JP3630079B2 - Repair replacement time detection method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a railway vehicle using a vibration accelerometer attached to the railway vehicle. Of cushioning member How to detect repair / replacement time To the law Related.
[0002]
[Prior art]
Railcars include various components such as air springs and shock absorbers such as various dampers, and wheels, and these parts can be repaired or replaced according to the degree of wear. Safety and comfort are maintained while driving.
[0003]
Wear of parts included in a railway vehicle is detected by removing the part from the vehicle and inspecting it for each predetermined period or period set as the mileage, and abnormalities such as wear are detected by the inspection. In the event of failure, repair and replacement with new parts will be carried out.
[0004]
In addition, some parts may need to be attached to a dedicated inspection machine.For example, with a damper attached to a bogie part of a railway vehicle to absorb vibration during traveling, the damper is removed from the railway vehicle and used as an inspection machine. In addition to the actual inspection work, accompanying work with a great amount of work and work time is required, such as removing from the inspection machine and reattaching to the railway vehicle after installation and inspection.
[0005]
The abnormalities detected by these inspections include, for example, a deterioration of the damper, an air spring puncture, and a wheel shape abnormality called a flat that occurs due to a stop operation during traveling.
[0006]
[Problems to be solved by the invention]
However, normal parts that do not require replacement must be inspected with accompanying work such as attachment and removal of parts every predetermined period, which requires a large amount of work and work time. .
[0007]
In addition, when there is an abnormality such as a damper deterioration, air spring puncture, or wheel shape abnormality, it is necessary to immediately repair or replace it from the viewpoint of ensuring safety while driving and maintaining comfort. Nevertheless, there is a problem in terms of safety and comfort, because there is a possibility that the business run may be performed without detecting the abnormality until the inspection cycle is reached.
[0008]
The present invention has been made in view of such circumstances, attached a vibration accelerometer to a railway vehicle to measure the amplitude and frequency during traveling, based on the measurement values obtained by the measurement, Buffer member By detecting the repair / replacement time and occurrence of abnormalities, it is possible to reduce the amount of work and time required for inspection, and to maintain the safety and comfort during business travel. Legal For the purpose of provision.
[0009]
[Means for Solving the Problems]
The repair replacement time detection method according to the first invention is A buffer member, Railway vehicle with vibration accelerometer To detect the repair and replacement time of the buffer member In the repair and replacement time detection method, Of the buffer member Vibration while driving By vibration accelerometer Based on the measured value obtained by measuring and Of the buffer member It is characterized by detecting the repair and replacement time.
[0010]
In the repair and replacement time detection method according to the first aspect of the present invention, based on the vibration measured during traveling. Buffer member For example, based on the vibration in the longitudinal direction of the bogie of the railway vehicle, for example, the repair time of the yaw damper is detected, or on the basis of the vibration in the vertical direction of the vehicle body of the railway vehicle, for example, the air spring is repaired and replaced. Because the timing is detected, the Buffer member It is possible to perform an efficient inspection without the need for work such as removal, and to reduce the amount of work and time required for the inspection. Buffer member Should be repaired or replaced because it is possible to detect the situation immediately. Buffer member Since it is possible to prevent business travel in the state of using, it is possible to ensure safety and maintain comfort during travel.
[0011]
The repair and replacement time detection method according to the second invention is the first invention, The buffer member is one of a vertical shaft damper, an air spring, a yaw damper, and a vehicle body left-right motion damper. It is characterized by that.
[0012]
The repair and replacement time detection method according to the second invention is: Detects the time for repair and replacement of the vertical axis damper, air spring, yaw damper, and vehicle left / right damper It is possible.
[0013]
The repair replacement time detection method according to the third invention is: Detects the time for wheel replacement in a railway vehicle equipped with a vertical vibration accelerometer for detecting the vertical vibration of the vertical axis damper and a vertical vibration accelerometer for detecting the vertical vibration of the air spring. In the repair and replacement time detection method, vibration during travel of the vertical axis damper is measured by a vertical vibration accelerometer for detecting the vertical axis damper, and vibration during travel of the air spring is measured by a vertical vibration accelerometer for detecting the air spring. Measure and detect the repair / replacement timing of the wheel based on the measured vibration value of the vertical axis damper and the measured vibration value of the air spring It is characterized by that.
[0014]
In the repair and replacement time detection method according to the third invention, By detecting the repair / replacement timing based on the measurement values of multiple vibration accelerometers, the detection accuracy can be improved, ensuring safety during driving. Is possible.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the present invention will be described in detail with reference to the drawings illustrating embodiments thereof.
FIG. 1 is a side view schematically showing the inside of a vehicle body and a carriage part of a railway vehicle to which the repair / replacement time detection method of the present invention is applied, and FIG. 2 is a railway vehicle carriage to which the repair / replacement time detection method of the present invention is applied. It is a top view which shows a part typically.
[0028]
In the figure, reference numeral 1 denotes a railway vehicle. The railway vehicle 1 has a rectangular parallelepiped shape, and a vehicle body portion 2 on which passengers and cargo and other objects to be transported are placed, and the vehicle body portion 2 are arranged in front and rear to support the vehicle body portion 2 from below. It also has a pair of cart parts 3 and 3.
[0029]
The carriage unit 3 has an H shape in a plan view including left and right side beam portions 3a and 3a arranged in parallel to the traveling direction, and a horizontal beam portion 3b passing the side beam portions 3a and 3a, and the left and right side beam portions. 3a and 3a have two pairs of axle boxes 3c, 3c,... At the front and rear, respectively, and the two front and rear axle boxes 4 and 4 are rotated by the two pairs of axle boxes 3c, 3c,. The axles 4 and 4 support a pair of wheels 5, 5,.
[0030]
Are disposed between the shaft boxes 3c, 3c,... And the side beam portions 3a, 3a, and the vertical shaft dampers 6, 6,. By this, it functions as a buffer member which suppresses that vibration from wheels 5, 5, ... transmits directly to side beam parts 3a and 3a.
[0031]
In addition, air springs 7 and 7 for connecting the vehicle body 2 and the carriage 3 are fixed to the connecting portions of the side beam portions 3a and 3a and the lateral beam portions 3b, and the air springs 7 and 7 expand and contract in the vertical direction. Thus, it functions as a buffer member that suppresses the vibration in the vertical direction of the carriage unit 3 from being directly transmitted to the vehicle body unit 2.
[0032]
Furthermore, on the outside of each side beam portion 3a, 3a, a yaw damper 8 that connects the vehicle body portion 2 and the carriage portion 3 is formed in an L shape by a buffer portion that expands and contracts in the front-rear direction and an arm portion that is fixed to the vehicle body portion 2. One end of the buffer portion 8 is fixed, and the buffer portion of the yaw dampers 8 and 8 expands and contracts in the front-rear direction, thereby suppressing the vibration in the front-rear direction of the carriage unit 3 from being directly transmitted to the vehicle body unit 2. Functions as a member.
[0033]
A vehicle body left-right motion damper 9 is provided which has a rod shape, both ends are fixed to the vehicle body portion 2 and the center portion is supported by the cross beam portion 3b. It functions as a buffer member that suppresses direct transmission of vibration in the direction to the vehicle body portion 2.
[0034]
Further, in order to measure these vibrations, vertical shaft dampers that measure vibration acceleration in the vertical direction are provided on the shaft boxes 3c, 3c,..., The upper portions of the shaft boxes 3c, 3c,. Detecting vertical vibration accelerometers 10, 10,... In the vicinity of the part of the vehicle body 2 supported by the carriage unit 3, the air spring detecting vertical vibration accelerometers 11, 11 for measuring the vertical vibration acceleration, on each side In the vicinity of the connection portion between the beam portions 3a and 3a and the horizontal beam portion 3b, the longitudinal vibration accelerometers 12 and 12 for detecting the yaw damper for measuring the vibration acceleration in the longitudinal direction, and the body lateral movement damper 9 in the vehicle body portion 2 are fixed. In the vicinity of, left and right damper vibration accelerometers 13 for measuring the vibration acceleration in the left and right direction are respectively disposed, and the measurement values obtained by the respective vibration accelerometers are measured in the interior of the vehicle body 2. Controls arranged in It is sent to the 14.
[0035]
The controller 14 that receives the measurement value includes an analysis unit 14a having a function of analyzing the received measurement value in real time, and a detachable recording medium 14b that records the measurement value and the analysis result. The analysis result is used as an output signal. And output to a vehicle monitor (not shown).
[0036]
The controller 14 is used as a repair / replacement time detection device and / or an abnormality detection device in the present invention. After the traveling is finished, the recording medium 14b is removed from the controller 14 and an external processing device 15 using a personal computer or the like is used. The processing device 15 receives the recorded measurement value, performs analysis processing using processing such as FFT, and outputs the analysis result, thereby allowing the processing device 15 to detect the repair replacement time of the present invention. You may use as an apparatus and / or an abnormality detection apparatus.
[0037]
Next, the measurement principle of the repair and replacement time detection method and abnormality detection method of the present invention will be described.
FIG. 3 is a graph showing measured values of the vertical vibration accelerometer 10 for detecting the vertical axis damper used in the repair / replacement timing detection method of the present invention.
FIG. 3A shows time history data of measured values when the vertical axis damper 6 is normal, and FIG. 3B shows time history data of measured values when the vertical axis damper is repaired and replaced.
[0038]
By comparing FIGS. 3A and 3B, it can be seen that the waveforms are clearly different between the normal time and the repair replacement time.
Therefore, the amplitude threshold value A1, the frequency lower limit side threshold value Fl1, and the frequency upper limit side threshold value Fh1 are set in advance for the amplitude peak value An1 (n = 1 to i) and the frequency Fn1 (n = 1 to i) of each vibration. In addition, the amplitude peak value An1 of the data preprocessed by filters such as a low pass filter, a band pass filter, and a band stop filter exceeds the amplitude threshold value A1, and the frequency Fn1 is lower than the frequency lower limit side. When the number of times entering the threshold value Fl1 and the frequency upper limit side threshold value Fh1 is counted (An1 ≧ A1 and Fl1 ≦ Fn1 ≦ Fh1 → N1 = N1 + 1) ≧ N01), it is possible to determine that the vertical axis damper 6 has deteriorated and the repair and replacement time has been reached.
[0039]
However, in order to prevent misjudgment, when the data exceeding various threshold values is discontinuous, for example, when there is an interval longer than a predetermined time or period from the time of the previous count, it is desirable to clear the number N1 to zero.
[0040]
The frequency Fn1 is obtained by calculating the time Tn1 from the time when the vibration acceleration shows the minimum value to the time when the vibration acceleration shows the maximum value, and calculating from the obtained value Tn1 using the calculation formula shown by the following formula 1.
[0041]
Fn1 = 1 / (2 × Tn1) ............ Formula 1
[0042]
In other words, the measurement value obtained by the vertical vibration accelerometer 10 for detecting the vertical axis damper is transferred to the controller 14, where the measurement value is received by the controller 14, and the received measurement value is compared with the threshold value by the analysis unit 14a. By analyzing the output and outputting the analysis result to the vehicle monitor, it is possible to determine that the vertical axis damper 6 has reached the repair replacement time even during traveling, and the analysis result from the vehicle monitor is sent to the repair facility. By transmitting the data, the repair facility can prepare for repair / replacement, so that the repair / replacement can be performed promptly after the traveling is completed.
[0043]
FIG. 4 is a graph showing the result of frequency analysis by FFT of measured value data of the vertical axis damper detecting vertical vibration accelerometer 10 used in the repair / replacement timing detection method of the present invention.
4A shows a result when the vertical axis damper 6 is normal, and FIG. 4B shows an analysis result of the repair time for the vertical axis damper 6, both of which are set in advance. It is the result of analyzing the running results for the section.
[0044]
Note that the travel section here may be an entire run or a specific section where a prominent analysis result can be easily obtained. In the case of a specific section, point data from the vehicle monitor side The position can be specified by transmitting data that can specify a position such as to the controller 14 or inputting the point data directly to the controller 14.
[0045]
By comparing the analysis results of normal and repair / replacement times in FIGS. 4 (a) and 4 (b), it is confirmed that a remarkable peak appears in the vicinity of a specific frequency at the repair / replacement time compared to the normal time. it can.
Therefore, the PSD threshold value P1, the lower limit side threshold value fl1 and the upper limit side threshold value fh1 are set in advance for the peak value and the frequency fp1 of the peak value, and the measured value data during traveling is subjected to FFT analysis to obtain the peak value fp1. Exceeds the PSD threshold value P1 (fp1 ≧ P1), and the frequency fp1 falls between the lower limit side threshold value fl1 and the upper limit side threshold value fh1 (fl1 ≦ fp1 ≦ fh1), the repair timing of the vertical axis damper 6 is changed. Can be determined to have reached.
[0046]
That is, the measurement value of the vertical vibration accelerometer 10 for detecting the vertical axis damper passed to the controller 14 is recorded in the recording medium 14b.
After the traveling, the measured value recorded on the recording medium 14b is read into the processing device 15, and when the processing value obtained by performing the FFT analysis by the processing device 15 exceeds a predetermined threshold, the repair replacement time is set. By outputting the indicated signal as an analysis result, it is possible to determine that the vertical axis damper 6 has reached the repair replacement time, and thus it is possible to improve the determination accuracy of the repair replacement time.
In the above-described embodiment, an analysis method using FFT analysis is described. However, the present invention is not limited to this, and for example, weblet analysis that simultaneously obtains position information may be used.
[0047]
FIG. 5 is a graph showing measured values of the air spring detection vertical vibration accelerometer 11 used in the repair / replacement timing detection method of the present invention.
FIG. 5A shows time history data of measured values when the air spring 7 is normal, and FIG. 5B shows time history data of measured values when the air spring 7 is repaired and replaced.
[0048]
By comparing FIGS. 5 (a) and 5 (b), it can be seen that the amplitude is larger at the repair and replacement time than at the normal time.
Therefore, the amplitude threshold value A2, the frequency lower limit threshold value Fl2, and the frequency upper limit side threshold value Fh2 are set in advance for the amplitude peak value An2 (n = 1 to i) and the frequency Fn2 (n = 1 to i) of each vibration. The amplitude peak value An2 of the data pre-processed by the filters such as the low-pass filter, the band-pass filter, the band-stop filter, etc. exceeds the amplitude threshold value A2 and the frequency Fn2 is the lower frequency side threshold value. Counts the number of times entering Fl2 and the frequency upper limit threshold value Fh2 (An2 ≧ A2 and Fl2 ≦ Fn2 ≦ Fh2 → N2 = N2 + 1), and the counted number N2 exceeds a preset number threshold N02 (N2 ≧ N02), it is possible to determine that the air spring 7 has a puncture tendency and has reached the repair replacement time.
[0049]
However, in order to prevent misjudgment, when the data exceeding various threshold values is discontinuous, for example, when there is an interval longer than a predetermined time or period from the time of the previous count, it is desirable to clear the number N2 to zero.
[0050]
The frequency Fn2 is obtained by calculating the time Tn2 from the time when the vibration acceleration shows the minimum value to the time when the vibration acceleration shows the maximum value, and calculating from the obtained value Tn2 by the calculation formula shown by the following formula 2.
[0051]
Fn2 = 1 / (2 × Tn2) ............ Formula 2
[0052]
That is, the measurement value obtained by the vertical vibration accelerometer 11 for air spring detection is transferred to the controller 14, which receives the measurement value, and compares the received measurement value with the threshold value by the analysis unit 14a. By performing analysis and outputting the analysis result to the vehicle monitor, it is possible to determine that the air spring 7 has reached the time for repair and replacement even during traveling. It is possible to do this, and by sending the analysis results from the vehicle monitor to the repair facility, the repair facility can prepare for repair replacement. Can do.
[0053]
FIG. 6 is a graph showing the result of frequency analysis of the measured value data of the vertical vibration accelerometer 11 for air spring detection used in the repair replacement time detection method of the present invention by FFT.
FIG. 6A shows the result when the air spring 7 is normal, and FIG. 6B shows the analysis result of the repair time for the air spring 7.
[0054]
By comparing the analysis results of the normal time and the repair / replacement time in FIG. 6, the peak frequency band transitions at the repair / replacement time as compared with the normal time, and the value is also larger.
Therefore, the PSD threshold value P2, the lower limit side threshold value fl2, and the upper limit side threshold value fh2 are set in advance for the peak value and the frequency fp2 of the peak value, and the measured value data at the time of traveling is subjected to FFT analysis to obtain the peak value fp2 Exceeds the PSD threshold value P2 (fp2 ≧ P2), and the frequency fp2 falls between the lower limit side threshold value fl2 and the upper limit side threshold value fh2 (fl2 ≦ fp2 ≦ fh2), the air spring 7 is in the repair and replacement period. It can be judged that it has reached.
[0055]
That is, the measurement value of the air spring detection vertical vibration accelerometer 11 passed to the controller 14 is recorded in the recording medium 14b.
After the traveling, the measured value recorded on the recording medium 14b is read into the processing device 15, and when the processing value obtained by performing the FFT analysis by the processing device 15 exceeds a predetermined threshold, the repair replacement time is set. By outputting the indicated signal as an analysis result, it can be confirmed that the air spring 7 has reached the repair / replacement time, and this makes it possible to improve the determination accuracy of the repair / replacement time and to deal with it before an abnormality occurs. Become.
In the above-described embodiment, an analysis method using FFT analysis is described. However, the present invention is not limited to this, and for example, weblet analysis that simultaneously obtains position information may be used.
[0056]
FIG. 7 is a graph showing measured values of the longitudinal vibration accelerometer 12 for detecting the yaw damper used in the repair / replacement timing detection method of the present invention.
FIG. 7A shows time history data of measured values when the yaw damper 8 is normal, and FIG. 7B shows time history data of measured values when the vertical axis damper 6 is repaired and replaced.
[0057]
By comparing FIGS. 7 (a) and 7 (b), it can be seen that the amplitude is larger at the repair and replacement time than at the normal time.
Therefore, the amplitude threshold value A3, the frequency lower limit threshold value Fl3, and the frequency upper limit side threshold value Fh3 are set in advance for the amplitude peak value An3 (n = 1 to i) and the frequency Fn3 (n = 1 to i) of each vibration. , The number of times the amplitude peak value An3 of the data preprocessed by filters such as a low pass filter, a band pass filter, and a band stop filter exceeds the amplitude threshold A3, and the frequency Fn3 is the lower frequency limit Counts the number of times that falls within the threshold value Fl3 and the frequency upper limit threshold value Fh3 (An3 ≧ A3 and Fl3 ≦ Fn3 ≦ Fh3 → N3 = N3 + 1), and the counted number N3 exceeds a preset number of times threshold N03 (N3 ≧ N03), it can be determined that the yaw damper 8 is in a deterioration tendency and the repair and replacement time has been reached.
[0058]
However, in order to prevent misjudgment, it is desirable to clear the number N3 to zero when data exceeding various threshold values is discontinuous, for example, when there is an interval equal to or longer than a predetermined time or period since the previous counting.
[0059]
The frequency Fn3 is obtained by measuring the time Tn3 from the time when the vibration acceleration shows the minimum value to the time when the vibration acceleration shows the maximum value, and calculating from the obtained value Tn3 by the calculation formula shown by the following formula 3.
[0060]
Fn3 = 1 / (2 × Tn3) ............ Formula 3
[0061]
That is, the measurement value obtained by the yaw damper detection longitudinal vibration accelerometer 12 is transferred to the controller 14, and the controller 14 receives the measurement value, and the analysis unit 14a compares the received measurement value with the threshold value. And output the analysis result to the vehicle monitor, so that it is possible to determine that the yaw damper 8 has reached the repair replacement time even during traveling, thereby performing abnormal measures such as low-speed traveling or emergency stop. In addition, by sending the analysis results from the vehicle monitor to the repair facility, the repair facility can prepare for repair replacement. .
[0062]
FIG. 8 is a graph showing the result of frequency analysis by FFT of measured value data of the yaw damper detection longitudinal vibration accelerometer 12 used in the repair / replacement timing detection method of the present invention.
FIG. 8A shows a result when the yaw damper 8 is normal, and FIG. 8B shows an analysis result of the repair and replacement time of the yaw damper 8. In FIG. 8B, a graph indicated by a dotted line is an analysis result when the yaw damper 8 is in an initial deterioration state.
[0063]
By comparing the analysis results of the normal time and the repair / replacement time in FIG. 8, a remarkable peak appears near a specific frequency in the repair / replacement time as compared with the normal time, and this peak shows the deterioration of the yaw damper 8. It can be confirmed that it grows as it progresses.
Therefore, the PSD threshold value P3, the lower limit side threshold value fl3, and the upper limit side threshold value fh3 are set in advance for the peak value and the frequency fp3 of the peak value, and the measured value data at the time of traveling is subjected to FFT analysis to obtain the peak value fp3. Exceeds the PSD threshold value P3 (fp3 ≧ P3), and the frequency fp3 falls between the lower limit side threshold value fl3 and the upper limit side threshold value fh3 (fl3 ≦ fp3 ≦ fh3), the yaw damper 8 has reached the repair replacement timing. Can be determined.
[0064]
That is, the measurement value of the yaw damper detection longitudinal vibration accelerometer 12 passed to the controller 14 is recorded in the recording medium 14b.
After the traveling, the measured value recorded on the recording medium 14b is read into the processing device 15, and when the processing value obtained by performing the FFT analysis by the processing device 15 exceeds a predetermined threshold, the repair replacement time is set. By outputting the indicated signal as an analysis result, it is possible to determine that the yaw damper 8 has reached the repair / replacement time, and this can improve the determination accuracy of the repair / replacement time and cope with it before an abnormality occurs. It becomes.
In the above-described embodiment, an analysis method using FFT analysis is described. However, the present invention is not limited to this, and for example, weblet analysis that simultaneously obtains position information may be used.
[0065]
FIG. 9 is a graph showing measured values of the left and right damper vibration accelerometer 13 used in the repair and replacement time detection method of the present invention.
FIG. 9A shows time history data of measured values when the vehicle body left-right motion damper 9 is normal, and FIG. 9B shows time history data of measured values of the vehicle body left-right motion damper at the repair and replacement time.
[0066]
By comparing FIG. 9A and FIG. 9B, it can be seen that the amplitude is larger at the repair replacement time than at the normal time.
Therefore, the amplitude threshold value A4, the frequency lower limit threshold value Fl4, and the frequency upper limit side threshold value Fh4 are set in advance for the amplitude peak value An4 (n = 1 to i) and the frequency Fn4 (n = 1 to i) of each vibration. , The number of times the amplitude peak value An4 of data preprocessed by filters such as a low pass filter, a band pass filter and a band stop filter exceeds the amplitude threshold value A4, and the frequency Fn4 is on the lower frequency side When the number of times exceeding the threshold value Fl4 and the frequency upper limit side threshold value Fh4 is counted (An1 ≧ An and Fl4 ≦ Fn4 ≦ Fh4 → N4 = N4 + 1), and the counted number N4 exceeds a preset number threshold N04 (N4 ≧ N04), it can be determined that the vehicle body left-right motion damper 9 has deteriorated and the repair and replacement time has been reached. A.
[0067]
However, in order to prevent misjudgment, it is desirable to clear the number N4 to zero when data exceeding various predetermined values is discontinuous, for example, when there is an interval equal to or longer than a predetermined time or period since the previous counting.
[0068]
The frequency Fn4 is obtained by measuring the time Tn4 from the time when the vibration acceleration shows the minimum value to the time when the vibration acceleration shows the maximum value, and calculating from the obtained value by the calculation formula shown by the following formula 4.
[0069]
Fn4 = 1 / (2 × Tn4) ............ Formula 4
[0070]
In other words, the measurement value obtained by the left and right dynamic damper vibration accelerometer 13 is transferred to the controller 14, and the controller 14 receives the measurement value, and the analysis unit 14a compares the received measurement value with the threshold value. And outputting the analysis result to the company monitor, it is possible to determine that the vehicle body left-right motion damper 9 has reached the repair replacement time even during traveling, and the analysis result is transmitted from the vehicle monitor to the repair facility. By doing so, the repair facility can prepare for repair / replacement, so that the repair / replacement can be carried out promptly after the traveling.
[0071]
FIG. 10 is a graph showing a result of frequency analysis by FFT of measured value data of the left and right damper vibration accelerometer 13 used in the repair / replacement timing detection method of the present invention.
FIG. 10A shows a result when the vehicle body left-right motion damper 9 is normal, and FIG. 10B shows an analysis result of the vehicle body left-right motion damper 9 when it is repaired and replaced.
[0072]
By comparing the analysis results of normal and repair replacement times in Figs. 10 (a) and 10 (b), it is confirmed that a remarkable peak appears near a specific frequency at the repair replacement time compared to normal time. can do.
Therefore, the PSD threshold value P4, the lower limit side threshold value fl4, and the upper limit side threshold value fh4 are set in advance with respect to the peak value and the frequency fp4 of the peak value, and the measured value data at the time of traveling is subjected to FFT analysis to obtain the peak value fp4. Exceeds the PSD threshold value P4 (fp4 ≧ P4), and the frequency fp4 falls between the lower limit side threshold value fl4 and the upper limit side threshold value fh4 (fl4 ≦ fp4 ≦ fh4), the vehicle body left-right motion damper 9 is repaired and replaced. It can be determined that the time has come.
[0073]
That is, the measured value of the left-right motion damper vibration accelerometer 13 passed to the controller 14 is recorded in the recording medium 14b.
After the traveling, the measured value recorded on the recording medium 14b is read into the processing device 15, and when the processing value obtained by performing the FFT analysis by the processing device 15 exceeds a predetermined threshold, the repair replacement time is set. By outputting the indicated signal as an analysis result, it is possible to determine that the vehicle body left-right motion damper 9 has reached the repair replacement time, thereby improving the determination accuracy of the repair replacement time and dealing with it before an abnormality occurs. It becomes possible.
In the above-described embodiment, an analysis method using FFT analysis is described. However, the present invention is not limited to this, and for example, weblet analysis that simultaneously obtains position information may be used.
[0074]
FIG. 11 is a graph showing measured values of a vibration accelerometer that measures the vibration acceleration in the vertical direction used in the repair replacement timing detection method and abnormality detection method of the present invention.
FIG. 11 shows the result of measuring the vibration acceleration in the vertical direction in order to judge the abnormality detection of the wheel 5 and the detection of the repair replacement time using the vertical vibration accelerometer 10 for detecting the vertical axis damper. FIG. The time history data of the measurement value at the normal time is shown, and FIG. 11B shows the time history data of the measurement value when the abnormality of the wheel 5 called flat occurs.
[0075]
By comparing FIGS. 11A and 11B, it can be read that when the flat is generated, vibration having a large amplitude is generated at a constant period as compared with the normal time.
Therefore, the amplitude threshold value A5, the frequency lower limit threshold value Fl5, and the frequency upper limit side threshold value Fh5 are set in advance for the amplitude peak value An5 (n = 1 to i) and the frequency Fn5 (n = 1 to i) of each vibration. The amplitude peak value An5 of data preprocessed by a filter such as a low-pass filter, a band-pass filter, and a band stop filter exceeds the amplitude threshold value A5, and the frequency Fn5 is a lower frequency threshold value. Counting the number of times that falls within Fl5 and the frequency upper limit threshold value Fh5 (An5 ≧ A5 and Fl5 ≦ Fn5 ≦ Fh5 → N5 = N5 + 1), and the counted number N5 exceeds a preset number threshold N05 (N5 ≧ N05), it is possible to determine that a flat has occurred on the wheel 5 and that the repair and replacement time has been reached.
[0076]
However, in order to prevent misjudgment, when the data exceeding various threshold values is discontinuous, for example, when there is an interval longer than a predetermined time or period from the time of the previous count, it is desirable to clear the number N5 to zero.
The frequency Fn5 is obtained by calculating the time Tn5 from the time when the vibration acceleration shows the minimum value to the time when the vibration acceleration shows the maximum value, and calculating from the obtained value by the calculation formula shown by the following formula 5.
[0077]
Fn5 = 1 / Tn5 ............ Formula 5
[0078]
In other words, the measurement value obtained by the vertical vibration accelerometer 10 for detecting the vertical axis damper is transferred to the controller 14, where the measurement value is received by the controller 14, and the received measurement value is compared with the threshold value by the analysis unit 14a. By analyzing the output and outputting the analysis result to the vehicle monitor, it is possible to determine that the wheel 5 has reached the time for repair replacement even during traveling, thereby performing abnormal measures such as low-speed traveling or emergency stop. In addition, by sending the analysis results from the vehicle monitor to the repair facility, the repair facility can prepare for repair replacement. it can.
[0079]
FIG. 12 is a graph showing the results of frequency analysis by FFT of measured value data of a vibration accelerometer that measures the vibration acceleration in the vertical direction used in the repair replacement timing detection method and abnormality detection method of the present invention.
FIG. 12 shows the result of the vertical vibration acceleration measurement and the FFT analysis performed to determine the abnormality detection of the wheel 5 and the detection of the repair replacement time using the vertical vibration accelerometer 10 for detecting the vertical axis damper. a) shows the result at the normal time, and FIG. 12B shows the time history data of the measured value when the abnormality occurs.
[0080]
By comparing the analysis results of the normal and repair / replacement times in FIGS. 12 (a) and 12 (b), it is confirmed that a remarkable peak appears near a specific frequency at the repair / replacement time compared to the normal time. can do.
Therefore, the PSD threshold value P5, the lower limit side threshold value fl5, and the upper limit side threshold value fh5 are set in advance for the peak value and the frequency fp5 of the peak value, and the measured value data at the time of traveling is subjected to FFT analysis to obtain the peak value fp5. Exceeds the PSD threshold value P5 (fp5 ≧ P5), and the frequency fp5 falls between the lower limit side threshold value fl5 and the upper limit side threshold value fh5 (fl5 ≦ fp5 ≦ fh5), the wheel 5 has reached the repair replacement timing. Can be determined.
[0081]
That is, the measurement value of the vertical vibration accelerometer 10 for detecting the vertical axis damper passed to the controller 14 is recorded in the recording medium 14b.
After the traveling, the measured value recorded on the recording medium 14b is read into the processing device 15, and when the processing value obtained by performing the FFT analysis by the processing device 15 exceeds a predetermined threshold, the repair replacement time is set. By outputting the indicated signal as an analysis result, it can be confirmed that the wheel 5 has reached the repair / replacement time, and this makes it possible to improve the determination accuracy of the repair / replacement time and to deal with it before an abnormality occurs. .
In the above-described embodiment, an analysis method using FFT analysis is described. However, the present invention is not limited to this, and for example, weblet analysis that simultaneously obtains position information may be used.
[0082]
As the vibration accelerometer, the vertical vibration accelerometer 11 for air spring detection attached to the vehicle body 2 is used in addition to the vertical vibration accelerometer 10 for detecting the vertical axis damper attached to the carriage 3 as described above. Even if it is used, it is possible to detect an abnormality and detect a repair / replacement time. When an abnormality is detected by the vertical vibration accelerometer 10 for detecting the vertical axis damper attached to the carriage unit 3, which wheel 5 is abnormal. Can be detected.
[0083]
However, it is desirable not to make a judgment based on any of the values of the plurality of vibration accelerometers, but to make a judgment by comprehensively measuring the values of the plurality of vibration accelerometers. Since the frequency can be expressed by the following Equation 6, it can be detected that a flat has occurred when a peak appears at the same frequency in the measurement values of a plurality of vibration accelerometers.
[0084]
f = V / π · D Equation 6
Where f: frequency (Hz)
V: Speed (m / s)
D: Wheel diameter (m)
[0085]
Next, processing in the repair and replacement time detection method and abnormality detection method of the present invention will be described with reference to the flowchart shown in FIG.
Various vibration accelerometers such as the vertical vibration accelerometer 10 for detecting the vertical axis damper measure vibration (step S1), and pass the obtained measurement value to the controller 14 (step S2).
[0086]
The controller 14 records the received measurement value on the recording medium 14b (step S3), performs preprocessing with a filter (step S4), and whether both the amplitude and frequency of the preprocessed data exceed the threshold value. Is determined (step S5).
[0087]
If it is determined in step S5 that at least one of the amplitude and the frequency does not exceed the threshold value (step S5: N), the process returns to step S1 and is repeated.
[0088]
In step S5, when it is determined that both the amplitude and the frequency exceed the threshold (step S5: Y), the threshold is continuously determined (step S6), and when it is determined that the amplitude and frequency are not continuous (step S6: N), a variable Nn (n = 1 to 5) indicating the number of times the threshold has been exceeded is cleared to zero (step S7).
In step S6, when it is determined that they are continuous (step S6: Y), the process of step S7 is not performed.
Then, 1 is added to the variable Nn (step S8), and it is determined whether or not the variable Nn exceeds the number-of-times threshold N0n (step S9).
[0089]
If it is determined in step S9 that the variable Nn does not exceed the number-of-times threshold N0n (step S9: N), the process returns to step S1 and is repeated.
In step S9, when it is determined that the variable Nn exceeds the number-of-times threshold N0n (step S9: Y), an abnormality signal is output to the vehicle monitor as an analysis result detecting the repair replacement time or an analysis result detecting the abnormality ( Step S10).
[0090]
And the person in charge can recognize the repair replacement time and abnormality of various parts based on the obtained abnormality signal.
The same processing is performed when determining the repair / replacement timing and abnormality of various parts based on a plurality of measured values.
[0091]
【The invention's effect】
As described above in detail, the repair and replacement time detection method according to the present invention. In law Is based on vibrations measured while driving Buffer member Because it detects the repair time of the Buffer member It is possible to perform an efficient inspection without the need for work such as removal, and to reduce the amount of work and time required for the inspection. Buffer member Should be repaired or replaced because it is possible to detect the situation immediately. Buffer member Since the vehicle can be prevented from traveling in the state of using the vehicle, it has excellent effects such as ensuring safety during driving and maintaining comfort.
[0092]
More Run By detecting abnormalities such as wheel shape abnormalities while driving based on vibrations measured during the course, Buffer member It is possible to perform an efficient inspection without the need for work such as removal and visual inspection, and it is possible to reduce the amount of work and time required for the inspection, and promptly respond to the occurrence of an abnormality. Since it is possible to take measures, it is possible to achieve excellent effects such as ensuring safety while driving and maintaining comfort.
[Brief description of the drawings]
FIG. 1 is a side view schematically showing the inside of a vehicle body and a carriage part of a railway vehicle to which a repair / replacement time detection method of the present invention is applied.
FIG. 2 is a plan view schematically showing a bogie part of a railway vehicle to which a repair / replacement time detection method of the present invention is applied.
FIG. 3 is a graph showing measured values of a vertical vibration accelerometer for detecting a vertical axis damper used in the repair and replacement time detection method of the present invention.
FIG. 4 is a graph showing the result of frequency analysis by FFT of measured value data of a vertical vibration accelerometer for detecting a vertical axis damper used in the repair replacement timing detection method of the present invention.
FIG. 5 is a graph showing measured values of an air spring detection vertical vibration accelerometer used in the repair / replacement timing detection method of the present invention.
FIG. 6 is a graph showing the result of frequency analysis by FFT of measured value data of an air spring detection vertical vibration accelerometer used in the repair and replacement time detection method of the present invention.
FIG. 7 is a graph showing measured values of a longitudinal vibration accelerometer for yaw damper detection used in the repair / replacement time detection method of the present invention.
FIG. 8 is a graph showing the result of frequency analysis by FFT of measured value data of a yaw damper detection longitudinal vibration accelerometer used in the repair replacement timing detection method of the present invention.
FIG. 9 is a graph showing measured values of a left and right dynamic damper vibration accelerometer used in the repair and replacement time detection method of the present invention.
FIG. 10 is a graph showing the result of frequency analysis by FFT of measured value data of a left and right dynamic damper vibration accelerometer used in the repair replacement time detection method of the present invention.
FIG. 11 is a graph showing measured values of a vibration accelerometer that measures vibration acceleration in the vertical direction used in the repair and replacement time detection method and abnormality detection method of the present invention.
FIG. 12 is a graph showing the result of frequency analysis by FFT of measured value data of a vibration accelerometer that measures the vibration acceleration in the vertical direction used in the repair and replacement time detection method and abnormality detection method of the present invention.
FIG. 13 is a flowchart showing processing in the repair and replacement time detection method and abnormality detection method of the present invention.
[Explanation of symbols]
1 Railway vehicles
2 body parts
3 trucks
3a Side beam
3b Cross beam
3c axle box
4 axles
5 wheels
6 Vertical axis damper
7 Air spring
8 Yodanpa
9 Body left / right damper
10 Vertical vibration accelerometer for vertical axis damper detection
11 Vertical vibration accelerometer for air spring detection
12 Longitudinal vibration accelerometer for detecting the yaw damper
13 Left-right damper vibration accelerometer
14 Controller
14a Analysis unit
14b recording medium
15 Processing device

Claims (3)

In a railway vehicle equipped with a buffer member and attached with a vibration accelerometer , in a repair replacement time detection method for detecting a repair replacement time of the buffer member ,
The vibration during running of the buffer member is measured by a vibration accelerometer ,
A repair / replacement time detection method, comprising: detecting a repair / replacement time of the buffer member based on a measurement value obtained by the measurement. 2. The repair replacement timing detection method according to claim 1, wherein the buffer member is any one of a vertical shaft damper, an air spring, a yaw damper, and a vehicle body lateral movement damper . Detects the time to repair or replace wheels in a railway vehicle equipped with a vertical vibration accelerometer for detecting the vertical vibration of the vertical axis damper and a vertical vibration accelerometer for detecting the vertical vibration of the air spring. In the repair and replacement time detection method,
The vibration during running of the vertical axis damper is measured by a vertical vibration accelerometer for detecting the vertical axis damper,
The vibration during traveling of the air spring is measured by a vertical vibration accelerometer for air spring detection,
The measurement value of the vibration of the upper and lower shaft damper and based on the measurement value of the vibration of the air spring, <br/> repair replacement time detecting how to and detecting the repair replacement time of the wheels.

Images