SU1587438A1 - Method of detecting faults in articles - Google Patents

Abstract

The invention relates to non-destructive testing and can be used to control surface defects in products by acoustic emission (AE) signals. The aim of the invention is to increase the reliability by opening surface defects by mechanical loading of the product and reducing the AE of the defect-free material by preliminary local cooling of the surface. The product is loaded, locally cooled, applied to methane and cooled again. When cooling, AEs are recorded and, with respect to its parameters, with two cooling judgments about the quality of the products. 1 il.

Description

The invention relates to the field of non-destructive testing and can be used to control surface defects in products by signals of acoustic transmission (AE).

The aim of the invention is to increase the reliability by opening surface defects by mechanical loading of the product and reducing the AE of the defect-free material by preliminary local cooling of the surface.

The drawing shows a device for implementing a method for detecting defects in products,

The device contains a Dewar vessel 1 with a liquid refrigerant (for example, nitrogen), an electric heater 2 placed inside the Dewar vessel 1, a cold pipeline 3, a nozzle 4, a throttling gasket 5 made of a fibrous or porous material, a thermocouple 6, sweat pressed to a local area

the surface of the controlled product 7, the meter 8, connected to the output of the thermocouple, the piezoelectric transducer 9 and the acoustic emission device 10 connected to the output of the transformer 9.

The method of detecting defects in products is carried out as follows.

The controlled article 7 is mechanically loaded to a predetermined load, for example, tensile stresses are created in the walls of a controlled container by providing an overpressure inside the container. A piezotransducer 9 is installed on the surface of the product 7 at a distance L from the controlled local surface area, the parameters of the AE signals are measured by the device 10, and the AE associated with the stressed state of the material is stopped (the pressure inside the tank remains constant

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test period). Then the refrigerant pipe 3 with the nozzle 4 is brought to a controlled area of the surface of the product 7 (container) and a gasket 5 is applied to the surface. The surface of the product 7 is locally cooled, and the cooling zone is determined by the dimensions of the gasket 5, through which the gaseous refrigerant is throttled. The size of the nozzle 4 is chosen such that, outside of it, no water vapor crystallizes on the surface of the product 7, i.e. surface temperature was greater than 0 ° C

The temperature of the local controlled area is measured by a thermocouple 6 and a meter 8. The speed and degree of cooling are controlled by the electric heater 2. The gasket 5 is moved to the next controlled area and its local cooling is performed.

thirty

35

Thus, all areas of the product to be monitored are scanned (for example, a weld), while the parameters of the AE signals are recorded by the devices 10.

Then the areas of the product 7, which are to be monitored, are thoroughly cleaned from contamination, degreased and dried, thereby completely freeing surface defects from contamination and moisture. A layer of liquid indicator substance with high penetrating power, for example, penetrant, with crystallization temperature C is applied to areas of the product 7. Then, using a cleaner, for example ethyl alcohol, the penetrant is removed from the surface of the product 7 so that its part remains which filled the cavities of open surface defects. After re-drying, the controlled areas of the product are re-locally cooled in an order similar to the initial cooling (the first and second cooling are performed to the same temperature t.), And the register 40 is produced

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Thus, it is possible to increase the reliability of the preliminary mechanism and the local state of the product.

Claims (1)

Formula of The method of detecting whether the surface of the product on the substance, the surface covered from the surface, about these defects, cooling the surface of the crystallization cooling liquids, reads the signals, according to their parameter of defects, which, in order to increase the preliminary loading of the product is the deposition of the surface of the heat sink, which is equal to the cooling rate, and is found in relation to the emission pair at the first parameters of AE signals. Sraviiv-5 core cooling. 0 five 0 five AE parameters are observed during the first and repeated cooling, and by their relation, the presence of defects is judged. If during re-cooling the AE signals are not observed or their level is significantly lower than during the first cooling, then they conclude that the controlled section of the product is defect-free (due to the Kaiser effect for the defect-free material during repeated loading caused by thermal exposure to the initial temperature, AE is non-existent) . If at repeated thermal loading registr-. Intensive AE signals are detected, it is concluded that surface defects are present in the controlled area, since cooling is accompanied by crystallization of the penetrant in the cavity of the defect. Thus, the method allows to increase the reliability of control due to the preliminary mechanical loading and local cooling of the product surface. Formula of gaining The method of detecting defects in products, which consists in applying a layer of liquid substance capable of filling open surface defects on the surface of the product, removing it from the surface, leaving defect cavities, and locally cooling the surface of the product to a cooling temperature below crystallization temperatures of a liquid substance, record acoustic emission signals, judging by their parameters the presence of defects, different with the fact that, in order to increase the reliability, a preliminary mechanization is performed Generally loading the product and local cooling the surface of the product to a temperature equal to the re-cooling temperature, and the presence of defects is judged by the ratio of acoustic emission parameters during the first and second local cooling. /  five