RU2293313C1 - Method for controlling area of metallic cross-section of steel rope and device for realization of said method - Google Patents

Abstract

FIELD: technology for determining area of cross-section of steel rope.

SUBSTANCE: in accordance to metal, steel rope is longitudinally magnetized by means of constant magnets and magnetic duct to saturation state, parameters of magnetic stream are measured in two symmetrically positioned points, and for determining change of transverse area results are added, while parameters of section of magnetization flow are measured between similar and symmetrically positioned parts of magnetic duct, after that on basis of performed calibration of known indications of magneto-sensitive sensors, appropriate for loss of cross-section of steel rope of 100 and 0%, control over loss of metallic cross-section of steel rope is performed.

EFFECT: increased precision of control over area of transverse metallic cross-section of steel rope.

2 cl, 1 dwg

Description

The invention relates to the field of non-destructive testing of ropes made of steel ferromagnetic wire.

The prior art in the field of non-destructive magnetic control of such objects can be represented by the following known solutions.

A known method of non-destructive testing of the cross-sectional area of extended ferromagnetic objects (RU 2204129 C2, RF, IPC 7 G 01 N 27/82), which consists in the fact that the section of the controlled rope is longitudinally magnetized to a state close to saturation, using a magnetizing node with poles (magnetic core and permanent magnets), facing the axis of the controlled object, and in the interpolar space near the surface of the rope measure the magnetic induction. The measurement is carried out in a pair of points lying on a line parallel to the axis of the controlled object, the signals about the measurement results at these points are added up and thus receive information about the cross section of the controlled object.

Its disadvantages include the low accuracy of measuring the loss of the cross section of the control object, due to the fact that the measurement of the loss of the cross section is carried out by summing them, and if there is a local defect, a change in the cross section of the control object that does not correspond to the true one will be recorded due to the influence of the scattering field arising in region of a local defect during saturation of the material of the steel rope during its longitudinal magnetization and leading to distortion of information about the actual loss of the cross section.

There is also a method of non-destructive testing of the cross-sectional area of steel wire ropes (DE 19601707 A1, West Germany, IPC G 01 N 27783), which consists in the fact that the portion of the object being inspected is longitudinally magnetized to a state close to saturation using a magnetizing assembly with poles (magnetic circuit and permanent magnets) facing the controlled object. Using Hall sensors, the induction of the magnetic field under the poles of the magnetizing unit is measured at two symmetrically located points, the results of measuring the field under the poles are summarized, and based on this, the cross-sectional area is judged.

The disadvantages of the described method include the fact that the measurement of the cross-section loss is carried out by registering the signals of the Hall sensors installed under the poles of the magnetizing unit, and the magnetic induction they measure does not linearly depend on the position of the ferromagnetic object, which makes calibration difficult and therefore leads to significant measurement error of a given value.

A device is proposed for non-destructive testing of the cross-sectional area of extended ferromagnetic objects (RU 2204129 C2, RF, IPC 7 G 01 N 27/82), which contains a magnetizing unit in the form of a magnetic circuit with magnetic poles (permanent magnets) located at its ends facing the channel for passing the controlled object, the measuring unit in the form of a magnetizing unit located between the poles of the magnetic circuit and magnetically sensitive sensors that are connected to the signal processing unit are magnetically sensitive sensors. The magnetic circuit of the measuring unit is made up of three elements located along the axis of the channel for the passage of the controlled object, of which the two extreme are the same and are installed symmetrically and with a gap relative to the middle element, and the magnetically sensitive sensors of the measuring unit are installed in pairs on a line parallel to the axis of the channel existing for passage controlled object, in the gaps between the middle and extreme elements of the magnetic core of the measuring node.

The disadvantage of the described device is the high error of control of the loss of the cross section of the control object, due to the fact that the measurement of the loss of the cross section is carried out by summing them, and if there is a local defect, a change in the cross section of the control object that does not correspond to the true one will be recorded due to the influence of the scattering field arising in the region local defect during saturation of the material of the steel rope during its longitudinal magnetization and leading to distortion of information about the real loss of cross-section.

A device is known (DE 19601707 A1, Germany, IPC G 01 N 27/83), which contains a magnetizing unit in the form of a magnetic circuit with magnetic poles (permanent magnets) located at its ends, facing the channel for the passage of the controlled object, and magnetically sensitive located under the poles sensors. The outputs of the magnetosensitive sensors are connected to the sensor signal processing unit.

The disadvantages of this device include the fact that the measurement of the cross-section loss is carried out by registering the signals of the Hall sensors installed under the poles of the magnetizing unit, and the magnetic induction they measure does not linearly depend on the position of the ferromagnetic object, which makes calibration difficult and therefore leads to a significant measurement error of a given value.

The task of the technical solution is aimed at improving the accuracy of controlling the area of the transverse metal section of the steel rope.

The problem is solved by longitudinally magnetizing a section of a steel rope to a state of magnetic saturation using permanent magnets and a magnetic circuit and measuring the parameter of a part of the magnetizing flux between identical and symmetrically located parts of the magnetic circuit. The change in the magnetizing flux is proportional to the change in the transverse metal section of the steel rope. To determine the area of its transverse metal section, the measurement results are summed up at two points symmetrically located.

The claimed method can be implemented using a device for controlling the cross-sectional metal section of steel ropes, which includes permanent magnets, a magnetic circuit for creating and supplying magnetic flux to the steel rope. The latter consists of two parts located symmetrically, installed with a gap, which, together with the grooves located on the end surfaces facing the gap, serves to install magnetically sensitive sensors and allows to obtain a linear distribution of magnetic flux through them. The presence of the grooves makes it possible to weaken the influence of the air gap on the magnetic flux that magnetizes the steel rope. The outputs of the magnetosensitive sensors are connected to recording equipment, which includes blocks for normalizing signals, processing and displaying the results.

The drawing shows a General view of the device that implements the proposed method.

A device for controlling the transverse metal area of a steel rope 1 includes permanent magnets 2, a magnetic circuit 3 for creating and supplying magnetic flux 4 to the steel rope 1. The latter consists of two parts located symmetrically, installed with a gap 5, which together with the grooves 6, located on the end surfaces facing the gap 5, is used to install magnetically sensitive sensors 7 and allows you to get a linear distribution of magnetic flux through them. The presence of the grooves 6 makes it possible to reduce the influence of the air gap 5 on the magnetic flux 4, which magnetizes the steel rope 1. The outputs of the magnetosensitive sensors 7 are connected to recording equipment 8, which includes blocks for normalizing signals, processing and displaying the results.

The material of the section of the steel cable 1 is longitudinally magnetized to the state of magnetic saturation with the help of permanent magnets 2, creating a magnetic flux 4, and a magnetic circuit 3, which consists of two parts arranged symmetrically, and installed with a gap 5. On the surfaces of the parts of the magnetic circuit 3, facing the gap 5, grooves 6 are made for installing magnetosensitive sensors 7, the outputs of which are connected to recording equipment 8, where the signals from magnetosensitive sensors 7 enter the signal rationing unit alov, whose readings are transmitted to the processing unit and display the result.

The preparation of the device for controlling the transverse metal section is carried out in two stages.

At the first, a measurement of the magnetic field induction without a steel rope is carried out and the obtained value is fixed by registering the point "section loss - 100%". The next step is to install a steel rope with a nominal cross section in the device, and the readings of the magnetically sensitive sensors are recorded in the recording equipment.

As a result of the calibration, the readings of magnetosensitive sensors are known, corresponding to a loss in the cross section of the steel rope of 100 and 0%, which allows monitoring the loss of the metal cross section of the steel rope.

When monitoring the state of the transverse metal section of steel ropes, the device moves relative to it, and measures the loss of the section of the steel rope along its length. Length measurements are synchronized using a length sensor, technical solutions for which are widely known and therefore not shown.

The proposed technical solution allows to increase the accuracy and reliability of the control of the transverse metal section and thereby increase the safety of operation of steel ropes.

Claims (2)

1. A method for determining the cross-sectional area of a metal wire rope, which consists in the longitudinal magnetization of the steel wire using permanent magnets and a magnetic circuit to a saturation state, measuring the magnetic flux at two symmetrically located points, and to determine the change in the transverse area, the results are summarized, characterized in that measure the parameters of the part of the magnetizing flux between the same and symmetrically located parts of the magnetic circuit, after which the potassium Along with the known readings of magnetosensitive sensors corresponding to the loss of the steel rope section of 100 and 0%, the loss of the metal section of the steel rope is monitored. 2. A device for controlling the transverse metal area of a steel rope, consisting of permanent magnets, a magnetic circuit, magnetosensitive sensors connected to a recording apparatus, which includes blocks for normalizing signals, processing and displaying results, characterized in that the magnetic circuit consists of two identical and symmetrically located parts that are installed with a gap, and on the end surfaces of the parts of the magnetic circuit facing it, grooves are made in which the magneto ity of sensors.