JP4692517B2 - Method for diagnosing laying position of derailment prevention guard for railway vehicles - Google Patents

Description

  The present invention relates to a method for diagnosing whether or not the position of a derailment prevention guard installed in order to ensure traveling safety of a railway vehicle is correct.

After the “Hibiya Line Derailment Overturn Accident” that occurred in 2000, as disclosed in Non-Patent Document 1, the Hibiya Line Derailment Accident Investigation Report established the standards for installing derailment prevention guards on tracks. .
Journal of Japan Railway Facility Association, 2001-April issue, p25-28

  However, even if the derailment prevention guard is installed at the correct position in accordance with this installation standard, for example, when it is removed during night construction and then reinstalled after construction, the installation position may shift or be installed. It cannot be said that there is no case to forget.

  In addition, even if the derailment prevention guard is installed at the correct position according to the installation standards, if the vehicle is actually run and the derailment coefficient (= lateral pressure Q / wheel load P) is measured on the vehicle, the track will be misaligned or Due to the installation error, it cannot be said that there is no case where it is installed at a position deviated from a place where the derailment coefficient is large.

  Therefore, in order to ensure higher safety, it is necessary to check whether the derailment prevention guard is installed in the correct position and whether the derailment prevention guard is installed in a place where the derailment coefficient is large. .

  However, conventionally, the laying position of the derailment prevention guard is determined solely by measuring the distance on the track side when laying the track, and the location of the derailment coefficient when the vehicle is traveling is compared with the laying position of the derailment prevention guard. , It was necessary to check each different data. In addition, it has not been confirmed from the traveling vehicle whether the derailment prevention guard is laid correctly.

  The problem to be solved by the present invention is that it cannot be determined in real time during traveling whether or not the derailment prevention guard is laid at the correct position and whether or not it is installed in a place with a large derailment coefficient. is there.

  The method for diagnosing the position of a derailment prevention guard for railcars according to the present invention is based on whether or not the derailment prevention guard is laid at the correct position in real time during traveling and whether or not it is laid at a place where the derailment coefficient is large. The purpose is to make a decision.

That is, the laying position diagnosis method for the first railcar derailment prevention guard according to the present invention includes:
Attach a non-contact sensor to the part of the railcar trolley facing the derailment prevention guard laid along the track,
Understand where the vehicle is running,
Comparing the laying position information of the derailment prevention guard held in advance with the detection result of the derailment prevention guard laying position by the non-contact sensor,
The most important feature is to determine in real time during traveling whether or not the derailment prevention guard is laid correctly.

In addition, the second method for diagnosing the laying position of the derailment prevention guard for railway vehicles according to the present invention includes:
A non-contact sensor is provided on a portion of the railcar bogie that can measure wheel load and lateral pressure on the vehicle, facing the derailment prevention guard laid along the track,
While running the vehicle, compare the derailment coefficient obtained from the measurement results of the wheel load and lateral pressure, and the detection result of the derailment prevention guard laying position by the non-contact sensor,
The main feature is to determine in real time during traveling whether or not the derailment prevention guard is laid at a position with a high derailment coefficient.

  In the present invention, since the installation position of the derailment prevention guard can be confirmed online while traveling, a safer railway system can be realized.

  In the second aspect of the present invention, the derailment coefficient obtained from the measurement results of the wheel load and the lateral pressure is instantaneously compared with the detection position of the derailment prevention guard, so that the derailment prevention guard can be properly provided in a place where the derailment coefficient is large. You can check if it is laid.

The best mode for carrying out the present invention will be described below with reference to FIGS.
FIG. 1 is a view showing an example of attachment of a non-contact sensor used in a method for diagnosing the position of a railcar derailment prevention guard according to the present invention.

  The derailment prevention guard 2 is laid inside a wheel 5 that rolls on a pair of tracks 1, and the relative positional relationship between the track 1 and the derailment prevention guard 2 is constant.

  Therefore, for example, as shown in FIG. 1, a non-contact sensor 4 such as a laser displacement sensor is provided on the bogie frame facing the upper surface 2a of the derailment prevention guard 2 between the wheels 5 in the front-rear direction of the bogie 3 for railway vehicles. Thus, at the laying position of the derailment prevention guard 2, the distance L1 from the non-contact sensor 4 to the upper surface 2a of the derailment prevention guard 2 can be measured.

  On the other hand, at the position where the derailment prevention guard 2 is not laid, the distance L2 measured by the non-contact sensor 4 is the distance to the ground, and therefore this measurement distance L2 is the upper surface of the derailment prevention guard 2 from the non-contact sensor 4. This is greatly different from the distance L1 up to 2a.

  Therefore, if the distances L1 and L2 are measured by the non-contact sensor 4 during traveling, a measurement waveform as shown in FIG. 2 is obtained, and the position where the derailment prevention guard 2 is laid is instantaneously displayed. Moreover, it can be detected accurately.

  Accordingly, the traveling position during traveling of the vehicle is grasped from the relationship between the route information held in advance and the accumulated traveling distance, and the detection result of the laying position of the derailment guard 2 by the non-contact sensor 4, the construction drawings, etc. By comparing the laying position information of the derailment prevention guard 2 held in advance, it is possible to determine in real time during traveling whether the laying position of the derailment prevention guard 2 is correct. This is the first method of the present invention.

  According to the method of the first aspect of the present invention, for example, when the derailment prevention guard 2 is removed at night construction, etc., even if the derailment prevention guard 2 is forgotten to be re-installed after construction, derailment is performed when the first power generation vehicle is running. Since it is possible to detect forgetting to install the prevention guard 2, a safer railway system can be realized.

  Further, if the non-contact sensor 4 for carrying out the first method of the present invention is provided on a railway vehicle carriage capable of measuring wheel load and lateral pressure on the vehicle, the wheel load and lateral pressure are measured while the vehicle is running. The derailment coefficient can be obtained from the result.

  Therefore, if the calculated derailment coefficient is compared with the detection result of the laying position of the derailment prevention guard 2 by the non-contact sensor 4, it is determined whether the derailment prevention guard 2 is laid at a position where the derailment coefficient is large. Can be determined in real time. This is the second method of the present invention.

  Here, a railway vehicle bogie that can measure wheel load and lateral pressure on the vehicle is, for example, a wheel shaft on the front side in the traveling direction of the bogie 3 and a wheel shaft (so-called PQ wheel shaft) equipped with a device for measuring wheel load and lateral pressure. A non-contact displacement meter is arranged in a shaft box or the like, and the displacement amount of the wheel rim portion or plate portion is measured by the displacement meter, and the lateral pressure is obtained based on this result. No. 88967, a cart equipped with a wheel load and lateral pressure measuring device that combines the method for measuring the wheel load and the method of measuring the wheel load from the vertical displacement of the shaft spring.

  According to the second method of the present invention, it is possible to confirm whether or not the derailment prevention guard 2 is properly laid at a location where the derailment coefficient is large, as well as confirming the laying position of the derailment prevention guard 2.

  The present invention is not limited to the above example, and it goes without saying that the embodiments may be changed as appropriate within the scope of the technical idea described in each claim.

  For example, in the above example, the laser displacement sensor is shown as the non-contact sensor 4 that measures the distance to the derailment prevention guard 2, but an ultrasonic sensor or an eddy current sensor can be used as long as the distance can be measured in a non-contact manner. May be used.

  Further, instead of detecting the laying position of the derailment prevention guard 2 instead of measuring the distance to the derailment prevention guard 2, an ON / OFF switching sensor in which the ON / OFF signal is switched at the distance at which the derailment prevention guard 2 is detected. It is good. If such a non-contact sensor is employed, the method of the present invention can be implemented at a lower cost.

It is a figure which shows the example of attachment of the non-contact sensor used for the laying position diagnostic method of the derailment prevention guard for rail vehicles of this invention, (a) is the figure seen from the side of a vehicle advancing direction, (b) is also from the front FIG. It is a figure which shows the example of a detection measurement waveform of a derailment prevention guard.

Explanation of symbols

1 Track 2 Derailment Prevention Guard 3 Dolly 4 Non-contact Sensor 5 Wheel

Claims (3)

Attach a non-contact sensor to the part of the railcar trolley facing the derailment prevention guard laid along the track,
Understand where the vehicle is running,
Comparing the laying position information of the derailment prevention guard held in advance with the detection result of the derailment prevention guard laying position by the non-contact sensor,
A method for diagnosing the laying position of a derailment prevention guard for a railway vehicle, wherein whether or not the laying position of the derailment prevention guard is correct is determined in real time during traveling. A non-contact sensor is provided on a portion of the railcar bogie that can measure wheel load and lateral pressure on the vehicle, facing the derailment prevention guard laid along the track,
While running the vehicle, compare the derailment coefficient obtained from the measurement results of the wheel load and lateral pressure, and the detection result of the derailment prevention guard laying position by the non-contact sensor,
A method for diagnosing the laying position of a derailment prevention guard for a railway vehicle, characterized in that whether or not the derailment prevention guard is laid at a position having a high derailment coefficient is determined in real time during traveling.   The laying position diagnosis method for a railcar derailment prevention guard according to claim 1 or 2, wherein the noncontact sensor detects a distance from the noncontact sensor to the derailment prevention guard.

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