EP1301385A1

EP1301385A1 - Device for mechanically and electrically monitoring the adjustment drive of points motors

Info

Publication number: EP1301385A1
Application number: EP01984228A
Authority: EP
Inventors: Herbert Achleitner; Anton Schaffer; Josef Hörtler
Original assignee: Voestalpine VAE GmbH; Voestalpine Weichensysteme GmbH
Current assignee: Voestalpine Turnout Technology Zeltweg GmbH; Voestalpine Railway Systems GmbH
Priority date: 2000-07-14
Filing date: 2001-07-12
Publication date: 2003-04-16
Anticipated expiration: 2021-07-12
Also published as: AT4844U1; US20040069910A1; DK1301385T3; CN1285478C; CZ200351A3; PL359103A1; WO2002006104A1; AU2002222924A1; CZ293033B6; CN1458893A; CA2415546A1; PL204400B1; ES2307663T3; ATE399691T1; CA2415546C; DE50114074D1; HUP0301738A2; PT1301385E; EP1301385B1; US7191986B2

Abstract

The invention relates to a device for monitoring the function of devices (4) for adjusting movable points elements (2, 3), in which the movable points elements (2, 3) are interlinked via a coupling rod (13). Said coupling rod (13) comprises rod parts (14, 15) that can be displaced relative to each other in the axial direction. The device is further provided with sensors (34, 35) for detecting at least two different positions of displacement of the coupling rod parts (14, 15).

Description

Device for the mechanical and electrical inspection of the adjustment device of point machines

The invention relates to a device for checking the function of devices for converting movable switch parts, in which the movable switch parts are connected to one another via an opposing rod.

A device for converting movable switch parts has become known, for example, from AT 405 925 B. In this known device, two parts which are axially displaceable relative to one another can be displaced in a position which is non-positively coupled to one another in at least one direction of movement, the parts which are displaceable relative to one another being formed by a tube and a rod guided in the tube and at least partially arranged in a stationary outer tube are. The locking members for the end position locking are formed by balls which cooperate with the axially displaceable parts and the outer tube and can be moved in the radial direction into a locking position in a recess or inner ring groove of the outer tube. The rod guided in the tube is at the same time designed as a piston rod for a hydraulic cylinder-piston unit, so that the device known from AT 405 925 B not only ensures end position locking for movable switch parts, but also effects the changeover of the switch. In addition, a rigid coupling rod is provided in the known device, via which the switch tongues are connected, so that when a tongue is adjusted, the corresponding corresponding movement of the second tongue is non-positively ensured.

Numerous proposals have already become known for checking the correct functioning of such end position locking and changeover devices. For example, AT 405 925 B describes sensors which are adjacent to the end face of the hydraulic cylinder piston unit or cylinder and thus the distance of the tubular tube connected to the tongue. signal the component from the required end position. A break in the coupling rod leads, for example, to the fact that the movement of the two tongues in the same direction is no longer guaranteed, so that the tongue moving from the system into the storage area is secured against further displacement via a separate locking groove in a position in which a correct end position is not was achieved. In this case, the sensors signal that the tongue is too far from the required end position, but such a function check has the disadvantage that it cannot be said with certainty whether the coupling rod is actually broken or whether the sensor is not functioning correctly , A further safety device for controlling the changeover movement of movable switch parts has become known from WO 97/33784, in which the distance between the stock rail and the adjoining tongue is determined by means of inductive sensors in order to check that the tongue fits exactly.

Due to the constantly increasing demands on the control of rail switches and due to the increasingly strict safety regulations prescribed by the railway operators, the previously known safety devices are not sufficient and it is therefore an object of the present invention to provide a device with which an additional function check of devices for the changeover and end position locking of movable switch parts. In particular, the invention aims to provide an additional mechanical function control in which any deviation of the tongue position from the respective target position and any malfunction of the end position lock can be electronically monitored directly and in which the exact cause of the fault can be deduced directly on the basis of the signals generated. To achieve this object, the design according to the invention essentially consists in that the coupling rod consists of two rod parts displaceable in the axial direction relative to one another and that sensors for detecting at least two mutually different displacement positions of the Coupling rod parts are arranged. The fact that a two-part coupling rod is provided, the two parts of which are displaceable in the axial direction relative to one another, changes the axial length of the coupling rod during the reorganization of the switch and thereby creates the possibility during the changeover process to generate sensor signals which are different Show the displacement positions of the coupling rod parts to each other. Sensors are therefore provided for the detection of at least two mutually different displacement positions of the coupling rod parts. Such a two-part coupling rod is particularly suitable when using change-over devices, in which the movable switch parts are not moved synchronously, i.e., for example, via a rigid coupling rod, but in which the remote tongue is first unlocked and moved over a first partial path, after which only the changeover process for the adjacent tongue begins. Such a changeover device has the advantage that the tongue located in the system is held in this position for a longer time, even while the changeover process is starting. During the entire conversion process, the coupling rod parts move in such a way that the coupling rod initially becomes longer at the beginning of the conversion process, then maintains its length and, at the end of the conversion process, reaches its original length again. The sensors can thus signal at least three switching operations during the entire changeover process, so that an almost continuous functional check of the changeover device is ensured. In interaction with other control devices, for example those that are integrated in the locking device or those that are attached directly to the rails, a second control level can be realized with the checking device according to the invention and thus also a statement about the cause of a possible error can be made.

A preferred development of the device according to the invention is that the coupling rod parts have stops to limit the axial mutual displaceability. This ensures that the length change of the coupling rod is only possible within defined limits and that the coupling rod takes over the effect of a rigid coupling rod when the maximum length given by the stops is reached and thus guarantees a synchronous movement of the two movable switch parts over part of the changeover path is. This has the advantage that the locking of a tongue simultaneously ensures a certain securing of the second tongue even when the locking device for one of the two tongues no longer functions correctly.

In a particularly advantageous manner, a coupling rod part has a tubular part encompassing at least one axial partial region of the other coupling rod part. Such a design enables a coaxial arrangement of one rod part within the tubular part of the other coupling rod part, so that overall an encapsulated, externally closed device is created, within which the sensors and other components can be arranged protected from external influences.

In a particularly simple manner, the tubular part of one coupling rod part here has a stop which engages behind a piston-shaped end piece of the other coupling rod part. In this way, an exact stop is defined in a simple manner, which defines the maximum length of the coupling rod.

The coupling rod parts are advantageously connected to one another via a spring, in particular a helical spring. Such a design has the advantage that the mutual displacement of the two coupling rod parts to one another is not hindered, but that if the coupling rod breaks, ie if the two tongues are no longer rigidly connected to one another, the coupling rod is held in its initial position. The spring holds the two coupling rod parts in a certain position to each other, in which the two Coupling rod parts can not be moved against each other due to the action of the spring, so that the sensors can not generate switching signals. In this way, a break in the coupling rod is reliably detected even in a monitoring station that is locally removed from the changeover device.

In a particularly simple manner, the sensors are designed as contacts, so that the reliability of such sensors can be increased further and a corresponding signal is only reliably generated when the corresponding end position is reached. In a preferred manner, a first sensor is rigidly connected to a coupling rod part, the sensor interacting with an actuating element arranged on the tubular part in order to detect a first displacement end position of the coupling rod parts. This sensor is thus arranged in such a way that it can be displaced together with a coupling rod part relative to the other coupling rod part and, when a displacement end position is reached, that is to say when the stops for limiting the change in length of the coupling rod interact, cooperates with a rigid actuating element arranged on the tubular part and generate a signal this way. Furthermore a second sensor is preferably rigidly connected with a coupling rod part, said second sensor for detecting a second displacement end of Koppel tange parts wi th a disposed within the tubular member stop face interacts, wherein further the stop face supported within ^'of the tubular member relative to said resiliently displaceable can be . Such a resilient mounting of the stop surface for the second sensor, which signals the final displacement position, which corresponds to the contact of the tongues, has the advantage that there is no elastic deflection of the adjacent tongue, which can be triggered, for example, by a train running over it Triggers a switching signal, since the resiliently mounted stop surface follows this resilient movement of the tongue. In a particularly advantageous manner, the design is such that the stops are arranged displaceably. As a result, the limitation of the change in length of the piston rod given by the stops can be set, so that the test device can be adapted to the conditions given by the changeover and locking device in each case. For this purpose, the piston-shaped end piece is advantageously connected to a coupling rod part by means of a thread, it also being possible for the tubular part to be connected to a coupling rod part by means of a thread.

In order to enable central monitoring of the switch lock and the correct switch changeover, the sensors are advantageously connected to an evaluation and monitoring device. The signals of other sensors can also be fed to such an evaluation and monitoring device, so that a detailed error analysis can be carried out.

The invention is explained in more detail below on the basis of exemplary embodiments schematically illustrated in the drawing. In this figure 1 a switch changeover device with a coupling rod, Fig. FIG. 2 shows an enlarged representation of the left side of the changeover device according to FIG. 1, FIG. 3 shows an enlarged representation of the right side of the changeover device according to FIG. 1 and FIG. 4 shows a partial representation of the coupling rod in section.

In Fig. 1 shows a stock rail 1, with 2 a switch tongue resting against the stock rail 1 being shown. The remote switch tongue is labeled 3. Between the switch tongues 2 and 3, a device for adjusting and locking the position of the switch tongues 2 and 3 is provided, which is designated by 4. The changeover device 4 in this case comprises an external tube 5, which extends on both sides of a central region, which is designed as a cylinder 6. Inside the cylinder 6 is a hydraulic one Movable piston 7 is arranged, wherein the hydraulic medium is pressed into the effective working spaces via hydraulic lines 8 and 9. The piston 7 is connected to a continuous piston rod 10 which has different cross-sectional areas over its axial length. Furthermore, tubes 11 are provided which are connected to the switch tongues 2 and 3 via connection devices 12. The connection devices 12, which are described in detail in WO 99/20511, ensure that vibrations of the switch tongues 2 and 3 can be kept completely away from the changeover and locking system 4 and at the same time a play-free absorption of the changeover forces is made possible. In Fig. 1, a coupling rod 13 can also be seen, which consists of the rod parts 14 and 15. The parts 14 and 15 are each coupled to a part of the connecting device 12 connected to the switch tongue 2 and 3, respectively. The encapsulated part 16 of the coupling rod 13 is shown in more detail in FIG. 4 and described in more detail below.

2 and 3, the operation of the changeover and locking mechanism is now shown in more detail. The left-hand side of FIG. 1 shown in FIG. 2 is the side which is responsible for the locking position of the remote tongue 3. The locking elements, which are formed by an expandable ring 17 and the associated balls 18, are in this case held by an axial region 19 of the piston rod 10 in the locking position against a stop 20 in a recess 21 of the outer tube 5, with a displacement of the with the Tongue 3 connected tube 11 is prevented from the remote position of the tongue in a system position by the stop 20 and the ring 17. This locking position for the remote tongue 3 can only be released in that the piston rod 10 is displaced by the piston 7 in the direction of arrow 22, the balls 18 reaching the smaller diameter axial area 23 of the piston rod 10. With a further movement of the piston rod 10 in the direction of arrow 22, a stop shoulder 24 of the larger diameter is reached Area 19 of the piston rod 10 in operative connection with the balls 25, so that the switch tongue 3 is driven via the tube 11. At the same time, however, a displacement of the piston rod in the direction of arrow 22 unlocks the adjacent tongue 2, as shown in FIG. 3. The piston rod 10 comes into a position in which the outer ring 26 located in the locking position, under the force of its spring 27 with the associated balls 25, can emerge from the locking position on the end region 28 of the coupling rod 10 which is set to a smaller diameter, whereby a relative displacement of the tubular part 11 relative to the outer tube 5 is made possible. With the further displacement of the piston rod 10 by the application of fluid to the piston 7 in the direction of arrow 22, the inner stop shoulder 29 of the full cross-section axial region 19 usually does not come into operative connection with the balls 18, since yes, the entrainment of the tongue 2 via the Coupling rod 13 takes place.

The overlap lengths of the closure members can be chosen, for example, such that after a piston adjustment of 14 mm (a), an active adjustment of the remote tongue 3 begins, so that the coupling rod part 14 is taken along by the remote tongue 3. As in Fig. 4 can be seen in more detail, thus moves at the beginning of the part-operation process of the coupling rod part 14 in the direction of arrow 22, but the coupling rod part 15, which is connected to the adjacent tongue 2, remains immobile. The coupling rod part 15 is in this case connected via a thread to a tubular part 30 which engages around the coupling rod part 14. A piston-shaped end piece 31 is connected to the coupling rod part 14 and is engaged behind by a stop 32 of the tubular part 30. Between the stop 33 of the piston-shaped end piece 31 and the stop 32 of the tubular part 30, a distance b is provided at the beginning of the operation. After a piston travel of, for example, 12 mm, the piston-shaped end piece 31 now comes into contact with the stop 32 of the tubular part 30, so that the coupling rod part 15 and thus the attached lying tongue 2 is taken. At this time, the closure of the adjacent tongue 2 is already unlocked, so that the tongue 2 is moved from the system into the storage area via the coupling rod. As long as the adjacent tongue 2 is carried directly by the coupling rod, there is no active entrainment of the adjacent tongue 2 by the piston rod 10, since the balls 18 do not come into contact with the stop 29 of the piston rod. For this purpose, the length c must be chosen greater than the sum of the lengths a and b.

Only when the switch tongue 3 comes into contact with the stock rail does the switch tongue 2 no longer be carried along via the coupling rod, so that the balls 18 now come into contact with the stop 29 and thus the tongue 2 is actively taken along by the piston rod 10. From this point in time, the stop 33 of the piston-shaped end piece 31 moves away from the stop 32 of the tubular part 30 until the switch tongue 2 is locked via the ring 17 and the locking balls 18. The original distance b is then again present between the stop 33 and the stop 32 of the piston rod parts.

Sensors 34 and 35 are rigidly connected to the coupling rod part 14 and signal the respective displacement end positions of the coupling rod parts 14 and 15. In the initial position, in which the stops 32 and 33 are held at a distance b from one another, the contact switch 35 is in contact with the ring-shaped contact part 36. During the changeover process, the sensor 34 then contacts a mating contact 37 attached to the tubular part 30, whereupon at the end of the switching process, the contact holder 35 again triggers a switching signal. A sequence of switching signals is thus generated during the entire relocation process, which enables a precise functional check of the changeover device.

An axial play d remains between the end face 38 and the end face 39, which is caused by the elastic deflection or can be overcome by vibrations of the adjacent tongue. If the maximum allowable play of the tongue is established, this causes the tubular part 30 to bear directly against the coupling rod part 14, so that a further locking of the remote tongue via the coupling rod is ensured. In order not to trigger switching signals of the sensor 35 in the event of such vibrations or deflections of the adjacent tongue, the annular contact part 36 is resiliently mounted within the tubular part 30 via a spring 40.

A spring 41 is provided between the coupling rod part 15 and the end piece 31 of the other coupling rod part 14. If the coupling rod breaks, the spring 41 has the effect that the distance b between the stops 32 and 33 is maintained. In this way, a relative displacement of the coupling rod parts 14 and 15 with respect to one another can be avoided, so that in this case the contact switches 34 and 35 do not trigger any signals. Overall, the two coupling rod parts 14 and 15 are secured by a nut 42.

Claims

Claims:

.1 . Device for checking the function of devices for converting movable switch parts, in which the movable switch parts are connected to one another via a coupling rod, characterized in that the coupling rod (13) consists of two rod parts (14, 15) which are displaceable in the axial direction and that sensors (34, 35) for detecting at least two mutually different displacement positions of the coupling rod parts (14, 15) are arranged.

2nd Device according to claim 1, characterized in that the coupling rod parts (14, 15) have stops (32, 33) for limiting the axial mutual displaceability.

3. Device according to claim 1 or 2, characterized in that the one coupling rod part (15) has a tubular, at least one axial portion of the other coupling rod part (14) encompassing part (30).

4. Device according to claim 3, characterized in that the tubular part (30) of a coupling rod part (15) has a stop (32) which engages behind a piston-shaped end piece (31) of the other coupling rod part (14).

5. Device according to one of claims 1 to 4, characterized in that the coupling rod parts (14, 15) via a spring (41), in particular a helical spring, are connected to one another.

6. Device according to one of claims 1 to 5, characterized in that the sensors (34,35) are designed as contact holders.

7. Device according to one of claims 3 to 6, characterized in that a first sensor (34) is rigidly connected to a coupling rod part (14) and for detecting a first ver End sliding position of the coupling rod parts cooperates with an actuator (37) arranged on the tubular part (30).

8. Device according to one of claims 3 to 7, characterized in that a second sensor (35) is rigidly connected to a coupling rod part (14) and for detecting a second displacement end position of the coupling rod parts (14, 15) with an inside the tubular part ( 30) arranged stop surface (36) interacts.

9. Device according to claim 8, characterized in that the stop surface (36) within the tubular part (30) is resiliently mounted relative to this.

10. Device according to one of claims 2 to 9, characterized in that the stops (32,33) are arranged displaceably.

11. Device according to one of claims 4 to 10, characterized in that the piston-shaped end piece (31) over a

Thread is connected to a coupling rod part (14).

12. Device according to one of claims 3 to 11, characterized in that the tubular part (30) is connected via a thread to a coupling rod part (15).

13. Device according to one of claims 1 to 12, characterized in that the sensors (34,35) are connected to an evaluation and monitoring device.