DE3638681A1 - Device for remote-monitoring rotary-current points drives - Google Patents

Abstract

In order to monitor the two possible drive limit positions, two current direction-sensitive indicators (PPU1, PPU2) are provided which are connected in parallel with one another via exclusion contacts (WL/5, WL/6) of a running-direction selector. A direct voltage monitoring source (60V = ) conducts control potential to the two indicators via the rotary current lines (L1 to L4), the motor windings (W1 to W3) of the drive and its limit-position contacts (AK1 to AK4) if the drive (A) assumes one of its limit positions. In this process, a pole-turning changing switch (WL/1 to WL/4) which is connected into the adjustment and monitoring circuit and has the purpose of prescribing the respective running direction of the drive ensures that the phase position of the control potentials fed to the inputs of the two direct current indicators is the same in both drive limit positions. If the contacts of the running-direction selector switch at the wrong time, the phase position of the control potentials fed to the direct current indicators changes, the fault which has occurred being detectable from the switching state of the indicators. <IMAGE>

Description

The invention relates to a device according to Preamble of claim 1.

Such a device is known from E-PS 00 52 759. There is a facility at an electronic position plant for dining and remote monitoring of over four lines three-phase switch machines reported, in which the star point connections of the motor windings from the drive Controlled end position contacts are provided, via which the motor windings when closing switch contacts on the rotary power supply can be connected. After rotating the drive and reaching the new end position includes an over two of the four end position contacts, the three motor windings and the Four three-phase lines led monitoring circuit for a DC-powered switch monitor. This monitor is excited when the switch takes one of its two end positions, the control current is switched off and the DC monitoring voltage is activated. The monitor to detect the turnouts The end position is in series with two ge in the monitoring circuit special monitors to identify the respective situation the soft. The switch position monitors react above them assigned diodes or via exclusion contacts one Direction selector on the monitoring currents. The usage of contacts of a direction selector in the connection or Short circuit of the switch position monitors instead of diodes should have the purpose of the functional behavior of the running direction to check voters. If the direction selector did, however due to a disturbance, d. H. without an adjustment process was initiated, changes to the other position, so the wrong turnout position monitor then activated, for the observer, however, the position is not recognizable as such drawing issued. The remedy is here - as in the E-PS 00 52 759 specified at the end of the description - an arrangement with diodes assigned to the position monitors and two separately  ten, over the exclusion contacts of the direction selector end position monitors. The position monitors serve Identification of the actual state of the monitored switch and the End position monitor to identify the respective target closing befitting. By comparing the actual and target status mel mishandling of the direction selector determine.

The object of the invention is to provide a device for remote transmission wake up from four-wire described three-phase turnout drives specify the preamble of claim 1, with a Malfunction of the run specifying the target position of a switch direction selector with a minimum of circuitry Effort and procedural evaluation of monitoring mel can be reliably recognized.

This task is characterized by the characteristics of the Claim 1 solved. A particular advantage of the inventor Invention device is seen in that an almost Ineffective switch position monitoring is possible and that the Full-size DC monitoring voltage on each activated switch position monitor is available.

Advantageous training and further developments of the invention Facility are specified in the subclaims. So allow the features of claim 2 when opening the drive Trigger a turnout report via the message and via guard circles for the switch position reports without this in addition to the indicator required for this, any additional Licher switching means in the drive circuit required. After the Features of claim 3 are the indicators used in advantageously as a current-controlled process level converter to train directly to the entrances of a subordinate Neten data processing device can be affected. Your inputs are in accordance with the features of claim 4 to form part of the way as light-emitting diodes of optocouplers.

The invention is based on one in the drawing illustrated embodiment explained in more detail. The  Drawing shows in three figures the circuit of a four-wire operated three-phase turnout drive together with the means for remote monitoring of the drive. In the drawing are a individual monitoring and signaling circles through thicker lines optically highlighted. In the

Fig. 1 highlighted monitoring and reporting circles serve the turnout location in the one in

Fig. 2 highlighted monitoring and reporting circles of the turnout location in the other location and in

Fig. 3 highlighted alarm and surveillance circles serve to identify a turnout report.

The individual switching means are designated identically in FIGS . 1 to 3. The actual switch setting and monitoring circuit is shown in the left part of the figures, and the means for monitoring the drive are shown in the right part.

The drawing shows schematically a point machine A , which is fed via four lines L 1 to L 4 and can be controlled and monitored from an interlocking. The drive has a three-phase motor with the windings W 1 to W 3 , which are connected in a known manner via end position contacts AK 1 to AK 4 . A three-phase three-phase network with the phases RST and the common zero point N serves as the power supply device for reversing the drive. In the three-phase lines L 1 to L 3 contacts WS / 1 to WS / 3 of a control switch are switched, which are temporarily closed to apply the supply voltage to the motor windings W 1 to W 3 of the drive A. The respective direction of rotation of the drive is determined by the switching position of contacts WL / 1 to WL / 4 of a direction selector. This direction selector forms with its contacts WL / 1 to WL / 4 a pole reversing switch for the motor windings W 1 and W 3 . It is reversed by the interlocking before the control switch is switched on to specify the respective direction of rotation in the other position and remains in this position until the next reversal command is prepared or issued.

In Fig. 1 it is assumed that the point machine assumes one of its two end positions. The motor windings are separated from the mains by contacts WS / 1 to WS / 3 . As long as these contacts are open, further contacts WS / 4 to WS / 6 of the control switch are closed. They make it possible for monitoring and signaling circuits to form via the four feed lines, the three motor windings and two of the four end position contacts. A plurality of current direction-sensitive monitors PPU 1 to PPU 3 are connected into the signaling and monitoring circuits, and at their outputs switch output data H (high) or L (low) to the inputs provided for this purpose of a microcomputer MC indicated in the drawing. This microcomputer recognizes the respective state of the monitored switch from the output data of the monitors supplied to it and the output data of further monitors not shown in the drawing. The monitors PPU 1 to PPU 3 are advantageously set up as process level converters for converting the monitoring current supplied to them on the input side into an output DC voltage which is suitable for direct input into the microcomputer MC . The process level converter detected the monitoring direct current via an LED connected to its two input terminals of an optocoupler. In addition to current direction evaluation, these optocouplers also serve to isolate potential between the signaling and monitoring circuits and the microcomputer.

In the assumed end position of the drive, the plus potential originating from a DC voltage source of 60 V = lies above WS / 4 , L 3 , W 2 , AK 2 , W 1 , L 2 , WL / 1 , L 1 , WS / 5 and WL / 5 at the plus input of the switch position monitor PPU 1 . The negative potential of the direct voltage monitoring source is present via L 4 , AK 3 , W 3 , L 1 , WL / 3 , L 2 , WS / 6 at the minus input of the position monitor PPU 1 . As a result of the flowing DC monitoring current, the switch position monitor PPU 1 passes at its output a corresponding output data H to the microcomputer, which recognizes from this input data that the drive has assumed a very specific end position, e.g. B. the one in which the associated switch is to be driven over its right strand.

In Fig. 2 it is assumed that the drive A assumes its other end position in which the associated switch can be driven over its left strand. The contacts of the direction selector take the position shown in Fig. 2 because the direction selector was reversed before the drive rotated. The end position contacts AK 1 to AK 4 have also changed their switching position. In the position of the drive shown, the positive potential of the DC voltage monitoring source via WS / 4 , L 3 , W 2 , AK 1 , W 3 , L 1 , WL / 2 , WS / 5 and WL / 6 becomes the positive input of the turnout position monitor PPU 2 leads. The negative potential of the DC voltage monitoring source is above L 4 , AK 4 , W 2 , L 2 , WL / 4 and WS / 6 at the minus input of the switch position monitor PPU 2 . This switch position monitor switches via its output an output date of value H to an associated input of the microcomputer MC , which recognizes the respective end position of the drive and thus the associated switch position.

The comparison of the monitoring and signaling circuits highlighted in FIGS . 1 and 2 for different drive end positions shows that when the drive contacts change at the drive connections 1 and 2, the polarity of the DC monitoring voltage is reversed. In the device known from the E-PS, this phase reversal leads to monitoring currents flowing in different directions, each of which influences one or the other switch position monitor via the diodes, and indicates this to the respective actual state of the drive. This actual state of the drive is to be compared there with the separately detectable target state of the drive. When he inventive device is achieved in that the monitoring and signaling circuits are performed via the pole-reversing switch, that the phase position of the potentials to be detected by the switch position monitors - proper function behavior of the direction selector required - is retained in both drive end positions. Exchanging the end position contacts AK 1 and AK 4 in Fig. 2 based on the representation of Fig. 1, the phase position of the voltages at the terminals 1 and 2 of the drive, the contacts WL / 2 and WL / 4 of the pole reversing switch ensure that on the leads leading to the switch position monitors, the same phase position of the DC monitoring voltage is present as in FIG. 1.

Through the series connection of the end position contacts with the contacts of the pole reversing switch, the message about the actual state of the drive (potential on lines L 1 and L 2 ) with the message about the target state of the drive (position of the contacts of the pole reversing switch) linked to an AND condition. If the direction selector comes into its other switching position at the wrong time, then the polarity of the DC monitoring voltage supplied to the two inputs of the respectively activated switch position monitor is reversed, ie there is negative potential at its plus input and plus potential at its minus input. Both switch position monitors then carry L potential at their output and thus inform the downstream microcomputer of the accident that has occurred.

In addition to the two turnout position monitors PPU 1 and PPU 2 , a further monitor PPU 3 is provided, which serves as a turnout indicator. The negative input of the point entry detector is routed to the center conductor L 4 of the three-phase network, while its positive input is connected to the three-phase line L 2 . If the turnout is opened, the turnout indicator should respond and output a corresponding message to the microcomputer. Such a case is assumed in FIG. 3. The reporting circuit shown results when the switch is opened from the position assumed in FIG. 1. The end position contacts AK 1 and AK 3 of the drive have changed. The plus potential of the DC voltage monitoring source lies above WS / 4 , L 3 , W 2 , AK 1 , W 3 , L 1 , WL / 3 , L 2 and WS / 6 at the plus input of the turnout detector PPU 3 . The negative input of the detector is connected via L 4 directly to the negative pole of the DC voltage monitoring source. If the turnout were opened from the other end position, the plus potential present at terminal 3 of the drive would be fed to the turnout detector via AK 2 , W 1 , L 2 , WL / 4 , and WS / 6 , thus identifying the fault.

The microcomputer, not shown, can for example a control computer of an electronic signal box or the Ab run control computer of a maneuvering system. It can be in the microcomputer in each case a single computer or one Act computers of a computer system.

Claims (4)

1.Device for remote monitoring of four-wire operated three-phase turnout drives with contacts arranged in the star point connections of the motor windings and controlled by the drive, via which, after the drive has rotated and the new end position has been reached, one of the four lines and the three windings of the drive motor Guided monitoring circuit for two indicators for detecting the one or the other end position of the point machine closes, which can be activated above one another via exclusion contacts of a direction selector which specifies the target position of the drive and switches which are closed outside the actuating phase, characterized in that
that the indicators (PPU 1 , PPU 2 ) are formed sensitive to the current direction and are connected to those two three-phase lines (L 1 , L 2 ) that make contact in the drive (A) via one end position each (AK 3 , AK 4 ) on the center conductor ( L 4 ) of the three-phase network,
that these two three-phase lines (L 1 , L 2 ) between the connections to the indicators (PPU 1 , PPU 2 ) and the motor windings (W 1 to W 3 ) by one of contacts (WL / 1 to WL / 4 ) of the direction selector Pole reversing switches are connected and that the center conductor (L 4 ) to one (-) and the third three-phase line (L 3 ) via a switch (WS / 4 ) closed outside the actuating phase to the other pole (+) of a DC voltage monitoring source ( 60 V =) are connected. 2. Device according to claim 1, characterized in that a further indicator (PPU 3 ) is provided, one input of which is routed to the center conductor (L 4 ) and the other input of which to the three-phase line (L 2 ) is connected, via the pole reversing switch (WL / 1 to WL / 4 ) and a drive winding (W 3 or W 1 ) are connected to those end positions (AK 1 , AK 3 or AK 2 , AK 4 ) which are connected when the drive is opened (A ) change from the respective end position. 3. Device according to claim 1 or 2, characterized in that the current direction-sensitive indicators (PPU 1 , PPU 2 , PPU 3 ) are provided by level converters for converting the respective input DC voltage into a suitable DC output voltage for the input of the indicator messages in one the indicator messages evaluating microcomputer (MC) . 4. Device according to claim 1, 2 or 3, characterized in that the current direction-sensitive indicators (PPU 1 , PPU 2 , PPU 3 ) are represented on the input side by the LEDs of optocouplers.