SU1425536A1 - Method of non-destructive check of coatings - Google Patents

Abstract

The invention relates to non-destructive quality control of coatings and can be used to control gas-thermal coatings by acoustic emission signals (AE). The aim of the invention is to increase the reliability of control by identifying types of coating defects. The coated article is loaded in steps. At each step of loading, under the load under load, the amplitude envelope of the AE signals, the decay time, the attenuation coefficient of the envelope of the amplitude, and the presence of secondary peaks of the amplitude envelope are measured. According to these parameters, various types and sizes of defects are determined: the degree of porosity and the bridge structure of gas-thermal coatings. 1 hp f-ly, 2 ill. (L

Description

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I The invention relates to; to unwelcome; quality control of coatings and can be used to control gas-thermal coatings by acoustic emission signals (AE).

The purpose of the invention is to increase the reliability of the control by identifying the types of defects of the coatings due to the step loading, which increases the informativity of the signals of the AE signals.

  Fig. 1 shows the load diagram of load S as a function of time, illustrating the loading of the structure 7 / cn in the implementation of the method of non-destructive control of the surface of Fig. 2, the shape of the AE signals for the materials; Ikogo coatings.

I The method is carried out as follows,.

Claims (2)

I A coated product is loaded by | an external mechanical force. A napher-dye coating can be subjected to a breaking or a shear load or a compressive load. During loading, AE signals occur on the surface of the product. -1u to the law up to the moment of first flight AE, and loading is stopped, the load Pp, is recorded at which the first signals of the AE were recorded. "Determine the value of incremental load i for each subsequent load step by expression 14 &R  R Too where i required load% Accuracy of the product at a constant load Pp is determined by the wind time T of the envelope of the amplitude of the signals Y. and r averaged at a time and time, then the product is loaded stepwise, maintaining uninterrupted Kaia-steps of the speed of the load increment & F and the time T of exposure of the product under constant load. / At the stage at the stage during the delay, the envelope aIvsh.ptyydy of AE signals,. , the load is higher than 1) Pj.pi, not; e. sand) about “Load R , o are determined by the number of oscillations during the delay time more than 10 times higher than the number of oscillations over time. S m holding under load Pp. For the envelopes of the amplitudes of the AE signals, the average decay time 5 determined at each load step is the ratio of the sum of the attenuation times at each step to the number of load steps, the average value of the amplitude envelope attenuation coefficient, the numerical value of the secondary amplitude peaks and the time of their delay relative to the first peaks. According to the specified parameters of AE signals, various types of defects and their sizes are identified. By the average decay time around By determining the amplitude of the signal agents, the degree of porosity of the gas-thermal coatings is determined. According to the difference; the nature and time of delay of the secondary peaks of the envelope of the amplitude determine the special S is the defect of gas coatings (bridge structure) in the boundary zone between the coating and the substrate, which have different coefficients. thermal expansion. 8 Thus, the proposed method makes it possible to determine various types of defects in thermal spray coatings by analyzing the AE signals recorded during stress 5 foam loading products with coating , F o rm u l a 0 1 p. A method of intact control of coatings 5 which consists in loading a product with a coating by an external mechanical force during loading registers the acoustic force. 5 scraps and by their parameters determine the defectiveness of the coating, that is, in order to increase the reliability of the control due to the specific certificate and the types of load defects carried out stepwise with an additive load at each stage equal to the decay time of the envelope of the amplitude of the acoustic emission signals, the decay time is measured at each 5 steps The attenuation coefficient of the envelope amplitude, the presence of secondary peaks of the envelope a split J reveal the average values of the attenuation coefficient and decay time and over them and The sizes and types of coating defects are determined by the presence of secondary amplitude peaks. 2. Method pop. 1, differing from the fact that the magnitude of the load increment is chosen by the formula i P LR I I l I R RI Too with 425536 where r 1 f and load increment at each stage; required accuracy of load measurements; the load at which the occurrence of the first acoustic emission pulses is recorded. g7 Ml b Structures For Hocmu4HOu cmf: Kmtflbi desrvkta For defect with high porous / drink