SU221366A1 - INSTALLATION FOR DYNAMIC BALANCING ROTORS - Google Patents

Description

Installations are known for dynamically balancing the rotors on the coast, comprising a control unit, an imbalance magnitude measurement unit, an imbalance angular position measurement unit, induction sensors and a photodiode sensor, a rotation speed measurement unit I3, and an electrical calibration unit.

The proposed installation differs from the known ones in that it is equipped with a quark generator and a trigger counter, to the inputs of which pulses are fed from a quartz geyerator and reference pulses from a photodiode sensor, and from the output, during the overrun period, a pulse is removed serves as a signal for automatic fixation of measured values. The unit for measuring the angular position of the imbalance is made in the digital phase meter using calibrated impulses from a crystal oscillator.

This makes it possible to improve the accuracy of measuring the measurement moment when the rotor rotation frequency is equal to the tuning frequency of the measurement units for the magnitude and angular position of the imbalance, and also to improve the accuracy of the measurement of the angle of inconsistency.

a ustaiozka; in fig. 2 is a block diagram of the measurement of the angular position of unbalance.

The installation consists of a unit / control unit, movable supports 2, induction sensors 3 and -i, tuning unit 5, selective amplifiers 6 and 7. Instruments S and 5 indicating the amount of imbalance, blocks 10 and 11 measuring the angular position I and equilibrium, 12 lights, a photodiode 13, a formatter 14 reference pulses, a rotational speed measurement unit 15, a quartz generator 16, an electrical calibration unit 17, a former 18, triggers

19 and 20, cascade 2 / soviadeni.

The installation works as follows. The unit / control start-up unit turns on the drive for the balance product 22.

The displacement of the two supports 2 is converted by the induction sensors 5 and 4 into an electrical signal, which through the tuning unit 5 and the selective amplifiers b and 7 are fed to instruments S and 9 to read the amount of imbalance and to the blocks 10 and 11 to measure the imbalance of the balance.

These pulses are generated in the reference pulses by the shaper 14 and fed to the rotation speed measurement unit 15. Pulses from a crystal oscillator 16 with a frequency of 360 times greater than the tuning frequency of the selective amplifiers 5 and 7 are supplied to the other input of the block 15.

Block 15 operates in such a way that while the rotor's rotation speed is less than the tuning frequency of the measuring system, there are pulses at its output, and as soon as the rotation speed exceeds the tuning frequency of the system, the impulses will disappear. At this time, the control unit 1 will turn off the drive of the trimmed product. With a certain delay, which is set by the block /, the coasting of the equilibrated product begins. The first emerging pulse at the output of block 15 is the counting resolution impulse and the block means / fixes the angular position of the imbalance on the blocks 10 and //. The calibration unit 17 forms a square pulse from the reference pulse, the main component of which is equal in magnitude and opposite in phase to the signal from sensors 3 and 4. The signal from the sensors and the signal from block 17 are fed to the input of the selective amplifiers, creating a zero measuring system that corresponds to the reference rotor.

The unit for measuring the angular position of the imbalance works as follows.

The signal from the selective amplifier 6 is fed to the shaper 18, which forms a heavy seat impulse and iodizes it at the input of the trigger 19. The reference pulse is applied to one input of the trigger 20, and the second is given to the reference resolution pulse. In the event of a resolution pulse, trigger 20 is moved, and when a reference pulse appears, it returns to its original position. Trigger 20 triggers trigger 19, which returns to its initial position with a pulse formed from the signal of the selective amplifier 6. At the output of trigger 19, a time pulse is obtained, the beginning of which corresponds to 5 occurrences of the reference pulse and the end of a heavy spot. For the duration of this pulse, a coincidence stage 21 opens, which transmits pulses from a quartz oscillator 16. Since the frequency

0 of the crystal oscillator 16 is 360 times the rotor speed, the number of pulses at the output of the cascade 21 coincides with the angular position of the imbalance in degrees.

Subject invention

An installation for dynamic balancing of the rotors on the coast, comprising a control unit, an unbalance magnitude measurement unit, an unbalance angular position measurement unit, induction sensors and a photodiode sensor, a rotation speed measurement unit and an electric unit

5, in order to increase the accuracy of determining the measurement time, when the rotor rotation frequency is equal to the tuning frequency of the measurement units for the magnitude and angular position of the imbalance, as well as to improve the accuracy of measuring the angular position of the imbalance, it is equipped with a quartz oscillator and a trigger meter, the inputs of which pulses are supplied from quartz

5 of the generator and the reference pulses from the photodiode sensor, and from the output, during the overrun period, a pulse is taken to the units measuring the magnitude and angular position of the unbalance, which serves as a signal for automatic

fixing the measured values, and the unit for measuring the angular position of the unbalance is made in the form of a digital phase meter using calibrated pulses from a crystal oscillator.

-P-L.