EP3186446A1

EP3186446A1 - Monitoring the structural integrity of dam structures

Info

Publication number: EP3186446A1
Application number: EP15757242.1A
Authority: EP
Inventors: Markus Aufleger
Original assignee: Individual
Current assignee: Individual
Priority date: 2014-08-28
Filing date: 2015-08-28
Publication date: 2017-07-05
Also published as: WO2016030527A1; DE102014112383A1

Abstract

The invention relates to a method for recognizing structural changes in a crest (101) of a dam structure (100), wherein a test signal is transmitted via a test signal line (150) in the form of a cable that is located in the area of the crest (101) of the dam structure (100), and a structural change in the crest (101) of the dam structure (100) is recognized on the basis of an analysis of the transmitted test signal, said analysis of the transmitted test signal including a distributed strain measurement.

Description

Monitoring the structural integrity of shut-off structures

The present invention relates to a method and a device for detecting structural changes in the crown of a shut-off structure, in particular a dam or a dam.

State of the art

A shut-off structure, as part of a dam, is a man-made structure, mostly constructed in the course of streams, to create a reservoir and generate electricity in power plants. Conventional shut-off structures are dam, dam, barrage or weir.

In particular, the shut-off structures at dams are designed either as dams or as dams. Very often they have considerable reserves with regard to their load-securing capacity, but also considerable risk potentials due to the usually very large energy contents stored in the water volumes of the storage compartments. Failure of these systems can not be excluded in principle. Breakage of barrier dams (dams and dams) is particularly possible due to failure of the structures (eg overflow, internal erosion) or acts of violence, ie essentially by human action, such as accidental or wanton destruction. The structural integrity of shut-off structures can be monitored, for example, by regular inspections and surveys. Likewise, as a simplification, monitoring by video cameras and the like can be performed. take place, but still the video image must be monitored. Since a breakage of the barrier structure can occur for a short time after visible damage has occurred, the intervals of visual monitoring must be kept relatively small. Overall, the above types of monitoring are therefore very complex and expensive, and moreover error-prone if they are not carried out conscientiously. DE 195 06 180 C1 and DE 196 21 797 AI treat a method for monitoring dams using distributed temperature measurements. The objective here is the detection of increased leakage in the dyke area. Structural changes of the dike crown can not be recognized. DE 10 2006 023 588 B3 describes a geotextile for Deichertüchtigung, which is equipped with sensor fibers for simultaneous dyke monitoring. The geotextiles are used to improve dike slopes, which are therefore only monitored. Structural changes of the dike crown can not be recognized.

JP 2001-082934 A and JP 2001-108493 A describe measuring systems which have individual, defined measuring points. Spatially coherent, continuous monitoring of shut-off structures is not possible. Also, structural changes of the dike crown can not be detected.

It is desirable to have a simple and inexpensive yet reliable and as automatic as possible possibility to monitor the structural integrity of the crown of Absperrbauwerken in order to respond in case of damage in particular early.

Disclosure of the invention According to the invention, a method and a device for detecting structural changes of the crown of a shut-off structure, in particular a dam or a dam, with the features of the independent claims are proposed. Advantageous embodiments are the subject of the dependent claims and the following description.

Based on a comprehensive study of the various failure modes of dams and dams and the calculation of the catastrophic tidal waves resulting from a breakage of these facilities, it has become clear that there is currently no reliable dam warning system and that a particularly advantageous arrangement consists of a measuring signal line installed in the area of the crown for the distributed measurement of strains or deformations. The advantages here are the local and temporal continuous measurement and a very robust mode of operation.

The invention provides a simple and inexpensive yet reliable way to continuously monitor the structural integrity of the crown of Absperrbauwerken locally and temporally, in order to respond in case of damage in particular early. Thus, for example, the damage development may possibly be stopped in time or at least limited in scope and effects and / or an emergency program, in particular evacuation measures, be started as soon as possible. The invention achieves this by monitoring the crown of the shut-off building by means of evaluation or analysis of a measuring signal, which is transmitted via at least one running in the crown of the Absperrbauwerks measuring signal line in the form of a cable. Cable is understood to mean a single or multi-core composite of conductors (cores or fibers) sheathed (eg with insulating and / or protective material). The analysis of the transmitted measurement signal involves a distributed strain measurement, in particular by means of Brillouin Optical Time Domain Reflectometry

(BOTDR) and / or Brillouin Optical Time Domain Analysis (BOTDA), so that information about the integrity and the deformation state of the measurement signal line and its immediate surroundings are obtained from the analysis of the transmitted measurement signal. The transmission and / or evaluation takes place continuously or regularly in preferably short time intervals, so that a continuous or substantially continuous monitoring of the structural integrity can take place. If the measuring signal indicates a structural change in the crown of the shut-off building, this can immediately lead to the triggering of at least one emergency function. The emergency function to be activated is preferably selected from the group of alarming of one or more private or public authorities (operator, security, civil protection, police, fire brigade, rescue, relief organizations, etc.) or an operating function of the plant containing the barrier structure (for example dam), e.g. the opening of drains (e.g., bottom outlet, spillway), stopping power generation, etc.

It has been shown that almost all known causes of failure (inter alia in case of overflows as well as foundation failure / internal erosion, but also in wanton damage) result in considerable deformations or structural changes in the area of the crown of the shut-off structure at a comparatively early stage of damage development.

In the area of the crown, the measurement signal line is routed on the crown or to a certain depth below the crown, so that structural changes of the crown (ie the top of the shut-off structure) can still be detected. Preferably, the depth is at most dimensioned such that the measuring signal line runs above the accumulation target. The stowage target is the water level that is normally allowed for its normal use condition. Further preferably, the depth is at most 2 m, 1.5 m, 1 m, 0.5 m, 0.4 m, 0.3 m, 0.25 m, 0.2 m, 0.1 m or 0.05 m or is between two of these values.

The consequences of the failure of shut-off structures depend to a great extent on the time of detection of the failure. The invention focuses on the timely recognition of significant structural changes in the area of the shut-off building crown. In addition to a measurement signal line, only one measurement signal generation unit and one measurement signal evaluation unit are necessary for this purpose. The measurement signal generation unit and the measurement signal evaluation unit are expediently integrated in a common device. Expediently, the measurement signal generation unit and / or the one measurement signal evaluation unit are arranged at a distance from the shut-off structure, for example at an adjacent slope. This reduces the risk of damaging the unit (s), which could potentially lead to a malfunction.

Preferably, the monitoring of the crown of Absperrbauwerks is linked to the measurement of the water level in the storage space (and thus with the risk potential). As a result, an automatic evaluation of the hazardous situation can take place, wherein, depending on this, it is then preferably decided automatically about the type of emergency function to be triggered.

According to a preferred embodiment, the measurement signal line runs between the measurement signal generation unit and the measurement signal evaluation unit, wherein the measurement signal generation unit is arranged at one end of the measurement signal line and the measurement signal evaluation unit at the other end of the measurement signal line. This leads to a simple construction of the device.

Advantageously, the measurement signal line along the longitudinal direction of Absperrbauwerks, i. transversely to the direction of flow of the jammed water, laid.

This allows a large area of Absperrbauwerks monitor in a simple manner. The course of the measurement signal line can be substantially horizontal just be. It can also be curved or angular horizontally and / or also have vertical components. In any case, in horizontal projection along the longitudinal direction of the shut-off structure, it has a length which is expediently a significant proportion (preferably at least 50%, 60%, 70%, 75%, 80%, 90% or 95% or exactly 100%) of the length of the Crown along the longitudinal direction of Absperrbauwerks corresponds, since essentially only this proportion is also monitored.

Advantageously, the measuring signal line is simply laid along the longitudinal direction of the shut-off building. This is a simple embodiment with minimal cable length.

According to a further preferred embodiment, the measuring signal line is reciprocated along the longitudinal direction of the shut-off building, i. relocated one or more times. Although this increases the necessary line length, it also increases the monitored volume and the detection sensitivity. For example, the measuring signal line on the water side of the crown of the shut-off building can be laid in one direction and on the air side of the crown of the shut-off building in the other direction. Alternatively or additionally, the measuring signal line may be laid in a first depth of the crown of the shut-off structure in one direction and in a second, differing from the first depth of the crown of Absperrbauwerks in the other direction. As an alternative or in addition, the measuring signal line can be laid in a meandering manner in the plane and / or in the depth in a multiply reversing manner.

Preferably, the measurement signal line along the longitudinal direction of the Absperrbauwerks an odd number often reversed back and forth laid. Thus, both ends of the measuring signal line are located on the same side of the shut-off building, which reduces the effort for signal feed-in and signal evaluation. The measurement signal evaluation unit is set up to detect a structural change in the shut-off structure by evaluating the measurement signal. In the simplest case, this can be the absence of the measuring signal if the measuring signal line is damaged. Depending on the specific type of measurement signal line and the measurement signal generation, however, different variants are preferred here.

In particular, current (e.g., control of the voltage of a large electrical loop, strain gauges) and / or light (control of fiber optic cable continuity or control of strain and temperature through distributed fiber optic strain and temperature measurements) may be used as the measurement signals.

According to a preferred embodiment, a DC or AC signal is transmitted via a designed as a one, two or multi-core cable measurement signal line. Damage to the crown, which leads to damage to the cable, is detected as a change in the transmitted measurement signal.

According to a preferred embodiment, an alternating current signal is transmitted via a measuring signal line designed as a coaxial cable or as a (in particular shielded) cable with twisted pairs (twisted pair). Damage to the crown, which leads to damage to the cable, is detected as a change in the transmitted measurement signal. According to another preferred embodiment, a light signal is transmitted via a measuring signal line designed as a glass fiber. Damage to the crown, which leads to damage to the cable, is detected as a change in the transmitted measurement signal. The monitoring takes place, for example, by the constantly repeating or continuous control of the light transmission of the line with a suitable technology, in particular by means of laser technology, and / or by the constantly repeating or continuous Execution and automatic evaluation of distributed strain and temperature measurements with the help of a suitable laser technology.

Distributed fiber optic measurements allow the determination of temperature and strain changes along a fiber. This type of fiber optic measurement is based on the Brillouin scattering of laser light and can advantageously be performed with a standard single-mode optical fiber. Because the Brillouin frequency depends on the elongation of the fiber, it is possible to correlate frequency shift and strain. However, since the strain distribution is indistinguishable from a change in temperature distribution, simultaneous measurement of the Brillouin frequency shift and the spontaneous Brillouin power is useful to avoid cross-sensitivity. This makes it possible to separate a strain change from a temperature change. This technique allows the measurement of temperature and strain in a fully distributed manner over the entire length of a standard singlemode optical fiber, for example, up to 30 km. In strain measurement, the local resolution is about 1.0 m, i. that a measured value can be determined approximately every meter along a glass fiber. Depending on the equipment of a structure or terrain, detailed, multi-axial strain patterns and local anomalies can be identified and localized with high accuracy. Basically, a device based on Brillouin Optical Time Domain Reflectometry (BOTDR) or Brillouin Optical Time Domain Analysis (BOTDA) is needed for distributed fiber optic strain measurement.

BOTDR devices are preferred because, unlike BOTDA devices, they do not require two-sided access to the fiber. Measurements are made by sending laser pulses from the device into a connected fiber and measuring the frequency shift of the backscattered light. The transit times between the emitted laser pulse and the received, backscattered light determine the location of the corresponding frequency shift in the fiber (local resolution). The distributed fiber optic strain measurement offers the considerable advantage over other methods that deformations can be quantified. As a result, a significantly higher informative value and reliability with respect to the failure mechanisms to be detected is made possible. This makes it possible to report structural changes only if they go beyond the usual thermally induced deformations. Depending on the severity of the change, it is then preferable to automatically decide on the type of point to be notified (only operators, operators and civil protection, etc.).

Although the invention will be described essentially with reference to shut-off structures, it is also useful for monitoring other elongated structures, such as e.g. Bridge girders, roads, tracks, pipelines or similar can be used advantageously.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

The invention is illustrated schematically with reference to an embodiment in the drawing and will be described in detail below with reference to the drawing. figure description

Figure 1 shows a controlled according to a preferred embodiment of the invention dam in a cross-sectional view.

FIG. 2 shows the dam from FIG. 1 in a frontal view from the water side. Detailed description of the drawing

A preferred embodiment of the invention will be described below with reference to Figures 1 and 2, wherein like elements are provided with the same reference numerals. FIG. 1 shows a shut-off structure designed here as a dam wall 100 for damming a body of water 200 with a water level H in a cross-sectional view and FIG. 2 in a frontal view from the water side.

The dam 100 is bounded on its upper side by a crown ("crown") 101 and limits in turn a storage space (in the figure on the left). In the example shown, a measuring signal line formed here as an optical waveguide or fiber optic cable 150 is laid at a distance A from the water side or bin side crown edge at a distance A, which extends substantially along a longitudinal direction L of the dam wall 100 extends horizontally over a length which, as is clear in Figure 2, substantially (here at least 95%) corresponds to the length of the dam 100 in the direction L. The optical fiber cable 150 is connected to a signal generation and evaluation device 160, which is formed in the illustrated embodiment as a BOTDR device. From this BOTDR device 150 laser pulses are sent into the fiber optic cable, whereby the frequency shift of the backscattered light is measured. The transit time between the emitted laser pulse and the received, backscattered light determines the location of the corresponding frequency shift in the fiber optic cable 150. The measure of the frequency shift is a measure of the elongation of the glass fiber at this point, which in turn is correlated with the elongation of the glass fiber surrounding dam wall material, in particular concrete. Preferably, the fiber optic cable 150 is already laid in the production of the dam 100, in particular poured into the concrete. However, it can also be retrofitted, for example, by providing the dam with a recess, inserting the fiber optic cable 150 into the expanse and expediently potting it there in order to produce a strain-transmitting operative connection between the glass fiber cable and the dam wall. Alternatively, the fiber optic cable in the recess or on the crown at several points fixed to the dam, so that in this way the strain between the points connected to the dam wall can be determined. Although this reduces the spatial resolution of the measurement, however, the mounting effort is reduced.

If the dam consists of several separately manufactured blocks, there are usually more or less large expansion joints between these blocks. Appropriately, the measurement signal line is arranged in the region of these joints so that a conventional thermally induced strain does not affect the measurement signal so that a structural change is assumed, but that the measurement signal line is attached and dimensioned at the joints between the individual dam blocks so that only at Significant measurement signals occur beyond the usual thermally induced deformations.

If, in the area of the crown 101 of the dam 100, a structural change occurs, the fiber optic cable 150 is stretched or possibly interrupted at one or more points. Both alternatives are recognizable in the measurement signal, whereby in addition the extent of the frequency shift can be used to deduce the degree of elongation and thus the extent of the structural change. If, by evaluating the measurement signal in the BOTDR device 160, it is determined that a predetermined expansion threshold is exceeded, it will become automatic from the BOTDR device 160 (which is expediently arranged in a building) triggered a corresponding emergency function, in particular a warning signal or alarm signal transmitted to a competent authority. The selection of the receivers of the alarm signal preferably takes place as a function of the extent of the structural change. With a small structural change, only the operator can be informed, whereas in a larger structural change expediently also public authorities such. As police, fire or civil protection, alarmed. Conveniently, the selection of the point to be alarmed is also made dependent on the water level H, so that at a low water level also only the operator and at a large water level also public places are alerted. The alerting can be via wired or wireless transmission methods, such. As phone, wireless, mobile, satellite connection, etc. generate.

In addition to alerting, the emergency function to be triggered may also be an operational function of the plant containing the shut-off structure (e.g., dam), e.g. the opening of drains. In summary, an embodiment of the invention relates to a method for detecting severe structural changes to dams or dams, wherein in the crown area of these structures at a suitable location typically above the storage target connected to an automatic measuring unit measurement signal line in a suitable manner over the entire length or a significant partial length of the Built structure is integrated so that in a serious structural change of the building a clear measurement signal is registered and thereby the structural change is detected.

Claims

claims

A method for detecting structural changes of a crown (101) of a shut-off structure (100), wherein a measurement signal is transmitted through a in the region of the crown (101) of the Absperrbauwerks (100) arranged measuring signal line (150) in the form of a cable and wherein a structural change of the crown (101) of the Absperrbauwerks (100) is detected by analysis of the transmitted measurement signal, wherein the analysis of the transmitted measurement signal comprises a distributed strain measurement.

2. The method of claim 1, wherein at least one emergency function is triggered when a structural change of the crown (101) of the Absperrbauwerks (100) is detected.

3. The method of claim 2, wherein the at least one emergency function is selected from the group comprising alerting one or more locations or an operational function of the plant containing the shut-off structure.

4. The method of claim 2 or 3, wherein additionally a water level (H) in one of the Absperrbauwerk (100) limited storage space is measured and the at least one emergency function depending on the water level (H) is selected.

5. The method according to any one of the preceding claims, wherein the Meßsignal- line (150) on the crown (101) or at a depth (D) below the crown (101) is arranged, wherein the depth is at most dimensioned so that the measuring signal line runs above the storage destination.

6. The method according to any one of the preceding claims, wherein the measuring signal line (150) at most 2 m, 1.5 m, 1 m, 0.5 m, 0.4 m, 0.3 m, 0.25 m, 0.2 m, 0.1 m or 0.05 m or between two of these values below the crown (101).

7. The method according to any one of the preceding claims, wherein the measuring signal line (150) extends substantially along a longitudinal direction (L) of the Absperrbauwerks (101).

8. The method according to claim 1, wherein the measurement signal line (150) in horizontal projection along a longitudinal direction (L) of the shut-off structure has a length which is at least 50%, 60%, 70%, 75%, 80%, 90% or 95% or exactly 100% of the length of the crown (101) along the longitudinal direction (L) of Absperrbauwerks (100) corresponds.

9. The method according to any one of the preceding claims, wherein a structural change of the crown (101) of the Absperrbauwerks (100) is detected by a lack of the transmitted measurement signal or by a scattering of the transmitted measurement signal.

10. The method according to any one of the preceding claims, wherein a current signal or light signal is transmitted as a measurement signal.

11. The method according to any one of the preceding claims, wherein the analysis of the transmitted measurement signal additionally comprises a distributed temperature measurement.

12. The method according to any one of the preceding claims, wherein the analysis of the transmitted measurement signal comprises a Brillouin Optical Time Domain Reflectometry (BOTDR) and / or a Brillouin Optical Time Domain Analysis (BOTDA).

13. A device for detecting structural changes in a crown (101) of a shut-off building, comprising a measuring signal line (150) arranged in the region of the crown (101) of the shut-off building (100) and a measuring signal generating unit and a measuring signal evaluation unit Method according to one of the preceding claims.

14. The device as claimed in claim 13, wherein the measurement signal generation unit and a measurement signal evaluation unit are parts of a device (160) which has a Brillouin Optical Time Domain Reflectometry (BOTDR) and / or a Brillouin Optical Time Domain Analysis (BOTDA ).

15. The method or device according to any one of the preceding claims, wherein instead of the crown of a Absperrbauwerks a bridge girder, a road, a track or a pipeline is monitored.