DE1605440C - Circuit arrangement for setting and monitoring electrical drives for switches in interlockings - Google Patents

Description

Umsclialtkontakt carry out, whose rest side in Connection circuit of the motor for switching the turnout in the event of malfunctions in the monitoring of the associated Switch section is arranged.

An embodiment of the invention is shown in the drawing and will be described in more detail below described.

In Fig. 2 only those circuit parts are shown which are absolutely necessary for understanding.

In Fig. 1 is the active zone of a switch W, consisting of the switch section JW and the lead section JV . The length / the lead section can be monitored on the one hand by a track relay - with an isolated lead section - and on the other hand by the arrangement of axle counting devices. Both devices - track relays or axle counting devices - are assigned locking switching means that prevent the switch W from being switched when a car running off reaches the forward section JV.

In the lower part of FIG. 2 parts of a point machine are shown, which via the control lines Ll to L4 with. is connected to the switching means for setting and monitoring in the interlocking system. The windings U, V, W, Hl and Hl are assigned to the point servomotor , and the contacts AK- and AK + are controlled by the point drive as a function of the point position. In the upper part of FIG. 2, a switch starting relay WA with the contacts WA 1 and WA 2 is shown, which is brought into the operative position via the transformer when the switch is switched. Furthermore, a monitoring relay WÜ, contacts WLl and WLl of a switch position relay ( not shown), contacts WNl to WN3 of a network relay ( not shown) for switching on the motor circuits, contacts WPl and WP1 of a switch test relay ( not shown), contacts WTl and WTl of a switch button, contact WHT of a group (not shown) -Weichhilfstaste and a contact Gl, which is controlled by the blocking switching means assigned to the advance section, is shown. The contact WHT switches zero potential N of the three-phase network R, S and T to a bus L. Furthermore, a direct current source with the potentials + and - is indicated, the negative potential of which is connected to the zero potential N of the three-phase network.

If one of the circuit parts of FIG. 2 associated turnout, this can be initiated on the one hand by manual operation with a turnout group key and the relevant turnout button or on the other hand by an attached changeover order from the stored sequence program. In both cases , the relays belonging to the contacts WTl and WTl, WLl and WL1, WPl and WP1 and WNl to WN 3 are influenced one after the other, so that the aforementioned contacts in FIG. 2 change position shown. Voltage is applied to the motor windings Hl, V and W via the contacts WN1 and WN 3 and the relay WA is brought to pick-up by the current flowing in this circuit via the transformer Tr. Contacts WA 1 and WA 2 are switched over and close the circuit Phased, contacts WA 1, WPl, WLl, line Ll, winding Hl, drive contact AK +, line Ll, contacts WP1, Gl, WAl, zero potential N. This starts the point servomotor in two phases to start up and actuate the contact AK + in the point machine, so that now the motor winding U is connected to phase S in series with the auxiliary winding Hl. The motor now continues to run in the normal three-phase circuit.

It takes until the point servomotor actually starts up - caused by the pull-in sound Fall times when initiating the changeover

ίο successively influenced points test, point position, Point setting relay - for example 0.25 seconds, which is about 25 to 50% of the actual changeover time the switch can be.

The length of a lead section that was previously at a given carriage speed by the Factor from the pure changeover time of a switch, for example 0.5 seconds, and the switching times, e.g. B. 0.25 seconds, the switching means claimed for the initiation of the switch switch, z. B. Relay, is determined can by the application of the circuit arrangement in which the occupation of a lead section dependent locking switch means the already initiated switching process of the switch interrupt before the electric drive is set in motion, shortened by 50%, for example will.

When using a switch network relay, which switches on the circuits of the drive motor with the windings U, V, W, Hl and Hl , for example according to FIG be arranged. If electronic switching means, e.g. B. thyristors used to switch on the motor, the blocking switching means can act on the control circuits of the four-layer triodes. In the case of the FIG. Circuit part shown 2 for a rotary current-controlled switch drive two-phase start-up of the engine via the four Stel lines L1 to L4, the decisive for the length L, FIG. 1, the run-on part point operating time can be further reduced in an advantageous manner in that portion of a contact Gl of the flow associated locking switch means in the circuit required only for starting the motor, e.g. B. Phase 5, contacts WAl, WPl, WLl, line Ll, auxiliary winding Hl, drive contact AK +, line L 2, contacts WP 2, G /, WA 1, zero potential N is arranged.

In the event of malfunctions in the monitoring device of the flow section, which bring the locking switch means into the occupied state, a further change of the switch, z. B. by the contact Gl, Fig. 2, prevented. In this case, however, it must be possible to switch the faulty turnout by operating the turnout auxiliary key and the turnout setting key assigned to the turnout. Since the switch auxiliary button is only required once for all switches, a contact WHT switches the potential N to a bus L when the switch auxiliary button is pressed. By simultaneously pressing the relevant switch setting button, the switch is switched and now applies the potential on the bus via the contact WTl to the corresponding circuit of the servomotor via the idle side of the blocking switch shown as changeover contact GI in FIG. 2.

The circuit arrangement is not limited to the exemplary embodiment shown in FIG. but can just as well be used in interlocking circuits implemented with electronic switching means will. The blocking of the switch changeover can depend on isolated track circuits, Axle counting devices or the like. Take place either as special lead sections or as actual switch sections are arranged, so z. B. with free maneuvering movements.

1 sheet of drawings

Claims (4)

1 2 setting of the corresponding run-up sections prevents marshalling yards are equipped with automatic signal boxes in order to improve the 1. Circuit arrangement for setting and over- 5 shunting operation to achieve by a dense and rapid wake-up of electrical drives for turnouts running sequence. The changeover takes place in process signal boxes with pre-run sections located in front of the turnouts after a stored sequence section, in which the program automatically changes over the turnouts by manually operated shunting units as a function of what is going on. The turnout effective zones, which are used for operational safety or are required depending on the sequence program, should be initiated in the switching means they have operated and length changes should be as short as possible so that the turnouts can be performed depending on the associated sequence operation. One therefore divides the occupied turnout sections as well as the turnout active zone into a turnout section and the occupation of the associated flow sections a flow section. The switch section is prevented, characterized in that, 15 has a blocking length which, depending on the Weidaß, is the form of the occupation of a leading section and on which the sequence movement (JV, Fig. 1) -dependent blocking switching means (Kon- has no influence untimely clock Gl, Fig. 2) the already initiated circumnavigation of the switch, as long as there is still a wheel setting process ( e.g. contacts WTl, WPl and between the tongue and stock rail, prevented WP 2 turned, Fig. 2) of the associated switch 20 to the. On the other hand, the length of the lead section is interrupted before the electric drive (represented by the windings U, V, W, Hl and Hl by the carriage speed and the switches) is set in motion, since the lead length is set in motion. must, that no running car in a still circulating 2. Circuit arrangement according to claim 1, there can be a running switch. characterized in that contacts (G /) of the 25 At a given carriage speed, the Blocking switching means in the connection circuits of the length of the flow section only through the the switching means, turnout setting time, which switch on the motor circuits. The turnout (e.g. through the contacts WN1 to WN3 presently now consists of the pure changeover time and the placed) are arranged. Switching time required to initiate the changeover 3. Circuit arrangement according to claim 1, such switching means together. The pure change-over is characterized by the fact that with three-phase control time for turnouts for sequence operation is about th turnout drives with two-phase start-up 0.5 to 1 second, and the switching times of the switching of the motor via four control lines (Ll to L 4, medium if they are in the The usual relay technology (fig. 2), which is carried out by the switch after switching over, can achieve values of around 0.25 seconds. With co-drive controlled contacts (e.g. AK +) , the point setting time moves between the three-phase switching over three control lines values 0.75 and 1.25 seconds. This turnout (Ll, L3 and LA) continues to run, contacts (G /) of the actuating time together with the required wagon lock switching means in the circuit required only for the start of the speed determines the length of the advance down motor (via the wire section. It has hitherto been customary for the initiation of the deviceL2) to be arranged. 40 To prevent switching of a switch when the 4. Circuit arrangement according to claim 3, since active zone of a switch through a running edge through characterized in that one in which is occupied for the yaw unit. Starting the motor required circuit (of the invention is based on the object S via Ll, Hl, Ll according to N, Fig. 2) to shorten the length of the lead section by ter contact (G /) of the blocking switching means as switchover 45 the switching times that are designed to initiate the switchover switch, whose rest side is in transition of a turnout are required, in which the Be-connection circuit (via the contacts WT1 and calculation for the length of the flow section and WHT after zero potential N) of the motor are taken into account. This object is achieved according to the invention by monitoring the associated switch section (JW, 5 °, that the one from the occupation of a lead section, Fig. 1) is arranged. dependent blocking switching means the already initiated Interrupt the switching process of the associated switch before the electric drive starts moving .. ·· .-. . . . · Is set. "' "55' According to a further embodiment of the invention are contacts of the blocking switching means in the switching circuits of the switching on the motor circuits Switching means arranged. Are three-phase current controlled point drives in the interlocking system The invention relates to a circuit arrangement 60 with two-phase motor start-up via four actuators Providing and monitoring electrical instructions after switching over from switch drives For switches in interlocking systems with contacts controlled in front of the drive in normal three-phase switch sections existing flow sections, circuit continues to run over three control lines who reverses the switching of the turnouts by hand, the contacts of the locking switch are in operated or, depending on the sequence program, the actuating 65 required to start the motor Switching means initiated and a switching of the circle is arranged. It is advantageous to use the in Switch depending on the associated current setting required for starting the motor Switch sections as well as with the circle arranged contact of the blocking switching means as