DE3725123A1 - Method for selective vibration monitoring of rotating machines - Google Patents

Abstract

The invention relates to a method for increasing selectivity during the investigation of vibration for diagnosis and monitoring of the mechanical state and the operational behaviour of rotating machines, in particular thermal turbo-engines on sliding bearings, with the aim of avoiding damage, early detection of damage and the avoidance of consequential damage. It is the object of the invention to take account of the previously existing possibilities of diagnosis on the design particulars of the relevant installations in general and their way of running in particular by further consideration of the vibration indicators (absolute amount and phase angle). This is accomplished according to the invention by filing in an indicator memory (1) the signal components of the various states, which components are harmonic with respect to the rotation frequency, by filing the arithmetic mean for each signal component in a reference value memory (2) and using a monitoring module (3) to determine the differential value indicator between the actual state and mean reference state, to compare it with the standard range and to signal any infringements. In addition to the indicator memory (2), a parameter memory (4) is formed which detects the associated operating parameters at the respective measuring point. A regressor 5 provides a function for predetermining the reference value. <IMAGE>

Description

Field of application of the invention

The invention relates to a method for increasing the selectivity in vibration monitoring for diagnosis and monitoring the mechanical condition and the operating behavior rotating machines, especially sliding thermal ones Turbo machines with the aim of avoiding damage, early detection of damage and avoiding consequential damage.

Characteristic of the known solutions

Are still in national and international standards and Guidelines Monitoring procedures for vibrations on rotating Machines set up before a global assessment of the Run out of vibration levels. For the evaluation of mechanical vibrations For example, the vibration intensity is displayed on bearings the outer surfaces of bearing housings in the frequency range from 10 to 1000 Hz as the measured variable. With wave vibrations is preferred the maximum wave deflection is used as the assessment variable. The effective value determination (formation of the quadratic Mean value) or the determination of the peak value for shaft vibrations has the consequence that all essential information of the vibration signal (e.g. frequency components, phase position)  get lost for further diagnostic processing and not be available.

The known methods according to DD-WP 158 581 and DD-WP 221 550 go from a cause-related selective monitoring by:

• - Realization of a phase-locked detection related to the rotor the bearing and shaft vibration signals,
• - selective processing of the vibration signals via order analysis, d. H. automatic calculation and monitoring of vibration indicators (Amounts and phase angle) for those with plain bearings Main frequency components typical of turbomachinery (rotational frequency, double rotational frequency),
• - Summary of the remaining spectrum into a new parameter, the "residual vibration level" which corresponds to the signal level, if the rotational and double rotational frequency component is eliminated,
• - FFT analyzes are carried out to determine further signal components only if the residual vibration level or its change is sensitive specified limit values violated.

The disadvantages of existing systems lie in the insufficient, arbitrary Determination of the system constants. It will be any State defined as reference state. This approach takes into account not changes that are out of the normal fluctuation range of the influencing operating parameters result. Besides, they are measurable effects in vibration behavior depending on the constructive Special features of the respective turbo set, the respective measuring point and the driving style of the turbo set.

Aim of the invention

It is the aim of the invention, the diagnostic options on plain bearings Turbo machines in the sense of early damage detection and to increase condition-based maintenance. In particular, it works therefore, type-specific, location-dependent parameters of vibration diagnostics  to determine the mechanical state and its changes to be able to clearly evaluate.

The selectivity of the monitoring is intended with the solution according to the invention rotating machines for the detection of abnormal operating conditions be increased to an optimal level that the current one Detectability threshold for anomalies significantly expanded in quality.

State the nature of the invention

The invention has for its object a method for vibration diagnosis to create on slide-bearing turbomachinery that it allows the structural peculiarities of the systems concerned in general as well as your driving style in particular further consideration of the vibration indicators (amount and phase angle) to consider.

According to the invention, the measurement of wave and / or Bearing vibration signals by the in a pointer memory Rotational frequency harmonic signal components - especially the first and second harmonic - stored in different states which are characterized by being one in normal Operation typical fluctuation range for the operating parameters paint over. The arithmetic Filed for each signal portion. Around the middle reference pointer fluctuation ranges arise, which are the constructive peculiarities of the turbo set, the peculiarities of its driving style and the Record the respective measuring location and mark the real normal range. The reference value pointer marks the center of one Area that covers the normal range. Has a monitoring module the task of the difference pointer between the current state and to determine the middle reference state and with the extension of the Compare normal range in order to avoid possible injuries to the To signal normal range. After the experience is the extension the area around the middle reference pointers at the various Measuring points of different sizes. Especially if There are large vibrations depending on the parameters Scattering areas. According to the invention, this is taken into account that in addition to the pointer memory, a parameter memory is formed  the associated operating parameters for the respective measuring point detected. If the number of individual measurements is sufficiently large, can also add characteristic key figures according to statistical Methods are valued. A so-called regressor provides a function that makes it possible to set the reference value to predetermine. This creates a parameter-dependent reference pointer, which allows, in particular, the operating parameter-dependent To detect fluctuations. Through this behavior the selectivity of the surveillance to detect abnormal Operating conditions increased significantly.

With the solution according to the invention it is now possible to

• - from a global assessment of the mechanical condition to to go over type-specific, location-dependent monitoring,
• - from the knowledge of the damage processes taking place a cause-related Carry out surveillance,
• - to take into account the parameter dependency of vibration states and
• - Changes in the mechanical condition more sensitive than before possible to determine.

Embodiment

The solution according to the invention uses a vibration monitoring system ahead that the in the characteristics of the known technical Solutions made demands met. For example is based on a measuring and monitoring principle according to DD-WP 158 581 to lay. With reference to the attached drawing is a preferred form of process for the invention Solution shown. The drawing shows

Fig. 1 is a basic representation of the staggered form the 3-fold limit monitoring for explaining border and reference values,

Fig. 2 Vector to the invention to be determined limit and reference values (GD; O),

Fig. 3 flow diagrams for determining the limit and reference values ( GD; O) .

The points P ( i = ( i, n)) in FIG. 1 show the movement curve of a selective oscillation pointer

characterized. This movement curve includes those that are possible in practical operation Changes to a corresponding vibration pointer. The Task, abnormal operating conditions, which are reflected in the vibration behavior express and damage-related changes as accurately as possible and to be recorded in the development stage is defined by the definition of permissible ranges (limit values) solved.

• - G 1 , G 2 are limit values (advance warning, main warning) for the amounts of the selective oscillation pointers. They roughly correspond to the limit values for vibration intensity or effective value for bearing vibrations and peak values for shaft vibrations specified in the international vibration standards. This enables a rough assessment of the condition of the machine (state of the art).
• - GD characterizes the permissible range for changes of a selective vibration indicator around the reference state P ₀, with the vectors be tested for limit violation.
  This makes it possible to record "normal" parameter-dependent changes, which are also influenced by the respective measuring location, ie by the special design features.
• - GT limits the temporal, in particular sudden, change of a selective vibration indicator to a permissible value by the vectors P ₂ P ₁, P ₂ P ₃. . . P _n P _n-1 can be calculated and tested.

According to the invention, the permissible limits GD are set at the lowest possible level, taking into account the normal vibration behavior.

FIG. 2 shows the basic ways to limit and reference value determination. In case a) there are no parameter-dependent influences on the vibration indicator. Case b) shows parameter dependency.

For a), the selective vibration quantities for the 1st or 2nd harmonic component are stored in pointer memory 1, preferably in component form ( x , y direction). The arithmetic mean of the respective diagnostic variable is transferred to the reference value memory 2 in accordance with the essential requirements for the distribution of the individual states. In the monitoring module 3 , the comparison of the current and reference status and the test for violation of the limit GD takes place . GD is again empirically in a so-called instruction phase z. B. as the maximum value of the vectors ( i = 1, n) . Further processing and corresponding signaling then take place through the monitoring module 3 .

The method according to a) is unsuitable for b) (see large circle in FIG. 2). With the aid of state estimation in Fig. 3b parameter-dependent reference and limit values may be determined. In addition to the selective oscillation pointers, the operating parameters are also recorded in the parameter memory 4 . The regressor 5 provides a multidimensional random vector in the instruction phase, with which a reference value ( O ₁, O ₂... O _n ) is then estimated based on the current machine state, which reflects the behavior of the turbomachine impressed in the instruction phase, if the number the individual measurements were sufficiently large.

The further processing in the monitoring module 3 then takes place as in a).

• List of the reference symbols used: 1 pointer memory 2 reference value memory 3 monitoring module 4 parameter memory 5 regressor G 1 limit values for absolute values G 2 limit values for absolute values GD limit values for differential parameters GT limit values for transient parameters x amount of a selective oscillation pointer ϕ phase angle of a selective oscillation pointer i, r, k, n , m, p Count quantities O Reference state of a selective oscillation pointer P State points FFT Fast Fourier transformation

Claims (2)

1. A method for monitoring the vibration of rotating machines by measured value acquisition of shaft and / or bearing vibration signals by means of selective methods for determining the vibration pointer (amount and phase angle), characterized in that in a pointer memory ( 1 ) the harmonic signal components to the rotational frequency, in particular those of the first and second harmonics are stored for different states, which span a typical range of fluctuation for the operating parameters in normal operation, the arithmetic mean for each signal component is stored in a reference value memory ( 2 ) and a monitoring module ( 3 ) determines the difference value pointer between the current state and the average reference state , compares with the normal range and signals any violations of the normal range. 2. The method according to claim 1, characterized in that in addition to the pointer memory ( 2 ), a parameter memory ( 4 ) is formed, which detects the associated operating parameters for the respective measuring point and a regressor ( 5 ) provides a function for predetermining the reference value.