EP2265911A2

EP2265911A2 - Method for monitoring an electrodynamic motor

Info

Publication number: EP2265911A2
Application number: EP09753716A
Authority: EP
Inventors: Max Hobelsberger; Bernhard Mark
Original assignee: Alstom Technology AG
Current assignee: General Electric Technology GmbH
Priority date: 2008-04-15
Filing date: 2009-04-01
Publication date: 2010-12-29
Also published as: CN102047084A; US20110084671A1; WO2009144061A3; US8378645B2; WO2009144061A2; CN102047084B

Abstract

The invention relates to a method for monitoring an electrodynamic motor, especially a generator (1) comprising a rotor arrangement (11) mounted along a rotatable shaft (10) inside a stator (12), forming an air gap (17) with the stator (12). According to said method, measuring signals depending on a magnetic field generated by the electrodynamic motor are detected and evaluated by means of at least one sensor (18) arranged inside the air gap (17) or inside the stator (12). The method is characterised in that the measuring signals are taken as a basis for evaluating the dynamic load on the shaft (10).

Description

Method for monitoring an electrodynamic machine

Technical area

The invention relates to a method for monitoring an electrodynamic machine, in particular a generator, having a rotor assembly mounted within a stator along a rotatable shaft and including an air gap with the stator in which at least one is disposed within the air gap or within the stator Sensor measurement signals are detected and evaluated, which depend on a magnetic field generated by the electrodynamic machine.

State of the art

Electrodynamic machines convert mechanical energy into electrical energy (generator operation) or electrical energy into mechanical energy (electric motor operation). The transformation is based on the Lorentz force, which acts on moving charges in a magnetic field.

The following is an example, without any limitation, on electrodynamic machines that work as generators, received. In particular, the embodiments relate to large-scale installations, e.g. large synchronous generators, such as those used in industrial power generation.

The generator has a rotor mounted on a shaft which rotates within a fixed stator at a rotor rotational frequency. During rotation, the rotor generates a circulating magnetic DC field, which in the stator windings produces a sinusoidal electrical voltage and thus a sinusoidal current induced. The DC field of the rotor is generated by current-carrying windings, which are arranged in grooves which extend parallel to the axis of rotation. The windings exist in large-scale systems, for example, hollow metal bands whose outer surfaces are electrically insulated from each other by means of a plastic layer. Inside the hollow metal bands circulates mostly a cooling medium.

Electrodynamic machines, in particular large generators, are monitored during operation in order to be able to detect, in particular, vibrations of the shaft or their causes at an early stage and in order to avoid damage to the machine.

The vibrations of the shaft preferably occur in the form of torsional vibrations, pendulum vibrations and / or bending vibrations. Torsional vibrations are vibrations that lead to a non-uniform rotational frequency along the shaft and thus to a torsion of the shaft. For example, they can be caused by sudden load changes. The torsional vibrations are very small vibrations, usually with a phase amplitude in the range of 0.01 °, but can still lead to a very high load on the shaft. The frequencies with which torsional vibrations occur depend on the nature of the material and the thickness of the shaft, the masses connected to the shaft and the size of the system.

As pendulum oscillations quasi-periodically damped changes in the rotational frequency of the shaft to the mains frequency (typically 50 or 60 Hz) are called, which are caused for example by shock-like interference from the network and also have a torsional effect on the shaft. Typically, however, pendulum oscillations result in significantly slower changes in the instantaneous angular velocity at which the shaft is rotating, or the instantaneous phase of the rotational motion, than the aforementioned torsional vibrations. For example, in a large-scale generator for industrial power generation, which has a nominal rotor rotational frequency of typically 50 or 60 Hz, Torsional vibrations with typical frequencies between 100 and 300 Hz and pendulum oscillations with typical frequencies of 5 to 10 Hz.

In addition, vibrations may also be caused by rotor winding closures or may be due to non-uniform pole arrangements of the magnetic field generated by the rotor.

To protect the electrodynamic machine from damage, it is switched off when excessive vibration occurs.

US Pat. No. 3,506,914 discloses a method by which rotor windings can be detected which, as mentioned above, can lead to vibrations. For the detection of rotor windings the so-called stray field measurement is used, in which with the help of air gap sensors, which are mounted in the air gap between the rotor and stator, the rotor generated, running tangentially to the rotor surface magnetic stray field is measured. It is exploited that Windungsschlüsse cause measurable in the air gap modification of the stray field.

Another approach for the determination of wave vibrations, which emerges from various documents, such as. US 3,934,459, US 3,885,420, US 4,148,222, US 4,137,780, US 4,317,371, is that for detecting torsional vibrations of the shaft outside of the rotor and stator, a gear with is connected to the shaft, which generates during the rotation of the shaft in one or more surrounding sensors periodic measuring signals, the period of the number of teeth and the rotational frequency of the shaft depends. Torsional vibrations of the shaft cause a phase or frequency modulation of the detected signals. The disadvantage of this approach, however, is that a gear must be provided as a signal generator. A subsequent installation can be impossible or difficult and associated with correspondingly high costs. One known from US 4,444,064 method for detecting torsional vibrations is to first impress a magnetic pattern in the shaft, which acts as a pulse generator in operation.

From US 4,793,186 a torsion measuring instrument is known, which is connected to the phase winding terminals of a permanent magnet generator, which is coupled to the shaft of a generator. By evaluation, i. by frequency demodulation by means of PLL technology, the generated voltages are closed to the torsional vibrations. The method can only be used in systems with permanent magnet generator and also relatively inaccurate.

Another possibility for determining torsional vibrations along a generator shaft is described in JP 52110449. It is based on the measurement and evaluation of phase-terminal currents of the generator. This method is also relatively inaccurate and also requires current transformers for higher frequencies.

The above-mentioned methods relate exclusively to the measurement of torsional vibrations, but not to the detection of bending vibrations.

On the other hand, EP 1 537 390 B1 shows a method with which, in addition to torsional oscillations, pendulum and bending oscillations can also be detected. For this purpose, wave currents occurring on the shaft and / or shaft voltages outside the generator are tapped and evaluated.

Presentation of the invention

The invention is based on the object of developing a method for monitoring an electrodynamic machine, in particular a generator, in such a way that reliable detection of substantially all oscillation forms occurring along the shaft becomes possible. For this purpose, the most cost-effective and retrofittable even in already operating generators measures should be required. The solution of the problem underlying the invention is specified in claim 1. The solution according to the method for monitoring an electrodynamic machine advantageously further developing features are the subject of the dependent claims and the further description in particular with reference to the embodiment refer.

According to the solution, the method for monitoring an electrodynamic machine with a rotor assembly mounted within a stator along a rotatable shaft, which includes an air gap with the stator, in which detected by at least one within the air gap (17) or within the stator sensor arranged measuring signals and are evaluated, which depend on a magnetic field generated by the electrodynamic machine, characterized in that the measurement signals obtained with the sensors arranged in the air gap or within the stator are used for detecting vibrations of the shaft. These vibrations are, in particular, torsional vibrations, pendulum vibrations and / or bending vibrations. In a particularly advantageous manner, the measurement signals for determining the natural frequencies of the shaft oscillation are evaluated accordingly.

Particularly preferred is a method in which the measurement signals to be evaluated are detected by already existing sensors, which are also provided for the detection of rotor windings. Such sensors preferably detect the tangential and / or radial magnetic field generated by the electrodynamic machine in the air gap between the rotor assembly and the stator. Alternatively or in combination with this, the main magnetic flux in the stator laminated core is also detected. Magnetic field-sensitive sensors are preferably used in the manner of a coil, a conductor loop, a Hall sensor or a magnetoresistive sensor.

The sensory detected measurement signals are preferably detected in the time domain and / or in the frequency domain, for example by Fourier transformation of in the time domain Analyzes measured signals, wherein the detected measurement signals are evaluated at a nominal rotor rotational frequency and / or a multiple of the nominal rotor rotational frequency with respect to the phase, frequency and / or amplitude behavior.

In particular, the detected measurement signals are examined with respect to frequency, phase and / or amplitude modulations contained therein. These can be seen in the spectrum as secondary lines of the nominal rotor rotational frequency or their harmonics or as broadening of the spectral lines belonging to the nominal rotor rotational frequency or its harmonics. The phase or frequency response is preferably analyzed by demodulation techniques known from radio technology. These include both analogous methods, e.g. Frequency shift methods or digital methods, e.g. Sampling method with temporally periodic sampling times.

To analyze the amplitude behavior, known analog or digital methods of amplitude demodulation are preferably used.

In particular, in the digital demodulation method, the detected measurement signals or signals derived therefrom are sampled at a sampling rate equal to the nominal rotor rotational frequency or an integer multiple, i. a harmonic, approximately equal to this frequency.

The phase or frequency fluctuations of the detected measurement signals at the nominal rotor rotational frequency and / or the multiples of the nominal rotor rotational frequency are preferably determined based on a respective reference phase or reference frequency profile. The phase or frequency fluctuations of the detected measurement signals are subsequently used as a basis for evaluating the rotor rotational movement at nominal rotor rotational frequency and serve as a measure for the expression of the torsional vibrations and / or the pendulum oscillations of the shaft. The Referenzphasen- or frequency response is obtained from a reference signal having a larger phase constancy. Suitable is in particular a signal derived from the mains voltage.

In order to be able to determine the actual, time-varying torsion of the shaft as accurately as possible, which manifests itself in a deviation from a linear phase curve of the rotational movement with respect to time, preferably several frequency bands of the detected measurement signals are analyzed simultaneously. It is examined whether the phase fluctuations in the different frequency bands are correlated with each other. For further evaluation, it is preferred to use only those having a correlation from the quantity of detected phase fluctuations of the measurement signals.

In an advantageous procedure, limit values for the phase or frequency fluctuations are specified. If exceeding the limit values is detected by the acquired measured values, a signal is generated or a shutdown of the electrodynamic machine is performed. In particular, the limits are determined for each frequency band, i. for the nominal rotor rotational frequency and its multiples, indicated and compared with the respective associated values of the phase fluctuation.

Furthermore, it has been recognized that determined amplitude fluctuations can be evaluated as a measure of bending vibrations in a suitable manner. In this case, as it were, several frequency bands of the detected measurement signals are simultaneously analyzed and examined for correlated amplitude fluctuations. Particularly preferably, a value for evaluating the rotor movement is determined exclusively on the basis of the correlated amplitude fluctuations.

In particular, a limit value for the amplitude fluctuations is predetermined and, when the limit value is exceeded, a signal is generated or a switch-off of the electrodynamic machine is forced.

In a further preferred embodiment of the method for detecting bending oscillations, an inductive air coil can be used as the sensor, which is acted upon by a higher-frequency current or voltage signal. In particular, this signal has a frequency above 500 Hz. The impedance fluctuations of the inductive air coil are evaluated. By measuring the impedance fluctuations or the current or voltage fluctuations, the sensor coil, which occur for example due to eddy current losses or inductance changes, bending vibrations can be detected. This corresponds to the functional principle of an eddy current sensor. Particularly advantageous is the combination of field sensor and vibration sensor in a sensor head.

In a particularly preferred embodiment of the method, the torsional, pendular and / or bending vibrations are detected, which are triggered by transient processes, for example by sudden load changes or shock-like disturbances in the network. The transient process manifests itself in a sudden change in the phase, frequency and / or amplitude behavior of the acquired measurement signals, in particular in transient phase, frequency and / or amplitude modulations. The excited torsional, pendular and / or bending vibrations cancel again after the transient excitation with characteristic time constants. From the information obtained during the excited state information about the phase, frequency and / or amplitude fluctuation, in particular from their spectra, it can be concluded on the torsional or Biegeschwingungs- natural frequencies of the wave. Above all, however, transient phase modulations that occur at harmonics of the nominal rotor rotational frequency indicate torsional vibrations of the shaft.

The inventive method is used in particular for continuous monitoring of an electrodynamic machine.

Brief description of the invention

The invention will be described below without limiting the general inventive idea using an embodiment with reference to the Drawing described as an example. All elements not essential to the immediate understanding of the invention have been omitted. It shows:

Fig. 1 shows a schematic section through a generator with a within the

Air gap mounted sensor

Ways to carry out the invention, industrial usability

FIG. 1 shows a schematic section through a generator arrangement 1 for displaying details for magnetic field generation. The rotor 1 1 is rotatably mounted within the stator 12 on a shaft 10 along a rotational axis 14. The rotor 1 1 has in grooves 15 extending current-carrying rotor windings 16 which generate the magnetic main field 2. The course of the magnetic field lines of the main field 2 is illustrated by arrows within the rotor 1 1, the air gap 17 and by the dashed lines in the stator 12. In addition to the main field 2, whose field lines emerge substantially orthogonal to the rotor surface, an air gap scattering field 3 forms in the air gap 17 with tangential to the rotor surface and radial field components, which is measured with one or more so-called air gap sensors 18. Until now, the air gap sensor 18 was used exclusively for detecting rotor windings, which is manifested by a clear change in the amplitude of the measured stray field 3 at a specific angular position of the rotor arrangement.

The solution according to the method provides for a further analysis of the output signal of the air gap sensor 18.

The output signal of the air gap sensor 18, which is generated by the stray field 3, changes during the rotation of the rotor assembly consisting of rotor 1 1 and shaft 10, wherein typically each groove 15 of the rotor 1 1 a localizable signal change, for example in the form of a sinusoidal signal tip , generated. The output signal of the air gap sensor 18 is therefore a periodic alternating signal with pronounced harmonics of the nominal rotor rotational frequency. In particular, the output signal has a harmonic in the range of the number of slots N, ie, a spectral component at N times the rated rotor rotational frequency.

Torsional movements or rotational fluctuations of the rotor 1 1, and thus of the shaft 10, are expressed in fluctuations of the phase angle of this signal or in fluctuations of the phase angle of the individual harmonics of this signal, a phenomenon that equals a phase or frequency modulation.

For the purpose of determining torsional movements, ie torsional oscillations or pendulum oscillations, the output signals of the air gap sensor 18 are therefore demodulated in order to separate the phase change, which is to be expected from the nominal rotational movement of the rotor assembly, from the phase fluctuations due to torsional movements.

In this case, the output signal is preferably examined simultaneously in different frequency ranges, in particular at the harmonics of the nominal rotor rotational frequency. The output signal or a signal derived therefrom-which is generated, for example, by filtering and preamplification-is first split, for example, in order to supply it in parallel to different demodulation stages. In the various demodulation stages, the individual spectral components of the output signal or of the signal derived therefrom are then demodulated.

The rotor movement is shared simultaneously in almost all stray field harmonics. Thus, the harmonics of the time function s _k (t) of the stray field can be formulated by the following relationship:

s _k (t) = C _k ^■ cos (ΔΦ + .phi.k kωt + _k) Ideally, the individual phase fluctuation angles ΔΦ are in the following relationship to each other:

ΔΦ, / ΔΦ _j = i / j.

Where: i, j, k harmonic order numbers, ω nominal rotor rotational frequency S _k (t) k-th harmonic time function C k k-th harmonic amplitude Φ _k k-th harmonic phase offset ΔΦ _k time-varying phase fluctuation of the k-th harmonic th harmonics.

From the set of the simultaneously detected phase fluctuation angles, those are selected by suitable filtering which are correlated with each other or strongly with the rotor movement (and thus the wave motion), in order to determine the actual rotor movement and thus the actual torsional movement. Harmonics whose phase variations are not strongly correlated with rotor motions, e.g. the harmonics with the network fundamental frequency, on the other hand, are hidden from the calculation. In contrast to the analysis of a single spectral component, this ensures a higher immunity to interference of the measurement result.

Bending vibrations along the shaft lead to a variation of the distance between the rotor 11 and the air gap sensor 18, so that the amplitude of the output signal of the air gap sensor 18 changes. Accordingly, it is possible to deduce the amplitude and the frequency of the bending oscillations with methods of amplitude demodulation.

The method steps described in the exemplary embodiment can also be used analogously in a method that detects the magnetic field by means of sensors arranged in the stator laminated core, since a rotation angle-dependent change of the magnetic field can also be evaluated here. LIST OF REFERENCE NUMBERS

generator

main field

Air gap field

stray field

foundation

wave

rotor

stator

casing

Rotor axis of rotation

groove

rotor windings

air gap

Air gap sensor

Claims

claims

1. A method for monitoring an electrodynamic machine, in particular a generator (1), with a within a stator (12) along a rotatable shaft (10) mounted rotor assembly (1 1) with the stator (12) has an air gap (17) includes, in which by means of at least one within the air gap (17) or within the stator (12) arranged sensor (18) measuring signals are detected and evaluated, which depend on a magnetic field generated by the electrodynamic machine, characterized in that the measurement signals for detecting of oscillations of the shaft (10) are taken as a basis.

2. The method according to claim 1, characterized in that form the vibrations of the shaft (10) in the form of torsional vibrations and / or pendulum vibrations and / or bending vibrations.

3. The method according to claim 2, characterized in that the detected measurement signals or signals derived from the measurement signals for the determination of natural frequencies of the oscillations of the shaft (10) are evaluated.

4. The method according to any one of claims 1 to 3, characterized in that the measurement signals from at least one sensor (18) are detected, which is also used for the detection of rotor windings.

5. The method according to any one of claims 1 to 4, characterized in that for detecting the measuring signals, a magnetic field-sensitive sensor (18) in the manner of a coil, a conductor loop, a Hall sensor or a magnetoresistive sensor is used.

6. The method according to any one of claims 1 to 5, characterized in that the detected measurement signals in the time domain and / or in the frequency domain are analyzed, and that the detected measurement signals at a nominal Rotor rotational frequency and / or a multiple of the rated rotor rotational frequency with respect to their phase, frequency and / or amplitude behavior are analyzed.

7. The method according to any one of claims 1 to 6, characterized in that the detected measurement signals are examined with respect to therein frequency modulation and / or amplitude modulation.

8. The method according to any one of claims 6 to 7, characterized in that the detected measurement signals are sampled at a sampling rate corresponding to the nominal rotor rotational frequency or an integer multiple of this frequency.

9. The method according to any one of claims 6 to 8, characterized in that phase or frequency fluctuations of the detected measurement signals at the nominal rotor rotational frequency and / or the multiples of the nominal rotor rotational frequency are determined, and that the phase or frequency fluctuations of the detected measurement signals for Assessment of the rotor rotational movement at nominal rotor rotational frequency are used as a measure of the torsional vibrations and / or the pendulum oscillations of the shaft.

10. The method according to any one of claims 6 to 8, characterized in that a plurality of frequency bands of the detected measurement signals are analyzed simultaneously and examined for correlated phase fluctuations.

11. The method according to claim 10, characterized in that a value for the evaluation of the rotor movement is determined exclusively on the basis of the correlated phase fluctuations.

12. The method according to any one of claims 6 to 10, characterized in that limit values for the phase or frequency fluctuations are specified, and that when the limit values are exceeded, a signal is generated or a Shutdown of the electrodynamic machine is done

13. The method according to claim 6, characterized in that detected amplitude fluctuations are evaluated as a measure of bending vibrations.

14. The method of claim 6 or 13, characterized in that a plurality of frequency bands of the detected measurement signals are analyzed simultaneously and examined for correlated amplitude fluctuations.

15. The method according to claim 14, characterized in that a value for the evaluation of the rotor movement is determined exclusively on the basis of the correlated amplitude fluctuations.

16. The method according to any one of claims 13 to 15, characterized in that a limit value for the amplitude fluctuations is specified, and that when the limit value is exceeded, a signal is generated or a shutdown of the electrical machine takes place.

17. The method according to any one of claims 13 to 16, characterized in that for detecting the bending vibrations, an inductive air coil is used as a sensor (18) which is acted upon by a higher-frequency current or voltage signal, and that impedance changes of the inductive air coil are evaluated.

18. Method according to claim 6, characterized in that transient processes trigger torsional, pendular and / or bending oscillations of the shaft (10), and that in a spectrum of the detected measuring signals or in a spectrum of demodulated signals transient phase , Frequency and / or amplitude modulations occur.

19. The method according to claim 18, characterized in that the transient phase modulations of the harmonics of the nominal rotor rotational frequency as Note on torsional vibrations are evaluated.

20. The method according to claim 18 or 19, characterized in that for detecting the natural frequencies of the oscillations of the wave part of the spectrum of the detected measurement signals and / or a part of the spectrum of the demodulated signals are evaluated, in which the transient phase, frequency and / or amplitude modulations occur.