RU2641511C2 - Method for determining mechanical stresses in steel structures by magnetic control method - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: value of coercive force in the control point is measured at least 8 times in different directions. According to the measurement results a circular diagram of the coercive force values dependence from the orientation angle is plotted, the direction of extreme values of coercive force is determined and the direction of stresses is determined by them. The value of the coercive force is determined by the extreme values of the coercive force at the control point.

EFFECT: increased determination accuracy of the stressed state of the steel structures.

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Description

The invention relates to the field of assessing the technical condition of metal structures and can be used to determine the existing mechanical stresses in structures where the direction of action of the stresses is not known, for example, in steel supporting metal structures of the ground-based space infrastructure.

A known method of using coercive force as an indicator parameter for non-destructive testing of mechanical stresses. In this method, the KIFM-1 coercimeter is used to measure mechanical stresses in welded bodies and end caps of electric machines (material - St3) (S. A. Musikhin, V. F. Novikov, N. V. Borisenko. On the use of coercive force as indicator parameter for non-destructive testing of mechanical stresses // Defectoscopy - 1987. - No. 9. - p. 57-59).

The disadvantage of this method is the lack of information on the use of the obtained by using the samples of the dependence of the values of the coercive force on the acting stresses on real objects, i.e. about the place and direction of control at the object of study.

A known method for determining the stress state of steel structures, in which a sample of material is cut, cut from a material similar to the material of the structure, in the process of stretching measure the coercive force. The dependence of the coercive force on the applied voltage for a given material is obtained. Then, the coercive force of the metal of the structure is measured and the stress state is determined using the obtained dependence (V.F. Muzhitsky, B.E. Popov, G.Ya. Bezlyudko. Magnetic control of the stress-strain state and residual life of steel metal structures of lifting structures and vessels, working under pressure. // Defectoscopy. - 2001. - No. 1. - pp. 38-46).

The disadvantage of this method is the large error in determining the stress state due to the difference between the initial (no load) coercive force of the metal of the sample and the structure under study.

A known method of determining mechanical stresses in steel structures, in which samples are made from a material similar to the structural material, which are subjected to strain aging of various degrees, determine the anisotropy of the coercive force of the metal of the samples as the difference between the values of the coercive force, measured across and along the applied load, from the magnitude of the stresses in sample, stretch the samples, build the dependence of the values of the anisotropy of the coercive force on the applied stresses for the samples, approximate was obtained according straight plotted and the slope of lines of the coercive force of the sample measured along the applied load is measured coercivity metal structure along and across the action of stresses. The value of the coercive force, measured along the action of stresses, determine the angular coefficient of the line corresponding to the current state of the metal structure. The anisotropy of the coercive force is calculated, the magnitude of which determines the mechanical stresses in the steel structure (RF Patent No. 2281468, IPC G01L 1/12, G01N 27/83. Publish. 08/10/2006).

The disadvantage of this method is the lack of reliable information about the direction of the current stresses in the controlled area of the object of study, which do not always coincide with the geometric axes of the metal structure.

Closest to the claimed method is a method for determining mechanical stresses in a structure, taken by us as a prototype. In the known method, a sample is made from a material similar to the construction material, the sample is stretched, and the anisotropy of the coercive force, measured as the difference between the values of the coercive force, measured across and along the applied load, is measured, the dependence of the anisotropy of the coercive force on the magnitude of the stresses in the sample is obtained, then measured anisotropy of the coercive force of the metal of the structure and determine the magnitude of the voltage using the obtained dependence (V.L. Sviryuk, I.V. Gramotnik, A.N. Bezrukov, OV Prorovskaya. Assessment of the condition of the metal of the casings of blast furnaces and air heaters by the method of non-destructive testing. // Defectoscopy. - 2003. - No. 9. - P. 37-43).

The disadvantage of this method is the lack of reliable information about the direction of current stresses in a controlled area of the object of study. In practice, there are frequent cases in which the direction of stress is not obvious in the diagnosis of metal structures. In this method, coercive force is used as a diagnostic feature. And it is the values of the coercive force that directly depend on the orientation of the attached magnetic device relative to the voltage line during measurement. Unreasonable directions of coercive force measurements reduce the accuracy of the results obtained on the technical condition of structural metal.

The objective of the invention is to provide a method for determining mechanical stresses, in which the technical result is to increase the accuracy of determining mechanical stresses by taking into account the direction of action of mechanical stresses in the metal without the use of additional equipment.

This technical result in a method for determining mechanical stresses of steel structures, which consists in the fact that a sample is made from a material similar to the material of the structure, the sample is stretched, and the anisotropy of the coercive force, defined as the difference between the values of the coercive force, measured across and along the applied load, on the value stresses in the sample, measure the anisotropy of the coercive force of the metal of the structure, determine the magnitude of the voltage using the obtained dependence, agree According to the invention, it is achieved by first determining the actual direction of the stresses at the control point of the structure, for this measure the value of the coercive force at this control point at least 8 times in different directions, each time changing the orientation angle of the attached magnetic device by no more than 45 ° from the previous position, turning it around its axis, using the results of these measurements, build a circular diagram of the dependence of the coercive force on the orientation angle of the attached magnetic device The properties for a given point determine the directions of the extreme values of the coercive force, they determine the direction of the stresses, while the direction of the maximum values of the coercive force indicates the direction of the compression stress, and the minimum - tensile, the extreme values of the coercive force determine the values of the acting stresses at the control point structures, using them in the dependences of the values of the anisotropy of the coercive force on the acting stresses previously obtained for the sample.

The solution of this problem is based on the dependence of the coercive force on the value of the crystal lattice parameter. Of course, many factors influence the value of the coercive force, as a complex characteristic of the metal structure, such as: the level of internal microstresses, grain boundary thickness, grain size, the presence of non-ferromagnetic inclusions, the presence of various metal phases, etc. But in the case under consideration, the most a significant factor is the change in the distance between the nodes (atoms) of the crystal lattice. So, with an increase in this distance, the influence of the magnetic moment of one atom on the magnetic moment of the neighboring atom decreases, which leads to lower energy costs for reorienting the magnetic moment of the system, and, consequently, to a decrease in the value of the coercive force. With a decrease in the crystal lattice parameter in the process of magnetization reversal, it is necessary to overcome the strength of the exchange interaction between atoms, which will require more energy for this process and will invariably lead to an increase in the coercive force. To the greatest extent, these processes will manifest themselves along the actual stress directions in the structure.

The proposed method consists in sequentially performing the following operations:

1. Obtaining the dependence of the anisotropy of the coercive force on the acting stresses, for which:

- make a sample of a material similar to the material of the structure;

- stretch the sample and in the process of stretching measure the anisotropy of the coercive force, defined as the difference between the values of the coercive force, measured across and along the applied load;

- get the dependence of the anisotropy of the coercive force on the magnitude of the stresses in the sample.

2. Determine the actual direction of stress at the control point of the structure, for which:

- measure the value of the coercive force at the control point at least 8 times in different directions, each time changing the orientation angle of the attached magnetic device by no more than 45 ° from the previous position, turning it around its axis;

- based on the obtained values, a pie chart is built up showing the dependence of the coercive force on the orientation angle of the attached magnetic device for a given control point;

- determine the direction of the extreme values of the coercive force;

- in the directions with extreme values of the coercive force on the pie chart, the direction of stresses is determined, while the direction of the maximum values of the coercive force indicates compression stresses, and the minimum - tensile stresses.

3. Determine the values of the current stresses, for which:

- the maximum and minimum values of the coercive force are determined from the pie chart of the dependence of the values of the coercive force on the orientation angle of the attached magnetic device;

- determine the anisotropy of the coercive force using the maximum and minimum values of the coercive force;

- determine the values of the effective stresses at the control point using the anisotropy of the coercive force in the dependence of the anisotropy of the coercive force obtained on the samples on the magnitude of the stresses in the sample.

The claimed method is illustrated by drawings:

- in FIG. Figure 1 shows a pie chart of the values of the coercive force in units of A / m for the tensile region of the I-beam (profile No. 10, steel 10) under a bending load in the elastic zone of deformations (dashed line combines the points of the values of the coercive force obtained without load, solid - with load);

- in FIG. Figure 2 shows a pie chart of the values of the coercive force in A / m units for the compression region of the I-beam (profile No. 10, steel 10) under bending load in the elastic zone of deformations (the dashed line combines the points of the values of the coercive force obtained without load, the solid - with load).

Using the present invention allows more accurately determine the voltage values of the steel structure at any point, given the actual direction of stress. The determination of the stress state, for example, of ground-based space infrastructure facilities, when assessing the technical condition, makes it possible to decide on the need for their reconstruction, reinforcement or replacement, which generally increases the reliability and safety of their work.

Claims (1)

The method for determining the mechanical stresses of steel structures, which consists in the fact that a sample is made from a material similar to the construction material, the sample is stretched and the anisotropy of the coercive force, measured as the difference between the values of the coercive force, measured across and along the applied load, is measured, and the dependence of the anisotropy of the coercive forces from the magnitude of the stresses in the sample, then measure the anisotropy of the coercive force of the metal of the structure and determine the magnitude of the stress using the obtained dependence, characterized in that the value of the coercive force at the control point is measured at least 8 times in different directions, each time changing the orientation angle of the attached magnetic device by no more than 45 ° from the previous position, turning it around its axis, the results of these measurements build a pie chart of the dependence of the values of the coercive force on the orientation angle of the attached magnetic device for a given point, determine the direction of the extreme values of the coercive force, according they determine the direction of stresses, while the direction of the maximum values of the coercive force indicates the direction of the compression stresses, and the minimum indicates tension, the extreme values of the coercive force determine the values of the effective stresses at the control point, using them in the dependences of the anisotropy of the coercive force previously obtained for the samples from current stresses.

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