JP6672040B2 - Temperature detection device for railway vehicles - Google Patents

Description

  The present invention relates to a temperature detection device for a railway vehicle, and more particularly to a temperature detection device for a railway vehicle that detects a train number of a railway vehicle and detects a temperature around an underfloor device and a bogie for each formation of the railway vehicle.

DESCRIPTION OF RELATED ART Conventionally, the following patent documents are disclosed as a technique which detects the temperature of the underfloor equipment of a railroad vehicle, or the equipment around a bogie.
For example, Patent Document 1 (Japanese Patent Application Laid-Open No. 2000-146770) relates to non-contact detection of an underfloor device of a vehicle from the ground side while traveling, and furthermore, an underfloor device of which vehicle is abnormal. There is disclosed a vehicle underfloor monitoring device capable of identifying a vehicle.
Specifically, a temperature detecting means provided on the ground in a non-contact manner with the train detects the temperature under the floor of the passing vehicle at a constant cycle from the side of the running train. The time-series vehicle under-floor temperature obtained by the temperature detecting means is input to the heat graph creating means, and a heat graph of the vehicle under-floor temperature in which the vertical axis is the vehicle under-floor temperature and the horizontal axis is the passing time of each vehicle is created. Is done. The calculating means compares a portion corresponding to the temperature data of the underfloor equipment in the heat graph created by the heat graph creating means with the temperature limit value stored in the temperature limit value storage means, and outputs the comparison result. ing.
Further, Patent Document 2 (Japanese Patent Application Laid-Open No. 2000-38133) discloses an underfloor equipment monitoring device capable of quickly and quantitatively performing an abnormality inspection of an underfloor equipment immediately after operation.

Specifically, a vehicle sensor that detects a running vehicle, a vehicle type identification unit that identifies the type of the traveling vehicle, a speed sensor that measures the traveling speed of the vehicle, and a temperature distribution state of equipment under the floor of the vehicle immediately after operation. And a temperature sensor which measures the temperature distribution from the side of the vehicle in a non-contact manner while the vehicle is traveling, and corrects a temperature distribution state measured by the heat sensor in accordance with the traveling speed of the vehicle measured by the speed sensor. And a judging means for judging an abnormal temperature of the device based on the judgment.
Patent Document 3 (Japanese Patent Application Laid-Open No. 2000-351372) discloses a method of matching an image with a temperature distribution with high accuracy regardless of a change in train speed.
Specifically, the first sensor unit is provided with two transmission sensors on the side of the vehicle, and the second sensor unit is provided with two transmission sensors, of which one transmission sensor of the first sensor is provided. A temperature sensor is installed in the vicinity of. The interval between the first and second sensor units is 5000 [mm], and the installation interval between the transmission type sensors is 200 [mm]. Each of the first and second transmission type sensors detects the passage of a train wheel and records the time one by one, and calculates the speed of the train based on this, the standard size of the train and the installation interval of each sensor. I do. The vehicle position is grasped by adding the number of wheels that have passed through the transmission type sensor. The temperature distribution data obtained at the time closest to the time when the wheel crosses one transmission sensor of the first transmission sensor unit is extracted and adjusted to the wheel position. Image data is offset in anticipation of the installation position of the video camera. Then, interpolation processing is performed on the remaining temperature distribution data and image data based on the speed data.

By the way, as a method of detecting the passage of a vehicle, the conventional one uses a magnetostrictive wheel detector in which an internal contact operates when a wheel (or axle), which is a metal body, approaches.
In addition, the above-mentioned conventional underfloor equipment monitoring device is difficult to respond to temperature detection of a heating device at a speed close to the maximum speed of a railway vehicle, or an abnormal condition such as a weather abnormality or an accident while the railway vehicle is running. In the case where the vehicle stops once and then starts again, the temperature cannot be measured, and all the temperature detection data of the train set must be discarded.
Further, as a conventional passage detection method, the following detection method using a magnetostrictive wheel detector has the following problems.
(1) In some cases, the vehicle cannot be detected due to disturbance from a traveling vehicle or a rail, or the wheels are erroneously detected.
(2) In order to detect a wheel, it is necessary to mount the wheel very close to the limit of the building limit.
(3) Since the rail is attached to the rail using the mounting bracket, the rail may be directly subjected to vibration and may be damaged.
(4) The response speed is slow, and it cannot respond to a vehicle running at high speed.
(5) Since the detection range of the wheel is wide and the width of the wheel cannot be detected accurately, when the vehicle stops and restarts on the detector, the time-series measurement data cannot be accurately converted to the vehicle position.

JP 2000-146770 A JP 2000-038133 A JP 2000-351372 A

  The present invention has been made in view of the circumstances described above, and has as its object to provide various devices provided on a floor device or a bogie of a traveling vehicle (hereinafter, these devices are collectively referred to as “floor devices”). The temperature can be accurately detected, and the temperature can be detected not only at the time when the railway vehicle whose temperature is to be detected is at an arbitrary speed, that is, at a low speed, but also at a time when it reaches the maximum speed. In addition, even if a running railroad vehicle stops and then starts again, a railcar temperature detecting device capable of detecting the temperature information accurately and automatically in a time-series manner. Is to provide.

The temperature detecting device for a railway vehicle according to claim 1, wherein the first wheel detecting means and the second wheel detecting means each include a photoelectric projector and a photodetector for detecting passage of a plurality of wheels of a running vehicle before and after a measurement section. Wheel detection means,
A first vehicle body detection unit and a second vehicle body detection unit that are arranged close to the first wheel detection unit and the second wheel detection unit and determine whether the vehicle is on the measurement section. Means,
Formation identification means for reading the formation information of the running vehicle,
Vehicle speed detection means for detecting the speed of the traveling vehicle based on the passing time of the traveling vehicle when passing between the first wheel detection means and the second wheel detection means being the measurement section;
Temperature detection means for acquiring the temperature of a plurality of parts in the underfloor equipment of the vehicle from the side of the track near the measurement section where the vehicle travels in a non-contact manner.
Processing means for detecting the temperature of a plurality of parts in the underfloor equipment of the vehicle in time series based on the information obtained from each of the means,
The processing means includes:
As long as one of the first vehicle body detection means and the second vehicle body detection means is in a state of detecting the vehicle body, the temperature detection by the temperature detection means and the storage of the detected temperature data are continued,
Until such time as the vehicle has reached the second wheel sensing means which is fixed intervals apart relative time point when it reaches the said first wheel sensing means disposed in the reference position in the row in run the previous SL line path The speed calculated by the vehicle speed detection means based on the required time, the travel distance of the vehicle from the reference position calculated by the elapsed time from the reference time, and the reference time obtained from the temperature detection means Based on the measured temperature time-series data, to sequentially obtain the temperature of a predetermined portion in the underfloor equipment of each vehicle to create a measured temperature time-series data for each predetermined portion of the vehicle,
The temperature of a plurality of parts of the underfloor equipment for each of the vehicle formation numbers can be detected in time series based on the vehicle formation number read by the formation identification means .

The first temperature detecting device for a railway vehicle according to claim 2, wherein the first wheel detecting means and the second wheel detecting means each include a photoelectric projector and a photodetector for detecting passage of a plurality of wheels of a running vehicle before and after a measurement section. Wheel detection means,
A first vehicle body detection unit and a second vehicle body detection unit that are arranged close to the first wheel detection unit and the second wheel detection unit and determine whether the vehicle is on the measurement section. Means,
Formation identification means for reading the formation information of the running vehicle,
Vehicle speed detection means for detecting the speed of the traveling vehicle based on the passing time of the traveling vehicle when passing between the first wheel detection means and the second wheel detection means being the measurement section;
Temperature detection means for acquiring the temperature of a plurality of parts in the underfloor equipment of the vehicle from the side of the track near the measurement section where the vehicle travels in a non-contact manner.
Processing means for detecting the temperature of a plurality of parts in the underfloor equipment of the vehicle in time series based on the information obtained from each of the means,
The processing means includes:
As long as one of the first vehicle body detection means and the second vehicle body detection means is in a state of detecting the vehicle body, the temperature detection by the temperature detection means and the storage of the detected temperature data are continued,
Until such time as the vehicle has reached the second wheel sensing means which is fixed intervals apart relative time point when it reaches the said first wheel sensing means disposed in the reference position in the row in run the previous SL line path The speed calculated by the vehicle speed detection means based on the required time, the travel distance of the vehicle from the reference position calculated by the elapsed time from the reference time, and the reference time obtained from the temperature detection means Based on the measured temperature time-series data, to sequentially obtain the temperature of a predetermined portion in the underfloor equipment of each vehicle to create a measured temperature time-series data for each predetermined portion of the vehicle,
Based on the vehicle formation number read by the formation identification means, the temperature of each of the plurality of parts of the underfloor equipment for each of the vehicle formation numbers can be detected in time series, and the reference time point is used as a reference. The apparatus is characterized in that the measured temperature time-series data for each predetermined part is edited into position conversion waveform data having a temperature distribution corresponding to the underfloor equipment and can be displayed via the display means. .

Temperature sensing system for a railway vehicle according to claim 3, in the temperature sensing system for a railway vehicle according to claim 1 or 2, the both have the body of the first vehicle detection means and the second vehicle detecting means If that the status is not detected is characterized by being configured to terminate the temperature detection and storage of the detected temperature data by the temperature detecting means.
The temperature detecting device for a railway vehicle according to claim 4 is the temperature detecting device for a railway vehicle according to claim 1 or 2 , wherein the processing unit includes the first wheel detecting unit, the second wheel detecting unit, A predetermined portion of the under-floor equipment of the traveling vehicle based on each information, controlling operations of the first vehicle body detecting means, the second vehicle body detecting means, the temperature detecting means, and the knitting identifying means. In addition to creating time-series data of measured temperatures for each of the devices, extracting a maximum temperature for each predetermined range of the underfloor equipment, and generating an alarm when the maximum temperature exceeds a predetermined threshold. It is characterized by.
The temperature detecting device for a railway vehicle according to claim 5 is the temperature detecting device for a railway vehicle according to claim 1 or 2, wherein the first wheel detecting unit and the second wheel detecting unit are oil-resistant and waterproof. there to become faster photoelectric sensor response speed, when the circular arc which is a part of the wheel of the left and right sides passes, by blocking the light beam between the light receiver and the projector, detects the passage of the wheels It is characterized by having been configured to obtain.

The temperature detecting device for a railway vehicle according to claim 6 is the temperature detecting device for a railway vehicle according to claim 1 or 2, wherein the temperature detecting unit , the knitting identifying unit , the wheel detecting unit , and the vehicle body detecting unit are iron bridges. In the case of detecting the temperature above, it is characterized in that a part of the bridge structure is attached to a gantry using the bridge.
The temperature detecting device for a railway vehicle according to claim 7 is the temperature detecting device for a railway vehicle according to claim 1 or 2, wherein the temperature detecting unit , the knitting identifying unit , the wheel detecting unit , and the vehicle body detecting unit are ground. in the case of detecting the temperature in it is characterized by being configured to attach to the frame which is provided independently of the railway line.

  ADVANTAGE OF THE INVENTION According to this invention, while being able to accurately and automatically detect the temperature of the several parts in the underfloor equipment of the traveling vehicle, the railway vehicle whose temperature is to be detected has an arbitrary speed, that is, not only when the vehicle is traveling at a low speed. In addition, temperature detection is possible even at the time of traveling to the maximum speed, and further, even if a situation in which the running railway vehicle stops and then restarts occurs, the temperature information is chronologically obtained. It is possible to provide a railway vehicle temperature detecting device that can accurately and automatically detect the temperature.

It is a lineblock diagram showing the whole railcar temperature sensing device composition concerning a 1st embodiment of the present invention. It is a perspective view showing composition of an important section of a rail car temperature sensing device concerning a 2nd embodiment of the present invention, and arrangement relation with a rail car and a railroad track (rail). It is a timing chart which shows generation timing of each detection signal in the temperature sensing device for rail vehicles concerning a 1st embodiment of the present invention. It is the graph which showed the temperature distribution which matched the measured temperature time series data for every predetermined part which sets a measurement trigger as a reference position with each position of the underfloor equipment of a railroad vehicle. FIGS. 3A and 3B show an external configuration of a formation number reading antenna, wherein FIG. 3A is a plan view, FIG. 3B is a front view, and FIG. The two heat detectors, the two wheel detectors, the two body sensors, the one formation number reading antenna, the relay box, and other devices of the temperature detection device for a railway vehicle according to the third embodiment of the present invention. It is a top view which shows a planar arrangement relationship. FIG. 7 is a left side view showing an arrangement relationship of each device shown in the third embodiment of FIG. 6 as viewed from a left side. FIG. 7 is a front view showing an arrangement relationship of each device shown in the third embodiment of FIG. 6 as viewed from the front side. It is a flowchart figure which shows operation | movement of the temperature detection apparatus for railway vehicles which concerns on the 1st-3rd embodiment of this invention. FIG. 10 is a flowchart showing a continuation of the operation of the railway vehicle temperature detecting device according to the embodiment of FIG. 9.

Hereinafter, the present invention will be described through a temperature detecting device for a railway vehicle according to the first embodiment to the third embodiment of the present invention, but the following embodiments will describe the invention according to the claims. It is not intended to be limiting, and not all combinations of the features described in the embodiments are necessarily essential for solving the invention.
FIG. 1 is a block diagram showing the overall configuration of the railway vehicle temperature detecting device according to the first embodiment of the present invention.
In FIG. 1, a temperature detecting device for a railway vehicle (sometimes referred to as a “vehicle temperature detecting device”) according to the first embodiment includes a first vehicle body sensor 1 and a second vehicle body sensor as vehicle body detecting means. 2. First wheel detectors 21a and 21b and second wheel detectors 22a and 22b as wheel detecting means, heat detectors 31 and 32 as temperature detecting means, knitting number reading antenna 12 as knitting identifying means, It includes a relay box 11 and a processing device 10 having a function as processing means.
As an aspect of the first embodiment, the processing device 10 includes a first vehicle body sensor 1, a second vehicle body sensor 2, first wheel detectors 21a and 21b, second wheel detectors 22a and 22b, The operation of each of the heat detectors 31 and 32, the junction box 11 and the formation number reading antenna 12 is controlled to perform measurement, and time-series temperature measurement data for each temperature measurement device is created (hereinafter, this data is referred to as " Measured temperature time series data ”).

In addition, the first vehicle body sensor 1, the second vehicle body sensor 2, the first wheel detectors 21a and 21b, the second wheel detectors 22a and 22b, the heat detectors 31 and 32, and the formation number reading antenna 12 are respectively provided. It is also possible to create time series data of measured temperatures for each predetermined part of the railway vehicle based on the detected information. Further, the processing device 10 determines the occurrence of an abnormal temperature rise in a predetermined range of each of the predetermined portions of the railway vehicle based on the measured temperature time-series data of each of the predetermined portions, and determines whether there is an abnormality. For example, it notifies the external general command room via the external antenna 10c.
The processing device 10 includes an A / D converter 10b that A / D converts information from the heat detectors 31 and 32, the first wheel detectors 21a and 21b, and the first and second body sensors 1 and 2, A knitting ID reading device 10a that receives knitting ID signals from the knitting number reading antenna 12 and reads knitting information, receives each of the above information, controls each unit, collects temperature information of a plurality of predetermined parts of the vehicle, and A processing unit 10c for editing the measured temperature time-series data and the position conversion data for each number and for each of the plurality of predetermined parts is provided.

Since a communication terminal device having a computer can be used as the processing device 10 (a ready-made product may be used), a description of the configuration is omitted here.
The first and second vehicle body sensors 1 and 2 generate a signal for the processing unit 10c to determine whether or not the vehicle body of the railway vehicle exists in or near the measurement section. As a characteristic function of the vehicle temperature detection device of the present embodiment, as long as the first and second vehicle body sensors 1 and 2 continue to recognize that the vehicle body is in or near the measurement section, It has the function of continuing temperature measurement.
As the first and second vehicle body sensors 1 and 2, for example, an ultrasonic sensor with a built-in amplifier can be used (a ready-made product may be used). For example, as the first and second vehicle body sensors 1 and 2, an ultrasonic sensor for obstacle detection with medium distance detection and narrow directivity for outdoor use can be used.

The first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b detect the presence of the wheels of the railway vehicle, that is, the passage of the wheels. More specifically, as described later with reference to FIGS. 6 to 8, the first and second wheel detectors 21 and 22 each include an arc portion (a lower portion on the ground contact surface side) that is a part of the left and right wheels. (Arc). The first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b are installed at predetermined constant intervals (e.g., equivalent to the circumference of one rotation of the wheel) along the traveling direction of the vehicle. Is done. The wheel detector 21a and the wheel detector 22a are on the light emitter side, and the wheel detector 21b and the wheel detector 22b are on the light receiver side. The light emitter and the light receiver may be provided on either side. Based on the time difference between when the first wheel detectors 21a and 21b detect one wheel and when the second wheel detectors 22a and 22b separated by a predetermined distance detect the wheel, and based on the distance at the predetermined interval. Thus, the average moving speed of the railroad vehicle while the vehicle body of the railroad vehicle is in the measurement section can be calculated by the processing unit 10c.
A transmission type straight photoelectric sensor is used for the first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b, and a light source is configured using an infrared LED (for example, a wavelength of 870 nm). And

Incidentally, the use of the photoelectric sensor significantly improves the detection accuracy and the response speed as compared with the case of using a conventional magnetic sensor that easily picks up noise. It is desirable that this photoelectric sensor is, for example, an oil-resistant and waterproof photoelectric sensor. Although an off-the-shelf product may be used, as means for realizing an oil-resistant and waterproof photoelectric sensor, first and second wheel detectors 21a, 21b, 22a, and 22b are shown in FIGS. As shown, it is desirable to house it in a cylindrical housing. With such a configuration, even if there is rainfall or snowfall, the wheels can be detected without any trouble. In addition, it is desirable to provide a drain hole in this cylindrical housing.
The heat detectors 31 and 32 detect the temperature of a predetermined portion of the underfloor equipment of the railway vehicle. In the following description, it is assumed that heat detectors 31 and 32 detect the temperature of a predetermined portion of the underfloor equipment from both sides of the vehicle, respectively.
The formation number reading antenna 12 acquires the formation information (hereinafter, referred to as a formation number) of a railway vehicle. Specifically, as described later, the formation number reading antenna 12 reads information of an ID tag attached to an inclined surface below a skirt portion of a leading vehicle in a state of facing in parallel. RFID information is written in the ID tag as character string information.

As described above, the first vehicle body sensor 1, the second vehicle body sensor 2, the first wheel detectors 21a and 21b, the second wheel detectors 22a and 22b, the heat detectors 31 and 32, and the formation number reading antenna 12 However, it is assumed that the trains are always operating irrespective of the operation status of the railway vehicles, except for midnight when the trains are not operated. In particular, the heat detectors 31 and 32 collect temperature information of the predetermined portion of the vehicle in a non-contact manner. As shown in FIG. 3, the processing means 10c in the processing device 10 converts the measurement time-series data (raw data) for each composition number and for each predetermined part using the reference trigger (measurement trigger) as a time reference, as shown in FIG. obtain. Further, the processing means 10c edits the raw data from the measured temperature time-series data for each knitting number and for each of the above-mentioned predetermined parts so as to be converted into position-converted waveform data as shown in FIG.
The relay box 11 includes the first body sensor 1, the second body sensor 2, the first wheel detectors 21a and 21b, the second wheel detectors 22a and 22b, the heat detectors 31 and 32, and the knitting described above. It has a function of supplying power to devices such as the number reading antenna 12 and relaying information detected by each device to the processing device 10. In this transmission, the occurrence signal can be transmitted on a case-by-case basis, or a plurality of cases can be transmitted after being pooled.

  FIG. 2 includes the entirety of a railcar temperature detection device (hereinafter, may be simply referred to as a “detection device”) according to a second embodiment of the present invention and a railcar or railroad track to be measured. 1 is a perspective view schematically showing an external configuration. In general, railway lines define building limits for workpieces as one of the rules specific to the railway. That is, there is a restriction that a work or the like that supports the operation of a railway cannot be built in the space indicated by the building limits. Therefore, in FIG. 2, each component of the present invention, that is, the first vehicle body sensor 1, the second vehicle body sensor 2, the first wheel detectors 21a and 21b, the second wheel detectors 22a and 22b, the heat The detectors 31 and 32, the formation number reading antenna 12, and the like are installed outside the space indicated by the above-mentioned building limit specified for each railway. In addition, these components can be attached to a gantry installed independently of a railway line (track). As shown in FIGS. 5 and 8, the gantry can be installed on the ground beside the railroad track (track), or in a steel bridge, the gantry can be attached using a part of the bridge.

In the second embodiment shown in FIG. 2, the first vehicle body sensor 1 is on the left side when viewed from the top of the railway vehicle, and the second vehicle body sensor 2 is on the right side when viewed from the front of the railway vehicle. Has been installed.
Further, the first wheel detector 21a and the second wheel detector 22a are installed on the left side when viewed from the top of the railway vehicle, and the wheel detector 21b and the wheel detector 22b are mounted on the right side when viewed from the top of the railway vehicle. , Respectively. Further, the heat detector 31 is provided on the left side when viewed from the top of the railway vehicle, and the heat detector 32 is provided on the right side when viewed from the top of the railway vehicle.
A vehicle temperature detecting device according to a second embodiment of the present invention will be described with reference to a timing chart shown in FIG. The railway vehicle 100 that has entered from the right side of FIG. 2 has a composition number reading antenna 12 → first wheel detectors 21 a and 21 b → first vehicle body sensor 1, two heat detectors 31 and 32 → second vehicle body It passes in the order of sensor 2 → second wheel detector 22a, 22b.

Further, since the ID tag recording the composition number of the railway vehicle 100 is attached to the lower inclined surface of the right skirt portion when viewed from the front front of the railway vehicle 100, the corresponding composition number reading antenna 12 is As shown in FIG. 5C, the radio wave radiating surface 12a is attached obliquely so as to face parallel to the inclined surface of the skirt so that the ID tag can be read.
FIG. 3 is a timing chart showing the occurrence (generation) timing of a detection signal in the railway vehicle temperature detection device according to the first embodiment of the present invention.
In the figure, the horizontal axis indicates time, and the vertical axis indicates the level of each signal.
When the railway vehicle 100 approaches the measurement section, the above-described first vehicle body sensor 1, first vehicle body sensor 2, first wheel detectors 21a and 21b, second wheel detectors 22a and 22b, and heat detection Each of the devices 31 and 32 and the composition number reading antenna 12 generates a detection signal at the timing shown in FIG. 3 and sends it to the processing device 10 via the relay box 11.
The processing means 10c in the processing device 10 includes a composition ID signal of the composition number reading antenna 12, an occurrence signal of the first and second vehicle body sensors 1, 2, a first wheel detector 21a, 21b, and a second wheel detector. From the detection signals 22a and 22b, the timing (0 sec, N1 sec, N2 sec, N3 sec...) Of the measurement trigger serving as a time reference point for measurement can be known.

In the present embodiment, the measured temperature time-series data for each of the predetermined portions is obtained by using a measurement trigger (also referred to as a "measurement start trigger") from the first wheel detectors 21a and 21b as a reference position for each axis. Edit each time.
The processing unit 10c in the processing device 10 refers to the measurement trigger when editing the measured temperature time-series data to be the measured temperature time-series data for each of the predetermined parts. Also, the presence of the occurrence signals of the first and second vehicle body sensors 1 and 2 makes it possible to know that a certain railway vehicle has entered or is present in the measurement section of the present apparatus.
It is assumed that the above-described detection device and the temperature measurement device have been operating before the measurement trigger is generated, for example, before the start of the running of the power generating vehicle. Therefore, the processing unit 10e can always refer to the measured temperature information (for example, the measured temperature information of the heat detectors 31 and 32 shown in FIGS. 1 and 2).
The distance (interval) between the first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b is known (constant).
Therefore, the processing means 10c of the processing device 10 determines the time interval (time difference) between the signal generated by the first wheel detectors 21a and 21b and the signal generated by the second wheel detectors 22a and 22b, and the above-mentioned distance. Calculate the speed of In another aspect of the present embodiment, together with the time lapse information from the reference position, the measured temperature time-series data is edited so as to be measured temperature time-series data distributed around the predetermined site. It is displayed. The processing unit 10c of the processing device 10 refers to the speed of the railroad vehicle at the time of editing.

Further, the processing unit 10c measures the number of occurrences of the occurrence signals of the first wheel detectors 21a and 21b and the occurrence signal of the wheel detectors 22a and 22b, and recognizes the number of axles of the railway vehicle entering the measurement section.
Further, the processing means 10c grasps the timing of the end of the measurement from the number of axles of the railway vehicle entering the measurement section. Incidentally, the number of axles is generally different between a railway vehicle having a formation number (ie, a passenger vehicle) and another railway vehicle (for example, a construction vehicle). Similarly, in the case of the Shinkansen, the number of axles is different between a railway vehicle having a train number (ie, a passenger vehicle) and another railway vehicle (for example, a construction vehicle). Therefore, due to this difference, the processing unit 10c avoids measurement of, for example, a construction vehicle, and measures the temperature by focusing only on the railway vehicle having the number of axles indicating that it is a railway vehicle having a formation number (ie, a passenger vehicle). be able to.
FIG. 4 shows that the measured temperature time-series data for each predetermined portion with the measurement trigger generation position (first wheel) as a reference position is converted into the measured temperature time-series data distributed for each predetermined portion and edited again. FIG.
That is, the graph shown in FIG. 4 is obtained by converting the distances between the first wheel detectors 21a and 21b and each of the heat detectors 31 to 34 from the speed and the distance to the temperature measurement position of the vehicle body. It is.

FIG. 4 also shows the sensing device used and the temperature measuring device corresponding to the predetermined part, together with the measured temperature time-series data. In the upper part of FIG. 4, a predetermined portion of the underfloor equipment is illustrated with the positions of the first wheel detectors 21a and 21b, that is, the center of the front axle as a reference axis (0 m).
The graph shown in FIG. 4 is easy for the observer to visually recognize. Therefore, the processing means 10c can display the graph shown in FIG. 10 on a display device (display) 10f (see FIG. 1) as an attached facility and make it visible to the observer. Further, when detecting an abnormality in the measured temperature corresponding to the predetermined part, the processing means 10c notifies the fact to an external general command room or the like via the data communication terminal 10d and the external antenna 10e.
FIGS. 5A, 5B, and 5C show a configuration example of a formation number reading antenna 12 used in the vehicle temperature detecting device according to the first embodiment, and FIG. FIG. 1B is a front view, and FIG. 1C is a right side view.
An ID tag that records the composition information (here, the composition number) of the railway vehicle is attached to the inclined surface below the skirt portion of the leading vehicle of the railway vehicle whose temperature is to be measured. Therefore, it is assumed that the composition number reading antenna 12 is installed so as to comply with the regulations of the building limit and to be as close to the outside of the building limit as possible. The height direction is adjusted by the support 12b, and the radio wave radiating surface 12a of the antenna is set at a predetermined inclination angle (for example, 53 ° from a horizontal plane) so as to be along the inclined surface of the skirt [FIG. (C)). In FIG. 5, 12c is a base.

The formation number reading antenna 12 has a reading function by radio waves, and reads the recorded content of the ID tag instantaneously in a non-contact manner when the railway vehicle passes, thereby acquiring the formation number.
6 to 8 show heat detectors 31 and 32, first wheel detectors 21a and 21b, and second wheel detectors each showing a part of the configuration of the vehicle temperature detecting device according to the first embodiment. The arrangement relation of 22a, 22b, first and second vehicle body sensors 1, 2 and formation number reading antennas 1, 2 with respect to the railway line 101 is shown.
As shown in FIGS. 6 to 8, heat detectors 31 and 32, other first wheel detectors 21 a and 21 b, second wheel detectors 22 a and 22 b, first and second vehicle body sensors 1 and 2 The composition number (composition ID) reading antenna 12 and the like are disposed at positions outside the building limit on one and / or the other side of the railway line 101 via a stand, a support, and the like.
FIGS. 9 and 10 are flowcharts showing the operation of the temperature detecting device for a railway vehicle according to the first to third embodiments of the present invention.

Hereinafter, the operation of the temperature detecting device for a railway vehicle according to the first to third embodiments of the present invention will be described with reference to FIGS.
First, the operation shown in FIG. 9 will be described.
In step S1, it is in a state of waiting for a trigger signal from the first wheel detectors 21a and 21b.
In step S2, at the timing when the first wheel detectors 21a and 21b detect a wheel, a signal indicating the fact (that is, a measurement start trigger) is transmitted to the processing device 10 via the relay box 11. The processing unit 10c in the processing device 10 records the timing (time) at which the measurement start trigger was received.
In step S3, the processing unit 10c receives and records various detection signals transmitted via the relay box 11. Here, the various detection signals are the first wheel detectors 21a and 21b, the second wheel detectors 22a and 22b, the first vehicle sensor 1, the second vehicle sensor 2, and the heat detectors 31 and 32. Each of the composition number reading antennas 12 detects and generates a signal. However, these signals also include detection information, for example, a pre-trigger signal collected before, for example, two seconds before the occurrence of the measurement start trigger.

In step S4, the processing means 10c determines whether or not the number of passing axles of 64 axles has already been counted based on the occurrence signals of the first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b. Verify As a result, if the number of passing axles of 64 axes has already been counted, the processing unit 10c performs the process of terminating the measurement in step S7, and then executes the control flow in step S9 in which the control flow is indicated by another page connector (A). Move on to analysis start processing. Conversely, if the number of passing axles of 64 axles has not been counted, the processing unit 10c determines in step S5 to determine whether the vehicle body is in or near the measurement section. continue processing. In the determination processing in step S5, unless both the first vehicle body sensor 1 and the second vehicle body sensor 2 are turned off, the process returns to step S4 and the processing is continued.
In the determination process in step S5, when both the first vehicle body sensor and the second vehicle body sensor 2 are turned off, the processing unit 10c determines that the vehicle body has left the measurement section, and performs measurement in step S6. After the end processing, the flow of control is shifted to the processing of step S20 indicated by the other page connector (B).

Next, the operation shown in FIG. 10 will be described.
In step S9, the processing unit 10c performs a preparation process for analysis.
In step S10, the processing unit 10c calculates a transit time difference between the time when the vehicle wheel passes through the first wheel detectors 21a and 21b and the time when the wheel passes through the second wheel detectors 22a and 22b. I do.
In step S11, the processing means 10c determines the passing speed (distance difference) of the vehicle from the distance difference between the installation positions of the first wheel detectors 21a, 21b and the second wheel detectors 22a, 22b and the passing time difference. / Passing time difference = average speed).
In step S12, the processing unit 10c calculates the passing speed of the vehicle and the positional relationship of each measurement site of the underfloor equipment based on the detection time (detection time) of the first wheel detectors 21a and 21b. Then, the measured temperature time-series data for each predetermined part is edited again into the measured temperature time-series data distributed for each predetermined part. Thereafter, the processing unit 10c obtains, for each axis, a maximum temperature within a predetermined range centered on each of the passed parts for each axis from the measured temperature time-series data distributed for each of the predetermined parts. That is, based on the detection time (time point) of the first wheel detectors 21a and 21b as a reference, the maximum temperature within a predetermined range set in advance is extracted for each axis from the passing speed and the positional relationship between the measurement sites.

In step S13, the processing unit 10c executes a process of terminating the analysis.
In step S14, the processing unit 10c verifies whether the temperature of the first part of the underfloor equipment extracted in step S12 has exceeded a predetermined threshold. If the temperature of the first part of the underfloor equipment is not higher than the predetermined threshold, the process proceeds to step S16. Conversely, if the temperature of the first part is higher than the predetermined threshold, the process proceeds to step S15. After the first alarm is issued, the process proceeds to step S16. This alarm may be a lighting or blinking of a lamp, or an alarm by sound.
In step S16, the processing unit 10c verifies whether the temperature of the second portion of the underfloor equipment extracted in step S12 has exceeded a second threshold. If the temperature of the second part of the underfloor equipment is not higher than the second threshold, the process proceeds to step S18. Conversely, if the temperature of the second part of the underfloor equipment is higher than the second threshold, After the second alarm is issued in step S17, the process proceeds to step S18. Here, the first threshold value and the second threshold value may be different or the same.
Although the description has been made assuming that the temperature detection portions of the underfloor equipment are two, three or more temperature detection portions may be detected.

In step S18, the processing unit 10c waits until the next trigger notification is sent.
According to the railway vehicle temperature detecting device according to the first embodiment, since the first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b, which are photoelectric wheel detectors, are used. Unlike the conventional magnetic type, only the wheels are accurately detected without being affected by a vehicle or a rail. Therefore, the processing unit 10c can perform the above determination accurately and instantaneously.
In addition, since the first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b have a configuration in which a light emitter and a light receiver are installed on the left and right sides of the track, they are surely installed away from the above-described building limit. can do.
In addition, as shown in FIGS. 6, 7, and 8, the detection devices and the temperature measurement devices can be attached to a stand (for example, a bridge) independent of the track, so that they are directly subjected to vibration from the track. And the failure due to the influence of the vibration is less likely to occur.

In addition, the response speed of detection devices and temperature measurement devices is fast, and even a vehicle such as a Shinkansen running at the maximum speed of a railway vehicle, for example, about 285 km / h, is detected instantaneously without correcting arrival and passage of wheels. Therefore, the wheel detection accuracy can be significantly improved.
Further, each of the light emitter and the light receiver constituting the first wheel detectors 21a and 21b and the second wheel detectors 22a and 22b is housed in a cylindrical housing as shown in FIGS. (Furthermore, by providing a drain hole in the housing), even when rainfall or snowfall is encountered, wheel detection can be performed without any trouble.
The first vehicle body sensor 1 and the second vehicle body sensor 2 detect whether or not the vehicle is within the measurement range of the measuring device, and determine whether the wheel detection number is a vehicle having a train number (ie, a passenger car). Even if the number of axes is less than the specific number of axes (for example, 64 axes or 28 axes), if the vehicle is within the measurement range of the measuring device, it is determined that the vehicle is stopped on the device and the measurement is continued. Since the measured data can be stored without being discarded, the analysis result can be obtained in the above-described manner even when the vehicle is temporarily stopped and then the running is disclosed. Further, when the number of detected wheels is less than the number of axes (for example, 64 axes or 28 axes) specific to the vehicle having the formation number (ie, passenger car), and the vehicle goes out of the measurement range of the measuring device, The measurement can be stopped by determining that the vehicle is a vehicle or the like.

Further, since the two sensors of the first vehicle body sensor 1 and the second vehicle body sensor 2 are provided to ensure redundancy, even if one of them fails, the above-mentioned vehicle stop state can be determined.
Further, by editing the raw data, it is possible to obtain temperature distribution data for each predetermined portion, which is easy for the observer to visually recognize.
The present invention is not limited to the embodiment described above and shown in the drawings, and can be variously modified without departing from the scope of the invention.
For example, the distance between the heat detectors 31 and 32 in the running direction can be adjusted as appropriate, but the position in the direction perpendicular to the running direction needs to be set according to the device to be detected in the underfloor equipment, for example. It is desirable that the positional relationship between the heat detectors 31 and 32 in the traveling direction be the same.
In addition, the first wheel detectors 21a and 21b need not be disposed in front of the heat detector 31, and may be disposed between the formation number reading antenna 12 and the first vehicle body sensor 1 as shown in FIG. May be arranged.

In the block diagram shown in FIG. 1, the perspective view shown in FIG. 2, and the timing chart shown in FIG. 3, the first vehicle body sensor 1, the first wheel detectors 21a and 21b, the knitting number reading antenna 12, and the heat Although the mutual arrangement of the detectors 31 to 34 is different, there is no problem in the temperature detection function.
In the vehicle temperature detecting device, the heat detectors 31, 32, the wheel detectors 21a, 21b to 22a, 22b, the knitting identification antenna 12 and the like are installed on the installation side shown in FIGS. Although it is assumed that a part of the object is used for the arrangement, an appropriate gantry may be arranged on the side of the railway line arranged on the ground, and the gantry may be installed on the gantry.

1, 2 Body sensor 10 Processing device 10a A / D converter 10b Composition ID reader 10c Processing means 10d Data communication terminal 10e External antenna 10f Display 11 Relay box 12 Composition number reading antenna 12a Radio wave radiating surface 12b Prop 12c, base 21a, 21b , 22a, 22b Wheel detector 31, 32 Heat detector 100 Railway vehicle 101 Railway track

Claims (7)

First and second wheel detecting means including a photoelectric projector and a photodetector for detecting passage of a plurality of wheels of a running vehicle before and after a measurement section,
A first vehicle body detection unit and a second vehicle body detection unit that are arranged close to the first wheel detection unit and the second wheel detection unit and determine whether the vehicle is on the measurement section. Means,
Formation identification means for reading the formation information of the running vehicle,
Vehicle speed detection means for detecting the speed of the traveling vehicle based on the passing time of the traveling vehicle when passing between the first wheel detection means and the second wheel detection means being the measurement section;
Temperature detection means for acquiring the temperature of a plurality of parts in the underfloor equipment of the vehicle from the side of the track near the measurement section where the vehicle travels in a non-contact manner.
Processing means for detecting the temperature of a plurality of parts in the underfloor equipment of the vehicle in time series based on the information obtained from each of the means,
The processing means includes:
As long as one of the first vehicle body detection means and the second vehicle body detection means is in a state of detecting the vehicle body, the temperature detection by the temperature detection means and the storage of the detected temperature data are continued,
Until such time as the vehicle has reached the second wheel sensing means which is fixed intervals apart relative time point when it reaches the said first wheel sensing means disposed in the reference position in the row in run the previous SL line path The speed calculated by the vehicle speed detection means based on the required time, the travel distance of the vehicle from the reference position calculated by the elapsed time from the reference time, and the reference time obtained from the temperature detection means Based on the measured temperature time-series data, to sequentially obtain the temperature of a predetermined portion in the underfloor equipment of each vehicle to create a measured temperature time-series data for each predetermined portion of the vehicle,
A temperature for a railway vehicle, wherein a temperature of each of a plurality of portions of the underfloor equipment in the underfloor equipment is detected in a time-series manner based on the vehicle formation number read by the formation identification means. Detection device. First and second wheel detecting means including a photoelectric projector and a photodetector for detecting passage of a plurality of wheels of a running vehicle before and after a measurement section,
A first vehicle body detection unit and a second vehicle body detection unit that are arranged close to the first wheel detection unit and the second wheel detection unit and determine whether the vehicle is on the measurement section. Means,
Formation identification means for reading the formation information of the running vehicle,
Vehicle speed detection means for detecting the speed of the traveling vehicle based on the passing time of the traveling vehicle when passing between the first wheel detection means and the second wheel detection means being the measurement section;
Temperature detection means for acquiring the temperature of a plurality of parts in the underfloor equipment of the vehicle from the side of the track near the measurement section where the vehicle travels in a non-contact manner.
Processing means for detecting the temperature of a plurality of parts in the underfloor equipment of the vehicle in time series based on the information obtained from each of the means,
The processing means includes:
As long as one of the first vehicle body detection means and the second vehicle body detection means is in a state of detecting the vehicle body, the temperature detection by the temperature detection means and the storage of the detected temperature data are continued,
Until such time as the vehicle has reached the second wheel sensing means which is fixed intervals apart relative time point when it reaches the said first wheel sensing means disposed in the reference position in the row in run the previous SL line path The speed calculated by the vehicle speed detection means based on the required time, the travel distance of the vehicle from the reference position calculated by the elapsed time from the reference time, and the reference time obtained from the temperature detection means Based on the measured temperature time-series data, to sequentially obtain the temperature of a predetermined portion in the underfloor equipment of each vehicle to create a measured temperature time-series data for each predetermined portion of the vehicle,
Based on the vehicle formation number read by the formation identification means, the temperature of each of the plurality of parts of the underfloor equipment for each of the vehicle formation numbers can be detected in time series, and the reference time point is used as a reference. The measured temperature time-series data for each predetermined part is edited into position conversion waveform data having a temperature distribution corresponding to the underfloor equipment, and is configured to be displayed via display means. Temperature detector for railway vehicles. The processing means, wherein if none of the first vehicle detection means and the second vehicle detecting means reaches the state of not detecting the vehicle body, the temperature data temperature detection and detection by the temperature detecting means The railway vehicle temperature detecting device according to claim 1, wherein the storage is completed .   The processing means includes an operation of each of the first wheel detecting means, the second wheel detecting means, the first vehicle body detecting means, the second vehicle body detecting means, the temperature detecting means, and the knitting identifying means. And, based on each information, while creating the measured temperature time-series data for each predetermined portion of the underfloor equipment of the traveling vehicle, extract the maximum temperature for each predetermined range of the underfloor equipment, The temperature detection device for a railway vehicle according to claim 1 or 2, wherein an alarm is issued when the maximum temperature exceeds a predetermined threshold. Said first wheel sensing means and said second wheel sensing means, oil becomes faster photoelectric sensor response speed a waterproof, when the circular arc which is a part of the left and right sides wheel passes, The temperature detecting device for a railway vehicle according to claim 1, wherein the light beam between the light emitter and the light receiver is blocked to detect passage of the wheel. The temperature detecting means , the knitting identifying means , the wheel detecting means , and the vehicle body detecting means are configured to be attached to a gantry utilizing a part of a bridge structure when detecting temperature on an iron bridge. The temperature detecting device for a railway vehicle according to claim 1 or 2, wherein Said temperature sensing means, the formation identification means, the wheel detection means, the vehicle body detecting means, in the case of detecting the temperature on the ground, configured for attachment to the frame, which is provided independently of the railway line The temperature detecting device for a railway vehicle according to claim 1 or 2, wherein

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