RU2367924C1 - Method for formation of electromagnet radiation of deformed solid body, in particular from structural material - Google Patents

Abstract

FIELD: physics, measurement.

SUBSTANCE: technical solution is related to mining. Solid body is installed on test bench between armatures of capacitance detector EMI. Solid body is deformed by application of external force with the help of loading device, in which force element is movable. EMI signal is formed in process of crack formation of deformed solid body under load. EMI signal is transformed with the help of capacitance detector EMI and registered. Deformation of solid body is carried out by means of its cutting, tearing off cut particles from it by means of shift and creating cracks and microcracks in deformed solid body. As force element of loading device they use cutting tool with longitudinal arrangement of teeth, for instance hack saw, to which forward or reciprocal motion is imparted. EMI signal is formed as sum of EMI signal created by heat electrons that flew from surfaces of cracks and microcracks produced in deformed solid body in process of cut particles tearing off, and EMI signal created in process of oscillation of particles and section with positive charges that remained on surface of cracks and microcracks after fly-off of mentioned heat electrons and on the surfaces of torn-off particles.

EFFECT: simpler and cheaper method.

4 cl, 1 dwg

Description

The technical solution relates to mining and can be used for flaw detection of structural materials used in mining engineering and in mining processes, for example, for flaw detection of metal roof supports of underground mine workings.

A known method of producing electromagnetic radiation (EMP) by stretching samples of solids in the form of metal rods of a cylindrical shape (Electromagnetic effect at metallic fracture. Ashok Misra [I. Nature, vol. 254, March 13, 1975. P.133-134), according to to which the deformable metal rod is placed along an axis made in the form of a half-cylinder of a metal plate, which is used as a capacitor plate and from which side a tap is made to connect to the first input of the recorder, which is used as a storage oscilloscope, and a deformable metal rod is used as the second capacitor plate, which is connected to the second input of the recorder and ground. In this case, due to the formation of cracks and microcracks in the material of the deformable metal rod, a stream of electrons arises from the formed surfaces (crack faces), accompanied by electromagnetic radiation.

The disadvantage of this method is the need to use complex presses with significant breaking strength in the production of EMP of deformable metal rods, which complicates and increases the cost of the EMP process.

The closest in technical essence and the totality of essential features is a method for the study of EMP deformable to fracture of a solid in the form of a ring according to RF patent No. 2190203, class. G01N 3/08, E21C 39/00, G01N 27/00, publ. in BI No. 27, 2002, including installing it on a bench between the plates of a capacitive EMR sensor, deforming it with a tensile load by applying external force using a load device, including a frame and fixed and movable rods oppositely mounted on it, in which a deformable solid body, with this movable thrust, translational motion is reported, conversion using the indicated capacitive sensor that occurs during crack formation of a deformable solid body of the EMP signal and p recording is the its registration system. The external force from the load device to the deformable ring is transmitted by means of semi-cylindrical protrusions, which are equipped with movable and fixed rods and on which the deformable ring is worn. The translational motion of the movable rod is reported using a movable screw with a steering wheel mounted on the frame of the load device, and the force arising in the stationary rod at the time of rupture of the said ring is recorded using a strain gauge mounted on it. The signals of the capacitive and strain gauge sensors are recorded synchronously on the first and second channels of the registration system, respectively, and the results of the registration additionally judge the time interval between the occurrence of the EMR signal and the moment of destruction of the deformable solid.

The disadvantage of this method is the use of a press that provides breaking strength, which complicates and increases the cost of this method. Another disadvantage is the need to produce samples in the form of rings, which also complicates the method.

The technical task of the proposed solution is to simplify and reduce the cost of the method for producing electromagnetic radiation of deformable solids, in particular, from structural materials used in structures, by reducing the cost of destruction of a deformable solid and using simple means of destruction.

The stated technical problem is solved in that in the method of forming an EMP of a deformable solid, in particular, from a structural material, including installing it on a bench between the plates of a capacitive EMP sensor, deforming it by applying external force using a load device in which the power element is movable, EMP signal generation during crack formation of a deformable solid under load, EMP signal conversion using a capacitive EMP sensor and its registration, according to Solid solution pecifications deformation is effected by scoring it, tearing it from the slip incised particles and creating a deformable solid cracks and microcracks. For this purpose, a cutting tool with a longitudinal arrangement of teeth, for example, a hacksaw blade, to which a translational or reciprocal movement is reported, is used as a power element of the load device. In this case, the EMP signal is formed as the sum of the EMP signal generated by thermal electrons emitted from the surfaces of cracks and microcracks formed in the deformable solid when the cut-off particles are detached, and the EMP signal created by the oscillation of particles and sections with positive charges remaining on the surfaces of the cracks and microcracks after the departure of the mentioned thermal electrons and on the surfaces of the detached particles.

With such a combination of features, the surfaces of both formed by notching cracks and microcracks and the formed surfaces of the detached particles are included in the operation. At the moment of separation of the incised particles, in accordance with the law of conservation of momentum, vibrations of free surfaces occur (due to the recoil effect). The emitted thermal electrons and the positive charges of these oscillating surfaces will form EMP signals. The EMP signal in the form of the sum of the indicated EMP signals reaches the plates of the capacitive EMP sensor, on which opposite charges occur. A potential difference occurs between the plates of the capacitive EMR sensor, and a current arises in a closed circuit, which is amplified by a differential amplifier and fed to the input of the recording device.

The use of a cutting tool with a longitudinal arrangement of teeth as a power element of the loading device — a hacksaw blade that performs translational or reciprocal motion — makes it possible to notch and tear apart particles of a deformable solid, that is, to form new surfaces in the simplest way through which thermal electrons and positive charges are formed. This simplifies the implementation of the method. In addition, the use of a hacksaw blade eliminates the need for presses to destroy a deformable solid, which reduces the cost of its destruction.

The considered mechanism of EMP formation from the sum of various EMPs corresponds to the real composition of EMP observed in experiments.

It is advisable to carry out the specified deformation of a solid body using a cutting tool in the form of a hacksaw blade with a single-row rectilinear arrangement of teeth. A hacksaw blade with this arrangement of teeth is the simplest cutting tool.

It is advisable to carry out the specified deformation of a solid body by forming two parallel grooves, for which a cutting tool in the form of a hacksaw blade with a double-row straight tooth arrangement is used. The extreme teeth during the translational movement of such a hacksaw blade form two parallel grooves on the surface of the deformable solid, the depth of which is one hundredth or tenth of a millimeter. These grooves, firstly, create new surfaces for the release of thermal electrons, which contributes to the solution of the technical problem, and secondly, weaken a deformable solid in a narrow area between grooves. When translating or reciprocating the hacksaw blade, its teeth shift the weakened surface between the two grooves, tearing apart particles of a deformable solid. Due to this, the energy intensity of the process of shear and separation of particles decreases and the formation of new particles increases, which increases new surfaces and, accordingly, increases the intensity of the arising EMR. All this contributes to the solution of the technical task.

It is also advisable to carry out the specified deformation of a solid body using a cutting tool in the form of a hacksaw blade with a wavy arrangement of teeth. Most hacksaw blades are available with a wave-shaped arrangement of teeth. This allows you to increase the width of the cut through the gap and reduce the energy intensity of separation of particles in the process of their shift. The increase in the size of the detached particles allows to increase the area of the formed new surfaces and, accordingly, to increase the intensity of the generated EMR, which contributes to the implementation of the technical task.

The essence of the proposed technical solution is illustrated by an example of a specific implementation and a drawing, which shows a schematic diagram of a stand for implementing the method.

At the test bench, a sample of a deformable solid 1 is tested (see the drawing), which can be used as a part from a structural material taken from the structure under study. The stand contains plates 2 and 3, forming a capacitive sensor 4. In the diagram: 5 is the power element of the load device in the form of a hacksaw blade (hereinafter referred to as the hacksaw blade 5), performing translational or reciprocal motion (in a particular case, this is a hacksaw driven manually moved); 6 - particles of a deformable solid body 1 formed during the movement of a hacksaw blade 5; 7 and 8 - formed surfaces (crack faces), as well as the surface of the incisions; 9 - propagating electromagnetic wave (EMP). The plates 2 and 3 using a shielded wire 10 are connected to a recording device 11. A sample of a deformable solid 1 is mounted on a stand using supports 12 and 13.

The method of forming the EMR of a deformable solid, in particular from a structural material, is implemented as follows. A hacksaw blade 5, for example, with a two-row rectilinear longitudinal arrangement of teeth during forward movement forms cuts on the surface of the deformable solid 1: these are two parallel strips of small recesses (hundredths, tenths of a millimeter) that weaken the resistance of the sample material of the deformable solid 1. Then translational or reciprocating movement of the hacksaw blade 5, its teeth tear off particles 6 of the material sample of the deformable solid body 1 located between allelic cuts. The formed surfaces 7 and 8 (crack faces) become sources of thermal electrons. Flying into the free space of a crack, they emit electromagnetic waves 9 (EMP). Due to the emission from the surface, thermal electrons carry away part of the negative charge. As a result, the areas of free surfaces 7, 8 acquire a positive charge. If these areas with positive charges will move in space, then they will emit electromagnetic waves 9 (EMP). Since positive charges are somehow related to the formed surfaces of the deformable solid 1, the parameters of their radiation will differ from the parameters of the radiation of thermal electrons. Both electromagnetic fields will simultaneously reach the plates of the capacitive 4 EMR sensor, creating some common potential and, accordingly, a common total EMR signal.

The proposed method involves the simplest capacitive sensor 4 with a differential amplifier (not shown), which can be made in any laboratory from improvised material and simple microcircuits. As a recording device 11, either a storage oscilloscope available in laboratories or a computer with an analog-to-digital converter for input analog signals, the acquisition of which in modern laboratories is not difficult, can be used. As the power element of the load device can be used the simplest hacksaw blade 5 or file.

As a sample of a deformable solid 1, a part of any device can be used that needs to be checked for residual strength or for the durability of its components and parts, or for some other strength parameters.

If the problem arises of examining a product for its strength, durability, then it is enough to obtain the EMP of this product, examine its spectral composition and compare it with the spectral composition of the same product, but taken from a new design. In this case, with the specified equipment, the proposed method practically does not require additional costs.

Thus, the proposed method for the formation of EMR from the totality of the above characteristics and used material means allows us to solve the technical problem - the simplification and cost of obtaining EMR of deformable solids, in particular, from structural materials.

Claims (4)

1. A method of forming electromagnetic radiation (EMP) of a deformable solid, in particular, from a structural material, including installing it on a bench between the plates of a capacitive EMP sensor, deforming it by applying external force using a load device in which the power element is movable, generating a signal EMP in the process of crack formation of a deformable solid under load, transformation of the EMP signal using a capacitive EMP sensor and its registration, characterized in that the deform A solid body is carried out by cutting it, tearing off notched particles from it and creating cracks and microcracks in the deformable solid, for which purpose a cutting tool with a longitudinal arrangement of teeth, for example, a hacksaw blade, which is transmitted or reciprocated, is used as a power element of the load device - translational motion, while the EMP signal is formed as the sum of the EMP signal created by thermal electrons emitted from the surfaces of cracks and microcracks, OF DATA in a deformable solid in the separation notched particles and electromagnetic radiation signal generated at the oscillation particles and areas with positive charges remaining on the surfaces of cracks and microcracks after the emission of said electrons and heat on the surfaces of detached particles. 2. The method according to claim 1, characterized in that the deformation of the solid is carried out using a cutting tool in the form of a hacksaw blade with a single-row rectilinear arrangement of teeth. 3. The method according to claim 1, characterized in that the deformation of the solid is carried out by the formation of two parallel grooves, for which a cutting tool in the form of a hacksaw blade with a double-row straight tooth arrangement is used. 4. The method according to claim 1, characterized in that the deformation of the solid is carried out using a cutting tool in the form of a hacksaw blade with a wavy arrangement of teeth.