SELF-SUPPLIED DEVICE FOR A LOGISTIC/DIAGNOSTIC MONITORING FOR RAILWAY VEHICLES

Abstract

A self-supplied device for a logistic/diagnostic monitoring for cargo type railway vehicles, adapted to be applied to an axle of a vehicle, rotating during the vehicle travel; the device comprises an autonomous electric generator to generate electric power from the rotation of the axle composed of a Winding fixed With respect to the rotation of the axle and composed of a turn of electrically conducting material, and a rotary magnet fastened to the axle to be rotated by the axle the Winding generating an electric voltage When it is placed at the interface With the rotary magnet.

Claims

1-8. (canceled)

9. A self-supplied device for a logistic and diagnostic monitoring for cargo type railway vehicles comprising: a) at least one axle of a cargo type railway vehicle adapted to be applied through a railway bush, wherein the axle rotates during the travel of the cargo type railway vehicle; b) at least one autonomous electric generator adapted to generate electric power from a rotation of the axle, wherein the electric power is used for supplying power to one or more sensors, one or more than one onboard system, or both one or more sensors and one or more than one onboard system; and c) at least one bush cover for a fixed winding, the least one autonomous electric generator, the one or more sensors, the one or more than one onboard system and for fastening the self-supplied device to a bush body of the at least one axle.

10. The self-supplied device according to claim 9, further comprising at least one circuit for managing the generated electric power and of at least one backup battery for managing and accumulating the electric power generated on the winding.

11. The self-supplied device according to claim 10, further comprising: a) at least one temperature sensor; b) at least one acceleration sensor; c) at least one wireless transmission system; d) at least electronic means adapted to measure the frequency of the electric power generated in order to perform the odometer/tachometer function; and f) at least one info-mobility system comprising: 1) at least one geolocation system; 2) at least one telecommunication system; and 3) at least one wireless communication system for the reception of data from one or more of the bush covers, wherein the systems and sensors being supplied with electric power by at the least one autonomous generator by interposing the means for managing and accumulating the electric power.

12. The self-supplied device according to claim 11, wherein electric power for each of the sensors and the wireless systems and the info-mobility systems and the means to measure frequency is supplied by a specific dedicated circuit.

13. The self-supplied device according to claim 11, wherein the least one autonomous electric generator comprises at least one winding fixed with respect to the rotation of the axle.

14. The self-supplied device according to claim 13, wherein the winding comprises at least one turn of electrically conducting material, and of at least one rotary magnet fastened to the axle to be rotated by the axle.

15. The self-supplied device according to claim 14, wherein the winding is adapted to generate an electric voltage when placed at an interface with at least one rotary magnet.

16. The self-supplied device according to claim 11, wherein the railway bush comprises: a) a bush body a bearing; and b) a bearing stop and fastening screws of the stop to the axle, wherein the rotary magnet is placed on at least one head of one of the fastening screws of the bearing stop of the bush.

17. The self-supplied device according to claim 11, wherein the autonomous electric generator is an axial type generator.

18. The self-supplied device according to claim 11, wherein the autonomous electric generator is adapted to perform functions of an odometer and a tachometer by conditioning a signal generated by the electric generator following the rotation of the axle.

Description

[0031] The present invention will be better described by some preferred embodiments thereof, provided as a non-limiting example, with reference to the enclosed drawings, in which:

[0032] FIG. 1 shows a perspective view of a preferred embodiment of the device according to the present invention;

[0033] FIG. 2 shows a sectional view of a railway bush in view of the application of a device according to the present invention;

[0034] FIG. 3 is an exploded perspective view of a preferred embodiment of the device according to the present invention;

[0035] FIG. 4 shows a graph which represents the vertical acceleration (in the ordinates) as function of time (in the abscissas) of a railway vehicle under normal traveling conditions; and

[0036] FIG. 5 shows a graph which represents the vertical acceleration (in the ordinates) as function of time (in the abscissas) of a railway vehicle under travel conditions when a dynamic alarm condition occurs.

[0037] In general, the present invention deals with a self-supplied device for a logistic/diagnostic monitoring for vehicles through such device, in particular for railway vehicles of the cargo type: for such purpose, it will be described below, merely as an example, how the device according to the present invention will be preferably described as applied to a railway vehicle, such as a cargo wagon, but it is wholly clear that the same device can be applied to any other type of vehicle without thereby departing from the scope of the present invention.

[0038] The device according to the present invention is therefore aimed to provide information and/or services related to monitoring and info-mobility for vehicles: in the particular case of railway vehicles, for example of the cargo type, the device according to the present invention can be specifically arranged to provide information and/or signals and/or alarms related to the detection of an incoming derailment of such vehicle.

[0039] The solution proposed in the present invention can be related, in general and as will be described below in more detail, to a rotary harvester of the type with generator with axial magnetic flux, which allows easily installing permanent magnets in the head of the fastening screws of the cover rotating inside. In such case, the installed magnets are not invasive with respect to the safety of the railway axle. They are further easily installed without modifying the mechanical features. Other proposed installations for generators with radial magnetic flux require the installation of a rotary element integral with the railway axle, which can bring about local modifications of the bush-bearing assembly. Instead, the presence of magnets as proposed in the present invention leaves unchanged the type of bush-bearing assembly anyway guaranteeing the presence of the magnetic flux.

[0040] Moreover, a possible radial installation can be less safe and more costly.

[0041] Therefore, with reference to the Figures, it is possible to note that the device (1) is adapted to be applied to at least one axle (20) of a vehicle, such as for example to the bush body (12) of a railway bush of the axle of a railway vehicle, such axle (20) being rotating for example around a rotation axis (R-R) during the travel of such vehicle and, advantageously, such device (1) according to the present invention comprises at least one autonomous electric generator, preferably of the axial type, adapted to generate electric power from the rotation of the axle (20), such electric power being used to supply with current one or more sensors and/or systems arranged on board the device (1) itself; in addition, as can be seen below in more detail, the autonomous electric generator can also be adapted, by suitable conditioning the signal generated by the electric generator following the rotation of such axle (20), to perform the function of an odometer/tachometer.

[0042] Preferably, and within the scope of the present invention, such sensors and systems can be mainly aimed to the detection of travelling parameters, such as travelled distance and speed, and of the temperature and acceleration conditions of the railway bush, together with sending, through a info-mobility system, both data detected by the sensors and the vehicle position. As can be seen below, the whole transmission of data measured in the device (1) is preferably managed by systems for the wireless transmission, technology which can allow managing the communication of sampled parameters also on board the vehicle between wagon and wagon and/or between wagon and locomotive, thereby locally managing possible alarms derived by a real time monitoring.

[0043] In such case, the device (1) according to the present invention will be mechanically uncoupled from the vibrations of the railway axle, since the magnetic flux which supplies the turns will be completely axial. In this way, possible vibrations, very high in a railway bush, do not represent a strong potential source of damages for the generator. Advantageously, as will be seen below in more detail, the autonomous electric generator of the device (1) according to the present invention is capable both of generating electric power though not being mechanically connected to the vehicle traction system, and in particular to the axle (20) of such vehicle. The autonomous electric generator of the device (1) according to the present invention can further be adapted to perform the function of odometer/tachometer by suitably conditioning the signal generated by the electric generator, always following the rotation of such axle (20). For such purpose, the autonomous electric generator is composed of at least one winding (4) fixed with respect to the rotation of the axle (20), preferably at least with respect to the rotation axis (R-R), such winding (4) being composed of at least one turn of electrically conducting material, and of at least one magnet (5) fastened to such axle (20) to be rotated, for example around the rotation axis (R-R), of the axle (20), such winding (4) being adapted to generate an electric voltage when placed at the interface with at least one rotary magnet (5).

[0044] With particular reference to FIG. 2, it is possible to note an example of a railway bush seen in section, where one can see in evidence the bush body (12), the bearing (11), the bearing stop (7) and the fastening screws (6) of the stop (7): with particular reference to FIG. 3, it is possible to note that, preferably, the rotary magnet (5) is placed on at least one head of the fastening screw (6) of the bearing stop (7) of the bush. When the vehicle advances, the fastening screws (6) of the bearing stop (7) of the bush, being integral with the axle (20), rotate, for example around the rotation axis (R-R). Since the winding (4) is in a fixed position with respect to the screws (6) which have on their head one or more of the magnets (5), a rotary magnetic flux is created, variable in time due to the relative motion between at least one of such magnets (5) placed on at least one screw (6) and the winding (4) itself: this variation of the magnetic flux generates a difference of potential at the winding (4) terminals with consequent generation of an alternate electric power.

[0045] Obviously, the device (1) according to the present invention can further comprise suitable means for managing and accumulating the electric power generated on the winding and for reading the above alternate electric power to perform the function of odometer/tachometer. This function is performed by measuring the frequency of the generated voltage, scaling this property depending on the magnets being present and on the vehicle (4) wheel.

[0046] For the purposes of the present invention, and of the preferred function for which the device (1) according to the present invention is aimed, this latter one can further comprise: [0047] at least one temperature sensor (2); and/or [0048] at least one acceleration sensor (9); and/or [0049] at least one wireless transmission system, in particular for the transmission of data between bush covers and/or bush cover and locomotor for the timely management of alarms; and/or [0050] at least electronic means adapted to measure the frequency of the electric power generated in order to perform the function of odometer/tachometer; and/or [0051] at least one info-mobility system (10) comprising at least one geolocation system and/or at least one telecommunication system and/or at least one wireless communication system for exchanging data with the various measuring sensors/systems and, in particular, for the reception of data from one or more of such bush covers (3); the systems and/or sensors and/or means being supplied with electric power by at least one autonomous generator by interposing means for managing and accumulating the electric power, these latter ones composed, for example, of at least one circuit for managing the generated electric power and of at least one backup battery, preferably each of such sensors and/or of such wireless systems and/or of info-mobility and/or used means being supplied by a specific circuit dedicated thereto.

[0052] Preferably, the device (1) according to the present invention comprises at least one bush cover (3) for containing such fixed winding (4) of the above generator and of the above sensors and/or systems and of fastening the device (1) itself to the bush body (12), for example by interposing a perimeter flange (13) and related screws/bolts (not shown).

[0053] Obviously, the device (1) can be made of a suitable material such as to install, on the opposite face to the rotary axle, the windings and the temperature sensor. On the other side, in order to thermally insulate them, the electronic accumulating devices, the devices for processing the signal, the acceleration sensors and the wireless transmission devices will be installed in a more protected way.

[0054] Obviously, at least part of the bush cover (3) element can be made of a suitable material to guarantee the antenna protection and the signal transmission.

[0055] Preferably, the wireless transmission system is composed of a short-range RF transmission system of the ZigBee type or the like, for data detected by the above sensors to a coordinator connected to the info-mobility system and/or to the locomotor for the timely management of alarms coming from the various sensors: in particular, the geolocation system of the info-mobility system is of the GPS type, while the telecommunication system of the info-mobility system is of the type with GSM/GPRS transmission for relaying data received from the wireless transmission system to a suitable remote receiving system (not shown).

[0056] Preferably, the temperature sensor (2) is composed of at least one MEMS sensor of the Microchip MCP9803 type or the like, having a temperature range from 55 C. to +125 C. and a supply voltage from 2.7V to 5.5V. The sensor (2) is therefore connected to a microprocessor of the Texas Instrument cc2530 type or the like, which allows sampling and transmitting data measured by the sensor (2) through the wireless transmission system.

[0057] Preferably, the acceleration sensor (9) is a tri-axial accelerometer composed of a MEMS sensor of the Analog Device ADXL345 type or the like, having an acceleration measuring range on three axes equal to 16 g and a supply voltage from 2V to 3.6V. The sensor (9) is connected to a microprocessor of the Texas Instrument cc2530 type or the like, which allows sampling and transmitting data measured by the sensor (9), always through the wireless transmission system.

[0058] Preferably, the odometer/tachometer functionality is obtained through the help of a microcontroller of the Microchip PIC12F1612-I/P type, capable of frequency sampling the voltage generated by a winding of the generator and of suitably scaling it according to the number of magnets being present and/or the wheel radius of the vehicle.

[0059] The present invention can be applied to a process for a logistic/diagnostic monitoring for vehicles, in particular for railway vehicles of the cargo type, preferably implemented through at least one device (1) like the one previously described for detecting an incoming vehicle derailment.

[0060] Within the monitoring of accelerometer signals of a vehicle, in order to determine the occurrence of critical phenomena, it is necessary to handle a high amount of data and information.

[0061] A first parameter, which allows discriminating the presence or less of the occurrence of critical vibration phenomena, is the sampling frequency. In order to evaluate critical vibrating phenomena for the travel dynamics of the railway vehicles, the sampling frequency will have to be at least of some hundreds of Hertz till at least 1 kHertz.

[0062] The data analysis devices (CPU) installed on board the bush do not have available big memories for saving data, but they could handle the analogue signal detected almost in real time to determine the occurrence of possible incoming critical aspects, to then send only some mainly digital information when thresholds and alarms are exceeded.

[0063] Though using techniques for treating and analyzing signals known in literature which allow evaluating mean parameters of the dynamic behavior of a vehicle or of a vehicle component, with the current state of the art within the railway engineering, there is no efficient algorithm or device (which can be installed on cargo trains) for the dynamic determination of incoming derailments and for simultaneously detecting the occurrence of severe damages on axle/bush components.

[0064] In fact, it is not known how to recognize a phenomenon of incoming derailment or a phenomenon of wheel vibration with self-supplied compact devices and through digital alarms.

[0065] Such critical phenomena of the railway dynamics, in fact, have high vertical accelerations. The vertical acceleration of a cargo vehicle in a bush is anyway subjected to non-neglected mean values during the normal train travel due to the normal dynamics of the vehicle and of the route irregularity. Moreover, the presence of irregularities on a localized route, such as exchanges, creates very high acceleration peaks. Basing the data compression on the analysis of acceleration peaks (as proposed in literature) compared with pre-established thresholds, numerous false positive alarms can be detected, when there are line discontinuities or irregularities which anyway do not bring about a critical situation by themselves only.

[0066] On the contrary, basing the data compression on the analysis of the vibration signal and on the analysis of means or the analysis of RMS, it is required to compare the mean values with thresholds which must be calibrated on the type of route and on the knowledge of the mean irregularity of the route, this requiring long calibration times or the real time comparison with a data base of thresholds also highly affected by the dynamics of the vehicle type.

[0067] The idea of the present invention is computing, through a moving mean, the Root Mean Square/crest factor, in order to obtain a simple dynamic alarm parameter, which can point out the occurrence of axle critical points. The phenomenon of early derailment brings about RMS threshold ratio values which tend to unity, in a sudden way, with an order of magnitude greater than the normal travel value. While the vibration of wheels or the critical points of mechanical components of the axle bring about a value of the RMS/crest factor ration with repeated and continuous values greater than the travel noise values.

[0068] In particular, such process comprises the steps of:

a) sampling the accelerometer signal, detected for example by at least one acceleration sensor (9), on the three orthogonal directions at high frequency (up to 1 kHerz);
b) extracting a segment on a time base of the accelerometer signal sampled in step a);
c) computing the Root Mean Square, RMS, value of the acceleration signal of the segment obtained in step b);
d) computing the crest factor (computed as ratio between the maximum acceleration value in the segment of step b) and the RMS value);
e) transmitting, for example through the telecommunication system, data about maximum and minimum acceleration and RMS values for every segment; and
f) comparing values transmitted in step e) with the pre-set threshold values for the derailment.

[0069] The process as described above, through an analysis of vibrating data therefore allows recognizing, through alarms, the main dynamic parameters with particular reference to the incoming vehicle derailment.

[0070] The suitable analysis and comparison of sampled data further allows a lean data management with a better energy/computing efficiency when managing the physical quantities measured with the device (1) according to the present invention.

[0071] In particular, such process allows being implemented through a simple algorithm to be performed with the previously described device (1), to allow evaluating the crest factor and the RMS value of the acceleration on three axes in order to determine different critical dynamic behaviors of the vehicle and provide consequent alarms.

[0072] In fact, as can be noted in particular in the graphs of FIGS. 4 and 5, the offset between the crest factor and the RMS value can be advantageously used to evaluate the occurrence of catastrophic events, such as the derailment.

[0073] For example, as shown in particular in the graph of FIG. 4, the passage on an exchange SC under a travel condition of a railway vehicle has a high crest factor value (h1) and a RMS value (RMS 1) which remains within the normal mean values of the route, for example below a pre-set threshold value SD for derailment; the ratio between these two values is much lower than unity.

[0074] The derailment condition, as shown in particular in the graph of FIG. 5, instead has a crest factor value (h2) and a RMS value (RMS 2) which, with very similar values one to the other, determine a ratio next to unity. The RMS/h ratio therefore represents an index used as discriminant of warning and/or danger conditions. Another very sensible problem is the vibration which can be determined from algorithms based on the processing of such data.