SU1711099A1 - Method for thermographic nondestructive testing of electrical printed wiring - Google Patents

Abstract

The invention relates to the non-destroying control of electrical electronic installation; products and can be used to control multilayer printed circuit boards without destroying them. The purpose of the invention is to reduce the monitoring time and increase the reliability of determining the coordinates of a defect. The method consists in the fact that electrical circuits are applied to controlled circuits 1.4, their thermograms are observed, and cobras are determined (defect dinates 7. New in this method is that respectively, the beginnings and ends of each of the monitored circuits are connected, and the current strength after switching on is increased until the appearance of a defect or contour of the monitored circuits on the thermogram of the glow. 1 Il. (L

Description

The invention relates to non-destructive control of electrical installation of electronic products and can be used to control multilayer printed circuit boards (MPP) without destroying them.

There is a method for monitoring the MPP electrical circuits, in which, to find the short circuit location (SC), the monitored conductors are connected to the outputs of two generators (of different frequencies so that currents of different frequencies flow on different sides of the short circuit). Magnetic sensor connected to a current indicator , move over any short-circuited parts of the monitored circuits.The signal at the output of the sensor will have a frequency and polarity, depending on which of the sections with different flowing frequencies.

: current, he will be in this moment. If the sensor passes over the place of a short circuit, often—: that signal will change and the direction of deviation of the indicator arrow will change. .

The disadvantage of this method is the complexity and bulkiness of the necessary equipment, as well as the low accuracy of determining the location of a short circuit when monitoring circuits with a complex configuration.

Closest to the proposed method in terms of technical nature and the achieved effect is a thermographic method for monitoring electrical installation. The method aims to reduce the complexity and time spent in determining the location of the short circuit between the controlled circuits. In the control process, after installing the board in a coordinate device, which is an instrument rack with guides installed on one side for moving two mutually perpendicular rulers and a device for fixing the board, the beginning and ends of the controlled circuits are connected through a switching unit to a current source. Then, alternately, an electric current is passed through the first and second circuits and thermograms of these circuits are obtained on a thermal imager or thermal indicator film superimposed on the surface of the controlled MPP. Then a current is passed between the beginnings or ends of the monitored circuits and the location of the short circuit as the place of convergence of bands of different brightness is determined on the thermogram. Using a linear coordinate device to determine the coordinates of the short circuit. This method of determining short circuit has the following disadvantages.

Due to the small distance between the monitored conductors, the coincidence of the luminescence of different brightness can occur in other places where there is no short circuit (false points of the short circuit). Passing an increased power current through the conductor for its thermographic visualization can lead to its overheating and failure. In addition, connecting each circuit individually to the current source, and then connecting the beginning and end of the controlled circuits to each other and re-passing the electric current, takes a lot of time to control one pair of circuits.

The purpose of the invention is to reduce the monitoring time and increase the reliability of determining the coordinates of the defect location

This goal is achieved by the fact that according to the method of thermographic non-destructive testing of electrical printed circuitry, according to which an electric current is applied to the monitored circuits, their thermograms are recorded and the coordinates of the defect are determined. According to the invention, the first and second terminals of each of the monitored circuits are connected to each other, current is passed between the first and second monitored circuits, while the current strength after switching on is increased until the appearance of a defect or contour of the monitored circuits appears on the heatgram, the coordinate of the defect is determined by the luminous coordinate the point or coordinate of the intersection of the luminous contours of the controlled circuits in the thermogram.

It is known to conduct non-destructive testing of MPP by determining the location of a short circuit by passing through controlled circuits connected to generators electrical vibrations of various frequencies. In addition, there is also known a method for visual control of electrical circuits, in which an electric current is passed through the monitored unit alternately through controlled circuits and, observing the thermographic picture on the thermal imager, the location of a short circuit is determined.

In the proposed method, the initial and final conclusions of each controlled circuit are connected between themselves, and then an increasing current is passed through the controlled circuit until a glow appears in the location of the circuit. In addition, a gradual increase in current allows you to save controlled circuit from thermal overloads.

The introduction of the operation of connecting the beginning 'and the end of each circuit to each other and the simultaneous passage of electric current through them is an essential sign that allows ₂ θ to increase the reliability of determining the location of a fault.

The drawing shows a diagram of the method.

On circuit 1 there is 25 beginning 2 and end 3, circuit 4 has a beginning 5 and end 6. Between the indicated circuits there is a defective short circuit at point 7.

The method is carried out as follows, jq.

A controlled multilayer printed circuit board is installed in a fixture for mounting boards (not shown). Beginnings 2j 5 and ends 3, 6 of these circuits are connected to each other by means of switch 8 and voltage is applied smoothly to them and the appearance of a luminous point ₄ θ is observed on the screen of the thermal imager or heat-sensitive film (in case of excess of the resistance value at the location of the fault over the resistance value test circuits) or the circuit configuration of the test circuits (in the case of comparability of the resistance values of the test circuits and their intersection). Then, using the superposition of a standard coordinate grid, the location of the defect is determined.

Application of the proposed method for thermographic non-destructive testing of the electrical installation of the MPP allows you to increase the reliability of determining the location of short circuit in circuits with a complex configuration of conductors on the MPP, to reduce the complexity and time _? necessary to control the circuits, as well as to maintain the integrity of the conductors in the control process.

Claims (1)

Claim The method of thermographic non-destructive testing of electrical printed circuitry, which consists in applying electric current to the monitored circuit, recording their thermograms and determining the coordinate of the defect, characterized in that, in order to reduce the control time and increase the reliability of the determination, the coordinates of the defect are interconnected between the first and the second conclusions of each of the controlled circuits, passing current between the first and second controlled circuits, while the current strength after switching on is increased until the appearance of a luminous point or contour of controlled circuits on the heatgram, the defect coordinate is determined by the coordinate of the luminous point or the coordinate of the intersection of the luminous circuit of the circuits in the thermogram.