WO2008138858A1 - Wheel sensor - Google Patents

Abstract

The invention relates to a wheel sensor, in particular for a track clear detection unit, comprising two sensor channels (A, B) that work inductively and have a separate transmitter and receiver that are separated by a railway (1). The aim of the invention is to compensate interference voltages simply and effectively. To achieve this, a processing unit is provided to evaluate the level of received signals (8, 9) of the sensor channel (A or B) that is affected by the passing of a wheel and the other non-affected sensor channel (B or A). The processing unit has means for linking the received signals, (in particular by subtraction) (8, 9) of the non-affected and affected sensor channel (A, B).

Description

description

wheel sensor

The invention relates to a wheel sensor, in particular for a Gleisfreimeldeeinrichtung, with two inductively operating sensor channels having separated by a railroad transmitter and receiver.

Wheel sensors are used in the rail industry for the track vacancy, but also for other switching and reporting tasks. In this case, predominantly the magnetic field influencing effect of the iron wheels of rail vehicles is utilized. Two-channel sensors are needed to detect the train's direction of travel. When driving a vehicle wheel, the two sensor channels create sequentially offset in time ^¬ Sig nal, which are used for direction detection.

The operating according to the inductive mode of action wheel sensors can be in addition to the one- or two-channel design in proximity switches that detect the reaction of the iron wheels on a magnetic field generating sensor, and railroad systems encompassing systems with separate transmitter and receiver. The invention relates to a two-channel wheel sensor with separate transmitters and receivers.

All inductively operating sensors have in common that they are susceptible to interference with inductively coupled interference voltages in the range of the working frequency.

A cause of the disturbances are rail currents, which arise through the return current of a locomotive, whereby a harmonic content in the receiver generates a disturbance signal in the form of can induce exercise. This beating, which is superimposed on the received voltage, is difficult to separate from the wheel influence to be detected, because in this case low-pass filters fail as a matter of principle.

Another cause of interference voltages can also be arranged adjacent other sensors or sensor channels, which are operated at the same operating frequency and lead by mutual influence of their transmitter to beats.

In addition to a Dauerstörpegel on working frequency but can also high Kommutierungsstromflanken of up to 1 kA / microseconds occur that disturb impulsively. Interference signals of this kind are mainly induced by passing trains through their lines and transformers.

In order to increase the interference immunity of the sensors with respect to these disturbances, various sensor-type-specific approaches are known.

For the sensor design with only one reactance to the iron mass of the Ra ^{¬ of} the resonant circuit coil per channel, that is for proximity switches, a substantial compensation of the induced interference voltages by dividing the oscillating circle coil in at least two partial coils with opposite directions

Winding can be achieved, as described in DE 19 915 597 Al and DE 10 137 519 Al.

In generic wheel sensors with separate transmitter and receiver resonant circuits is proposed according to DE 10 122 980 Al to change the resonant frequency of the receiver resonant circuit relative to the transmitter frequency, in particular to suppress the interference of an eddy current brake. From DE 4 240 478 A1, a two-channel wheel sensor is known in which the two transmitters are operated at the same frequency, but with a 90 ° phase shift, in order to reduce the mutual influence of the transmitters.

According to EP 1 541 440 B1, a phase modulation of an electromagnetic resonant circuit for wheel sensors is proposed.

The invention has for its object to provide a gattungsge ^¬ MAESSEN wheel sensor having a simple design, increased interference immunity to interference voltages of different causes.

According to the invention the object is achieved in that a

Processing unit for level evaluation of received signals of the sensor influenced by a wheel passage sensor channel and the other, uninfluenced sensor channel is provided, wherein the processing unit comprises means for linking, in particular subtraction, the received signals of the uninfluenced and the affected sensor channel. Consequently, the two Sen ^¬ sorkanäle set next to a sum signal that includes a desired signal and an interfering signal, the interfering signal also available, which is used for large compensation of the induced interference by subtracting from the sum signal.

The purpose of the processing unit, which is preferably designed as a microprocessor. To the thus kom ^¬ pensierbaren interference include rail currents whose coupling is almost identical in both sensor channels and interference from other sources, for example due to the wheel sensor parallel running power cables or adjacent sensors. But even disturbances that are not induced as common mode noise, can be compensated, since the noise levels of any origin are measured quasi. In accordance with claim 2, each sensor channel is equipped with a transmitter-resonant circuit, wherein the two transmitter-Schwing ^¬ circuits have different operating frequencies. These operating frequencies differ in an order of magnitude in which the beats resulting from the coupling in of the respective other transmitter oscillation circuit can be suppressed by a low-pass filter on the receiver side. For example, the operating frequencies may be 40 kHz and 45 kHz.

A wheel sensor for detecting a Radbeeinflussung is characterized according to claim 3, characterized in that the two receivers each have a receiver resonant circuit, the Aus ^¬ output signal via a synchronous rectifier, which is controlled by the transmitter of the other sensor channel, a low-pass filter and a signal amplifier of the processing unit is supplied. In principle, it is sufficient to further process the signal from each receiver ^¬ gear-resonant circuit in each case one signal processing channel. According to the Radüberfahrt the first or the second sensor channel at the receiving end, a sum signal, containing the wanted signal with superimposed interference signal is produced on the first or the second Sig ^¬ nalverarbeitungskanal. The other, uninfluenced signal processing channel is acted upon only by the interference signal, so that the useful signal can be determined by subtraction in the processing unit.

The demodulation of the received signal is carried out in each signal ^¬ processing channel by synchronous rectification, that is, the phase of the transmitter acts on the synchronous rectifier ^¬ rectifier for phase-synchronous rectification of the received alternating signal. Synchronization signals of both transmitters are fed virtually cross-over to the synchronous rectifier of the other channel. As a result, the received signal is back in his transmitter-specific frequency components decomposed and rectified. The following lowpass serves to suppress the beats that have developed on the transmitter side. After the low-pass filter is followed by a signal amplifier for level adjustment, the output signal of the processing unit, in particular a microprocessor, is evaluated.

In a preferred embodiment characterized in claim 4, the output of each receiver Schwingkrei- ses two signal processing channels with synchronous rectifier, low pass filter and signal amplifier is supplied, wherein a synchronous rectifier of the transmitter of the one sensor channel and the other synchronous rectifier is driven by the transmitter of the other sensor channel. In this way, no signal processing channel must be used twice, that is, depending on the wheel crossing influenced state of the sensor channel either the sum signal or the noise processing. The level evaluation in the processing unit is simplified, since for each required input signal, namely the sum signal and interference signal for the one sensor channel and the sum ^¬ signal and interference signal for the other sensor channel, a sepa ^¬ rater signal processing channel and thus a specific input for the processing unit available stands. Ultimately, the safety of the wheel sensor function increases.

The invention based on a figurative Darge ^¬ presented embodiment will be explained in more detail.

The figure shows a block diagram of a wheel sensor.

It can be seen that the left and right of a railway rail 1 transmitter-resonant circuits 2 and 3 and receiver-Schwing ^¬ circuits 4 and 5 are arranged, which are associated with two sensor channels A and B. The two transmitter resonant circuits 2 and 3 are tuned to different operating frequencies, for example 40 kHz and 45 kHz. In a Radüberfahrt changed ^¬ the inductive coupling changed 6 and 7 between the transmitter resonant circuit 2 and 3 and the receiver resonant circuit 4 or 5, whereby at the output of the receiver oscillating circuit 4 and 5, a Empfangssig ^¬ nal 8 and 9 in Form of a so-called rolling curve or bell curve is formed. This rolling curve is used for Rader ^¬ recognition. By passing over both sensor channels A and B, two time-shifted signals are generated, which are used for

Direction detection can be used. The received signals 8 and 9 are each fed into two signal processing channels 10a and 10b or IIa and IIb whose essential components are synchronous rectifiers 12a and 12b or 13a and 13b, low-pass filters 14a and 14b or 15a and 15b and signal amplifiers 16a and 16b or 17a and 17b are. The synchronous rectifier 12a and 13a ^¬ the driven from the transmitter resonant circuit 2 of the first sensor channel A and the synchronous rectifier 12b and 13b are controlled by the station resonant circuit 3 of the second sensor channel B at ^¬. For this control, the phase position 18 be ^¬ tion 19, whereby the synchronous rectifier 12a and 13a or 12b and 13b can perform a phase-synchronous Gleich ^¬ direction of the receiving signal formed as an alternating signal 8 and 9 respectively. In this way, the received signal is 8 or 9 decomposed into its sender's specifi ^¬ frequency components, namely on the signal processing channels 10a and IIa for the sensor channel A and the signal processing channels 10b and IIb for the sensor channel B. By cross-demodulation is from a signal processing channel 10b respectively IIa of the associated Sensororka ^¬ nals A and B demodulated that signal component, that is filtered out, the on the working frequency of each ^¬ Weil's other sensor channel B or A from an ex- ternal source of interference in the receiver resonant circuit 4 relationship ^¬ 5 was induced. The signals on the other two signal processing channels 10a and IIb are obtained with by the demodulation of the circle directly Radüberfahrt the transmitter oscillating 2 or 3 coupled received signals 8 or 9. Thus ^¬ result to the signal processing channels 10a and IIb sum signals, the useful signal that and include the interference signal, and on the other two Signalverarbeitungska ^¬ channels 10b and IIa only the interference signals. In the subsequent low-pass filter 14a, 14b, 15a, 15b of each of the four Signalverarbei ^¬ processing channels 10a, 10b, IIa, IIb by the Einkopp- development of the respective other transmitter resonant circuit can be suppressed 2 relationship ^¬, 3 beats caused. This low-pass filtering ^¬ is possible because of the different operating frequencies of the transmitter resonant circuits 2 and 3. FIG. The low-pass 14a, 14b, 15a, 15b is connected via the signal amplifier 16a, 16b, 17a, 17b, which is used for level adjustment, with inputs U_A and U_b and U_b_stör U_a_stör and a microprocessor 20 verbun ^¬. The inputs U_a and U_b represent the two sum signals and U_b_stör and U_a_stör the two Störsig ^¬ signals. The microprocessor 20 combines the analog signals U_a and U_a_stör and U_b and U_b_stör with the possibilities of digital signal processing and generates an output signal 21 and 22, which is the difference U_a - U_a_stör and U_b - U_b_stör in the simplest case, and ultimately decides whether registered a bike crossing or not, or if an error message is issued.

Claims

claims 1 wheel sensor, in particular for a track vacancy detection device, with two inductively operating sensor channels (A, B), which by a railway track (1) separate transmitters and receivers ^¬ ger, characterized in that a processing unit for level evaluation of receive ^¬ signals (8,9 ) of the influenced by a Radüberfahrt sensor channel (a or B) and the respective other, uninfluenced sensor channel (B or a) is provided, wherein the proces ^¬ processing unit means for linking, in particular Subtrak ^¬ tion, the reception signals (8,9) of the unaffected and affected sensor channels (A, B). 2. Wheel sensor according to claim 1, characterized in that the sensor channels (A, B) transmitter oscillating circuits (2,3) are assigned, which have different operating frequencies. 3. Wheel sensor according to one of the preceding claims, characterized in that the two receivers each having a receiver resonant circuit (4,5) whose output signal via a synchronous rectifier (12b, 13a), the transmitter of the other sensor channel (A , B) is driven, a low-pass filter (14b, 15a) and a signal amplifier (16b, 17a) is supplied to the processing ^¬ processing unit. 4. Wheel sensor according to claim 3, characterized in that the output signal of each receiver resonant circuit (4,5) two signal processing channels (10a, 10b, IIa, IIb) with synchronous rectifier (12a, 12b, 13a, 13b), low-pass filter (14a, 14b, 15a, 15b) and signal amplifiers (16a, 16b, 17a, 17b) is guided to ^¬, wherein a synchronous rectifier (12a, 13a) from the transmitter of the one sensor channel (A) and the other Syn ^¬ chrongleichrichter (12b , 13b) is driven by the transmitter of the other sensor channel (B).