examples in Figs. 1 and 2, a Three-phase transformer for supplying the three-phase motor through drive contacts, two-phase operated in the drive end positions and three-phase in the intermediate position, with three different currents always flow through the windings of the three-phase motor of which, however, depending on the connection of the three-phase transformer Tr., the currents two field windings of the three-phase motor can also be in phase.

The circuit can also be used in an advantageous manner for electrical operation Barrier drives are used because here very often very long distances occurrence.

Claims (6)

PATENT CLAIMS: 1. Circuit for relay-controlled turnouts and signals in electrical interlockings, especially in track diagram interlockings, characterized in that a three-phase motor (M) is used for the drive in a constantly resolved star connection, which is powered by a symmetrical three-phase transformer (TY3) provided on or in the drive. whose primary windings (F1, F2, F3) are switched in two phases by drive contacts (ml, Yh2) in the end positions of the drive and three-phase in the intermediate position of the drive. 2. Circuit according to claim 1, characterized in that instead of the symmetrical Three-phase transformer (TY3) three alternating current transformers (TY ", TY32, TYas) can be used in a balanced circuit. 3. Circuit according to claims 1 and 2, characterized in that the star connection of the primary windings (F1, F2, F3) of the three-phase transformer (TY3) or the alternating current transformers (TY ", TY32, TY33) in the drive end positions by drive contacts (Ml, m2 ) is separated in such a way that of the three windings (F1, F2, F3) two windings (F1, F2 or F., F3) are connected in series and the third winding is led to the zero point of the three-phase network. 4. Circuit according to claims 1 to 3, characterized characterized in that the monitoring current over all four cable cores as well via all three primary windings (Fl, F2, F3) of the three-phase transformer (TY3) or the AC transformers (TY31, TY32, TY ") are connected in series. 5. Circuit according to claims 1 to 4, characterized in that one of the three secondary windings (F, ', F2', F2) of the three-phase transformer (TY3) or the three alternating current transformers (TY ", TY32, TY") each have one the three field windings (F, ", F21 ', F.") of the three-phase motor (M) are connected in series and the star point of these windings is constantly resolved. 6. Circuit after the Claims 1 to 5, characterized in that three-phase motors for low-current voltages and high currents are used.