SU1375984A1 - Method of non-destructive check of article strength - Google Patents

Abstract

The invention relates to non-destructive methods for controlling the strength of products and can be used to test products made of electrical insulating materials. The purpose of the invention is to improve the accuracy of controlling the strength of products made of electrically insulating materials, which is achieved by the impact of mechanical shock loading by vibration load, which persists for 1-2 minutes, electric charges on the edges of microcracks and other local structure defects. During the time of action of the shock load, electromagnetic radiation pulses are recorded, by the number of which the strength parameter of the product is determined. A higher number of pulses corresponds to a lower level of product strength. The method can be useful in determining the quality of products and in accelerated tests for resource or reliability. with e and

Description

coke

The invention relates to non-destructive testing methods for products and can be used to determine the relative strength level of electrical insulation materials and products thereof.

The purpose of the invention is to improve the accuracy of controlling the strength of products made of electrically insulating materials, which is achieved by applying a vibration load, creating electric charges at the edges of microcracks and other local structure defects, before loading a mechanical load, and then loading mechanical load, during which the number of pulses of electromagnetic radiation from the product is recorded. The method is carried out as follows.

The test product is subjected to a vibration load from any mechanical vibration exciter, such as an electromagnetic vibrator operating in the range of sound frequencies, before being tested for strength for 2 minutes. Then within 1-2 minutes after this, the product is subjected to mechanical loading by a shock dynamic load of a given force, for example, using a fixed height of a metal ball. During the time of action of this load, a pulsed electromagnetic signal is emitted from the product and perceived by a corresponding receiver, for example, a metal lining of a capacitive electrostatic field sensor placed at a distance of 3-5 mm from the surface of the product. This signal is amplified by an amplifier operating in the 10–10 Hz frequency band and recorded by an appropriate storage device or analog recorder. The number of pulses registered for the time interval corresponding to the rise and release of the shock load is calculated, and the relative strength parameter of the product is determined from this value by comparing it with the data obtained when testing control products of various strength levels. Two methods — the proposed and known methods of destructive control of static load. A higher number of pulses corresponds to a lower level of product strength. The values of breaking load, breaking stress, or some other parameters expressed in relative units, for example, a safety factor, can be used as relative parameters of the product strength. The use of the proposed method to control the strength of products made of electrical insulating materials makes it possible to reasonably predict their performance in various operating conditions and improve the quality of the manufactured products due to the targeted improvement of their design and technology, taking into account test data for the proposed method. The method can be useful for accelerated tests for the reliability and service life of products made of electrically insulating materials.

Claims (1)

Invention Formula The method of non-destructive testing of the strength of products, which consists in subjecting the product to mechanical loading of a given force, records the electromagnetic radiation generated by the product and determines the parameter , the strength of the product, characterized in that, in order to improve the accuracy of controlling the strength of products made of electrically insulating materials, before loading the product  subjected to the action of a vibration load, for 1-2 minutes thereafter, the product is subjected to mechanical loading of a shock dynamic load and the number of pulses is recorded during the time of action of this load,