JP2010236875A - Structure state change detection system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure state change detection system which can determine the damage state of a structure accurately and at low cost, on the basis of many pieces of vibration data. <P>SOLUTION: The structure state change detection system 100 includes a fixed route bus 2 having at least a wheel 42 supported by an axle 40 and a spring (a buffer member) for buffering vibrations transmitted to the axle 40; an axle vibration sensor 5 for detecting the vibrations of the axle 40; a memory (a storage means) 30 for storing the vibration data detected by the axle vibration sensor 5, when the fixed route bus 2 passes through a bridge (the structure) 43, or an object to be inspected; and a damage determination apparatus 34 for determining the damage state of the fixed route bus 2 by analyzing the vibration data. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a structure deformation detection system, for example, a structure deformation detection system that detects the presence or absence of damage related to a small and medium bridge based on vibration data obtained from a moving vehicle.

About 70% of the approximately 670,000 existing bridges in Japan were constructed in the 1960s and 1970s, and these have played an important role as social infrastructure for the past 40 to 50 years. It is coming. On the other hand, many constructed bridges are going to have a design life at the same time in the future. If this is left unattended, vehicles as heavy objects that pass over the bridge, natural wind and hydraulic power, etc. There is a risk of damage by. In addition to removing or banning bridges that have reached the end of their useful lives, measures to avoid such dangers include “renewal (replacement)” and “life extension through repair and reinforcement”. With regard to “renewal (replacement)”, it is difficult to replace all aging bridges at once due to economic and time constraints. In addition, when trying to extend the life of a bridge through repairs and reinforcements, the life cycle cost (LCC) should be minimized in view of all reasonableness within the framework of maintenance using the Bridge Management System (BMS). There is a need to select conservative measures. However, “investigation / inspection”, which is important in deciding how to deal with this problem, takes time and expense even with the development of various technologies such as elucidation of material degradation mechanisms, sensing, structural analysis, information processing, and communication in recent years. There is no change in this, and it may be difficult to judge whether or not the result of collecting and diagnosing a huge amount of information is an objectively sufficiently reliable conclusion. In any case, before the 670,000 bridges reach the useful life at the time of design, it is necessary to identify the progress of the deterioration (latent period, progress period, acceleration period, deterioration period) and decide how to deal with it. It is important for ensuring the minimum safety to monitor whether it is entering the deterioration period from the acceleration period and to deal with it with priority without missing it.
As a prior art, Non-Patent Document 1 reports a track monitoring system capable of high-frequency measurement for small and medium-sized railways. In this paper, a simple measurement system composed of an accelerometer and GPS is installed in a business vehicle, and a system for constantly monitoring the state of the track from the vehicle vibration during traveling is constructed. Non-Patent Document 2 is a paper on the research results of road structure soundness evaluation by running a multi-function inspection vehicle. The inspection vehicle evaluates soundness by measuring various response values while normally running on a bridge. As well as clarifying the required performance, the possibility of the evaluation technology system is presented.

Hironori Ishii, Yozo Fujino, Yusuke Mizuno, Kiyoyuki Kaido: Development of trajectory monitoring system (TIMS) using vehicle vibration during running of commercial vehicles, Proceedings of JSCE F Vol. 64 no. 1, 44-61, 2008.2. Kuniyuki Sugiura, Yoshinobu Oshima, Takashi Yamaguchi, Yoshikazu Kobayashi, Haruki Okano, Naruki Tojo . 17-8, New Road Technology Conference, 2008.7.

However, the prior art reported in Non-Patent Document 1 performs an inverse analysis using a frequency transfer function obtained from a vehicle dynamic model reflecting a natural frequency and a damping constant obtained from a free vibration test of a vehicle, This is a reverse calculation of the ups and downs of the track from the vertical acceleration of the traveling vehicle, and there is a problem that the calculation is complicated and the real-time property of the analysis result is low.
The prior art reported in Non-Patent Document 2 extracts the vibration component of the bridge from the response value of the vehicle running while oscillating, and the vehicle must be equipped with facilities for multi-function inspection. There is a problem that inspection costs increase.
The present invention has been made in view of such a problem. After confirming that the vibration data of the vehicle when passing through the structure to be inspected is similar to the vibration data of the structure, the present invention is applied to the vehicle. By detecting the damage state of the structure based on the vibration data of the attached vibration sensor, it is possible to accurately and inexpensively determine the damage state of the structure based on a lot of vibration data. The purpose is to provide a system.

In order to solve such a problem, the present invention provides a vehicle including at least a wheel supported by an axle and a buffer member that cushions vibration transmitted to the axle, and detects vibration of the axle. An axle vibration sensor, storage means for storing vibration data detected by the axle vibration sensor when the vehicle passes through the structure to be inspected, and the damage state of the structure by analyzing the vibration data A damage judging device for judging, the damage judging device comprising: data comparing means for comparing vibration data stored in the storage means with normal vibration data when the structure is normal; and the data comparison Damage determining means for determining whether or not the structure has been damaged based on the data compared by the means, and the damage determining means includes the data comparing means. If differences in the compared data is equal to or greater than a predetermined value, and judging the damage to the structure occurs.
The structural deformation detection system according to the present invention includes a vehicle, an axle vibration sensor attached to the axle of the vehicle, and a storage unit that stores vibration data obtained from the axle vibration sensor. Vibration data generated when the vehicle passes through the structure to be inspected is stored in the storage means. The stored vibration data is input to a damage determination apparatus installed at the center, and is compared with normal vibration data at a normal time related to a structure to be inspected that has been acquired in advance. The data comparison unit compares the difference between the normal vibration data and the vibration data, and determines that the structure has been damaged when the value exceeds a predetermined value. The predetermined value can be calculated in advance by simulation or the like. In addition, as the vibration data is acquired with more data, the accuracy of the data increases. Therefore, it is conceivable to use a route bus that travels the same route every day as a vehicle. Thereby, it is possible to determine the damage state of the structure accurately and inexpensively based on a lot of vibration data.

According to a second aspect of the present invention, a structure vibration sensor that detects vibration generated in the structure when the vehicle passes, and the vibration data detected from the axle vibration sensor and the structure vibration sensor are synchronized. Similarity determination means for determining whether or not the comparison result is similar, and vibration data obtained from the axle vibration sensor when the similarity determination means determines that each of the vibration data is similar Is regarded as vibration data generated from the structure.
Based on the vibration data of the axle vibration sensor provided in the vehicle, in order to determine the damage state of the structure that has passed, it is necessary to confirm in advance that the axle vibration data and the vibration data of the structure are similar (equivalent). It is necessary to keep. Therefore, in the present invention, prior to measurement, a structure vibration sensor is attached to the center of the structure of the structure to be inspected, and the vehicle with the axle vibration sensor attached in that state is passed through the structure. And obtain vibration data of structure vibration sensor. Then, it is determined whether or not the results of synchronizing and comparing the acquired vibration data are similar. If they are similar, the arrangement position of the axle vibration sensor is fixed, and the structure vibration attached to the structure is fixed. Remove the sensor. Here, when it is not similar, the position of the axle vibration sensor is changed to find a similar place. Thereby, the presence or absence of damage related to the structure to be inspected can be determined only by analyzing the vibration data acquired from the axle vibration sensor attached to the vehicle.

According to a third aspect of the present invention, the predetermined value of the difference of the data compared by the data comparison means is a value of vibration data when the cumulative damage probability related to the structure has advanced to the early stage of deterioration.
The relationship between the cumulative damage probability and the secular change can be classified into a latent period, a progress period, an acceleration period, and a deterioration period. In particular, a decrease in safety due to structural damage is expected from the late acceleration period to the early deterioration period. Therefore, in the present invention, the value of the vibration data at that time is determined by simulation assuming the damage when the cumulative damage probability progresses to the early stage of the deterioration period. Then, an upper limit value of the difference of the vibration data compared is determined based on the determined value, and when the value is exceeded, it is considered that some damage has occurred in the structure. Thereby, the presence or absence of damage to the structure can be determined quantitatively.

Claim 4 comprises a transmitter for transmitting a recognition signal indicating a recognition number for identifying the structure to the structure, and a receiver for receiving a recognition signal transmitted from the transmitter to the vehicle, When the vehicle receives the recognition signal by the receiver, the vehicle stores the recognition number and vibration data detected by the axle vibration sensor in association with each other in the storage unit.
For example, when a plurality of structures on a route through which the vehicle passes are to be inspected, the driver of the vehicle needs to operate the storage device every time the vehicle passes through the structure. However, it is not preferable for safety to perform such an operation while driving. Moreover, it is necessary to make correspondence so that it can be determined which structure the vibration data stored in the storage means is. Therefore, in the present invention, the vehicle is provided with a receiver, and the structure is provided with a transmitter that transmits an identification number that identifies the structure. When passing through the structure, the structure identification number and the axle vibration are transmitted. The vibration data from the sensor is stored in association with each other. As a result, it is possible to immediately recognize from which structure the vibration data is the data, and since the storage operation is automatically performed, the safety of driving can be improved.

According to a fifth aspect of the present invention, the vehicle includes a communication unit, and vibration data detected by the axle vibration sensor when the vehicle passes through the structure and a recognition signal of the structure are transmitted by the communication unit. And
For example, if the vehicle is a route bus, it will return to the bus center once the day's operation ends. And the vibration data memorize | stored in the memory | storage means are memorize | stored in the memory of the center computer installed in the bus center. However, it is troublesome to perform this operation every day. In addition, the vehicle must be provided with storage means. Therefore, in the present invention, the vehicle is provided with communication means (a transmitter for transmitting data), and vibration data detected by the axle vibration sensor when the vehicle passes through the structure and a recognition signal of the structure are transmitted to the bus center by the communication means. The bus center stores the received data. As a result, the operation of storing the vibration data in the center computer of the bus center can be omitted, and forgetting of operation and operation mistakes can be prevented.

According to a sixth aspect of the present invention, the vehicle includes a storage start button for operating the storage unit.
If the storage means is operated continuously, there is no need to worry about when to start the storage operation. However, the storage capacity of the storage means is enormous and wasteful data must be stored, and only the necessary data must be extracted from that. Therefore, the present invention includes a storage start button for operating the storage means in the vehicle. As a result, only necessary data can be stored with an inexpensive configuration, and the storage capacity of the storage means can be minimized.

According to the present invention, the stored vibration data is input to a damage determination apparatus installed in the center, and is compared with normal vibration data at normal time related to the structure to be inspected that has been acquired in advance. The data comparison means compares the difference between the normal vibration data and the vibration data, and determines that the structure has been damaged when the value exceeds a predetermined value. In addition, the damage state of the structure can be determined with an inexpensive configuration.
Prior to measurement, a structure vibration sensor is attached to the center of the structure of the structure to be inspected, and it is determined whether or not the results of comparing and comparing the acquired vibration data are similar. If there is, the arrangement position of the axle vibration sensor is fixed and the structure vibration sensor attached to the structure is removed, so it is only necessary to analyze the vibration data acquired from the axle vibration sensor attached to the vehicle, and the structure to be inspected. It is possible to determine the presence or absence of damage according to the above.
Further, assuming that the cumulative damage probability has progressed to the early stage of the deterioration period, the value of vibration data at that time is determined by simulation. Then, the upper limit of the difference of the vibration data compared based on the determined value is determined, and if the value is exceeded, it is assumed that some damage has occurred in the structure. It can be determined quantitatively.
In addition, the vehicle is provided with a receiver, and the structure is provided with a transmitter for transmitting a recognition signal. When passing through the structure, the recognition signal of the structure and vibration data from the axle vibration sensor are stored in association with each other. Therefore, it is possible to immediately recognize from which structure the vibration data is the data, and the storage operation is automatically performed, so that the driving safety can be improved.
Further, since the vehicle is provided with a storage start button for operating the storage means, only necessary data can be stored with an inexpensive configuration, and the storage capacity of the storage means can be minimized.

It is a figure which shows the relationship between a cumulative damage probability and a secular change. It is a figure which shows a bridge and a vehicle interaction system simple spring model. It is a figure which shows the spring model of the input to a vehicle type | system | group, and a sprung and unsprung deformation. It is a conceptual diagram of sub-structure separation of sprung-unsprung-bridge. It is a figure which shows a sensor arrangement position. (A) (b) is a figure which shows the sprung / unsprung acceleration Fourier spectrum of the center of a girder and a route bus. (A) is a figure which shows an example of the time history waveform of the rear-wheel unsprung response acceleration of the center of a digit | girder and a route bus at the time of driving | running | working at 30 km / h, and 40 km / h. (A) is 30 km / h, (b) is the figure which shows the unsprung acceleration response time history of the route bus rear wheel of 3 times passing near the center of a digit at the time of 40 km / h traveling. (A) is 30 km / h, (b) is a figure which shows unsprung measurement error probability distribution at the time of 40 km / h driving | running | working. (A) is a figure which shows the outline | summary of driving | running | working vibration simulation, (b) is an object bridge main girder cross section and a model figure, (c) is a figure showing the item of analysis data. (A) is a figure which shows a road surface uneven | corrugated parameter, (b) is a figure which shows a road surface uneven | corrugated power spectral density function. It is a figure showing a 4-degree-of-freedom system bus analysis model. (A)-(f) is a figure showing the eigenvalue analysis result of an object bridge. (A)-(d) is a figure showing the eigenvalue analysis result of a route bus. It is a figure showing the main girder virtual damage location. (A) is a figure showing a simulation pattern, (b) is a figure showing comparison of actual measurement and simulation of a digit center lower flange distortion at the time of 30 km / h run. (A) is a figure which shows the comparison of the unsprung acceleration response at the time of 30 km / h and 40 km / h driving | running | working, (c) is a figure which shows the maximum acceleration and the maximum differential acceleration about the difference in the presence or absence of damage. . (A) is a block diagram showing the configuration of a damage determination apparatus constituting the structural deformation detection system of the present invention, (b) is a route bus constituting the structural deformation detection system of the present invention is the inspection object The figure which shows a mode that vibration data is collected by the axle vibration sensor when passing through the bridge which becomes, (c) is a figure which shows a mode that a route bus passes a plurality of inspection object bridges. is there. It is a flowchart explaining the operation | movement which checks the similarity of this invention. It is a flowchart explaining operation | movement of the structure deformation | transformation detection system which concerns on one Embodiment of this invention.

Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings. However, the components, types, combinations, shapes, relative arrangements, and the like described in this embodiment are merely illustrative examples and not intended to limit the scope of the present invention only unless otherwise specified. .
In contrast to the framework of the periodic inspection by BMS (Bridge Management System) and the constant monitoring system of SHM (Structural Health Monitoring), the present invention shows the acceleration shown in region 1 from the diagram showing the relationship between cumulative damage probability and secular change in FIG. It is a structural deformation detection system focused on reliably extracting signs with relatively large changes when progressing from the late stage to the early stage of deterioration. Specifically, this is a technique for extracting bridge vibration properties from axle (unsprung) vibration information of a vehicle when a large heavy vehicle passes through the bridge. Moreover, in an aging structure, structural changes that have progressed from the late acceleration period to the early deterioration period are expected to cause some changes in bridge vibration during passage of large heavy vehicles. In the present invention, an experiment using an actual bridge and a route bus on a method for extracting information related to deformation of the bridge from unsprung vibration information and its feasibility, and a problem related to structural deformation detection and its solution. And it was examined using numerical analysis simulation.

橋梁３と車両２の相互作用について、橋梁３側へは車両２のバネ下反力Ｒ_Sを荷重ベクトルとして入力し、車両側へは橋梁のたわみ（δ（ｔ）Εｕｍ）と路面の凹凸（λ（ｔ））を強制変位ベクトル

として入力する。通過中の時刻ｔ〜ｔ＋Δｔでの橋梁−車両系を、単純にモデル化すると、図２に示すような３質点相互作用系バネマスモデルで表現できると考えられる。
この系における振動の発生源は、路面凹凸λ（ｔ）と橋梁たわみδ（ｔ）の入力により生じる車両側振動および、その反力による橋梁への加振である。ここで、ある期間中の計測における橋梁系と車両系を表す各種物理定数および路面の凹凸λが一定である場合を想定する。当然この相互作用系で何度計測を行っても毎回同じ結果が得られる。 FIG. 2 is a view showing a bridge and vehicle interaction system simple spring model. When the vehicle 2 passes through the bridge 3, the dynamic model can be expressed as a dynamic interaction problem of the bridge system motion equation represented by the equation (1) and the vehicle system motion equation represented by the equation (2).

Regarding the interaction between the bridge 3 and the vehicle 2, the unsprung reaction force R _S of the vehicle 2 is input as a load vector to the bridge 3 side, and the deflection (δ (t) ｔum) of the bridge and the road surface unevenness ( λ (t)) is the forced displacement vector

Enter as. If the bridge-vehicle system at time t to t + Δt during the passage is simply modeled, it can be expressed by a three mass point interaction system spring mass model as shown in FIG.
The source of vibration in this system is vehicle-side vibration caused by the input of road surface unevenness λ (t) and bridge deflection δ (t), and vibration to the bridge due to the reaction force. Here, it is assumed that various physical constants representing the bridge system and the vehicle system and the road surface unevenness λ in the measurement during a certain period are constant. Naturally, the same result can be obtained every time the measurement is performed with this interaction system.

も変化する。さらに、その車両系の振動の変化により、車両系反力すなわち加振力Ｒ_Sが変化するため橋梁のたわみδ（ｔ＋Δｔ）が変化する。そういった連鎖によって、橋梁の剛性Ｋ_mの変化による影響が橋梁系、車両系双方の計測結果に現れる。
以上より、劣化等による橋梁の構造変状は車両系の節点応答

の変化として現れるため、橋梁の変状を車両側で検知することは原理的に可能であると考えられる。本発明のシステムにおいては、δ（ｔ）が大きいほど検知が容易になるため、中小型車よりも大型車両が適しており、実測データ等を参考にすると大型車両の場合、Ｍ_A＞Ｍ_B、Ｋｓ＜Ｋｔであることから図３に示すようにバネ上（節点Ａ）よりバネ下（節点Ｂ）の方が橋梁の変化を検知しやすいと考えられるため、バネ下振動に着目することとした。また、より簡易なシステムを実現する必要があるため、絶対加速度計測とした。 Next, a case is assumed in which various physical constants representing the vehicle system and road surface unevenness λ are constant and the bridge stiffness K _m is deformed due to some damage. At this time, the deflection δ (t) of the bridge due to the reaction force from the vehicle system at an arbitrary time in measurement changes. As the δ (t) changes, the response of each node of the vehicle system

Also changes. Further, due to the change in the vibration of the vehicle system, the vehicle system reaction force, that is, the excitation force R _S changes, so that the bridge deflection δ (t + Δt) changes. By such a chain, it bridges system affected by changes in the stiffness K _m of bridges, appearing in the vehicle system both measurement results.
Based on the above, bridge structural deformation due to deterioration, etc. is the vehicle node response.

It appears that it is possible in principle to detect the deformation of the bridge on the vehicle side. In the system of the present invention, detection becomes easier as δ (t) is larger. Therefore, a large vehicle is more suitable than a small and medium-sized vehicle, and M _A > M _B , Since Ks <Kt, as shown in FIG. 3, it is considered that the unsprung (node B) is easier to detect the change of the bridge than the unsprung (node A). . Also, since it is necessary to realize a simpler system, absolute acceleration measurement was used.

式（３）に示すように、系において不変である時刻、剛性、減衰、質量といった物理量に依存する比例係数Ｐおよびテイラー展開等を用いて展開された時刻ｔ以前の状態定数（既値）を使って近似することができる。すなわち、入力ベクトルに対し、系への応答は系に依存する各定数に依存して比例配分されることを表す。 Next, the vibration property extraction of the bridge using the unsprung vibration data of the route bus will be described. It is necessary to clarify the correlation in detecting bridge vibration from unsprung vibration of route buses. Here, consider substructure separation by sprung-unsprung-bridge as shown in FIG. First, regarding the sprung-unsprung system of the route bus, when a forced displacement including the bridge deformation δ (t) is input to the unsprung route bus, the equation of motion is within a very short time when the difference method approximation holds.

As shown in the equation (3), the state constant (existing value) before time t developed using a proportional coefficient P depending on physical quantities such as time, stiffness, damping, and mass, which is invariable in the system, and Taylor expansion etc. Can be approximated using In other words, the response to the system is proportionally distributed depending on each constant depending on the system with respect to the input vector.

におけるマトリックスが存在すると予想される。すなわち、差分法近似が成り立つ微少時間内において、式（４）が成り立つ場合、橋梁の振動性状は路線バスのバネ下振動に比例し、橋梁側変状の影響によるＡ_bの変化は、路線バスのバネ下振動変化Ａ_Sに比例して現れることを表している。
本発明では、上記仮説に関して、実橋梁と路線バスを用いた検証実験を行った。実験対象は劣化の要因が相互に複雑に関係するＲＣ構造物とし、一般的な路線バスの全長が約１０ｍ程度であることから支間２０ｍ程度の短スパン単純梁構造物とした。対象橋梁は、１径間約２２ｍ、４主桁のＲＣ構造で５．１５ｍおきに幅０．２１ｍの横桁が５本存在する橋梁とした。この橋梁は供用後４４年以上が経過しているが、構造性能に影響するような大きな損傷は生じていない健全橋梁である。実橋梁振動と路線バスのバネ下振動の相似性を確認するため、路線バス後輪が橋梁を通過した際の橋梁鉛直振動と路線バス後輪のバネ下鉛直振動の同時計測を実施した。 Next, consider the vibration of the unsprung-bridge system with respect to the force transmitted from the sprung. For the input from the sprung to this system, the bridge and unsprung responses are also proportionally distributed depending on the physical constants of the system as before. Therefore, the response vector of the bridge the A _b at every moment, if the unsprung response vectors route bus to A _S,

A matrix is expected to exist. Namely, within the short time that difference method approximation holds, if the expression (4) holds, the vibration characteristics of the bridge is proportional to the unsprung vibration of the route bus, the change of A _b by bridge side Deformation effects, route bus It shows that it appears in proportion to the unsprung vibration change A _S.
In the present invention, a verification experiment using an actual bridge and a route bus was conducted with respect to the above hypothesis. The object of the experiment was an RC structure in which the causes of deterioration are intricately related to each other. Since the total length of a general route bus is about 10 m, a short span simple beam structure with a span of about 20 m was used. The target bridge was a bridge with approximately 22m span and 4 main girder RC structures with five transverse girders with a width of 0.21m every 5.15m. Although this bridge has been in service for over 44 years, it is a healthy bridge that has not suffered any significant damage that would affect its structural performance. In order to confirm the similarity between the actual bridge vibration and the unsprung vibration of the route bus, the bridge vertical vibration and the unsprung vertical vibration of the route bus rear wheel when the route bus rear wheel passed through the bridge were measured simultaneously.

  FIG. 5 is a diagram showing an installation place of an acceleration sensor (vibration sensor) attached to a route bus. The acceleration sensor 4 is installed on a spring at a substantially intermediate position between the front wheel and the rear wheel, and the acceleration sensor 5 is installed below the spring of the axle of the rear wheel. As for the traveling speed of the route bus, as a result of hearing the driver, the speed when traveling safely on general roads is about 30 km / h to 40 km / h. Three experiments were performed. About speed adjustment, the speed meter was confirmed visually. The weather in the bridge area was cloudy, the temperature was stable at 22.2 to 24.3 ° C, and the humidity was 79 to 89%, and the environment did not significantly affect the mechanical properties of the structure. It is thought. Further, the temperature of the axle of the route bus on which the sensor was installed was 43 ° C. in the measurement immediately after the traveling was completed. Therefore, it is considered that the influence of the axle temperature on the acceleration sensor installed on the running axle can be ignored. After recording the measurement start time, continuous measurement was performed without interruption. Immediately after the start of the experiment, the data on the bridge side and the route bus side were synchronized using the vibration data at the time of the step difference existing on the bridge.

  FIG. 6 is a view showing the Fourier center spectrum of the center of the girder, sprung, and unsprung acceleration. For each spectrum, continuous measurement data of about 4.5 hours was divided into 1000 pieces for 16.384 seconds, and after Fourier transform, noise was removed by averaging. As shown in FIG. 6A, the target bridge was found to have a dominant natural vibration of about 4.8 Hz. In addition, as shown in FIG. 6B, the route bus used has a dominant natural frequency in the vicinity of 1.8 Hz (symbol 7) on the spring and 10.0 Hz (symbol 6) below the rear wheel spring. It was. In general, the prevailing vibration frequency of large vehicles is 12 Hz to 15 Hz and the unsprung predominance frequency is 2.5 Hz to 3.5 Hz. Both were excellent at relatively high frequency.

図７（ａ）、（ｂ）に路線バスの後輪が桁中央を通過した時刻として“桁中央通過時”として示した。ちょうどその時刻において、波形８と９がおおよそ相似的な振動が現れることが確認できた。その他各２回の計測においても概ね同様な結果を得ることができた。また、図７（ａ）、（ｂ）で波形が異なっており、走行速度の違いが計測結果に影響していることが分かる。実際のモニタリングシステム運用では、走行速度への依存性を考慮した測定方法、および走行速度の違いに対応した計測結果を管理するデータ分類システムの構築が重要であるといえる。一方で走行速度が異なる場合においても、同じ比例マトリックスを用いて路線バス後輪のバネ下振動から橋梁の振動性状を抽出できることが確認できた。
次に、桁中央通過時間が約０．３秒と非常に短いため、２０Ｈｚ以下の低振動数成分に対してフーリエスペクトルによる卓越振動数の確認は困難であることから、桁中央および路線バスの後輪バネ下振動に含まれる振動数成分の分布について連続ウェーブレットを使って確認を行った（図示を省略）。その結果、路線バスの後輪が桁中央を通過する時刻において、３０ｋｍ／ｈ、４０ｋｍ／ｈの実験結果の両方で、桁中央、路線バス後輪バネ下振動のスカログラムは同様な形状を示した。
以上の実験結果から、加速度時刻歴波形においても、ウェーブレットによる卓越振動数の時間的分布に関しても、橋梁の鉛直振動加速度と通過する路線バス後輪のバネ下振動加速度との間に相似性を確認することができた。差分法近似がある程度担保できるような短い時間内においては、本発明で示した力学的仮定に基づき、橋梁の鉛直振動加速度と通過する路線バス後輪のバネ下振動加速度との間の相似的相関関係を用い、路線バスの後輪バネ下振動計測データから、橋梁の振動を推定し、構造モニタリングを行うことが十分可能であることを示すことができた。 FIG. 7A is a diagram showing an example of a time history waveform of response acceleration under the rear wheel springs of the center of a girder and a route bus when traveling at 30 km / h and 40 km / h. For all the experimental results, the similarity matrix equation (5) was used so that ΣA _b -P-1A _S P in the rear-wheel unsprung vibration A _S and the bridge vibration A _b was sufficiently small.

FIGS. 7A and 7B show the time when the rear wheel of the route bus passes through the center of the girder as “when the center of the girder passes”. At that time, it was confirmed that the waveforms 8 and 9 had roughly similar vibrations. In addition, almost the same results were obtained in each of the two measurements. Further, the waveforms are different between FIGS. 7A and 7B, and it can be seen that the difference in travel speed affects the measurement result. In actual monitoring system operation, it can be said that it is important to build a measurement method that takes into account the dependence on travel speed and a data classification system that manages the measurement results corresponding to the difference in travel speed. On the other hand, it was confirmed that the vibration characteristics of the bridge can be extracted from the unsprung vibration of the rear bus of the route bus even when the traveling speed is different.
Next, because the transit time at the center of the girder is as short as about 0.3 seconds, it is difficult to confirm the dominant frequency by Fourier spectrum for low frequency components below 20 Hz. The distribution of frequency components included in the rear-wheel unsprung vibration was confirmed using a continuous wavelet (not shown). As a result, at the time when the rear wheel of the route bus passes through the center of the girder, the scalograms of the center of the girder and the route bus rear wheel unsprung vibration showed the same shape in both the experimental results of 30 km / h and 40 km / h. .
Based on the above experimental results, both the acceleration time history waveform and the temporal distribution of the prevailing frequency due to the wavelet were confirmed to be similar between the vertical vibration acceleration of the bridge and the unsprung vibration acceleration of the route bus rear wheel passing through. We were able to. In a short period of time that the difference method approximation can be guaranteed to some extent, a similar correlation between the vertical vibration acceleration of the bridge and the unsprung vibration acceleration of the passing rear wheel bus is based on the dynamic assumptions presented in the present invention. Using the relationship, it was possible to estimate the vibration of the bridge from the rear wheel unsprung vibration measurement data of the route bus and to show that it is possible to perform structural monitoring sufficiently.

Next, an error including noise that occurs during measurement when the monitoring system is operated will be described. Specifically, an average is obtained for the measurement results of the rear wheel unsprung vibrations of the three buses measured in the experiments at a traveling speed of 30 km / h and 40 km / h, and the difference between the average value and each measurement result (error) is calculated. The size and its properties were confirmed. In the comparison, the measurement results when passing near the center of the girder were used. FIG. 8A and FIG. 8B show the unsprung acceleration response time history of the route bus rear wheel three times passing near the center of the beam when traveling at 30 km / h and 40 km / h. The measurement results are almost the same every time. When the average value 10 of the three acceleration response results and the difference 11 of each measurement data are calculated, the differential maximum acceleration is 0.2 m / sec ² (37% relative to the maximum acceleration 0.54 m / sec ² at 30 km / h). ), While the maximum acceleration during driving at 40 km / h was 0.69 m / sec ² , the differential maximum acceleration was 0.19 m / sec ² (28%). That is, although there is a certain degree of reproducibility of the experiment, it has been found that a measurement error of about 30% to 40% locally occurs with respect to the maximum acceleration in each measurement.

Next, the nature of the measurement error is analyzed. 9A and 9B show the variation of the differential acceleration during traveling at 30 km / h and 40 km / h in the probability distribution. The horizontal axis indicates the magnitude of the differential acceleration, and the vertical axis indicates the error occurrence probability. The differential acceleration generated during measurement, that is, the error 12 is approximately a normal distribution (reference numeral 13) with respect to the average value. Therefore, it is considered that the error during measurement is canceled out by averaging the measurement multiple times.
FIG. 10A is a diagram showing an outline of a running vibration simulation, FIG. 10B is a cross-sectional view of a target bridge main girder and a model diagram, and FIG. 10C is a diagram showing specifications of analysis data. . When examining the effects of structural deformation of bridges on unsprung vibrations of route buses, it is necessary to compare the vibrations during and after damage. However, since measurement after damage by an actual bridge is difficult, in the present invention, investigation was performed using a running vibration simulation by the substructure method. In the simulation study, we created an analysis model in a healthy state and an analysis model that hypothesized damage at the initial stage of deterioration, and considered changes in the unsprung response acceleration of the rear bus of the route bus on the analysis model due to the presence or absence of damage. .

桁上面には、式（６）に示すパワースペクトル密度関数で定義された路面凹凸をモンテカルロシミュレーションにより生成し再現させた。路面凹凸パラメータは図１１（ａ）に示すアスファルト舗装の平均値を用いた。生成した路面凹凸のパワースペクトル密度関数を図１１（ｂ）に示す。
路線バスのモデルは、事前に得たバネ上卓越振動数（１．８Ｈｚ）、バネ下卓越振動数（１０．０Ｈｚ付近）および、車検証に記載されたデータを基に、バネ上、バネ下卓越振動数が概ね合致する４自由度系バネマスモデルを作成した。なお、実験において、橋梁の鉛直振動と車軸中央のバネ下鉛直振動を比較したことから、本発明では簡易な２次元の車両モデルとした。路線バスの解析モデルを図１２に示す。 Next, an examination method by simulation will be described. The structural attenuation of the bridge was 2% Rayleigh attenuation in the primary-1 and primary-2 eigenmodes.

On the upper surface of the girder, road surface irregularities defined by the power spectral density function shown in Equation (6) were generated and reproduced by Monte Carlo simulation. As the road surface unevenness parameter, the average value of asphalt pavement shown in FIG. The power spectrum density function of the generated road surface unevenness is shown in FIG.
The route bus model is based on the pre-sprung prevailing frequency (1.8 Hz), unsprung prevailing frequency (around 10.0 Hz), and the data described in the vehicle verification. A four-degree-of-freedom spring mass model was created in which the dominant frequencies roughly matched. In the experiment, since the vertical vibration of the bridge was compared with the unsprung vertical vibration at the center of the axle, a simple two-dimensional vehicle model was used in the present invention. The route bus analysis model is shown in FIG.

  Prior to the running simulation, eigenvalue analysis was performed on the model of the target structure and route bus. In consideration of the bridge natural frequency measurement result (4.8 Hz) and the actual situation of the support, the bridge model has a primary-1 mode (4.8 Hz) in which a horizontal support spring of 200 kN / mm is installed in the direction of the bridge in the movable support. ) To the third order-2 mode (31.8 Hz) and the natural frequency and mode shape are shown in FIG. The effective mass ratio in the vertical direction in the primary-1 mode of the bridge was 77%. In addition, the first-order natural frequency when the starting point side boundary condition is set to Fix is 5.4 Hz, and in the case of complete Move, it is 3.5 Hz. At the same time, it can be said that it is important to model the boundary conditions including the bearing conditions in consideration of the actual situation regardless of the design conditions.

FIG. 14 is a diagram showing natural frequencies and mode shapes from the first order (1.8 Hz) to the fourth order (11.8 Hz) of the route bus model. The sprung vertical mode of the route bus and the unsprung mode of the front and rear wheels generally coincided with the experimental results (1.8 Hz above the spring and around 10 Hz below the spring). Next, referring to existing damage cases, for the virtual damage of the RC bridge from the late acceleration period to the early deterioration period, one main girder directly under the one-side lane through which the route bus passes is targeted. In addition, it was assumed that peeling occurred over the entire flange area under the main girder. The virtual damage portion 20 is shown in FIG. Furthermore, according to the effective mass ratio in the vertical direction obtained from eigenvalue analysis, the effective mass ratio of the primary-1 vibration mode was dominant at 77%. By applying the concept of plastic hinge region (1D = beam cross-section height) used in design and the like, the rigidity of the plastic hinge region was reduced by 1/100 as damage due to bending cracks or the like. The natural frequency of the primary-1 mode of the bridge in the virtual damage was 4.5 Hz. The traveling speed was set to 30 km / h and 40 km / h according to the experiment.
Under the above conditions, the unsprung vertical vibration acceleration of the rear wheel of the route bus when the route bus passed through the bridge was compared between the healthy model and the damaged model. The implemented simulation pattern is shown in FIG.

Next, simulation results and discussion will be described. First, for the strain at the center of the girder when the route bus traveled at 30 km / h, the validity of the analysis model was confirmed by comparing the results of actual measurement and simulation. A long gauge optical fiber sensor was used for the actual measurement of strain. The comparison result is shown in FIG. The simulation result 23 showed a slightly larger strain than the actual measurement 24. However, from the timing of maximum strain generation and the trend of strain increase / decrease, it was judged that there was no effect when examining the comparison of damage.
FIG. 17A and FIG. 17B are diagrams showing the unsprung vibration acceleration time history results of the rear bus of the route bus according to the difference in the presence or absence of bridge damage using a traveling simulation. FIG. 17C shows the maximum acceleration and the maximum differential acceleration with respect to the difference in presence or absence of damage. At a traveling speed of 30 km / h, it was confirmed that the maximum acceleration was about 14% and the maximum differential acceleration was about 13% depending on the presence or absence of damage. At 40 km / h, the maximum acceleration was about 1%, and the maximum differential acceleration was about 6%. If these differences can be detected in the actual measurement, the structural deformation of the bridge can be extracted.
Moreover, in this experiment, the error (30% to 40%) at the time of measurement was compared with the change (6% to 13%) in the unsprung vibration differential acceleration of the route bus due to the difference in the presence of damage obtained from the simulation result. It is necessary to consider the point that is larger. However, while changes in measured acceleration due to damage appear in the form of monotonous changes, the measurement error under certain conditions follows a normal distribution based on consideration of experimental results. When monitoring multiple times by bus all the time, if the trend of monotonic increase in acceleration response extracted from the acceleration measurement result under the bus rear wheel spring is grasped, it is possible to detect changes due to damage / degradation of the bridge Is enough.

As described above, in the present invention, as a means for solving various problems related to SHM, a proposal for a new monitoring method using a route bus which is a public transport and a technical problem were examined. The main conclusions obtained from the hypotheses, verification experiments, simulations, and the results and discussion are shown below.
1) From the results of simultaneous acceleration vibration measurement of the bridge and unsprung, using the similarity matrix under certain conditions, it is possible to estimate the vibration of the bridge that vibrates directly under the unsprung vibration of the route bus in a similar manner. I was able to show.
2) As a result of running simulation, it was confirmed that a certain change was observed in the vibration component under the spring of the route bus depending on the presence or absence of damage to the girder. It was also confirmed that measurement error elimination processing was necessary by conducting long-term and multiple measurements.
3) When damage as expected in the present invention occurs in a short span bridge, it is possible to detect the deformation from the unsprung vibration of the route bus, and from “late acceleration period to early deterioration period”. A monitoring system that extracts signs with relatively large changes in progress can be realized.

FIG. 18 (a) is a block diagram showing a configuration of a damage determination apparatus constituting the structural body deformation detection system of the present invention. In FIG. 18B, vibration data is collected by the axle vibration sensor when the route bus (vehicle) constituting the structure deformation detection system of the present invention passes through the bridge (structure) to be inspected. It is a figure which shows a mode typically. FIG. 18C is a diagram schematically showing a route bus passing through a plurality of bridges to be inspected.
The structure deformation detection system 100 includes a route bus (vehicle) 2 including at least a wheel 42 supported by an axle 40 and a spring (buffer member) that cushions vibration transmitted to the axle 41, and the axle 40. An axle vibration sensor 5 that detects vibration, a memory (storage means) 30 that stores vibration data detected by the axle vibration sensor 5 when the route bus 2 passes through a bridge (structure) 43 to be inspected, and vibration And a damage determination device 34 that determines the damage state of the route bus 2 by analyzing the data. The damage determination device 34 includes a sensor data memory 35 that stores vibration data stored in the memory 30, a normal data memory 36 that stores normal vibration data when the bridge 43 is normal, and a sensor data memory 35. Data comparison means 37 for comparing the stored vibration data with normal vibration data stored in the normal data memory 36, and whether or not the bridge 43 has been damaged based on the data compared by the data comparison means 37. Damage judging means 38 for judging, and the damage judging means 38 judges that damage has occurred in the bridge 43 when the difference between the data compared by the data comparing means 37 is not less than a predetermined value.

  The present invention includes a route bus 2, an axle vibration sensor 5 attached to the axle 40 of the route bus 2, and a memory 30 that stores vibration data obtained from the axle vibration sensor 5. Then, vibration data generated when the route bus 2 passes through the bridge 43 to be inspected is stored in the memory 30. The stored vibration data is input to the damage determination device 34 installed in the bus center 50, and is compared with normal vibration data at the normal time relating to the bridge 43 to be inspected that has been acquired in advance. The data comparison unit 37 calculates the difference between the normal vibration data and the vibration data, and determines that the bridge 43 has been damaged when the value exceeds a predetermined value. The predetermined value can be calculated in advance by simulation or the like. In addition, as the vibration data is acquired with more data, the accuracy of the data increases. Therefore, it is conceivable to use a route bus that travels the same route every day as a vehicle. Thereby, the damage state of the bridge 43 can be determined accurately and with a low-cost configuration based on a large amount of vibration data.

  18B, the route bus 2 includes a receiver 41 that receives a recognition signal transmitted from the bridge 43, and a transmitter 39 that transmits a recognition signal indicating a recognition number that identifies the bridge 43. When the recognition signal is received by the receiver 41, the route bus 2 stores the recognition number and the vibration data detected by the axle vibration sensor 5 in association with each other in the memory 30. For example, as shown in FIG. 18C, when the bridges A and C on the route through which the route bus 2 passes are to be inspected, the driver of the route bus 2 every time the bridge A and C passes through. It is necessary to operate the memory 30. However, it is not preferable for safety to perform such an operation while driving. Moreover, it is necessary to make correspondence so that it is possible to determine which bridge the vibration data stored in the memory 30 is. Therefore, in this embodiment, the route bus 2 is provided with a receiver 41, the bridges A and C are provided with a transmitter 39 that transmits a recognition signal, and the bridges A and C are recognized when passing through the bridges A and C. The signal and the vibration data from the axle vibration sensor 5 are stored in association with each other. As a result, it is possible to immediately recognize from which bridge the vibration data is the data, and since the storage operation is automatically performed, the safety of driving can be improved. In FIG. 18 (c), the bridge B is not an inspection object and therefore does not include the transmitter 39.

  FIG. 19 is a flowchart for explaining the operation of checking the similarity according to the present invention. First, the axle vibration sensor 5 is installed on the axle 40 of the route bus 2 and the bridge vibration sensor 45 is installed at the center P of the bridge 43 (S10). The route bus 2 is passed through the bridge 43 to be inspected (S11). At this time, data when passing at different speeds is acquired. The data of the axle vibration sensor 5 and the bridge vibration sensor 45 when the route bus 2 passes through the bridge 43 is stored in the memory 30 (S12). In order to improve the reliability of data, this operation is repeated a predetermined number of times (S13). When the data acquisition is completed, the data stored in the memory 30 is temporarily stored in a memory such as a PC, and the data of the axle vibration sensor 5 and the bridge vibration sensor 45 are synchronized and compared (S14). Then, the synchronized vibration data is displayed on the display device, and it is visually determined whether or not the waveforms are similar (S15). The determination of whether or not they are similar may be a method of comparing waveform levels for each time axis in addition to visual observation. If it is not similar in step S15 (NO in S15), the position of the axle vibration sensor 5 is changed (S18) and the process is repeated from step S11. If similar in step S15 (YES in S15), the axle vibration sensor 5 is fixed at the current position (S16). Then, the bridge vibration sensor 45 is removed from the bridge 43 (S17).

  In order to determine the damage state of the bridge 43 that has passed, based on the vibration data of the axle vibration sensor 5 provided in the route bus 2, the axle vibration data and the vibration data of the bridge 43 are similar (equivalent) in advance. It is necessary to confirm. Therefore, in this embodiment, prior to the measurement, the structure vibration sensor 45 is attached to the center of the bridge 43 of the bridge 43 to be inspected, and the route bus 2 to which the axle vibration sensor 5 is attached is passed through the bridge 43 in that state. The vibration data of the axle vibration sensor 5 and the structure vibration sensor 45 is acquired. Then, it is determined whether or not the results obtained by synchronizing and comparing the acquired vibration data are similar, and if they are similar, the arrangement position of the axle vibration sensor 5 is fixed and the structure attached to the bridge 43 The vibration sensor 45 is removed. Here, when it is not similar, the position of the axle vibration sensor 5 is changed to find a similar place. Thereby, the presence or absence of damage related to the bridge 43 to be inspected can be determined only by analyzing the vibration data acquired from the axle vibration sensor 5 attached to the route bus 2.

  FIG. 20 is a flowchart for explaining the operation of the structural deformation detection system according to the embodiment of the present invention. In this flowchart, the route bus side and the bus center side will be described separately. As described with reference to FIG. 18A, the route bus 2 includes the memory 30 and the axle vibration sensor 5, and the bus center 50 includes the damage determination device 34. On the bus center side, it is confirmed in advance by an existing system that the bridge 43 to be inspected is not damaged (S24), and the route bus 2 is passed through the bridge 43 (S25). Thereby, the bridge 43 vibrates and the axle vibration sensor 5 detects the vibration, and the vibration data is stored in the memory 30. This vibration data is stored as normal vibration data in the normal data memory 36 of the damage determination device 34 (S26).

On the other hand, on the route bus side, when the route bus 2 passes the bridge 43 to be inspected (S20), the bridge 43 vibrates and the axle vibration sensor 5 detects the vibration and stores the vibration data in the memory 30 ( S21). The route bus 2 repeats this operation until the operation ends (S22). When the operation of the day ends (YES in S22), the route bus 2 moves to the bus center 50 in order to analyze the vibration data stored in the memory 30 (S23). On the bus center side, the axle vibration data of the route bus 2 is stored in the sensor data memory 35 via the cable 31 (S27). Then, the data comparing means 37 compares the axle vibration data stored in the sensor data memory 35 with the normal vibration data stored in the normal data memory 36 (S28). The data comparison means 37 calculates the difference between the axle vibration data and the normal vibration data and inputs it to the damage determination means 38. The damage determination means 38 determines whether or not the difference value is greater than or equal to a predetermined value (S29). If the difference value is equal to or greater than the predetermined value (YES in S29), there is a possibility that the bridge 43 to be inspected may be damaged. (S31). On the other hand, if the difference value is not greater than or equal to the predetermined value in step S29 (NO in S29), the fact that the bridge 43 is normal is displayed (S32).
As shown in FIG. 1, the relationship between the cumulative damage probability and the secular change can be classified into a latent period, a progress period, an acceleration period, and a deterioration period. In particular, a decrease in safety due to structural damage is expected from the late acceleration period to the early deterioration period (region 1). Therefore, in the present embodiment, the value of the vibration data at that time is determined by simulation by assuming the damage when the cumulative damage probability progresses to the early stage of the deterioration period. Then, an upper limit value of the difference of the vibration data compared is determined based on the determined value, and when the value is exceeded, it is considered that some damage has occurred in the bridge 43. Thereby, the presence or absence of damage to the bridge 43 can be quantitatively grasped and determined.

In the case of a route bus, the bus center 50 is returned once the daily service is completed. The vibration data stored in the memory 30 is stored in the sensor data memory 35 of the damage determination device 34 installed in the bus center 50. However, it is troublesome to perform this operation every day. Further, the route bus 2 must be provided with a memory 30. Therefore, in this embodiment, the route bus 2 is provided with communication means (a transmitter for transmitting data), and the vibration data detected by the axle vibration sensor 5 when the route bus passes the bridge 43 and the recognition signal of the bridge 43 are communicated. The data is transmitted via the bus center 50 antenna 42 by the means, and the data received by the communication means 33 is stored in the sensor data memory 35 in the bus center 50. As a result, the operation of storing the vibration data in the damage determination device 34 of the bus center 50 can be omitted, and the forgetting operation or the operation mistake can be prevented.
Further, if the memory 30 is operated continuously, there is no need to worry about when to start the storage operation. However, the storage capacity of the memory 30 is enormous and wasteful data must be stored, and only necessary data must be extracted from the stored data. Therefore, in the present embodiment, the route bus 2 is provided with a storage start button for operating the memory 30. Thereby, only necessary data can be stored with an inexpensive configuration, and the storage capacity of the memory 30 can be minimized.

  2 route bus, 5 axle vibration sensor, 30 memory, 31 cable, 32 antenna, 33 communication means, 34 damage judgment device, 35 sensor data memory, 36 normal data memory, 37 data comparison means, 38 damage judgment means, 39 transmitter , 40 Axle, 41 Receiver, 42 Wheel, 43 Bridge, 44 River, 45 Structure vibration sensor, 100 Structure deformation detection system

Claims (6)

A vehicle including at least a wheel supported by an axle and a buffer member that cushions vibrations transmitted to the axle, an axle vibration sensor that detects vibration of the axle, and a structure to be inspected. Storage means for storing vibration data detected by the axle vibration sensor when performing, and a damage determination device for determining a damage state of the structure by analyzing the vibration data,
The damage determination device includes: data comparison means for comparing vibration data stored in the storage means with normal vibration data when the structure is normal; and based on the data compared by the data comparison means. A damage determination means for determining whether or not damage has occurred in the structure,
The structure change detection system, wherein the damage determination means determines that damage has occurred in the structure when the difference between the data compared by the data comparison means is a predetermined value or more. Similar results are obtained by synchronizing and comparing the structure vibration sensor that detects the vibration generated in the structure when the vehicle passes, and the vibration data detected from the axle vibration sensor and the structure vibration sensor. Similarity determination means for determining whether or not
2. The vibration data obtained from the axle vibration sensor is regarded as vibration data generated from the structure when each of the vibration data is determined to be similar by the similarity determination means. Structure deformation detection system described in 1.   The predetermined value of the difference of the data compared by the data comparison means is a value of vibration data when the cumulative damage probability related to the structure progresses to the early stage of deterioration. The structure deformation detection system described.   The structure includes a transmitter that transmits a recognition signal indicating a recognition number that identifies the structure, and the vehicle includes a receiver that receives a recognition signal transmitted from the transmitter. 4. When the signal is received by the receiver, the identification number and vibration data detected by the axle vibration sensor are associated with each other and stored in the storage unit. Structure deformation detection system.   The communication means is provided in the vehicle, and vibration data detected by the axle vibration sensor when the vehicle passes through the structure and a recognition signal of the structure are transmitted by the communication means. The structural body deformation | transformation detection system as described in any one of thru | or 4.   The structure deformation detection system according to any one of claims 1 to 3, further comprising a storage start button for operating the storage unit in the vehicle.

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