SE461084B - DEVICE FOR CHECKING THE CONDITION OF A REMOTE-CONTROLLED BODY E X V A DRIVE DRIVE TO A RAILWAY OR SIGNAL LAMP AT A RAILWAY SAVE - Google Patents

Description

461 084 2 10 15 20 25 governing means would be confused or connected to the wrong means. This is achieved by the remote-controlled means being provided with one or more special coding means, depending on the application. Each such gives rise to a pulse pattern which is characteristic of this particular organ in a current flowing through it.

Thereby, it can be determined at the controlling member whether a current through it also flows through a certain line portion at the remote-controlled member. If this consists of a gear drive, two different coding means are suitably used, one being connected in a special current path when the gear drive assumes one of its switching positions, while the other coding means is instead connected in the current path when the gear drive assumes its second switching position. If the remote-controlled means consists of a signal lamp, a single coding means is suitably used, which is connected in series with the lamp and adjacent to it. The pulse pattern then appears when the lamp is powered on.

The features of the invention appear from the claims.

DESCRIPTION OF THE DRAWINGS The invention will be described in more detail with reference to the drawings, in which Figures 1 and 2 show two different embodiments of a device according to the invention, Figure 3 shows a first embodiment of an encoding means which is included in the devices according to Figures 1 and 2, Figure 11 shows an example of a pulse pattern as phase with a coding device according to Fig. 3, Fig. 5 shows a second embodiment of a coding means as above, Fig. 6 shows an example of a pulse pattern as a phase with a coding means according to Fig. 5 and Fig. 7 shows a third embodiment on an encoder as above.

PREFERRED EMBODIMENTS Figure 1 shows a first embodiment of a device according to the invention. hfled 1 denotes a source of voltage and by 2 a special control receiver, which are assumed to be located in a railway switchgear. By Sa and 3b are denoted two switching elements and by ha and bb two special coding means, which are assumed to be located at a gear drive not shown in the figure to a railway gear.

The switching switch is arranged in a known manner to be switched by the gear drive. In one switching position of the switch, the switching positions shown in the figure are assumed, one coding means, ha, being connected in series with the voltage source 1 and the control receiver 2. switching position, the switching elements are reversed, the second coding means, ßb, being connected in series with the voltage source and the control receiver.

Each of the coding means 11a and Ab is arranged to give rise to a pulse pattern characteristic of this means in the current flowing through it when it is connected in a loop with a voltage source. This is done by changing the impedance of the coding means in a time-characteristic manner between two different values. One and the same pulse pattern is formed independently of the polarity of the voltage source, and the pulse pattern is suitably repeated continuously. The control receiver 2 in the switchgear is arranged to detect and distinguish different pulse patterns in a current flowing through it independent of the direction of the current. The receiver can then consist of a current-sensing receiver of known type.

By checking the received pulse pattern, it can thus be determined which of the coding means is connected in the loop. As a result, it can also be determined whether the gear unit is in the left or right position. It does not matter if the two lines between the switchgear and the gear unit have been confused and changed places. The polarity of the voltage source does not matter either. If the pulse pattern also contains information about which of several different gears it originates from, the risk of incorrect control results is also avoided if the wires are accidentally connected to the wrong gear.

In this example, the control receiver 2 suitably has four outputs, whereby left position, right position, incorrectly received pulse pattern and no received pulse pattern can be indicated. Incorrect pulse pattern can mean that the wires are connected to a different gear than the intended one. The fact that no pulse pattern has been observed can mean that the gear drive is in an intermediate position, whereby none of the coding means ha and lib have been switched on.

It is of course conceivable to replace the switching elements Ba and 3D with a single switching element which in a first switching mode connects the coding device 1: ai: ierie with the voltage source 1 and the control receiver 2, and which in: a second on-switching position instead switches the coding means lsb i series with ilessa ieniietrar. 461 10 15 20 25 084 Figure 2 shows a second embodiment of a device according to the invention.

The wire in figure 1 is denoted by 1 and 2 a voltage source and a control receiver, which are located in a switchgear. The units to the right of the dashed parts of the lines are in this case assumed to be located at a signal lamp 6 at a railway save. The lamp is lit by closing a switch 5 in the switchgear. The current through the lamp 6 also passes through a coding means 1i of the same type as the coding means 1 and lab connected in series with the lamp as above. In practice, the lamp 6 shown in the figure and the other units are of course only one of a number of similar sets. Each individual signal lamp is thus connected in series with an encoder, which gives rise to a pulse pattern which is characteristic of this particular encoder. In this way, it can be determined in each control receiver whether the supply current which is connected to a certain switch is actually led through the signal lamp for which the switch is intended.

With this device, incorrect signal images caused by incorrectly connected supply lines to the signal lamps are thus detected without the use of any special signal lines. Faulty connections can be due to confusions of different wiring pairs, which can result in a ready signal instead of a stop signal.

Of course, line breaks or broken signal lamps are also detected, since no pulse pattern is received in such cases. Under certain circumstances, short circuits can also be detected.

In this case, the control receiver 2 suitably has three outputs, whereby a correctly received pulse pattern, an incorrectly received pulse pattern and a no received pulse pattern can be indicated. Figure 3 shows a first embodiment of the coding means included in the devices described above. The coding means according to this example is intended to be input with a direct voltage from the switchgear, which means that the above-mentioned voltage source 1 is a direct voltage source. The coding means contains a zener diode bridge 10 and an energy storage capacitor 11, the function of which is to provide an internal supply voltage. Its polarity. is independent of the plarity of the voltage source 1 as above and of how the wires from the voltage source are connected. Denoted by 12 is a self-oscillating clock pulse generator (f: 5,461,084) which generates clock pulses with a predetermined frequency. The clock pulses are applied to a clock pulse input CL on a parallel / serial converter 13. To its parallel inputs is a symbolically marked, adjustable network 14 connected, with which the desired pulse pattern can be set, eg by jumper (tightening).

The pulses which form the pulse pattern are read out from the converter 13 in series form and are supplied to an optocoupler consisting of a light emitting diode 15 and a phototransistor 16.

The pulses from the optocoupler are inverted in a network consisting of a resistor 17, a zener diode 18 and a transistor 19. This network is connected to the series circuit in which the coding means enters via a diode rectifier bridge 20. The zener voltage across the diode 18 is selected so that it is slightly larger than the voltage across the phototransistor 16 when the transistor is fully conductive. Therefore, as the phototransistor conducts, the transistor 19 becomes non-conductive. The current through the series circuit is then determined by the resistance in it outside the encoder, including in the receiver, and by the resistance of the resistor 17 and the supply voltage reduced by the voltage drop across the phototransistor 16 and the diode bridges 10 and 20. Since the phototransistor is non-conductive, the transistor 19 is conductive. The current through the series circuit is then determined by the resistance in it outside the encoder and the supply voltage reduced by the voltage failure across the diode 18, the transistor 19 and the diode bridges 10 and 20.

By means of the diode bridges 10 and 20, the current can pass the coding means in both directions depending on the polarity of the voltage source and the connection of the wires.

Figure 1i shows an example of a pulse pattern as phase with a coding means according to Figure 3. The coding means is supplied with a direct voltage and gives rise to a square wave current due to the time-varying impedance in this means. An example of a binary pulse pattern has been highlighted in the figure.

Figure 5 shows a second embodiment example on an encoder as above.

In this case, the coding rig is intended to be supplied with a pulsed voltage, for example a fykantsvagsspärinirig. The above voltage source 1 is thus not a DC source in this case. The device differs from that according to Figure 3 in that a digitizing circuit 25, 26, a diode 27 and a resistor 28 have been added.

Uessntnrn, the klnckpiils generator is not self-oscillating but controlled. This is now 461 084 6 10 15 20 5 C- denoted 12 'instead of 12 and has an input S for synchronizing pulses.

In operation, short pulses are formed by the differentiating circuit 25, 26, which are applied to the synchronizing input S of the clock pulse generator 12 '. Thus, clock pulses are generated which are synchronous with the pulsed supply voltage, and which are applied to the clock input CL on the parallel / series converter 13. The resistor 28 accelerates the discharge of the blocking capacitance in the diode 27 and the diode bridge 10, so that the synchronizing pulses become more distinctive.

The synchronism is intended to facilitate the detection of the pulse pattern in the receiver by making synchronous detection possible. However, the supply voltage does not have to be pulse-shaped but can have another regularly varying shape over time, for example sine, from which synchronizing pulses can be derived. Figure 6 shows an example of a pulse pattern, which is in phase with an encoder according to Figure S. The supply voltage is assumed to be square waveform and is denoted v and gives rise to a square wave-shaped current i. During certain voltage pulses the current assumes a higher and below the other voltage pulses a lower value due to the time-varying impedance of the coding means. The same binary pulse pattern as in Figure 4 has also been highlighted in this figure.

Some encoders may give rise to a pulse pattern corresponding to a significantly higher current sub-value than that of other encoders. In the case of signal lamps, in order for different ones to shine equally brightly, it may therefore be appropriate to adapt the supply voltage for each individual lamp or the components of each coding means to the pulse pattern which each coding means gives rise to. Figure 7 shows a third embodiment of an encoder according to the above.

According to this example, the zener diode bridge 10 in the above-described encoders has been discontinued and replaced by a single zener diode 29 between the optocoupler 15, 16 and the diode bridge 20. The differential circuit 25, 26 and the diode 27 have been drawn with dashed connection lines, with which means that they shall not be in the coding orphan law if this is intended for a time-varying: riutnings- fl 10 15 7 461 084 voltage. An advantage of this embodiment compared to those described above is that three zener diodes are saved.

The optocoupler 15, 16 described above in Figures 3, 5 and 7 has the task of electrically isolating the parallel / series converter 13 from the means 16-19. However, the optocoupler can be eliminated if the converter 13 has the same zero potential as the transistor 16. This can, at least in the case of direct current, be achieved by connecting an insulating direct voltage converter (DC / DC converter) in the power supply to the pulse generator 12 and the current converter 13. the serial output of the converter 13 directly to the transistor 16, which is then an ordinary transistor instead of a phototransistor.

The adjustable network 14 connected to the converter 13 can also be replaced by a ROM memory. In this case, a longer bit pattern can be obtained than is practically possible with stirrups as above.

Other possible areas of use for the device according to the invention than for railway signaling are, for example, control of valve condition, doors and load hatches and limit position controls in various machines.

Claims (1)

1. 461 D84 p. 10 10 PATENT REQUIREMENTS 1. Device for checking the condition of a remote-controlled device, for example a gear drive of a railway gear, characterized in that the device comprises a series circuit with a voltage source (1) and a receiving device. In means (2), a first and second coding means (lia, lib) located at the remotely controlled means are each arranged so that when it is passed through a current give rise to a pulse pattern characteristic of this means in this current and switching means (Ba , 3b) for in a first state of the remote control means coupling said first coding means (Isa) in the series circuit and for in a second state of the remote control means coupling said second coding means (lib) in the series circuit, and said receiving means ( 2) is arranged to emit logic signals depending on which pulse pattern appears in the series circuit. (Figure 1) Z. Device according to claim 1, characterized in that each of the coding means (ha, lib) comprises a means (10, 11, 28) for generating an internal supply voltage therein when a current flows through the coding means. , the polarity of which is independent of the direction of the current, a pulse generator (12, 12 ') for generating clock pulses, a means (13, 14) for generating in step with the clock pulses a pulse bar which forms a pulse pattern characteristic of the coding means, a means (16 -19) whose impedance changes depending on the pulses in the pulse pattern between two different values and a rectifier bridge (20) which: causes a current through the coding means to pass said means (16-19) whose impedance changes between two different values in one and the same direction regardless of the direction of the current. Device according to claim 2, characterized in that the voltage source (1) emits a direct voltage and that the pulse generator (12) is self-oscillating. fi. Device according to claim 2, characterized in that the voltage source (1) emits a voltage which varies regularly over time, for example a pulsed voltage or a sinusoidal voltage at each of the coding means (ba, üb). Also comprises a differentiating circuit (25, 26) to generate pulses in step with the now varying voltage and that the pulse generator -Il2 ') is controlled by these pulses. Device for checking the condition of a remote-controlled means, for example a signal lamp at a railway track, characterized in that the device comprises a device located at the remote-controlled means (6) and in series therewith. coupled coding means (4) arranged to, when it is passed through by a current, give rise to a pulse pattern characteristic of this means in this current and a receiving means (2) connected in series with the remote-controlled means (6) and the coding means (4) arranged to output logic signals depending on whether or not said pulse pattern is received. (Figure Z) 6. Device according to claim 5, characterized in that the coding means (li) comprises a means (10, 11, 28) for generating an internal supply voltage therein when a current flows through the coding means, the polarity of which is independent of the direction of the current, a pulse generator (12, 12 '') for generating clock pulses, a means (13, 14) for generating in step with the clock pulses a pulse bar which forms a pulse pattern characteristic of the coding means, a means (16-19) whose impedance depending on the pulses in the pulse pattern changes between two different values and a rectifier bridge (20) which causes a current through the coding means to pass said means (16-19) whose impedance changes between two different values in one and the same direction independent of the current direction. Device according to Claim 6, characterized in that the voltage source (1) emits a direct voltage and that the pulse generator (12) is self-oscillating. Device according to claim 6, characterized in that the voltage source (1) emits a voltage which varies regularly over time, for example a pulse voltage or a sine voltage, that the coding means also comprises a differential excitation circuit (25, 26) for generate pulses in step with the varying voltage and that the pulse generator (12 ') is controlled by these pulses.