RU2520948C1 - Distributed crack sensor, method for registration of crack occurrence and localisation - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: distributed crack sensor consists of electrical conductors of the first group and electrical conductors of the second group isolated from each other, from material of the object and environment, at that conductors of on group are not intercrossed. The electrical conductors of the first group cross with each electrical conductor of the second group at the same point under angle α, preferably equal to 90°. The conductors of the same group are spaced from each other at the distance h equal for both groups. At that, according to the invention, in the crack sensor there are frameless double-electrode bidirectional symistors placed at the crossing point of the electrical conductors of the first group and the second group and connected by the first electrodes with the electrical conductors of the first group and by their second electrodes with the electrical conductors of the second group. The electrical conductors are thin-film, and layers of thin-film dielectric are placed so that the thin-film conductors are located between two layers of thin-film dielectric.

EFFECT: improvement of sensor.

2 cl, 3 dwg

Description

The claimed group of inventions relates to the field of diagnostics of the mechanical condition of structures, namely to the technique of diagnosing damage to the surface of structures, and can be used to monitor the surfaces of objects of aircraft.

A known method for the diagnosis of surface damage to structures [Pat.2006846 Russian Federation, IPC 5 G01N 27/20. A method for determining the place of occurrence of cracks / Geitenko EN, Erisov SL, Gadalin NI], which consists in the fact that electric currents pass through the elements of the conductive foil, which are pre-fixed through an insulating strip on the test surface and determine the location the appearance of cracks due to a change in the electric current passing through the elements of the conductive foil, which are combined into a system consisting of end elements interconnected by summing elements, supply weight currents to the end elements with a known cheniyami, different for each of them, the total current measured at the summing elements, compare it with a predetermined total power value and the result of comparison, the location of cracks.

This method allows you to determine the place of occurrence of cracks in one coordinate in the region related to one branching structure of the sensor by determining the change in current passing through the elements of the system.

Signs of an analogue that coincide with the essential features of the claimed invention are an insulating strip attached to the surface of the object, current-conducting elements, crack detection based on the absence of current in the circuit of the conductive elements.

The disadvantage of this method is the low accuracy of localization of the damage site.

A known method for the diagnosis of surface damage to structures [Pat.2365875 Russian Federation, IPC G01B 7/16. A method for diagnosing the state of construction / Baurova N.I., Zorin V.A.], according to which at least one local area of the probable occurrence of a defect is determined, a sensor is installed in this area, using material from graphitized carbon fibers based on polyacrylonitrile which, with tension, is fixed on the local area covered by the curable binder and is coated on top with a curable binder, and the elongation of the binder in the cured state is 10-20% more than the elongation material, and then a device is connected to the sensor that allows measuring the electrical resistance of the sensor, and the stress-strain state of the diagnosed structure is determined by the experimentally determined dependence of the electrical resistance of the sensor on deformation.

This method allows you to determine the presence of a defect in the coverage area of the sensor.

Signs of an analogue that coincide with the essential features of the claimed invention are the determination of the presence of a defect by a change in electrical resistance, a preliminary determination of the areas of the possible occurrence of a defect.

The disadvantage of this method is the time-consuming process of installing the sensor, improving the accuracy of determining the location of the defect is associated with dismantling and reinstalling the sensor, the inability to determine the location of the defect in two coordinates.

The closest in technical essence to the claimed group of inventions is a method and device for diagnosing damage to the surface of structures [Pat.2367936, Russian Federation, IPC G01N 27/00. Device for monitoring the state of a surface area of structures, a method for detecting damage to a surface area of a structure and diagnostic coating / Trufanov E.N., Trufanov D.N.].

The essence of the method lies in the fact that they perform integrity control of conductors attached to a surface area of structures. Moreover, these conductors are two groups and are electrically isolated from each other and from the electrically conductive parts of the surface of the structure. The conductors that make up one group do not intersect, and the conductors of different groups intersect at an angle α, and any two conductors from different groups intersect at no more than one point. With mechanical damage to the surface of the structure, electrical conductors mounted on the surface break. The specified gap is determined by the absence of electric current in the conductor when connecting its ends to a power source. The place (or places) of surface damage is determined using the wiring diagram of the structure according to the numbers of torn conductors as the set of intersection points of these conductors.

A device for diagnosing damage to the surface of structures contains electrical conductors attached to a portion of the surface of the structure. Moreover, these conductors are two groups and are electrically isolated from each other and from the electrically conductive parts of the surface of the structure. The conductors that make up one group do not intersect, and the conductors of different groups intersect at an angle α, and any two conductors from different groups intersect at no more than one point. The conductors of different groups are mainly made intersecting at an angle α = 90 °, while the conductors in each group are placed at a constant distance h from each other, equal for both groups.

The signs of the prototype, coinciding with the essential features of the claimed invention, are the electrical conductors of the first group and the electrical conductors of the second group, isolated from each other, from the material of the object and the environment, and the conductors of one group do not intersect, the conductors of the first group intersect with each conductor of the second group in one point at an angle α, mainly equal to 90 °, the conductors of one group are separated from each other by a distance h equal for both groups

The signs of the prototype, which coincide with the essential features of the proposed method, are registration of the occurrence and determination of the localization of cracks, including the integrity control of electrical conductors fixed on a section of the surface of the structure, by including the conductors of both groups in the electrical circuit and determining lines with resistance greater than a given value.

The reasons hindering the achievement of the technical result is the low accuracy of determining the location of the defect due to the lack of electrical connection between the conductors of the first group and the conductors of the second group.

The objective of the invention is to increase the accuracy of determining the location of a defect on the surface of the structure.

The technical result is achieved due to the fact that open-type two-electrode triacs are introduced into the device, located at the intersection of the electrical conductors of the first group and the electrical conductors of the second group and connected by the first electrodes to the electrical conductors of the first group, and the second electrodes to the electrical conductors of the second group, and the layers thin film dielectric, arranged in such a way that the thin film conductors are located between two layers of thin film dielectric.

The technical result is achieved due to the fact that in the method the detected defective conductors are checked segment by segment, for which a tripping voltage of the triacs is applied to the electrode of the thin-film conductor and, sequentially, to all the electrodes of the wires crossing it, and the current in the circuit is determined, while the current value is less than the specified the rupture of a thin-film conductor in this segment.

To achieve the desired technical result, a distributed crack sensor consisting of electrical conductors of the first group and electrical conductors of the second group, isolated from each other, from the material of the object and the environment, while the conductors of one group do not intersect, the conductors of the first group intersect with each conductor of the second group at one point at an angle α, predominantly equal to 90 °, the conductors of one group are separated from each other by a distance h equal to both groups, open-type two-electron are introduced one triacs located at the intersection of the electrical conductors of the first group and the electrical conductors of the second group and connected by the first electrodes to the electrical conductors of the first group, and the second electrodes to the electrical conductors of the second group, the electrical conductors being thin-film and thin-film dielectric layers arranged in this way that thin-film conductors are located between two layers of thin-film dielectric.

To achieve the desired technical result, a method for detecting the occurrence and determining the localization of cracks, including monitoring the integrity of electrical conductors fixed on a section of the surface of the structure, by including conductors of both groups in an electrical circuit and determining conductors having a resistance greater than a given value, is supplemented by the fact that the detected defective conductors checked segmentwise, for which the intersecting electrodes of the thin-film conductor and, sequentially, across all electrodes x of its conductors supply the tripping voltage of the triacs and determine the current in the circuit, while the current value is less than the specified value indicates a rupture of the thin-film conductor in this segment.

Comparing the proposed device and method with the prototype, we see that it contains new features, that is, meets the criterion of novelty. Carrying out a comparison with analogs, we conclude that the proposed device and method meet the criterion of "significant differences", since no new features are revealed in the analogues.

Figure 1 shows a section of the proposed distributed sensor cracks, figure 2 shows its topology, figure 3 shows its electrical circuit.

The distributed crack sensor consists of thin-film conductors of the first 1 and second 2 groups, mounted on the surface of the monitoring object by means of a thin dielectric film 3, electrically isolated from each other by a thin-film dielectric 4 and protected from the external environment by a thin-film dielectric 5, each conductor of the first group being electrically connected to each conductor of the second group through triac 6.

The device operates as follows.

When monitoring the object of study, a voltage is applied to the electrodes of thin-film conductors 1 fixed to the surface of the object to be monitored by means of a thin dielectric film 3, electrically isolated from the thin-film lines 2 by dielectric 4, and the current values are read. Next, a voltage is applied to the electrodes of the thin-film conductors 2, electrically isolated from the thin-film lines 1 by the dielectric 4 and protected from the external environment by the film 5, the current values are read. The application of the unlock voltage on conductors 1 and 2 unlocks the triac 6, which is located at the intersection of these lines.

The method is as follows.

The resistance of conductors 1, mounted on the surface of the monitoring object by means of a thin dielectric film 3, is measured electrically isolated from thin-film lines 2 by an insulator 4, the conductors 1 are determined, the resistance of which is greater than the critical value, then the resistances of conductors 2, electrically isolated from thin-film lines 1 by an insulator 4 and protected from the environment by a film 5, conductors 2 are determined whose resistance is greater than the critical value. Next, the detected defective conductors 1 are checked step by step, for which the unlocking voltage of the triacs 6 in the corresponding nodes is supplied to the detected defective conductors 1 and alternately to all conductors 2 and the current in the circuit is measured. Thus, in turn, all segments of the defective conductor are included in the circuit, the current in the circuit is measured, and segments in which the current is less than a certain set value are considered damaged. In the event that the segment is damaged and the current in the circuit is less than the critical value, the procedure is repeated, and the voltage to the detected defective conductor 1 is supplied from the opposite side and the search order of the conductors 2 is changed to the opposite. Thus, segments, the inclusion of which in the circuit leads to a decrease in current below a critical value, indicates the boundaries of the defective region. Next, the detected defective conductors 2 are checked step by step, for which the unlocking voltage of the triacs 6 in the corresponding nodes is supplied to the detected defective conductor 2 and alternately to all conductors 1 and the current in the circuit is measured. Thus, in turn, all segments of the defective conductor are included in the circuit, the current in the circuit is measured, and segments in which the current is less than a certain set value are considered damaged. In the event that the segment is damaged and the current in the circuit is less than the critical value, the procedure is repeated, and the voltage to the detected defective conductor 2 is supplied from the opposite side and the search order of conductors 1 is changed to the opposite. Thus, segments, the inclusion of which in the circuit leads to a decrease in current below a critical value, indicates the boundaries of the defective region.

Thus, the proposed device and method are a method for detecting the occurrence and determining the localization of cracks and a device for its implementation, allowing to determine the presence and localization of a defect (crack) on the surface of the diagnosed object.

The introduction of triacs to create a controlled electrical connection between thin-film conductors of the first and second groups allows to increase the accuracy of determining the localization of a defect in comparison with analogues.

Claims (2)

1. A distributed crack sensor, consisting of electrical conductors of the first group and electrical conductors of the second group, isolated from each other, from the material of the object and the environment, and the conductors of one group do not intersect, the conductors of the first group intersect with each conductor of the second group at one point under angle α, predominantly equal to 90 °, the conductors of one group are spaced from each other at a distance h equal for both groups, characterized in that open-type two-electrode triacs are introduced into it, located located at the intersection of the electrical conductors of the first group and the electrical conductors of the second group and connected by the first electrodes to the electrical conductors of the first group, and the second electrodes to the electrical conductors of the second group, the electrical conductors being thin-film and thin-film dielectric layers arranged so that the thin-film conductors are between two layers of thin-film dielectric. 2. A method for detecting the occurrence and determining the localization of cracks, including monitoring the integrity of electrical conductors fixed on a portion of the surface of the structure, by including conductors of both groups in the electrical circuit and determining conductors having a resistance greater than a specified value, characterized in that the detected defective conductors are checked segmentwise, why, on the electrode of the thin-film conductor and, sequentially, on all the electrodes of the conductors crossing it, a release voltage with imistors and determine the current in the circuit, while the value of the current less than the specified indicates a rupture of the thin-film conductor in this segment.

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