DE1105451B - Circuit for preferably lane-wise adjustable points u. like - Google Patents

Description

Circuit for switches and the like that can be set preferably on a route. The invention is concerned with circuits for preferably street-wise adjustable Switches and the like with switch group monitoring in railway security systems. In such cases, in which often several points circulate at the same time, exist the danger, d, ate in the event of failure of the control voltage due to overloading of the power supply facilities or for other reasons some switches remain in the middle position. Without special Measures would immediately affect the control voltage when it returns to everyone in the central position standing points be switched through, which is because of the high starting currents of the drive motors in the. in most cases lead to an immediate renewed failure of the control voltage would. This occurs especially when a weaker backup network, an emergency converter or similar auxiliary power sources have been switched on.

For these reasons, in the event of a control voltage failure, the other The process of walking around the street was prevented, and the guard had to go to that Return of the withstand voltage the not yet completely circulated turnouts individually rearrange. However, if such turnouts are changed individually using the turnout buttons, so, when you press the button for the first time, you return to the previous starting position back, and the desired new end message is only activated by pressing it again reached the switch buttons. Through this. there is not only an unnecessary loss of time, but such operating actions no longer appear logical either; just this should a, be avoided because the said. Operating actions not occur frequently, so that the keeper cannot control them through constant habituation; In addition, these operating actions are usually required precisely when anyway due to the failure of the power supply the company: bsa.blauf an increased Attention needs to be paid.

About the mentioned disadvantages of changing the individual points by hand To avoid as possible, it is known to provide an overcurrent switch that after failure of the mains voltage and switching to the reserve unit only in those Cases and then makes the manual adjustment necessary, in which coincidentally At the moment of the power failure, more point machines are running than the reserve unit are beneficial.

In another known arrangement, one looks for the overload of the Reserve aggregates and those then required; Manual changeover of each By doing this, switch points should be avoided as far as possible in the event of a power failure and the entry into force of the Reserve aggregates no longer have several turnout groups as in the normal changeover process at the same time, but switching on another group of points from the coast the point machines are made dependent.

The invention shows another way of using simple means to avoid the disadvantages mentioned, which is also in contrast to the known approaches can also be used to advantage with weakly designed emergency converters, since when the point machines are automatically switched on again after a power failure only enables a single turnout to be switched on within a turnout group.

According to the invention are in Stellspannungsausfa.ll during the Changeover process of any turnouts in a group to the control voltage lines the motors of the rotating point machines within the point machine circuits interrupted and these interruptions successively only for a single, Soar in each jointly monitored group in such a way that the restart of a switched off in the group monitoring during the cycle Turnout drive is controlled via the common monitoring line and that for the restart of the other point machines that have not reached the correct end position all point machines connected upstream in the group monitoring the have reached the correct end position and are monitored again in this position. It is advisable to restart the switch drives that were switched off during the cycle controlled by the fact that the power supply to the quiescent current monitoring line in the event of a control voltage failure polarity is reversed. The special requirements of the short-term switchover a full replacement power supply can be taken into account, that if the control voltage drops during the changeover, the control voltage lines are interrupted occurs with a time delay and the changeover process recurs within this time Control voltage is continued immediately. Generally one expects one Switching time to the fully-fledged substitute network of 200 milliseconds. Within this For a short time, however, the drive motors do not come to a standstill, and it kicks in when the replacement power supply comes into effect, there is still no significant increase in the switched on again.

After further invention of each of a group monitoring summarized switches a changeover in such a manner in a quiescent current monitoring line turned on, that this line to ziz a group monitoring relay switched through only when all tightened monitoring relays of the different points from the beginning of the line, on the other hand even at only a fallen switch monitoring relay from The beginning of the line is switched to the associated switch switching device. The polarity of the common monitoring line is expediently reversed until it is switched through again via all contacts of the monitoring relays to the group monitoring relays.

About the priority of manual switching of points over route-wise Maintaining joint conversion is another feature of the invention prevents the automatic continuation of interrupted standing processes of all switches, as long as the turnout group key is pressed. According to the further invention useful as a switching device to prevent the continuation of changeover processes that have already started, for switching the group monitoring, for the sequential connection of the turnouts, for group and network monitoring and / or for the turnout group keys the already used for existing and other purposes relays and buttons.

In the drawing is a possible embodiment of the invention shown. In the lower left part it contains any setting and Monitoring circuit for a three-phase controlled point machine with four cable cores between signal box (above the dash-dotted line) and drive (below the dash-dotted line); in the right half of the drawing are some for Switching the point machine on and off required relays are shown, and in In the upper part the drawing contains the switching means of the group monitoring as well the connection of the individual switch circuits provided according to the invention of group surveillance.

The actual control and monitoring circuit contains the connections of a three-phase network R, S, T and a direct current source 4 and -, also a collision alarm relay b17.4 with the contact W.4 1, the resistor Wä 1, a rectifier Gr and a Transformer Tf- with three windings 1-2, 3-4 and 5-6. Another relay W Ü 1 is used to monitor whether the switch is in one of its end positions. The on / off part contains a backup relay WL 1 with two windings I and 1I and, the contacts TV L 11 (in the monitoring circuit), tYL12, bVL13 and bJ'L14 and another backup relay bI7L2 with two windings I and 1I and the contacts WL21 (in the monitoring circuit), WL22, bVL23 and WL 24. Furthermore, two relays WP and bIr \ 'are shown with their contacts WP 1 to WP7 and WN1 to WN? 4, of which the contacts WP1 to bFP3 and bb'N1 to TYNN3 are in the control and monitoring circuit. In the circuit of the relay WP there is also a contact WA 2 of the relay WA, in the circuit of the relay WN there is another contact WA3 of this relay and in the circuit of the relay WL 1 there is a contact WÜ12 of the relay. WÜ1 arranged. The circuit of the relay WI4NT is provided with a capacitor Ko 1 and a resistor Wi2, and finally contacts WT 1 (in the monitoring circuit) to WT 5 of a switch button relay (not shown) are shown.

The drive part contains the three windings L ', L', W of the drive motor as well as an auxiliary winding H of this motor and the two end position monitoring contacts AK + and AK- controlled by the drive. These two contacts are also marked in a position corresponding to the plus position of the switch: when switching to the minus position, the contact AK-I-flips when the switch leaves the plus position, while the contact AK- flips when the "'calibrates the minus position achieved.

A group monitoring relay WG (` with a contact WGU1 and a group auxiliary relay @ t, 'GH with contacts WGH1 to WGH3 is shown in the upper part of the drawing. There is also a contact in the circuit of the relay WGH W NÜ 1 of a network monitoring relay, not shown. The thin line in the circuit of the relay WGU represents the group monitoring line in which the individual contacts WÜ11, WÜ21, WÜ31 etc. of the point monitoring relay are switched on. The thin-dashed lines indicate that any number further monitoring contacts of other points can be included in this line; the two strongly dashed lines lead to the circuits (not shown) of points W 2 and W3, which are otherwise constructed in exactly the same way as the illustrated circuit of points W 1. In the group monitoring line is also a break contact WGT a turnout group top button or a button relay of this button is shown.

In the basic position shown, the Clx monitoring circuit is via contact WT 1, relay WA, resistor Wi 1, contacts WN 1 and W1_ 11, line 1, contact AK -E-, auxiliary winding H, line 2, contact WP 2, end position monitoring relay W Ü 1 , Contacts WP 1 and WL 21, line 3, contact .4K-, motor windings h and W, line 4 and contacts WN2 and WP 3 switched through, and the relay Wi` 1 is attracted, while the relay WA, which is opposite the relay WÜ1 is low-resistance, only has fault current flowing through it and cannot attract. The relay WA normally acts as a collision detector; If the switch is opened in the drawn end position, the end position contact AK + lives and the relay WÜ1 is switched off by this contact, so that the relay WA can now attract via the folded contact AK + and the motor winding Ü. The resistor Wi 1 acts as a protective resistor for the relay WA. This change in the switching state can be registered as an opening message in circuits not shown. Contact WÜ 11 of the monitoring relay. W IU 1, which is located in the group monitoring line, is, like the contacts WÜ21 and W (731 of the other turnouts, in the position shown, and it is the group monitoring circuit via contact WGH3, group monitoring relay WGÜ, contacts W (31, W1721, WÜ 11 , WGT, WGH2 and resistor Wi3 switched through. In this circuit the relay WGZ` is picked up and its contact WGÜ1 in the circuit of the relay WGH is open.

When a turnout changeover is initiated, either by pressing the turnout buttons or in the case of joint turnout switching on a route-by-route basis, the individual switch switch relay is operated in a circuit not shown, its contacts TT'T 1 and WT 5 open, WT 2 and WT 3 closed and WT 4 switched will. With the contact IVT 1 the described monitoring circuit is interrupted, and the relay WÜ1 drops out, changes its contact WÜ11 and closes its contact WÜ12. The winding I of the relay WL 1 receives power via the contacts WT2, WP 4, WA'4, WC'12 and WL 22, attracts its armature, thus lifting the support of the armature of winding II and causing it to drop. The contacts WL 11 to WL 14 are switched over against the position shown. The relay WP is switched on via the now relocated contact WL13, the contact WL23 of the relay WI_2 and the previously relocated contact WT 4 , which relocates its contacts TYPE 1 and WI '2, WP 3 and WP 4 opens and WP 5 to WP7 closes. The capacitor Kol is connected to DC voltage via contact WA3 and resistor Wi2 and is charged.

The switching status that has now been reached remains as long as the button relay is energized. Will the turnout; If the buttons are released again or if all the switches have recorded the changeover indicator for the route changeover, the button relay drops out again and the contacts WT 1 to WT 5 return to the position shown. The supply for the relay WP is interrupted by the contact WT 4; however, the relay is provided with a sufficiently high dropout delay so that it initially remains activated. The winding I of the support relay WL 2 is switched on via the closed contact WT 3 and the previously closed contact WP5 as well as the folded contact WL 12 , and this support relay is also switched over, with the contacts WL21 to WL24 being folded against the position shown. The relay WN is now connected to voltage via the contacts WA 3, WP 6, WL 14 and WL 24 and picks up. Its contacts WN1 and WN2 are switched over, WN3 closed and WN4 opened. As a result of the switching of the contacts WN 1 and WIV 2 , a partial control circuit is created between the three-phase phases R and T, namely via the contacts WN 1, WL 11 (switched), line 3, contact AK-, windings h and W, line 4 and Contact WN2; in the process, a voltage is induced in the winding 5-6 from the winding 3-4 of the transformer Tr, which, via the rectifier Gr, pulls the relay WA , which closes its contacts WA 1 to W.4 3. With the contact WA 1 a second current path for the drive motor is established, namely from the three-phase phase R via the contacts WN1 and WP2, line 2, auxiliary winding H, drive contact AK +, line 1, contacts WL21 (flipped) 97P1 (flipped) and WA 1; this creates a voltage in the winding 1-2 of the transformer Tr which differs in phase from that in the winding 3-4, so that the relay WA remains energized via the winding 5-6 of the transformer Ty. The contact WA 2 has established the self-closing circuit of the relay WP running via the contact TT'P7, and this relay thus remains excited. The delay time of the relay WP is chosen so long that the previous interruption time is bridged in any case. In addition, the contact WA 3 has opened and the relay W1 \ 'has been switched off from voltage and switched on to the charged capacitor Ko 1 .

As a result of the creation of the two circuits via the auxiliary winding H or the windings T7 and W , the drive motor has started in two phases. The AK + contact has switched over, the auxiliary winding H has been disconnected and the winding U, which in turn is connected to the other two windings T 'and W at the star point, is connected to the three-phase S phase. As a result, the full torque comes into effect in the drive motor. The currents in the windings 1-2 and 3-4 of the transformer Tr are now shifted against each other by 12Q °, and the relay WA remains held.

When the new end position is reached, the contact AK- sets uin against the position shown and switches the three-phase phase R via the contacts W N1 and WL 11 and line 3 from the winding T 'to and from the auxiliary winding H. By disconnecting the winding 1%, a single-phase current is created between phases S and T via winding 1-2 of transformer Ur, contacts W-4 1, WP 1 and WL 21, line 1, contact AK -I -, windings U and W, line 4, contact WRT 2 and winding 3-4 of the transformer Tr. The two windings 1-2 and 3-4 are connected to one another; ice occur in them two currents phase-shifted by 180 °, so that no more voltage is induced in the winding 5-6 and the relay 9'A drops out. When the contact WA 1 opens, the single-phase circuit just described is also interrupted; the contact WA2 also opens the self-closing circuit for the relay WP, so that this drops out after its delay time has elapsed and its contacts WP1 to WP 7 return to the position shown. The contact WP 6 also interrupts the previously still effective excitation circuit for the relay WN, which also drops out and resets its contacts WN1 to WN4. The adjustment process is finished and via contact WT 1, relay TVA (not picked up due to fault current), resistor Wi1, contact WN 1, contact WL11 (flipped), line 3, contact AK- (flipped), winding H, line 2, contact WP 2, relay WÜ1, contact WP 1, contact WL21 (flipped), line 1, contact AK + (flipped), windings U and W, line 4, contacts R'N2 and WP3 again monitoring current flows through which the end position monitoring relay W ( 71 attracts, puts its contact WÜll back into the position shown and opens its contact W Ü12.

If the control voltage fails during the circulating process due to the interruption of phases R, S and T, the relay WA initially drops out because the winding 5-6 of the transformer Tr no longer receives any voltage. The opening contact WA2 interrupts the holding circuit of the relay WP. This relay has a drop-out delay of such a size that with a brief switchover to a fully-fledged backup network within about 200 milliseconds, the relay WP does not drop out, so that its holding circuit is maintained via the contact WA2 until this contact is re-energized as the relay WA via the transformer Tr closes again. Since the relay WN had not dropped out until then and the relay has now picked up again, will. the changeover process continues immediately.

However, if the control voltage failure lasts longer, e.g. B. because a switch to an emergency converter has to be made or for other reasons, the relay 11'P drops after opening the contact WA 2 with a delay and opens its contact I1 "P6, whereby the relay WN drops. Only now returns the withstand voltage again, the power supply to the point machine is interrupted by the contacts 1i: 1 "1, WN2 and WA1, which have moved back into the position shown. The voltage that has returned cannot initially bring about any change in this switching state that has now occurred.

According to the invention, the turnout drive is switched on again in the following way: When the network fails, the contact WN Ü 1 of the control voltage network monitor (not shown) has closed and has thereby caused the group auxiliary relay li'GH to attract, which closes its contact ti'GH 1 and the contacts WGH2 and II'GH 3 assigned. When the point changeover was initiated, the group monitoring line was interrupted by the connection of contacts WÜ 11 as well as W Ü 12 and il- ('31, and the group monitoring relay WG (' had dropped out and had its contact l1'Gi''1 closed via the closed contacts: II'G ('1 and WGH 1 a self-closing circuit has been formed for the relay WGH, which remains in place until all switches have reached the desired end position and the group monitoring relay 13 "G (' picks up again. 'By means of the Contacts Ii'GH2 and iilGH3, the supply lines to the group monitoring line have been reversed, so that the plus potential of this line is now applied to the relay iVP via the contacts Ti-GH 2, bi% GT, W ('11 (flipped) and WT 4) and this again With the first switch in the group monitoring circuit, as here with switch i1'1, it is also possible that the relay WP of this switch does not drop out if these last-mentioned switching processes take place sufficiently quickly . so that the changeover process can be continued immediately when the control voltage returns. All of the following points in this group are, however, initially prevented from continuing the changeover process. The switching process of the switch i1'1 now continues normally, as previously described, until at the end of the switching process the monitoring relay W ('1 of this switch picks up again and thus its contact II'('11 is returned to the position shown the positive potential placed at the beginning of the group monitoring line via the contacts WGH2 and IYGT is applied to the circuit (not shown) of the switch W2 via the covered contact Ti-L '11 and the contact WC 21, which is opposite to the position shown, so that there now the Relay 117P is energized again and the continuation of the changeover process of this switch can also be initiated. However, this only takes place if this''oak is also not yet in the desired end position; if, on the other hand, this is already the case, contact 1' is present. (I21 again in the position shown, and the positive potential from the beginning of the group monitoring line is passed on via contact WC-21 to contact W Ü 31 and can, if necessary, initiate the continuation of the changeover of this switch as well.

The support relays WL1 and WL2 remain in the previously set position when continuing an interrupted changeover process, in contrast to the continuation of a changeover process using the switch buttons, in which case these support relays would first be reset. Nevertheless, it is possible to switch individual points using a switch button, because the connection to the group monitoring line is disconnected by switching the contact WT 4 in the circuit of the relay WP and the switch switching is initiated as described above. By activating the turnout group key and opening the WGT contact, the automatic restart of the other turnouts is initially interrupted; the individual key operation is therefore always preferred, and it cannot happen that in addition to a turnout that has to be individually switched, other turnouts can start up by means of the described automatic reconnection. The automatic reconnection also allows only a single switch to be switched on, so that the circuit according to the invention can also be used to advantage with weakly designed emergency converters.

If all switches in this group have reached the desired end position, the group monitoring circuit is switched through via contacts 117GH2, WGT, W Ü 11, W U21, W Ü 31, relay WG (', contact WGH3 and resistor Wi3 WG (T picks up, opens its contact WGÜ 1 and thus interrupts the self-closing circuit of the relay WGH, which drops out and resets its contacts WGH2 and WGH3 to the position shown, thus reversing the polarity of the group monitoring line.

The invention is not limited to the illustrated embodiment; Above all, it can be used with any turnout drive and monitoring circuits can be used together.

Claims (7)

PATENT CLAIMS: 1. Circuit for preferably: route-wise adjustable turnouts and the like with turnout group monitoring in railway safety systems, characterized in that in the event of a control voltage failure during the changeover process of any turnouts in a group, the control voltage lines to the motors of the revolving point machines within the point drive circuits are interrupted ( Contacts WA 1, WN 1 and WA- 2 open) and these interruptions are canceled one after the other for a single turnout in each jointly monitored group in such a way that the restart of a turnout drive that was switched off in the group monitoring during the cycle (e.g. 11'1, relay Wül dropped out) is controlled via the common monitoring line and that for the restart of the other point drives (ii'2 or W3) which have not reached the proper end position, all point drives connected in the group monitoring system (111 or W 1 and W2) have reached the correct end position and are monitored again in this position (e.g. B. Relay WÜ1 picked up again). 2. Circuit according to Claim 1, characterized in that the power supply to the quiescent current monitoring line polarity is reversed in the event of a control voltage failure (using contacts WGH2 and WGH3). 3. A circuit according to claim 1, characterized in that at: control voltage failure during the Ums.tellvorgangs the interruption of the Stellspannungsleitungeu occurs with a time delay (by means of drop-out delay of the relay WP) and the changeover process within this time (z. B. the switching time to a backup network ) recurring control voltage is continued immediately. 4. A circuit according to claim 1, characterized in that a changeover contact (W Ü 11, W Ü 21 and W Ü 31) is switched on from each of the switches combined to form a group monitoring system (with relay WG (7)) in such a way that this The line is only switched through when the monitoring relays (e.g. WÜ1) of the individual points are activated from the start of the line to a group monitoring relay (WGÜ), but when only one point monitoring relay (WÜ1) has dropped out from the beginning of the line to the associated switch switching means (relay WP via contact WT 4 ) is switched. 5. Circuit according to claim 1 to 4, characterized in that the power supply remains reversed until the monitoring line is switched through again via all contacts (W Ü 11, W Ü 21 and W Ü 31) of the monitoring relay to the group monitoring relay (WGÜ) is. 6. Circuit for preferably adjustable by route Switches and the like with switch group monitoring in railway safety systems, in particular according to one or more of the preceding claims, characterized in, that the automatic continuation of interrupted switching operations prevents all turnouts is as long as the turnout group key is pressed (contact WGT open). 7. A circuit according to one or more of the preceding claims, characterized in that the switching means for preventing the resumption of started changeover processes, for switching the group monitoring, for the sequence connection of the switches, for the group and network monitoring and / or for the switch group key Existing and other-purpose relays and buttons can be used. Considered publications: German Patent Specifications No. 810 997, 871 314, 850463.