DE1161945B - Circuit arrangement for switching on, monitoring and locking or excluding electrical devices - Google Patents

Description

Circuit arrangement for switching on, monitoring and locking or Excluding electrical devices The invention relates to a circuit arrangement for switching on, permanent or temporary monitoring and locking or excluding electrical equipment, especially those in railway signal boxes, in which a series of similar switching elements in the form of a matrix corresponding to the Closure panel is arranged. Its main purpose is the switching operations mentioned to be carried out with a significantly lower technical effort than before.

It is known the newer interlockings, especially the so-called Track plan signal boxes, based on a relay circuit, the modular and relay groups connected to one another according to the track diagram having. As is known, as a result of the interconnection according to the site plan Difficulties in excluding routes arise when between two locations Several routes are possible in the track plan, as well as when controlling edge protection switches. As far as these deficiencies could be eliminated, there were other disadvantages: The additional ones Circuits could not be switched according to the track plan; also was No storage of several journeys that are not possible at the same time without special ones Additional memory for entire routes possible.

In further development of interlocking systems with partial and / or Complete routes as well as to avoid the deficiencies of the mentioned state of the art a device has also become known that is used to switch on the switching groups of the individual track plan elements as well as to monitor their operating states with similar electronic switching elements working in a matrix corresponding to the locking panel are arranged. This circuit arrangement would, however, if one used it for all took advantage of the switching operations in the interlocking, a relatively large technical one Require effort on such electronic components.

The subject of an earlier patent is also the use of switching means electronic circuit technology in interlocking circuits. But here are not matrices from such switching elements for a locking panels corresponding Structure applied.

The invention is intended to address the disadvantages of the known prior art technology can be avoided. This is done according to the invention in that each switching element connected to at least one coincidence gate according to row and column of the matrix is, in turn, depending on an interlocking device, z. B. a route or a switch is assigned.

The aim of the invention is essentially the already known partially electronic Interlocking circuitry to be further perfected. When applying the invention can with a lower cost of switching means while maintaining the same safety conditions more extensive tasks to secure the train routes can be solved. It takes only a single type of electronic gate to be used, the turning on and locking of points or the exclusion of routes from only one the coincidence gate is effected by the prepared closure or exclusion turns on.

Mainly results from the assignment of components to two or several coincidence gates a simpler one because of the simple circuit structure Tax audit and less work involved in troubleshooting.

The subject matter of the invention and its mode of operation are to be understood some embodiments shown in the drawings are described in more detail.

F i g. 1 contains a schematic representation of the interdependencies of electrical devices in the form of a locking panel common in railroad safety engineering, which shows the interdependencies of switches 1 and 2 and of routes a2, b and f as well as the interdependencies of the routes mentioned for a track plan (not shown). As is well known, the symbols (-I-) or (-) in the switch columns mean the position of the switches, whereas in the route columns the symbol (-) denotes the route set, (,) denotes the exclusion of two routes due to mismatching switch positions and (11) the exclusion of two routes for other reasons.

The in F i g. The circuits shown in FIGS. 2 and 3 each contain one Matrix m, the internal structure of which corresponds to that of the locking panel according to FIG. 1 corresponds. Only the two coincidence gates Gw and GF are shown in full, which ones the route f and the plus layer 2+ of the switch 2 are assigned. These two coincidence gates have according to the invention a common component D, "which is the connection between a row and a column in the matrix m.

In each of the gates Gw and GF connected to the matrix m there are dependency contacts kw; and kp and amplifier inputs VEW and VEF connected to the matrix. According to FIG. 2 these are in series, while according to F i g. 3 and 4, connected in parallel, to which columns and rows of the matrix are connected.

In the circuit according to FIG. 2, a current J can flow in the specified direction via the common component D ″ only if only one of the relays (not shown) carrying the dependency contacts kp and kW switches over, ie one of the named contacts is opposite to the position shown. The amplifier is designed so that with current flowing J no output current i may flow, so the connected relay W or F is de-energized. the current disappears when all dependency contacts kp and are kW in the position shown or to take all the other switching position.

Thus, the interaction of these two genus ter Gw and Gp is given. This is used in the example so that when the route f is set, the dependency contacts kp switch over and the relays W and F drop out as a result. The release of the relay W thus represents the switching on of the plus position of the switch 2. By contacts of this relay, the possibility of resetting from the plus position is prevented at the same time, so that the switch is closed in the plus position. However, if the switch is in the minus position and if it is not closed by a similar device in this position, it is switched to the plus position by switching on as described.

After the plus position has been reached and the closure is completed by the relay W dropping out, the dependency contacts kW switch over, so that the current J disappears again and the relay F thus picks up, which monitors the set point position.

An expedient development of the subject matter of the invention is shown in FIG. 3 shown. This representation differs mainly in this way from that according to FIG. 2 that in coincidence gates each one of the amplifier inputs VEW or VEp with one or more dependency contacts kW or kp via reverse current blocking diodes Dw 1 and DW z or D p.1 and D pz each connected in parallel according to row and column to the matrix m are.

This circuit works as follows: If a sinusoidal alternating voltage is applied to wires A 0 and A 2 , wires A 2 and A 1 will be positive compared to wire A 0 at certain times. A current then flows from wire A 1 via the amplifier input VEF and the diode DF z via the diode D ″, the matrix m to the gate Gw, its diode Dw, and the resistor Rw to the wire A 0, provided that the contact kw is open The magnetic amplifier of the gate GF is thus dependent on the contact kW in the gate Gw during the period described.

If instead the wires A 2 and A 1 are negative compared to the wire A 0, a current flows from the wire A 0 via the resistor RF of the gate GF, the dependency contact kp and the connected diode after the wire A 2. During this time, no current flows through the diode D, "in the matrix m to the amplifier input VEW, and the relay W in the gate GW picks up. This relay W therefore works depending on the position of the contact kp in the gate Gp.

The described dependency also exists between the dependency contact kW in the gate Gw and the relay F in the gate GF when the dependency contact kW is closed, i.e. during the time in which the wires A 2 and A 1 are positive compared to the wire A 0 . The dependencies described represent the interaction of the two gates.

The creation of the route now works in the same way as for the case according to FIG. 2 described in front of you. To resolve the route that has been formed, for example by pulling the dependency contact in the gate GI. again closed. As a result, the relay W pulls in the gate Gw, whereby the closure of the Soft 2 is canceled in the plus position, so that it can be steepened again and the Dependency contact kW goes into its basic position. This also causes the relay to drop F in the gate G ,, from again, and both devices are back in the basic position returned.

According to FIG. 4, the according to F i g. 3 used magnetic amplifier in the individual gates can be replaced by AC-operated transistors. The transistor p in the gate Gw is a p-n-p transistor, while the transistor n in gate GF is an n-p-n transistor. The choice of such is expedient Transistors of the specified types, whose electrical properties are symmetrical to one another whose operating characteristics are roughly the same with reversed polarity. The other switching means are essentially the same as in FIG. 3.

Another embodiment shows the arrangement according to FIG. 5 insofar as two coincidence gates Gp and GT when using the transistor circuit according to FIG. 4 are connected to only one terminal 1 of the common diode D in the matrix m . The gate GF assigned to the route acts both on the inputs of the transistors that control the relays TF and TE and, via the diode D, on the switching means for producing the positive position of the switch 2, while the coincidence gate GT of a partial route only acts on the switching means for Establishing the plus layer of the switch 2 is effective. The connection 2 of the diode D is assigned to the coincidence gate GW of the switch 2.

The mode of operation of the circuit of FIG. 5 is the same as that of FIG. 5 with regard to the interaction of the gates Gw and GT. 4 cooperating gates G, r, and GF, while the gate GF according to F i g. 5 still reverse current blocking diodes Gll and Eq. possesses, so that the gate GF is also brought into dependence on the plus position of the switch 2.

According to a further feature of the invention, the amplifiers are used as magnetic amplifiers and their cores are made of textured sheet metal, the advantage arises that with relatively small dimensions of the core, large useful powers can be controlled. In addition, only a very small residual current flows in when the amplifier is blocked the load side, which corresponds to the magnetizing current.

From Fig. 3 it can also be seen by which means the voltage induced from the load side to the control side of each magnetic amplifier can be compensated. The voltage drop caused by the voltage occurring between the wires A 1 and A 2 at the resistor Wy in series with the control side of the magnetic amplifier must be selected so that it is equal to or greater than the induced alternating voltage occurring in the control winding. This effect can also be approximated, as shown in FIG. 2 shown as an example, can be achieved in that the component D, "of the matrix m has such a resistor connected in series with the diode that only a very small, non-interfering current can develop in the matrix m.

In all the circuits shown, the relays W, F, TF or TE on the load side of the amplifier are each connected in parallel with a rectifier GlW, GIF, GITF or GITE; The magnetic energy of the relay coils should decay via these rectifiers during the pause in the load current. Since the load circuit of the magnetic amplifier is in a half-wave rectifier circuit, the rectifiers mentioned must have the reverse direction of forward direction as the rectifiers arranged in the load circuit of the respective magnetic amplifier.

When using transistors instead of magnetic amplifiers, the load circuit of the amplifier must also be supplied with direct current.

In the circuits with transistors, e.g. B. according to FIG. 4, the input side of the amplifier is connected in series with a bias voltage, which is formed from the voltage between the wires A 1 and A 2 . This bias voltage is equal to or greater than the voltage drop across the series connection of the resistor RF and the diode DF, which is also in series in the gate GF, and the diode D, ″ in the matrix m (cf. FIG. 3 @ and that in the gate GW with The diode connected in series with the amplifier input VEW This transistor circuit also has the advantage of being able to set the bias voltage mentioned so that the input current disappears as a residual current.

Instead of the previously mentioned transistors symmetrical with each other However, characteristic curves can also (if suitable circuits, not shown, are selected) Transistors of the same type are used.

The application of the circuits explained above is in the different station sizes. While all of the above explained embodiments on the direct interaction of routes and switches, but it is also, as is easy to see, the interaction of different types of facilities, such as B. Routes with partial routes and (over another matrix) the interaction of partial routes and switches is possible. But it is also conceivable that the aforementioned partial route devices are wholly or partially assigned to the points to be driven on and by means of the mentioned second matrix can be connected to the other track plan elements to be controlled.

For signal control, contacts can be in a coincidence gate monitoring relays located on one or more mixing gates are used act.

To increase the safety of the system can, as in the railway safety technology common, certain important circuits, such as B. for locking and monitoring the number of points to be driven on must be doubled.

However, the application of the subject matter of the invention is limited not, as mentioned at the beginning, only on the railway safety system; it can with success can also be used in cases where there are generally any connection, monitoring, Closure or exclusion processes are to be controlled.

Claims (7)

Claims: 1. Circuit arrangement for switching on, permanent or temporary monitoring and locking or excluding electrical devices, in particular those in railway signal boxes, in which a number of similar switching elements is arranged in the form of a matrix corresponding to the locking panel, characterized in that each switching element (D , ") according to the row and column of the matrix (m) is connected to at least one coincidence gate (GW and GF in FIG. 2 or GW, GT and GF in FIG. 5), which in turn is connected to an interlocking device ( e.g. route f or switch 2-f-) is assigned. 2. Circuit arrangement according to claim 1, characterized in that each interlocking device belonging to dependency contacts (kW and kF) with the input (VEW or VE.,) Of an amplifier also belonging to each device (z. B. the control winding of a magnetic amplifier ) are in series and that each of these series connections is connected to the matrix (m) according to row and column. 3. Circuit arrangement according to claim 1, characterized in that one or more of the interlocking device's dependency contacts (kW or kF) and a corresponding amplifier input (VEW or VEF) via reverse current blocking diodes (DW 1 and DW 2 or DF 1 and DF 2) are each connected to the matrix (m) in parallel by row and column. 4. Circuit arrangement according to claim 1 and 2 or 3, characterized by magnetic amplifiers, their core consists of textured sheet metal. 5. Circuit arrangement according to claim 4, characterized in that that the control side of each magnetic amplifier is in series with a bias generating switching element (W ") lies. 6. Circuit arrangement according to claim 1 and 2 or 3, characterized in that Transistor amplifier (F i G. 4 and 5) are provided, which are fed with direct and / or alternating voltage. 7. Circuit arrangement according to claim 6, characterized in that the input side of the transistor amplifier is in series with a bias voltage. B. Circuit arrangement according to claim 4 to 7, characterized in that the relay (W or F) lying in series with the output side of each amplifier is connected in parallel with a rectifier (Glw or GIF) whose direction of flow of the current flow direction (i) through the Relay is opposite. Documents considered: German Patent No. 922111; German Auslegeschrift No. 1039 556. Earlier patents considered: German Patent No. 1109 729.