RU2731030C1 - Method of resistive non-destructive testing - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention can be used for non-destructive inspection of condition of constructions, structures, mechanisms and machines experiencing static and dynamic loads. Substance of invention consists in fact that on extended surfaces of controlled structure there applied is layer of electroactive material and layer of electrically conductive material, wherein the electroactive material used is materials from organic and inorganic substances capable of changing their resistance depending on the change in the crystal structure of the metal sample, from each local section of the electrically conductive layer coinciding with the controlled section of the structure, bends are made in the form of conductors, the second ends of the conductors are used for connection of the measuring input of the measuring instrument, wherein presence of defects of local sections of structures is established by deviation of measured value of resistance of local area from reference value of resistance of this section, wherein reference values of resistances of local sections are pre-measured for initial good condition of the controlled structure.

EFFECT: technical result is possibility of increasing sensitivity and simplifying non-destructive inspection methods.

1 cl, 1 dwg

Description

The invention relates to the field of non-destructive testing, namely to diagnostics, monitoring and forecasting of the state of structures, structures, mechanisms and machines experiencing static and dynamic loads.

There is a known ultrasonic method for measuring the mechanical characteristics of the stress-strain state of the material of structural parts, which consists in the fact that impulse vibrations are excited in the object under study, characterized by the presence of longitudinal and shear components, causing the appearance of a sequence of bursts of pulses in the signal transmitted through the object under study for each input pulse, as measured parameters, t _n is the time interval between pulses in a pack and t _p is the interval between pulses, and the values of the relative deformation e and mechanical stress a are determined by special formulas. [Patent for invention No. 2107288 C1, IPC G01N 29/00, publ. 1998 g.]

The disadvantages of this method include the need for additional impact on the object under study, which leads to the complication and rise in the cost of creating a device on this principle of action.

There is a known method of non-destructive assessment of critical changes in the technical state of the metal, including surface preparation, exposure to the prepared surface with an indenter and determination of the microhardness of the metal, characterized in that first on the prepared surface of a sample made of metal similar to the metal of the structure under study, but in its original state, in various zones act with an indenter, carrying out a series of measurements in each zone, determine the distributions of microhardness values in each of the zones, from which the minimum microhardness value is determined, which is taken as the basic minimum value for a given metal, then the microhardness is measured in the same way in the considered section of the structure under study from the same metal , according to the measurement results, the distribution of microhardness values is determined, which is compared with the obtained base minimum microhardness value, while lower microhardness values in the metal are investigated of the studied structure in comparison with the basic minimum value of microhardness indicate the presence of critical changes in the metal of the investigated zone of the structure associated with the aging process in the metal. [Patent for invention No. 2545321 C1, IPC G01N 3/42, publ. 2015]

The disadvantage of this method is the need to use an additional metal sample, which leads to the complication of research and the relativity of the results.

There is a known method of non-contact pulsed ultrasonic flaw detection, including non-contact excitation of an ultrasonic pulse in an object by a powerful volumetric pulsed electric discharge, in which the front of the ultrasonic pulse corresponds to a frequency with a wavelength less than the size of the defects and the duration of the ultrasonic pulse corresponds to the frequency of the ultrasonic wave penetrating the entire depth of the object, and registration a time-synchronized pulsed source of a system for recording ultrasonic waves, synchronized in time in the mode of reflection or transmission of light, characterized in that to excite an ultrasonic wave in an object, a powerful volumetric pulsed electric discharge in a flow of hydrogen or helium gas is used, which also fills the gap between the generator of a volumetric electric discharge and the object ... [Patent for invention No. 2635851 C2, IPC G01N 29/04, publ. 2017]

The disadvantages of this method include the need to use a powerful volumetric pulsed electric discharge and gaseous hydrogen, which limits the scope of the method, reduces its explosion safety and increases the cost.

There is a known method for diagnosing the state of a structure, according to which at least one local area of the probable occurrence of a defect is determined, a sensor is installed on this area of the structure, and according to its indications, the state of the structure is determined, characterized in that the sensor is a base on which a color indicator is applied, and as the bases use a material made of graphitized carbon fibers based on polyacrylonitrile, and as a color indicator - a liquid crystal polymer capable of changing its color depending on the change in the electrical resistance of the base, the sensor with an interference fit is fixed on the test local area covered with a curable binder until the binder is cured, and to determine the state of the local area, a current source is connected to the sensor and the stress-strain state of the diagnosed structure is determined by the experimentally determined dependence of the color of the color indicator on deformation. [Patent for invention No. 2395786 C1, IPC G01B 7/16, publ. 2010]

The disadvantages of the device include the fact that the diagnosis of deformation using color indication limits the scope of application of the method exclusively to manual use and does not imply automation of the measurement process.

As a prototype, as the closest in technical essence to the claimed invention, the selected method for diagnosing the state of the structure, described in patent for invention No. 2395800 C1, IPC G01N 27/20, publ. 2010

The prototype describes a method for monitoring local damage to structures, including connecting to the controlled structure of means for measuring electrical resistance, characterized in that an insulating layer and a layer of electrically conductive material are applied to the extended surfaces of the monitored structure, the electrically conductive layer is made in the form of sectioned patterns, from each local area of the electrically conductive layer coinciding with the controlled section of the structure, taps are made in the form of conductors, the second ends of the conductors corresponding to the local sections of the pattern of the electrically conductive layer are used to connect the measuring input of the measuring device, while the presence of damage to local sections of structures is established by the deviation of the measured value of the resistance R _{i of the} local section of an electrically conductive pattern in excess of the reference value R _{ie of the} resistance of this section, taking into account the tolerances ΔR _ie , and the reference values of the resistances of local areas are pre-measured for the initial serviceable state of the controlled structure.

The disadvantages of the device include the fact that it is necessary to apply a layer of electrically conductive material in the form of a sectioned pattern, which complicates and increases the cost of the method. In addition, this method of monitoring local damages does not imply high sensitivity, since damages are determined by breaking off a layer of electrically conductive material, which makes it impossible to detect internal defects.

Electroactive materials are known which, when in contact with a metal sample and when the crystalline state of this sample changes, change their electrical resistance when an electric current flows through them. As a result of a change in the potential barrier at the interface between the electroactive material and the metal sample, the conditions for injection of charge carriers change, which leads to a change in resistance.

The problem solved by the invention is to create a method that would have high consumer properties by converting a change in the crystalline state of a metal sample into a change in electrical resistance.

The technical result achieved by using the claimed invention consists in converting a change in the crystalline state of a metal sample into a change in electrical resistance through the use of a layer made of an electroactive material.

The problem is solved by the fact that in the known method for monitoring local damage to structures, which includes connecting to the monitored structure of means for measuring electrical resistance, characterized in that a layer of electroactive material and a layer of electrically conductive material are applied to the extended surfaces of the structure to be monitored, and the electroactive material is used materials from organic and inorganic substances capable of changing their resistance depending on the change in the crystal structure of the metal sample, from each local section of the electrically conductive layer that coincides with the controlled section of the structure, they make taps in the form of conductors, the second ends of the conductors are used to connect the measuring input of the measuring device , while the presence of defects in local sections of structures is established by the deviation of the measured resistance value of the local section from the reference resistance value ia of this section, taking into account the tolerances, and the reference values of the resistances of the local sections are preliminary measured for the initial serviceable state of the controlled structure

The above distinctive features are new in comparison with the prototype, therefore, the invention meets the criterion of "novelty".

Patent studies have shown that in the studied prior art there are no similar technical solutions, i.e. The claimed technical solution does not follow explicitly from the studied prior art, and thus meets the criterion of "inventive step".

This technical solution can be reproduced in an industrial way, therefore, it meets the criterion of "industrial applicability".

The essence of the claimed invention is illustrated in FIG. 1 and is as follows. On the investigated metal sample 1, a continuous layer of electroactive material 2 is formed, on top of which a continuous layer of electrode 3 is formed, over which a continuous protective layer 4 is formed; the electrical resistance of the electroactive material is measured by applying a potential difference between the metallic image 1 and the electrode layer 3.

An example of the implementation of the proposed resistive method of non-destructive testing. The surface of the investigated metal 1 in the area of the probable occurrence of a local defect is cleaned of contaminants and polished until a roughness of class 12 is reached. After that, this area is cleaned with an alcohol solution (or other organic solvents). Further, in this area of the metal under study, a continuous layer of electroactive material 2, for example, a polymer from the class of polyarylenephthalides, with a thickness of 5⋅10 ^-6 m is applied by the paint and varnish method. Then layer 2 is dried at a temperature of 150 ° C for 30 minutes. On top of layer 2, a continuous layer of electrode 3 is formed from electrically conductive glue with a resistance of not more than 0.01 Ohm / cm ³ using an applicator with a thickness of not more than 1⋅10 ^-4 m. Then layer 3 is dried at a temperature of 120 ° C for 40 minutes. After that, a continuous layer of protective material is formed on the surface of layer 3, for example, a protective self-adhesive film made of fluoroplastic.

Next, a potential difference between the investigated metal 1 and the electrode layer 3 of 3 V is applied. And the electrical resistance of the electroactive material 2 is measured. When the crystal structure of metal 2 changes, for example, the appearance of defects, elastic and inelastic deformation, the conditions for charge injection into the electroactive layer change. material. Because of this, his resistance changes. The degree and type of deformation is determined by the experimentally determined dependence of the resistance of an electroactive material on deformation.

Given the novelty, inventive step and industrial applicability of the proposed technical solution, the applicant believes that it can be protected by a patent for an invention.

Claims (1)

A resistive method for carrying out non-destructive testing of metal structures, characterized in that a layer of an electroactive material and a layer of an electrically conductive material are applied to the extended surfaces of the controlled structure, and materials from organic and inorganic substances that can change their resistance depending on changes in the crystal structure are used as the electroactive material metal sample, from each local section of the electrically conductive layer coinciding with the controlled section of the structure, taps are made in the form of conductors, the second ends of the conductors are used to connect the measuring input of the measuring device, while the presence of defects in local sections of structures is established by the deviation of the measured resistance value of the local section from the reference the resistance values of this section, and the reference values of the resistances of the local sections are preliminary measured for the original serviceable the state of the controlled structure.

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