NL1018356C2 - Method and rail vehicle for improving railway security circuits involve detection of presence or otherwise of railway vehicle in part of selection to be covered by it - Google Patents

Abstract

The method and rail vehicle for improving railway security circuits involve detection of the presence or otherwise of a railway vehicle in a part of a section to be covered by it. It involves a voltage difference applied between two rails whereby the presence or absence of voltage difference over the part of the track is measured. The voltage difference between the rails is reduced from the vehicle actively to a predetermined value. In order to reduce the voltage difference between the rails, the rail vehicle is provided with at least two axles with wheels (1,2) on both sides for travelling over the rails and a measurement device (M) for measuring the voltage difference. To the measurement device is connected an active regulating device (R) to apply to the rails a frequency signal with complete capacity to bring the measured voltage difference to below a predetermined level.

Description

METHOD AND RAIL VEHICLE FOR THE IMPROVEMENT OF RAILWAY PROMOTION C1RCUITS

5 For rail transport, it is of great importance that the vehicles maintain a mutual distance such that the timely and safe braking of the vehicles at all speeds is less than approx. 70 km / h at all speeds.

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direct personal observation is insufficient and automatic systems are generally used to determine the position of a train on a route. If a train is present in a certain part of that route, a succeeding train will not be allowed to use that same part. Needless to say, for rail transport without a driver, such automatic protection is even more important.

A known system for protecting train traffic is called: automatic block system with protection by light signals. In this system, a track is subdivided into sections of varying length, for example from a few hundred meters to a thousand meters in length, also called blocks, in which only one train may be located. With the aid of a light signal, in modern systems also with a signaling in the driver's cabin, the driver is granted or denied access to a block 20.

In order to determine the presence or absence of a train in a block, track circuits or track steam runs are used in practice. With the aid of a transmitting device, a voltage difference is applied between the rails from one side of a block while on the other side there is a receiving device 25 in order to receive the voltage difference transmitted via the rails. If there is a train between the transmitter and the receiver, the rails are short-circuited at the bottom line and the receiver will no longer receive a signal, so that it is detected that the block is occupied.

Under normal circumstances, the contact between an electrically conductive wheel, normally made of steel, of a rail vehicle and the conductive rail, normally also made of steel, has good electrical conductivity properties. In the case of contamination of the rails or wheels by, for example, leaf residue, rust formation, sand or other non-conductive or poorly conductive substances, the short-circuiting effect between the rails in the presence of a train may be insufficient. If, due to such circumstances, it is not detected that a train is present, dangerous situations may occur, which must be avoided under all circumstances.

In the article “Train detection by track circuit, the effect of the wheel / rail interface from R.A. Wood, published in 1RSE ASPECT99 International Conference on 5 Sustainable Train Control for the Next Century, London, September 1999 ", is in addition to an overview of the possible properties of the wheel-rail contact, where both linear and non-linear characteristics occur, a number of methods are described for avoiding the effects of poor electrical contact between wheel and rail and improving electrical contact.

Methods and systems are described in U.S. Pat. No. 3,850,390, U.S. Pat. No. 3,958,782 and the equivalent Pat. No. NL 7601224 to recognize the occurrence of poor contact between wheel and rail. The disadvantage of this indirect method is the lack of absolute certainty with regard to good and poor working contact.

In the method described in U.S. Pat. No. 5,170,970, a high-frequency auxiliary voltage is applied to the rails with an amplitude such that the insulating layer breaks down between the wheel and rail and conduction for the signals of the track current path is also established. This method also lacks absolute reliability.

In addition to the above-mentioned systems and methods that operate from the road, solutions have already been proposed in the past that operate from the vehicle. Poor electrical contact on a certain route must be taken into account when introducing new modern railway vehicles.

In Japanese patent specification JP 09 099 837 two electrically short-circuited brushes are mounted on the vehicle, each of which makes contact with one of the two rails. The solution is maintenance-sensitive due to wear of the brushes and therefore also does not provide absolute certainty.

In Japanese patent specification JP 56 145 701, electrically short-circuited rollers are pressed onto the rails, the pressure force on the rollers being limited by the weight of the vehicle (which also applies to the normal wheels of the vehicle). This also results in wear and tear, which makes the solution susceptible to maintenance while operation is not absolutely guaranteed.

In U.S. Pat. No. 3,913,874 a high-frequency auxiliary voltage is applied from the vehicle to the rails with brushes in the vehicle, as a result of which the insulating layer is broken and the protective current can flow. A second set of brushes checks whether the improving effect of the current supplied by the first brush set has actually occurred. Here too wear occurs, which requires regular maintenance.

The system described in U.S. Pat. Nos. 2,211,181 and 2,176,616 has the same object: to break the insulating layer by applying an additional voltage. In this case the voltage is an alternating voltage and is supplied to the rails via the wheels.

In the article "Lightweight Vehicle Track Shunting, by Thomas K. Dyer, published in April 1981 by the US Department of Commerce National Technical Information Service", breakdown of the insulating layer between wheel and rail is achieved through inductive coupling. The transformer contains only one secondary winding, while due to a so-called loose coupling much voltage loss occurs in the transformer itself. If the contaminating layer has a predominantly linear electrical characteristic with an increased resistance value, the solution brings no improvement. The certainty of correct operation is also not guaranteed.

British patent GB 22 381 50 describes a method in which the contaminating layer between wheel and rail is breached from the vehicle by means of an induction loop which induces a current in the circuit consisting of the axles, the wheels and the rails. For this solution the disadvantages are the same as mentioned in connection with the above article.

Patents DE 631,804 and US 2,024,845 describe two similar systems that are both based on the principle of an active control system. An active system, however, can only be used safely if it is provided for detecting that the control circuit is not closed. In addition, the implementation is based on the use of electromechanical components. As a result, the principle as described in these patents can only be applied to track current runs with direct voltage and alternating voltages with low frequency. In addition, the control system is maintenance sensitive.

The present invention provides a method for detecting the presence or absence of a rail vehicle in a portion of a path to be traveled by the rail vehicle, wherein a voltage difference is applied between two rails with the presence or absence of the voltage difference across the part of the route

Um 83 5 6 4 is measured and the voltage difference between the rails from the rail vehicle is actively reduced to a predetermined value.

The present invention makes it possible to determine with certainty on the rail vehicle itself whether the device functions properly, irrespective of the electrical characteristics of possible contaminating insulating layers between wheel and rail and without excessive wear occurring.

The present invention also provides a rail vehicle provided with at least two axles with wheels on both sides for traveling over rails, wherein a voltage difference is present between the two rails and wherein the rail vehicle is provided with a measuring device for measuring said voltage difference, as well as of an active control device connected to the measuring device for applying to the rails a frequency signal of sufficient power to bring the voltage difference measured by the measuring device below a predetermined level.

In a preferred embodiment use is made of wheels in which the outer parts are insulated from the inner parts. If the measuring device is connected between the outer parts on the first axle and the output signal of the control device is applied to the outer parts of the wheels of the second axle, the wear due to the transmission of electrical signals can remain low, so that a great certainty about guaranteed for a long period of time.

In a further preferred embodiment, the transmission of the measurement signals takes place wirelessly, so that no wear can occur.

In a further preferred embodiment use is made of a switching power amplifier in which the transfer of energy is based on pulse width test. Thanks to the switching power amplifier, interference due to a polluting layer between wheel and rail is further reduced.

In order to give the measuring circuit for the switching frequency of the power amplifier a low impedance, a resonance circuit with suitable adjustment is preferably connected in parallel with the measuring device.

Further advantages, features and details of the present invention will be elucidated on the basis of the following description of a preferred embodiment thereof, with reference to the accompanying drawings, in which:

FIG. 1A, IB respectively diagrams of an existing train detection system in a first and second position, respectively

FIG. 2A is a diagram of a preferred embodiment of a method and rail vehicle according to the present invention.

A voltage difference of, for example, approximately 5 V is applied to the rails 2 by the transmitter 1 of the track current path. At some distance, that is to say a few hundred or a thousand meters away, a receiver 3 is connected between the rails, to which a green light signal 4 and a red light signal 5 are connected. Fig. 1A indicates the situation in which there is no train between the transmitter and the receiver and the green light signal 4 lights up.

As indicated in Fig. 2B, the voltage difference between the rails is eliminated by short-circuiting through at least one of the axes with conductive wheels 6, whereby the red light signal is energized by receiver 3.

In the railway vehicle according to a preferred embodiment of the present invention (fig. 2) schematically indicated by means of two wheel sets on the rails 15, the outer parts of these wheels are insulated relative to the axles and the inner parts of the wheels. On the outer parts of wheels contacting two respective rails, a measuring cell 1 is connected wirelessly or otherwise to a measuring member M, which is connected via a filter F to a control member R in which the measured voltage difference is compared with a desired reference value Ref. The output signal of the reference member is connected to a compensation device C which is connected via a power amplifier V to current voltage transfer member 2 which is connected to two other isolated mounted wheels in order to realize the desired voltage between the rails.

For use in combination with alternating current track current paths, wireless transmission of the control variable to be measured can take place in an alternative form by taking the current flowing in the measuring axis as a measure of the voltage present between the rails. A measuring coil arranged around the measuring axis then supplies the measuring signal for the current flowing through the axis. The great advantage here is that the measuring axis does not have to have insulated wheels. This is also advantageous for the characteristics of the vehicle with regard to electrical short circuit between the rails in case the active control system does not function due to defects or otherwise. The rigid, non-insulated measuring axis will behave like a conventional axis, in which case of course no improvement of the active control system will occur, but the vehicle will have the same behavior as a vehicle without the active control device. However, this point can be very important for assessing the safe applicability of the active scheme.

If it is determined in the measuring device M that the voltage difference is present between the two rails, this voltage difference is adjusted back via the control member to a desired (and adjustable) voltage difference. In this case the receiving device of course also determines with certainty that a train is present. In practice it will have to be determined what the maximum required power will be for reducing the voltage difference between the rails to the desired reference level of, for example, zero 10 V.

The above-mentioned parts of the preferred embodiment can be performed both analogously and digitally. In the embodiment in which, for example, filter insertion, compensation device and monitoring device are digitally implemented, it is conceivable that the measuring device and the filter device are integrated into a single circuit in which both functions are combined. The control member and the compensation device can also be integrated into a single circuit.

Transmission of signals from and to the rotating wheels is done in the first PREFERRED EMBODIMENT using slip rings. In particular, however, the measurement signals can also be transmitted wirelessly at a high frequency. If the current through the measurement axis is chosen as the control variable, a first preferred embodiment uses a rigid, non-insulated measurement axis around which a measurement coil is mounted.

The power amplifier can be in the form of a linear amplifier or a switching amplifier, based on pulse width control, pulse frequency control or other techniques.

In the latter case, a resonant circuit can be arranged parallel to the measuring device, which circuit is tuned to the switching frequency of the switching amplifier so that the measuring device forms a low impedance for this frequency. The high-frequency switching signal contributes to an electrical breakdown of a possibly polluting layer between wheel and rail at the location of the wheels where the measurement is to take place.

In the preferred embodiment shown, furthermore, a monitoring device B is connected to the power amplifier V in order to check the proper operation of the control system, for example by simultaneously measuring the magnitude of the output voltage and 7 output current of the power amplifier. Further conceivable checks can be made on the harmonic composition and the magnitude of specific frequency components of the voltage and current are applied to the rails.

The present invention is not limited to the above described preferred embodiments thereof; the rights sought are defined by the following claims within the scope of which many modifications are conceivable.

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Claims (13)

Method for detecting the presence or absence of a rail vehicle in a part of a route to be traveled by the rail vehicle, characterized in that a voltage difference is applied between two rails, the presence or absence of the voltage difference over the part of the route is measured and wherein the voltage difference between the rails from the rail vehicle is actively reduced to a predetermined value. 2. Rail vehicle provided with at least two axles with wheels on both sides for driving over rails, wherein a voltage difference is present between the two rails and characterized in that the rail vehicle is provided with a measuring device for measuring said voltage difference, and with an active control device connected to the measuring device for applying a frequency signal of sufficient power to the rails to bring the voltage difference measured by the measuring device below a predetermined level. Rail vehicle according to claim 2, characterized in that the wheels on at least two of the axles are at least partially electrically insulated relative to each other. Rail vehicle according to claim 2 or 3, characterized in that the outer parts of each of the wheels are electrically insulated relative to the inner part of those wheels Rail vehicle according to claim 2, 3 or 4, characterized in that the measuring device makes use of a wireless signal transmission from the wheels. 6. Rail vehicle as claimed in claim 2, characterized in that at least one of the axles has non-electrically insulated wheels while at least one of the other axles is provided with wheels of which the outer part is electrically insulated from the inner part. Rail vehicle according to claim 6, characterized in that the measuring device makes use of a measuring coil which is arranged around the rigid, non-insulated axle of the vehicle. Rail vehicle as claimed in one or more of the claims 2-7, characterized in that the control unit comprises a power amplifier for delivering an electric frequency signal of sufficient magnitude to the rails. - Rail vehicle as claimed in one or more of the claims 2-7, characterized in that the generating circuit for the electric frequency signal is connected via sliding contacts to the outer parts of the tracks. Rail vehicle as claimed in one or more of the claims 2-9, characterized in that the correct operation of the control device is checked by a device for monitoring the voltage and / or current associated with the frequency signal. Rail vehicle as claimed in one or more of the claims 2-10, characterized in that the control device is provided with a filter device for transmitting signals in the frequency range of the electrical signal applied to the rails. Rail vehicle as claimed in one or more of the claims 2-11, characterized in that the power amplifier is designed for switching. Rail vehicle according to claim 12, characterized in that a resonant circuit is connected in parallel with the measuring device, which resonator is tuned to the switching frequency of the power amplifier. 15 1018356