SU1054759A1 - Eddy current device for inspecting gaps - Google Patents

Abstract

Eddy current USTROPSTVO CONTROL GAP comprising sequentially soedinennne alternator, eddy current transducer with an excitation winding and two symmetrically disposed with respect to the winding axis of the excitation izmeritelnmi obmotkgili compensator, the signal processing unit, podklpchenny to the measuring coils and the comparison unit and recorder connected to KONffieHcaTopy, characterized in that In order to expand its functionality by monitoring products with periodically changing surfaces, it provides a series connected measuring intervals and the sync block unit, the second input of which is connected to vyhodu.bloka comparison, the output - to the recorder and the input of comparator unit, and inputs the measurement intervals unit connected to outputs of signal processing unit. SP 4 cl with

Description

The invention relates to an instrumentation technique and can be used to control the working gaps between the end surface of the turbine blades and the casing under extreme conditions for temperature and yes. . An eddy-current device for controlling gaps is known, containing a generator connected in series, an eddy-current transducer with an excitation winding and two si1 / 1 are symmetrically located relative to the axis of the excitation cwi windings, a compensator, an SR processing unit connected to the measuring windings, a comparison unit recorder 1. A disadvantage of the known device is low functionality, in particular the lack of control of products with a periodically varying surface. The purpose of the invention is the expansion of functional capabilities due to the control of products with periodically varying surfaces. The goal is achieved by the fact that an eddy current monitoring device for gaps containing a generator connected in series, an eddy current converter with an excitation winding and two measuring windings symmetrically located relative to the axis of the excitation winding, a compensator, a signal processing unit connected to the measuring windings, a comparison unit —And the recorder connected to the compensator, provided with a series-connected interval measurement unit and a timing synchronization unit, the second input of which Turnkey for comparing the output unit, the output - to the registrar .The inputs and comparing unit, and inputs the measurement unit and the intervals are connected to the outputs of the signal processing unit. The drawing shows block diagrams of an eddy current device for controlling gaps. The device contains sequentially connected generator-1, eddy-current transducer 2 with excitation winding 3 and symmetrically located relative to its axis by measuring windings 4, 5, compensator 6 with oppositely connected windings 7, 8 connected to measuring pin / i MOTKafvj 4, 5 and output winding 9, the recorder 10 connected to it, respectively, connected to the measuring windings 4, 5, the signal processing unit 11 from the amplitude detectors 12, 13 and the phase detector 14, the comparison unit 15 from the series-connected units 16 subtractors whose inputs are connected to the outputs of the amplitude detectors 12, 13, the first null organ 17, the first trigger 18, circuit 19, and the second null organ 20 connected in series, the input of which is connected to the output of the phase detector 14, and the second trigger 21, an output connected to the second input of the circuit 19. And, the interval measurement unit 22 and the synchronization unit 23 connected in series, the second input connected to the output of the circuit 19 AND of the comparison unit 15, the output to the recorder 10 and the second inputs of the trigger 15 and 21 of the comparison unit 15 and the inputs of block 2 2 spacing measurements are connected to the outputs of the amplitude detectors 12, 13 of the signal processing unit 11. The operation of the eddy current device for monitoring gaps is as follows. At an alternating current frequency of the order of 1 MHz, eddy currents arise on the conductive surface of the monitored object 24 on the excitation winding 24, which through their magnetic field demagnetizes the effect on the fluxes of magnetic induction, and therefore on the EMF of mutual induction 64 and 8; g induced in the measuring windings 4 and 5. When the monitored object 24 moves, and consequently, the flow directions of the vortex toKOBs change along the surface, both the EMF values 64 and d g and their phase angles Cf g change (and the output signals 2 and €. y It affects not only the near surface, but also the adjacent surface areas of the object. The signals from the measuring windings 4, 5, are fed to the inputs of the detectors 12-14 of the processing unit 11. The signals from the outputs of the AGP detectors 12 and 13 are subtracted in subtraction unit 16. When their signals are equal, the zero-body 17 emits a pulse, which triggers the trigger 18, which corresponds to the test surface with a gap of 25 in the equisignal zone of 0. This condition can also be satisfied with a uniform gap of 25 and 5 s, i.e. in the absence of a controlled surface or its electrical conductivity equal to zero in the interaction zone. With the passage of the test surface with a gap 25 (defect) of the magnetic flux axis of the excitation winding 3, the phases (p and cpj, which are compared on the Phase detector 14) change. At the time the phase difference passes ((f - fu) through O, the second zero-body 20 is triggered which gives a pulse to the second trigger 21. With signals from the outputs of the flip-flops 18 and 21 at the output of the circuit 19, And a signal appears that is converted by the synchronization unit 23

in the time interval that is required for registration in the registrar 10 of the value of the installation gap. Upon further movement of the monitored surface with a gap of 25 relative to the eddy current transducer, the signal decreases from one measuring winding and increases from the other, respectively, changes in signals from the amplitude outputs of detectors 12 and 13, which are converted by block 22 into a position code. According to the position code relative to the axis of the excitation coil, the gap measurement interval is formed using the interval measurement block 22 and the synchronization block 23, which, affecting the recorder 10, transfers it to the registration mode of the maximum gap size S. It is also possible to characterize the size and size of the gap in accordance with the position of the test surface within the limits of the required location, and with counting the number of cycles within the entire range of measurements (full rotation). To register a position code with a non-periodic change in the control zone, a special displacement transducer 1 can be used to form the code — a code coupled to the object under control. A non-periodically varying gap or defect can be examined within the conversion range.

five

The device allows to expand the functionality by providing control of products with a periodically changing surface, allowing automation of the process.

0 measurements.

Claims (1)

Eddy current device for controlling gaps, containing a series-connected generator, an eddy current transducer with an excitation winding and two meters symmetrically located relative to the axis of the excitation winding fl m ΟΊ windings, a compensator, a signal processing unit connected to the measuring windings and a comparison unit and a recorder connected to the compensator, characterized in that, in order to expand the functionality by monitoring products with a periodically changing surface, it is equipped with connected in series by the interval measurement unit and the synchronization unit, the second input of which is connected to the output of the comparison unit, the output to the recorder and the input of the comparison unit, and the inputs of the interval measurement unit are connected Single cheny to outputs of signal processing. blo1