DE9307718U1 - Circuit for resonance adjustment of the input and/or output resonant circuits of track circuits - Google Patents

Description

93G 40 70

Siemens AG

Circuit for resonance adjustment of the input and/or output resonant circuits of track circuits

The invention relates to a circuit according to the preamble of claim 1. Such track circuits are known from DE 29 51 124 C2, among others.

Track circuits are used to detect the occupancy status of a track section they monitor. To do this, a voltage is coupled into the rails at one end of the track section and the presence or absence of this voltage is determined at the other end. As long as the respective receiver receives a sufficiently high voltage level, the corresponding track section is reported as free. If a vehicle entering the track section short-circuits the two rails with its axles, the reception voltage at the track circuit receiver collapses and the section is reported as occupied.

To monitor adjacent track sections, the rails are either separated at the joints of the sections and insulated from each other or at least connected at the receiving end of the individual track sections by rail connectors, where the signal voltages coupled into the rails on the transmitting side are detected. For this purpose, the rail connectors are either designed to be frequency-selective, whereby they are tuned to the respective transmission frequency of the associated track circuit transmitter, or they are not designed to be frequency-selective; in this case, the voltage is measured at a

Gi/Nim / 17.05.93

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Rail connectors and/or the rails are coupled to a parallel resonant circuit, whose resonance frequency corresponds to the frequency of the respective track circuit transmitter (DE 29 51 124 C2). Successive track circuits are operated with voltages of different frequencies.

In order to ensure that the voltage that can be extracted from such an oscillating circuit on the receiving side changes as significantly as possible at the joints between two track sections, the receiving-side decoupling oscillating circuits must be tuned to the respective track circuit transmission frequency. This must be done on site, because the total inductance of the respective oscillating circuit is not only dependent on the inductance of the conductor loop used, but also on the inductance of the rails to which the respective receiving loop is coupled. The same considerations apply to the feeding of signal voltages into the rails on the transmitting side of the track circuits.

The object of the invention is to provide a circuit according to the preamble of claim 1, which allows the input and/or output resonant circuits at the isolating joints of track circuits to be adjusted to resonance with as little effort as possible.

The invention solves this problem by the characterizing features of claim 1. Advantageous embodiments and further developments of the invention are specified in the subclaims.

The invention is explained in more detail below with reference to an embodiment shown in the drawing.

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The drawing shows a schematic of a railway track in the area of an insulated joint-free isolating joint ET, between whose two rails Sl and S2 a multi-layered conductor loop Li is laid in such a way that a close coupling of parts of this conductor loop with the rails is ensured. This conductor loop is used to feed voltages of a specified frequency into the rails. The track currents flowing due to these voltages coupled into the rails are used at a remote location by at least one receiver provided for this purpose and tuned to the frequency of the track circuit transmitter to report the track section between the transmitter and receiver as free and occupied; the decoupling of the track current or a track current-dependent voltage on the receiving side can take place galvanically or inductively.

In order to achieve the highest possible signal level for coupling the highest possible track voltages into the rails of a track section, the conductor loop Ll must be adjusted to resonance together with a capacitor Cl; this is done by changing the capacitance of the capacitor Cl. The oscillating circuit must be adjusted on site because the inductance of the feeding oscillating circuit is not only determined by the inductance of the conductor loop Ll, but also by the inductance of the rails. The circuit shown in the drawing to the left of the feeding oscillating circuit is used to adjust the oscillating circuit. This circuit does not require an oscilloscope or frequency meter or the power supply devices required to operate them. It includes, among other things:

a quartz-controlled generator G, whose frequency can be adjusted to the respective nominal frequency of the track circuit to be fed, which is connected via an amplifier Vi and an ohmic decoupling resistor Rl to the output A of the

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circuit. The oscillating circuit to be tuned is connected to this output. A digital phase comparator is also provided, via which the generator frequency is compared with the resonance frequency of the oscillating circuit to be tuned. For this purpose, a voltage is coupled out of the generator's supply circuit via a high-pass filter HPi in front of the resistor Rl to block low-frequency interference voltages and is fed to a pulse shaper IFi, which provides square-wave signals of a specified level with a pulse-pause ratio of 1:1 at its output. Behind the resistor Ri, a voltage is also coupled out via a high-pass filter HP2 and made available to a pulse shaper IF2 corresponding to the pulse shaper IFl; depending on how far the resonance frequency of the oscillating circuit deviates from the reference frequency of the generator, this voltage has a more or less large phase deviation from the voltage coupled out before the resistor Rl. From this voltage, the pulse shaper IF2 forms a square wave voltage of the same amplitude as the pulse shaper IFi and the same pulse-pause ratio, which is shifted to one side or the other in relation to the square wave voltage of the pulse shaper IFl according to the deviation between the resonance frequency and the generator frequency, i.e. it either leads or lags behind this voltage.

The outputs of the two pulse formers are fed to a downstream EXOR element EO, which, as a result of the dynamic control of its inputs by the output signals of the two pulse formers, provides a square-wave voltage at its output, the pulse-pause ratio of which varies depending on the phase shift of its two input voltages. The duration of the output pulses of the EXOR element with respect to the pulse pauses increases with increasing offset of the output signals of the two pulse formers. The output clock signals are in

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a first RC element RC1 and fed to an amplifier V2. On the output side, this amplifier acts via a further RC element RC2 on a light-emitting diode field AL, which consists of several light-emitting diodes arranged next to one another on an arc or on a bar and which depending on the respective design of a control logic not shown in the drawing, either by the number of light-emitting diodes switched on or by the position of the light-emitting diode switched on within the light-emitting diode field indicates how far the respective resonance frequency of the oscillating circuit to be tuned differs from the reference frequency of the generator. The arrangement is selected in such a way that as the resonance frequency of the oscillating circuit is increasingly adjusted to the applied generator frequency, the input voltage at the light-emitting diode field decreases; another voltage curve could also be achieved using an inverting amplifier instead of the amplifier V2.

In addition to this LED array, there is another LED AP. This LED is fed from a NAND gate U via a monostable flip-flop M. The inputs of this NAND gate are connected to the output of the EXOR gate and to an output of one of the two pulse formers. Depending on which of the two pulse formers the NAND gate is connected to, the LED AP will either light up if the adjustment capacitor Cl is too high or too low. The LED AP is therefore used to identify in which direction this capacitor should be changed so that the resonance frequency of the oscillating circuit to be tuned matches the reference frequency of the generator. An operator now has nothing else to do than to determine the degree of detuning via the LED array and the direction

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in which the oscillating circuit is detuned compared to the reference frequency. By specifically adjusting the capacitance of the tuning capacitor Ci, the resonance frequency of the oscillating circuit to be tuned can be set to the reference frequency of the generator.

For this purpose, the operator has access to the capacitor Cl, which is housed together with the connections of the conductor loop in a connection housing near the track.

In order to be able to see by what amount the adjustment capacitor Cl needs to be changed, the operator can use a separate tuning capacitor C2, which is part of the circuit. If the operator adjusts the oscillating circuit using the capacitor C2 instead of the capacitor Cl, he can read from this capacitor the amount by which the capacitor Cl needs to be changed in order to achieve maximum energy feed into the track section to be monitored after the circuit has been removed. The capacitor C2 therefore makes the operator's work easier during adjustment because it is not necessary to gradually change the adjustment capacitor Cl in the connection housing until the oscillating circuit is adjusted to the reference frequency.

In the same way as in the case described above, the receiving-side resonant circuits of track circuits can also be tuned to specified receiving frequencies, whereby the respective receiving frequency must be compared with a corresponding reference frequency of the generator. The generator must be set to the respective nominal frequency of the track circuit. In contrast to the previously described embodiment of a transmitting resonant circuit, the receiving-side resonant circuits

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each arranged near rail connectors, via which the individual track circuits are closed.

To tune such receiving-side oscillating circuits, it is necessary - if the relevant information is not available - to first determine the frequency to which these oscillating circuits are to be tuned before fine tuning. To achieve this, parts of the circuit according to the invention can be used in conjunction with the LED field. To determine the frequency of a track circuit, an operator must first establish a connection from the receiving-side oscillating circuit to the input terminals E of the circuit. By switching the contacts Sl and S2 to carry out such a frequency search process, the voltage that can be coupled out of the receiving oscillating circuit is passed via the high-pass filter HPi and the pulse shaper IFl to one connection of a decoupling resistor R2. At the other connection of this resistor is a network of capacitors C3, C4 to Cn and an inductance L. With the help of the capacitors that can be switched on as required, this oscillating circuit can be set to any of the desired track circuit frequencies. If the frequency of the receiving oscillation circuit matches the set resonance frequency of the oscillation circuit made up of the inductance L and one or some of the capacitors C3 to Cn, a voltage maximum is produced at the input of an amplifier V3 compared to an arrangement in which the resonance frequencies of the receiving oscillation circuit and the adjustable oscillation circuit are different from one another.

The voltage output by amplifier V3 is rectified in a rectifier D and reduced to a minimum voltage using a differential amplifier V4. This is necessary so that the existing display logic of the light element field can be used in the same way as in the

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Fine tuning of the transmit and receive oscillation circuits can be used. If the resonance frequency of the receive oscillation circuit approximately matches the reference frequency of the oscillation circuit set from the inductance L and one or more of the capacitors Cl to Cn, the display of the LED field goes in the direction of: adjustment made. In order to then be able to fine tune the receive oscillation circuit, after switching the switches Sl and S2, the generator G of the circuit is set to the frequency that was specified by the capacitors of the circuit-side oscillation circuit that were previously connected. The fine tuning of the track-side oscillation circuit is then carried out in the same way as for fine tuning the transmit oscillation circuit with the aid of the capacitor C2 and by subsequently changing the capacitor Cl.

The circuit according to the invention for adjusting the transmitting and receiving oscillating circuits of track circuits requires only a few commercially available components and allows the adjustment to be carried out without having to use complex measuring equipment. The visual control of the adjustment process on a light-emitting diode field clearly shows the observer how large the frequency deviation still is and, using the additional light-emitting diode, in which direction the adjustment process should be continued.

Claims (7)

9364070 Protection claims 1. Circuit for resonance adjustment of the input and/or output resonant circuits of track circuits using at least one generator for outputting reference voltages tuned to the nominal frequencies of the individual track circuits and a track-side parallel resonant circuit consisting of an inductance formed from a variable capacitance and from a conductor loop and/or at least parts of the rails, characterized in that the alternating voltage generated in the generator (G) is applied to a series circuit consisting of a decoupling resistor (Rl) and the tunable resonant circuit (Ll, Ci), that high-pass filters (HPl, HP2) are connected before and after the decoupling resistor, the outputs of which are connected to pulse forming stages (IFl, IF2) which supply square-wave voltages with a predetermined pulse-pause ratio, that the outputs of these arrangements are connected to the inputs of an exclusive-OR circuit (EO), and that the output of this circuit is connected via an RC combination (RCl) to the input of a control for a light-emitting diode array (AL). 2. Circuit according to claim 1,
characterized in that an adjustable capacitor (C2) is connected in parallel to the tunable resonant circuit (Cl, Ll), with which the change in capacitance necessary to achieve resonance can be determined. 93G4070 3. Arrangement according to claim 1 or 2, characterized in that, to display the phase position, outputs of at least one pulse shaping stage (IFl) and the exclusive OR circuit (EO) are connected to the inputs of an AND or NAND gate (U) and that the output of this gate acts on a light-emitting diode (AP) via a monostable flip-flop (M). 4. Circuit according to claim 1, characterized in that the light-emitting diode field is designed as a bar or segment indicator. 5. Circuit according to claim 1 or 4, characterized in that the control of the light-emitting diodes of the light-emitting diode array takes place in point operation. 6. Circuit according to claim 1, characterized in that the output of the exclusive OR circuit is connected via an RC combination (RC1) to the input of an inverting amplifier, the output signal of which acts via a further RC element (RC2) on the control of the light-emitting diodes of the light-emitting diode array. 7. Circuit according to claim 1,
characterized in that an alternating voltage, the frequency of which is to be determined and which can assume one of several possible values, can be connected to the series circuit comprising a high-pass filter (HPl) and a pulse-forming stage (IFl), that the output of the pulse-forming stage is connected to a series 93G 4070 resonant circuit consisting of an inductance (L) and
switchable capacitances (C3, C4, Cn) for adjusting this oscillating circuit to one of the possible frequencies, and that the light-emitting diode field can be controlled via a diode (D) and a differential amplifier (V4).