SU1726786A1 - Device for controlling maximum rotor deviation from turbine axis - Google Patents

Abstract

The invention relates to a power system and can be used to control the position of a rotor during the start-up and operation of turbomachines. The purpose of the invention is to improve the accuracy and reliability of monitoring the values of the range of vibration displacement by restoring the full signal of the maximum vibration of the rotor in real time using the instantaneous values of the modules. For this, the device has two vibroperiod sensors placed near the rotor in the same plane along two mutually perpendicular directions. The signals of each of these sensors are squared, summed in the first adder, and after extracting the square root, are fed to the peak detector, at the output the signal of which the maximum (peak) value of the module of the vibration displacement of the rotor is formed. In order to measure the range of vibratory displacements, the full signal of the maximum vibratory displacement of the rotor is restored, for which the instantaneous values of the modules protruding from the output of the root extraction unit are multiplied in the signal multipliers by the unitary sine and cosine reference signals of the rotation frequency generated by the tag sensor signal and summed them in the second adder. The signal of this adder is fed to the converter, in which it is converted into a signal of the magnitude of the amplitude of the vibratory movements of the rotor, and is also fed to the normalizing unit for connecting an external processing and recording device. 1 il. (L C th o XI 00 about

Description

The invention relates to a power system and can be used to control the position of a rotor during the start and operation of a turbomachine.

It is known a device for monitoring the maximum deviation of a rotor from the axis of a Turbomachine, comprising first and second primary transducers (vibration displacement sensors) installed in the same plane in the same plane along two rotors,

perpendicular axes and each connected by its output to the input of the first and second quadrants, respectively, connected to the inputs of the first adder, the output of which is connected via a serially connected root extraction unit and a peak detector to the recorder and the threshold unit, the input of which is also connected to the first normalizing unit, and the output - with a signaling device, and a tag sensor.

connected to the input of the frequency multiplier. The output of the frequency multiplier is connected to one of the inputs of the cosine reference signal generator (functional converter), the other input of which is connected to the output of the peak detector. One of the inputs of the signal multiplier is connected to the output of the root extraction unit, and the other of its input is connected to the output of the cosine reference generator. The output of the device is the output of the signal multiplier.

However, the known device does not accurately generate a signal for the maximum deviation of the rotor from the axis of the turbomachine, because in it the formation (recovery) of this signal is performed by multiplying the modulus of the instantaneous vibration values (deviation) of the rotor, obtained at the output of the root extraction device, by the value of the unit cosine function, permission to form which is issued by the peak detector at the moment when the rotor deviates from the maximum (peak) value, and this is due to possible non-uniformity time interval between the peak values leads to a mismatch with the real period of vibration displacement, which causes the error of signal formation and control of the rotor deviation.

Closest to the invention is a device for monitoring the maximum deviation of the rotor from the axis of the turbomachine, containing the first and second primary converters installed near the rotor in the same plane along two mutually perpendicular axes and each connected to its input to the input of the first and second quadrants, respectively with the input of the first adder, the output of which is connected through a series-connected root extraction unit and a peak detector to the recorder and the threshold unit, whose input is from It is also connected to the first normalizing unit, and the output is connected with a signaling device. The label sensor is connected to the input of the frequency multiplier, the output of which is connected to the first inputs of the sine and cosine reference signal formers, the second inputs of which are connected to the output of the frequency multiplier, and the outputs to the first inputs of the multipliers of the signals whose outputs are connected to the inputs of the second adder.

In addition, the device contains two signal multipliers connected by the first inputs to the first and second converters, respectively, and the second to

the output of the sine wave reference shaper, the outputs of the multipliers are connected to the inputs of the low-pass filters. The output of the second adder is connected to the inputs of the frequency and phase meters, the other inputs of which are connected to the output of the sine-wave reference generator and the output of the frequency multiplier, which is connected to the input of the frequency meter. In addition, the frequency multiplier in it is connected to the input of the functional converter, the second input of which is connected to the pulse output of the peak detector, and the output to the signal multiplier, the second input of which is to the output of the root extractor. .

The disadvantage of this device is the same disadvantage as the previous one, since the formation of the maximum deviation signal is the same. And the use of a rigid attachment to the rotor by the mark allows only to determine the amplitude and phase of the reverse component and does not allow to generate a signal of the maximum deviation of the rotor in real time, which is necessary for determining and controlling the magnitude of the span. This reduces the reliability of vibrodiagnostics of turbomachines.

The purpose of the invention is to increase the accuracy and reliability of monitoring the values of the range of the vibration displacement of the rotor by restoring the full signal of the maximum vibration displacement of the rotor in real time.

5 The goal is achieved by the fact that the known device containing the first and second primary converters installed in the same plane near the rotor in two mutually perpendicular

0 OS and each connected by its output to the input of the first and second quadrants, respectively, connected to the inputs of the first adder, the output of which is connected via series-connected

5, the root extraction unit and the peak detector to the recorder and the threshold unit, the input of which is also connected to the first normalization unit and the output to the alarm device, the sensor of the label is connected to the input

0 frequency multiplier and with the first inputs of the sine and cosine shapers, the second inputs of which are connected to the output of the frequency multiplier, and the outputs with the first inputs of the first one

5 and the second signal multipliers, the outputs of which are connected to the inputs of the second adder, are equipped with a second normalizing unit and a vibration transducer, and the inputs of this unit and / this converter are connected to the output of the second adder, and the second inputs of the multiplier signals are connected to the output of the root extraction unit.

The drawing shows a block diagram of the proposed device.

The device contains the first and second primary converters 1 and 2, installed near the rotor 3 in the same plane (radial) along two mutually perpendicular axes and each connected by its output to the input of the first and second quadrants 4 and 5, respectively, connected to the inputs of the first adder 6 , the output of which is connected via a series-connected root extraction unit 7 and a peak detector 8 to the recorder 9 and the threshold unit 10, to the other input of which the first normalizing unit 11 is connected, and the output of the threshold unit 10 is connected A detector to the signaling device 12, and a sensor of the tag 13, connected to the input of the frequency multiplier 14 and the first inputs of the sinus generator 15 and the cosine reference signal former 16, the second inputs of which are connected to the output of the frequency multiplier 14, and their outputs to the first inputs of the multipliers 17 and 18 signals, the outputs of which are connected to the inputs of the second adder 19. The device also contains the second normalizing unit 20 and the transducer 21 of the range of vibratory movements, the inputs of which are connected to the output of the second adder 19. The second inputs are clever The inhabitants 17 and 18 of the signals are connected to the output of the root extraction unit 7.

The device works as follows.

From the primary transducers 1 and 2, the signals containing the instantaneous values of the component vibration displacements of the rotor 3 in the form of Sx (t) and Sy (t) are sent to the corresponding quadrants 4 and 5, squared and received respectively at the first and second inputs of the first adder 6, the output of which is supplied to the root extraction unit 7. The output signal of the root extraction unit 7 contains the modules Sxy (t) of the instantaneous values of the vibration displacements Sx (t) and Sy (t) of the rotor 3, which are fed to the peak detector 8.

The magnitude of the maximum (peak) vibration displacement module SSax of the rotor 3 in the plane of the primary transducers 1 and 2 is transmitted from the output of the peak detector 8 to the recorder 9, can be output to an external measuring device and simultaneously goes to the threshold unit 10, which compares with the setpoint signal of the first normalizing signal. block 11.

When the value of the vibratory displacement specified by the block 11 exceeds the level, the alarm 12 is activated, connected to the threshold block 10.

From the sensor 13 marks the signal in the form of a sequence of pulses with a frequency of a) rotation of the rotor 3 is fed to the frequency multiplier 14, as well as shapers 15 and 16 cosine and sine reference

signals with frequency (About rotation of the rotor 3 for synchronization of operation. From the output of frequency multiplier 14, a sequence of pulses of higher frequency goes to other inputs of drivers 15 and 16

cosine and sine reference signals, in which each period of rotation of the rotor 3 is converted into signals sin O) t and cos o) g with a unit amplitude. These signals arrive at the first inputs of the multipliers. 17

and 18, the second inputs of which are supplied with the instantaneous value of the module Sxy (t) from the output of the root extraction unit 7. After their multiplication in multipliers 17 and 18, the signals from their outputs are fed to the inputs of the adder 19. As a result of summing these signals, the output of the adder 19 produces a variable periodic signal proportional to the signal of the maximum deviation of the rotor 3, with a period equal to

the period of rotation of the rotor 3, and rigidly attached to it by the mark. This signal is converted into a vibration displacement signal by the vibration displacement converter 21, and the normalization unit 20 provides at its input a normalized alternating voltage signal proportional to the instantaneous values of the maximum deviation of the rotor 3.

The transducer 20 of the vibration displacement signal received at the output of the adder 19 is converted into a DC signal, which is proportional in magnitude to the range of the vibration displacement

the maximum deviation of the rotor 3. This signal from the converter 20 of the range of vibratory displacements can be output to an external recording device (not shown).

The implementation of the device according to the invention makes it possible to form a signal which is rigidly connected with the rotor and coincides in shape and size with the signal of the maximum deviation of the rotor and, thus,

eliminates the uncertainty of the known device. And this allows to increase the accuracy of real-time formation (reproduction) of the maximum deviation of the turbine rotor,

necessary for measuring the magnitude of the magnitude corresponding to the maximum deviation of the rotor, and for vibrodiagnostic control of the turbine unit.

In addition, an increase in the accuracy of obtaining the magnitude of the maximum displacement of vibration allows an increase in the accuracy of control of the position of the rotor in the bearing bore by comparing the magnitude of the peak and the peak value of the maximum deflection modulus.

Claims (1)

Apparatus of the Invention A device for monitoring the maximum deviation of a rotor from an axis of a turbomachine, comprising first and second primary converters installed near the rotor in one plane along two mutually perpendicular axes and each connected by its own output to the input of the first and second quadrants connected to the inputs of the first adder whose output is connected via serially connected extraction blocks 0 five 0 five the root and peak detector to the recorder and the threshold unit, the input of which is also connected to the first normalizing unit, and the output to the signaling device, and a tag sensor connected to the input of the frequency multiplier and. the first inputs of the sine and cosine reference signal formers, the second inputs of which are connected to the output of the frequency multiplier, and the outputs to the first inputs of the first and second multipliers of the signals, respectively, the outputs of which are connected to the inputs of the second adder, in order to increase the accuracy and reliability control of the magnitude of the vibro-displacement of the rotor by restoring the full signal of the maximum vibro-displacement of the rotor in real time, is equipped with a second normalizing unit and transforms a spreading magnitude shifter, the inputs of this unit and this converter are connected to the output of the second adder, and the second inputs of the signal multipliers are connected to the output of the root extraction unit. Tlrii with