The invention relates to a method and a device for detecting a pulse-type mechanical effect on a system part.
There is a need in a multiplicity of applications to continuously monitor the proper operation of a system part, for example a pipeline or a container in chemical process engineering or a fluid-flow machine, in order to detect disturbances in good time and to avoid serious consequential damage. A multiplicity of methods for such monitoring are known in the prior art.
European Patent EP 0 765 466 B1, corresponding to U.S. Pat. No. 5,479,826, proposes, for example, to undertake the monitoring of the vibrations of turbine blades with the aid of microwaves that are directed onto the turbine blades. Conclusions may be drawn on the turbine's state of vibration from the modulation of the microwaves reflected at the turbine blades.
In a method known from German Patent DE 198 57 552 A1, corresponding to U.S. Pat. No. 6,494,046, a rupture of a shaft of a turbine is detected by measuring rotational frequencies at ends of the shaft.
It is proposed in German Patent DE 198 43 615 C2 to undertake a diagnosis of a state of a combustion drive with the aid of an analysis of a frequency spectrum of measurement signals that are picked up with the aid of a sound pickup disposed in an air inlet region or exhaust gas region.
In German Patent DE 197 27 114 C2, corresponding to U.S. Pat. No. 6,208,944, a machine is monitored by detecting signals of structure-borne sound striking it, instead of air noise. In that known method, as well, there is an analysis of the respectively determined frequency spectra of the measurement signals detected by the structure-borne sound pickup.
In the case of a method disclosed in German Patent DE 195 45 008 C2, as well, the frequency spectrum of the measurement signal detected by a monitoring sensor, for example an acceleration pickup, is analyzed during the operation of the machine and compared with a reference frequency spectrum.
In order to be able to ascertain an intrusion of foreign parts into a gas turbine, in U.S. Pat. No. 4,888,948 a sensor is disposed at the inlet of the turbine, with the aid of which an electric charge induced by the foreign bodies is detected.
In a method disclosed in East German Patent Application DD 224 934 A1 for determining a change in state of a machine having rotating parts, measured values of a signal describing the operating state are detected continuously and compared with adaptive threshold values. Quantile values of the probability distribution of the measured values are determined recursively and adaptively in order to determine those threshold values. Parameters for the state of the machine are determined from the number and level of the instances of overshooting of the threshold values.
A particular problem is represented by loose parts that are entrained by a flow and strike a system part and which cause only a pulse-type, short term effect that is correspondingly problematic to demonstrate reliably.
Problems of that kind can occur, for example, in the case of gas turbines having combustion chambers which are lined with ceramic tiles for protection against overheating. Those ceramic tiles are subjected to high dynamic loads by alternating pressure fluctuations occurring in the combustion chamber. It can happen in that case that portions of the tiles on respective holders break away, are entrained by the flow of exhaust gas and strike the first guide-blade row of the gas turbine. That can lead to damage to the coating of the guide blades, and to destruction of the moving blades disposed therebehind. Moreover, there is the risk of a tile already damaged by the breaking away of portions becoming completely detached from the holders and possibly causing correspondingly massive damage to the gas turbine. In that case, the occurrence of small loose parts or an individual tile indicates an impending total breaking away of a tile or a number of tiles, and therefore switching off the gas turbine in good time and exchanging the damaged tiles prevent more extensive damage.
It is known in principle from International Publication No. WO 01/75272 A2, corresponding to U.S. Pat. No. 6,499,350, for the purpose of monitoring such impacts on a system part, to make use of suitable sensors to detect the impact through the use of structure-borne sound produced thereby. However, particularly in the case of gas turbines, the problem arises in that case that the normal level of operating noise is so high that even the signal component generated by the impact of a whole tile on the guide blade of the gas turbine is smaller than the background generated by the normal operating noises and therefore, in particular, the occurrence of relatively small portions cannot be detected by simply monitoring the amplitudes of the signals of structure-borne sound. It is therefore proposed in that publication, for the purpose of improving the signal-to-noise ratio, to subject the measurement signal picked up by a measuring sensor to bandpass or high-pass filtering in order to eliminate the signals of structure-borne sound produced in normal operation of the turbine in that way. Those measures are not, however, sufficient for reliably identifying a pulse-type event in the case of high background noises that vary temporally.
A method for detecting a pulse-type mechanical effect on a system part in the case of which the detected structure-borne sound signal is subjected to a windowed Fourier transformation, is known from International Publication No. WO 03/071243, corresponding to U.S. Pat. No. 6,907,368. Algorithms which are explained in more detail therein are used to derive an evaluation function K that indicates the occurrence of a pulse-type mechanical effect on the system part from a multiplicity of Fourier spectra determined in that way. The algorithm, specified in that publication, for deriving the evaluation function K, enables the precise detection of a signal component that is superposed on the noisy measurement signal and is to be ascribed to a pulse-type effect.
The important step in that proposed evaluation algorithm is that for each time window and each of the prescribed frequencies, the deviation of the magnitude A of the Fourier transform from a mean magnitude Ā is determined. In that case, a decisive significance attaches to the formation of the mean magnitude Ā, since there can be random changes in state in system parts, particularly in the case of a turbine, in which the system part changes from one operating state into another, and the operating or background noise can rise very quickly to a significantly higher level. The start of a so-called hum is such a change in state, in the case of a turbine, for example. That is caused by the configuration of the flames in an annular space, which can have the result that the entire combustion chamber is excited to sympathetic vibrations, with the vibration modes in the circumferential direction being preferred, in particular. Those resonance phenomena can in part break off abruptly and likewise start up again abruptly. If a sliding mean magnitude that is formed by a simple averaging as an arithmetic mean from a number of prior magnitudes is used as a basis for the method disclosed in International Publication No. WO 03/071243, corresponding to U.S. Pat. No. 6,907,368, with the content of International Publication No. WO 03/071243, corresponding to U.S. Pat. No. 6,907,368, being expressly incorporated by reference in the instant patent application, it has emerged that those noise fluctuations can lead to erroneous triggering. In order to avoid instances of such erroneous triggering, monitoring for pulse-type mechanical effects was therefore suppressed in practice during the humming of the turbine, which is detected by analyzing the signal characteristic.
In other system parts, as well, for example in a reactor pressure vessel of a nuclear power plant, operationally induced short-term operating noises are superposed on the continuous basic noises (fluid flow, pump noise), which are caused, for example, by permissible changes in the operating conditions and intentional interventions in the operating sequence (actuation of valves, movement of control rods).
It is accordingly an object of the invention to provide a method and a device for detecting a pulse-type mechanical effect on a system part, which overcome the hereinafore-mentioned disadvantages of the heretofore-known methods and devices of this general type and which are further improved in comparison with the method disclosed in International Publication No. WO 03/071243, corresponding to U.S. Pat. No. 6,907,368.
With the foregoing and other objects in view there is provided, in accordance with the invention, a method for detecting a pulse-type mechanical effect on a system part, in which an operating noise present in the system part is detected continuously by a sensor disposed on the system part, and is converted by the sensor into a measurement signal that is processed with the aid of the following method steps:
with Qα and Q1−α being respectively α and (1−α) quantiles of the magnitudes (A(fi,tm)) respectively determined in a time segment (T), with tm=t+mδt and with m being a whole number.
The invention is based in this case on the finding that a simple numerical averaging of the magnitude A can have the consequence that a fast transition of the operating state into a state having a higher noise level is erroneously interpreted as a burst signal, that is to say a signal resulting from a pulse-type effect on the system part. Such a signal is illustrated in the diagram of
The evaluation function K(t) derived from the measurement signal M in accordance with
varA(fi,t+δt)=kvarA(fi,t)+(1−k)(A(fi,t+δt)−Ā(fi,t))2, with δt being the time step in
which the magnitude A is respectively determined for a time window Δt. By selecting the parameter k, it is now determined to what extent a magnitude A(fi,t+δt) being newly added thereto influences the newly calculated mean magnitude Ā(fi,t+δt). This approach corresponds to an exponentially weighted averaging, with k determining the adaptation rate. In the event of a sudden change in the magnitude A(fi,t) from a constant initial value to a likewise constant new value, there would then be an approximately exponential adaptation of the new mean magnitude Ā to the new, currently present magnitude A with a time constant τ=δt/(1−k). For k=0.999 and δt≈3.2 ms, there is a time constant τ of 3.2 s.
As is to be gathered from
With the objects of the invention in view, there is concomitantly provided a device for detecting a pulse-type mechanical effect on a system part. The device comprises at least one sensor disposed at the system part for continuously detecting and measuring an operating noise present in the system part and outputting measurement signals (M). An A/D converter is connected downstream of the sensor for digitizing the measurement signals (M) output by the sensor. An arithmetic unit for receiving digitized measurement signals from the A/D converter is programmed to:
with Qα and Q1−α, being respective α and (1−α) quantiles of the magnitudes A(fi,tm) respectively determined in a time segment (T), with tm=t+mδt, and with m being a whole number.
Other features which are considered as characteristic for the invention are set forth in the appended claims.
Although the invention is illustrated and described herein as embodied in a method and a device for detecting a pulse-type mechanical effect on a system part, it is nevertheless not intended to be limited to the details shown, since various modifications and structural changes may be made therein without departing from the spirit of the invention and within the scope and range of equivalents of the claims.
The construction and method of operation of the invention, however, together with additional objects and advantages thereof will be best understood from the following description of specific embodiments when read in connection with the accompanying drawings.
Referring now to the figures of the drawings in detail and first, particularly, to
The arithmetic unit 12 includes, for each measuring channel, a processor for a fast calculation of a transform of the data relayed by the analog/digital converter 8, as well as a ring memory for storing a number L of the transforms determined by the transformation. This transformation can, for example, be a fast windowed Fourier transformation FFT. Any mathematical operation with which it is possible to represent this mathematical function with the aid of a complete set of orthogonal base functions is to be understood as a transformation of that function (a measurement signal M(t)) in the meaning of the present invention. As is the case with the Fourier transformation, these orthogonal base functions can be formed by an exponential function e−iωt. However, it is also possible in principle to use other periodic functions as an orthogonal base system. These transformations are used to calculate discrete transforms with the aid of a predetermined set of discrete parameters. In the case of Fourier transformation, these are permanently prescribed frequencies fi=ωi/2π that are selected in accordance with the respective system part, as is explained in more detail for a turbine, for example, in International Publication No. WO 03/071243, corresponding to U.S. Pat. No. 6,907,368.
For each measuring channel, an algorithm implemented in the arithmetic unit 12 and explained in more detail below employs the discrete transforms determined in the arithmetic unit 12 to determine an evaluation function K(t) dependent on time t that is compared in a comparing device 14 with a prescribed threshold value K0. An overshooting of the threshold value K0 (alarm threshold) serves as an index for the presence of a pulse-type signal component caused by a transient mechanical effect, and generates a corresponding trigger signal S. The trigger signal S is fed to a transient recorder 16 in which the measured data (measurement signals Ms) for a time range of 10 s, for example, is recorded and relayed to an evaluation computer 18 in order to permit the latter to be used to carry out a subsequent analysis.
A mean magnitude Ā(fi,t) is now formed from the values of the magnitude A(fi,t). This mean magnitude Ā(fi,t) is a temporally sliding mean which is determined in a sliding fashion in time steps δt as a function of the time t from a data record A(fi,t), assembled from M magnitudes A(fi,tm) of a time segment T, with the aid of a relationship:
wherein Qα and Q1−α are α and (1−α) quantiles of the magnitudes A(fi,tm) relatively determined in a time segment T, where tm=t+mδt and m is a whole number. To this end, the magnitudes A(fi,tm) associated with this time segment T, disposed by way of example symmetrically in relation to the instant t (with it holding in this case that
and M is odd), and respectively forming the data record A(fi,t) assigned to the instant t, are sorted in a sequence by value of the magnitude. The α or (1−α) quantile is then that value of the magnitude which is located at the position αM or (1−α)M of the sequence. In practice, values are set between 0.7≦α≦0.8, preferably α=0.75 for α. A mean magnitude Ā(fi,t) obtained with the aid of this calculating method is illustrated in
The α and (1−α) quantiles, Qα and Q1−α, respectively, are now used to calculate a mean deviation s(fi,t) of the magnitudes A(fi,tm) from the mean magnitude Ā(fi,t), by using a relationship:
with q1−α being the (1−α) quantile of the normalized Gaussian distribution or normal distribution.
This calculating method (quantile method) can therefore be used to calculate the mean and deviation of a data record without taking into account the values that are located outside the ranges defined by α and (1−α). This means that substantially higher magnitudes such as can occur in an additionally amplified fashion from a superposed burst signal are not taken into account, and thus also cannot corrupt the result. This method can be used in conjunction with the same quality of the result of calculation to select a substantially shorter time segment, for example a data record A(fi,t) including M=100 values of the magnitude A(fi,tj) and having a length of T=320 ms for the time segment for a time step δt=3.2 ms. Consequently, the mean magnitude Ā(fi,t) is adapted to rapid changes in the operating background so that they are unable to lead to corruption of the normalized spectra or to appear as erroneous displays in the monitoring. It is possible in the case of such a mode of procedure for the striking of loose parts to be detected even during the humming of a gas turbine, that is to say when sympathetic vibrations in the combustion chamber give rise to substantially higher background noises very abruptly, for example with a time constant of approximately 0.5 s in association with an amplitude rise by a factor of 5 and more.
The existing calculated mean magnitude Ā(fi,t) and the mean deviation s(fi,t) can now be used in a further computing step to determine, on the basis of the quantile method, an improved mean magnitude Āopt(fi,t) by eliminating from the respectively present data record A(fi,t) those magnitudes A(fi,tm) that are significantly greater than the previously calculated mean magnitude Ā(fi,t). In practice, it has proved to be advantageous in this case when calculating the mean to eliminate those magnitudes A(fi,tm) that are greater than Ā(fi,t)+3s(fi,t). With the complete data record A(fi,t), a renewed calculation of mean is then carried out with the aid of a δ or (1−δ) quantile, in which case
δ=α(M−ME)/M
holds, and ME is the number of the magnitudes A(fi,tm) that are greater than Ā(fi,t)+3s(fi,t). As an alternative thereto, it is also possible and mathematically identical to determine the a and (1−α) quantile anew with the aid of a data record reduced by these magnitudes (A(fi,tm). With the aid of these δ and (1−δ) quantiles, or of the α and (1−α) quantiles obtained with the reduced data record, an improved mean Āopt(fi,t) or an improved mean deviation sopt(fi,t) is now calculated in accordance with the above-mentioned formula.
With the aid of the mean magnitudes Ā(fi,t) or Āopt(fi,t) and of the mean deviation s(fi,t) or sopt(fi,t), a normalized deviation D(fi,t) of the magnitude A from the mean magnitude Ā is now calculated for each frequency in accordance with the following equation:
D(fi,tm)=(A(fi,tm)−
D(fi,tm)=(A(fi,tm)−Āopt(fi,t))/sopt(fi,t).
The magnitudes A(fi, tm) of M spectra are evaluated in order to determine the mean magnitude Ā(fi,t) valid at the instant t and the mean deviation s(fi,t) valid at this instant t. In other words: both the mean magnitude Ā(fi,t) or Āopt(fi,t) and the mean deviation s(fi,t) or sopt(fi,t) are constantly updated with the aid of M transformations. This updating is performed in time steps δt. The data record A(t+δt) forming the basis of the calculation of the new mean magnitude Ā(fi,t+δt) or Āopt(fi,t+δt) and of the new mean deviation s(fi,t+δt) or sopt(fi,t+δt) is formed in this case by deleting the first (oldest) magnitude and adding the newest magnitude. In the case of a time segment T disposed symmetrically relative to the instant t, these are the magnitudes:
In an advantageous refinement, the normalized deviation D(t, fi) is additionally averaged in a frequency range fi−L, fi−L+1, . . . fi+L surrounding the frequency fi and formed of 2 L+1 frequencies, and a mean normalized deviation
This additional computing step leads to a reduction in the level and breadth of fluctuation of normalized deviation in the ranges in which only background signals are present. The useful signal components are not markedly varied by the averaging in the frequency range, since they always occur in a fashion concentrated about neighboring frequency lines. This measure results once more in an improvement to the signal/background ratio by a further 10 to 15 dB.
A further improvement in the signal/background ratio is achieved when a threshold value D0 is additionally introduced, and a normalized deviation
The normalized deviations D(fi,t),
An evaluation function K(t) is now derived from this sum S(t) by extracting the root:
K(t)=√{square root over (S(t))} (1).
The latter serves as an indicator for the occurrence of an impact. As an alternative to this, it is also possible for the evaluation function to be formed from the difference between the root of the sum S(t) and a sliding time mean of this root
{tilde over (K)}(t)=K(t)−
and for it to serve as a characteristic for the occurrence of an impact. If K(t) or {tilde over (K)}(t) overshoots a threshold value K0 (alarm threshold), which is between 1.5 and 2 for gas turbines, this constitutes an indication for the impact of a loose part.
The evaluation function K(t) obtained in this way and with the aid of the mean normalized deviation
Nevertheless, it remains possible with the aid of the method according to the invention to reliably detect the striking of a loose system part.
Number | Date | Country | Kind |
---|---|---|---|
10 2006 004 947 | Feb 2006 | DE | national |
This is a continuation, under 35 U.S.C. §120, of copending International Application No. PCT/EP2007/000135, filed Jan. 10, 2007, which designated the United States; this application also claims the priority, under 35 U.S.C. §119, of German Patent Application DE 10 2006 004 947.0, filed Feb. 3, 2006; the prior applications are herewith incorporated by reference in their entirety.
Number | Name | Date | Kind |
---|---|---|---|
4888948 | Fisher et al. | Dec 1989 | A |
5479826 | Twerdochlib et al. | Jan 1996 | A |
6208944 | Franke et al. | Mar 2001 | B1 |
6494046 | Hayess | Dec 2002 | B1 |
6499350 | Board et al. | Dec 2002 | B1 |
6907368 | Bechtold et al. | Jun 2005 | B2 |
20010023582 | Nagel | Sep 2001 | A1 |
Number | Date | Country |
---|---|---|
224 934 | Jul 1985 | DE |
195 45 008 | Jun 1997 | DE |
197 27 114 | Feb 1999 | DE |
198 43 615 | Apr 2000 | DE |
198 57 552 | Jun 2000 | DE |
0 765 466 | Apr 1997 | EP |
0175272 | Oct 2001 | WO |
03071243 | Aug 2003 | WO |
Number | Date | Country | |
---|---|---|---|
20090048791 A1 | Feb 2009 | US |
Number | Date | Country | |
---|---|---|---|
Parent | PCT/EP2007/000135 | Jan 2007 | US |
Child | 12185307 | US |