RU2692397C9 - Method of studying physical-chemical processes on a loaded contact - Google Patents

Abstract

FIELD: control methods.

SUBSTANCE: invention relates to control methods of physical and chemical processes causing destruction of working surface in friction pairs at ultimate loads. Prepared is a sample consisting of two plates or two coaxial pieces of pipe, materials of which correspond to materials of test contact, on one side of the sample is applied an explosive layer, on the reverse side provide contact of the sample with a solid or damping medium, loading is carried out by blasting an explosive, the sample is sawed so that the contact area is available for analysis, and necessary sample preparation is carried out to remove residues of abrasive material from the tool, zone of contact is investigated for appearance of products of mechanical-chemical processes that have passed in the loaded zone; physical and chemical processes at the boundary are determined by composition, quantity and morphology of products fixed in the contact zone.

EFFECT: possibility of establishing mechanisms of destruction of working surfaces and their spatial localization in practically significant loading conditions.

3 cl, 8 dwg, 5 tbl

Description

The invention relates to methods for monitoring physico-chemical processes that cause the destruction of the working surface in friction pairs at ultimate loads. The method can be used to study the mechanisms of wear in piston-cylinder friction pairs of internal combustion engines or pumps, as well as barrel channels of artillery weapons. When modeling the loads of the studied processes, it is carried out by detonating the explosive charge.

Known are direct methods, test methods and devices [1-6] for obtaining information on the wear of friction pairs, allowing one to select satisfactory friction pairs and to predict their survivability under optimal operating conditions. In this case, either the wear parameters or the wear products of the friction pair materials dissolved in the lubricants are controlled.

A common drawback of existing methods and methods is the study of fracture products that are contained in lubricants from the reaction zone. The main disadvantage of direct methods is the inability to study products formed directly as a result of physicochemical processes and causing destruction.

Known methods for studying surface destruction using the atomic force microscope technique [7], which showed that the cause of the onset of destruction is the physicochemical and structural changes on the surface even in the absence of visible surface deformation (mesoscopic scale). This allows [7,8] to study the process under study in the regime of ultra-low wear, which is impossible with other methods. However, these methods are not applicable to studying the causes of failure under conditions of real loads with high intensity for mechanical systems such as cylinder-piston or bore.

Known methods for studying the destruction of the surface using the technique of atomic force microscope, electron microscope with the control of characteristic x-ray radiation from the studied surface [9]. This method made it possible to establish the mechanochemical processes that occur in the contact zone of the indenter and the surface under study.

The disadvantage of this method is the delocalization of the products of mechanochemical reactions and, as a consequence, the inability to compare the wear products with the place of their occurrence and / or the physicochemical process. In addition, this method does not allow the study of the mechanism of surface wear in the presence of a technological lubricant or adsorbed fine particulate matter or aerosols.

The technical result of the proposed method is to provide the possibility of establishing mechanisms for the destruction of working surfaces and their spatial localization in practically significant loading conditions.

The aim of the invention is the selection of optimal operating conditions of the mechanisms and the choice of methods and materials that protect the working surfaces [10, 11].

The technical result is achieved by the fact that when creating the ultimate mechanical load by an explosion, a sample is first prepared, consisting of two plates or of two coaxial pipe segments, the materials of which correspond to the materials of the test contact, a layer of explosive is applied to one side of the sample, and contact is provided on the reverse side a sample with a solid or damping medium, loading is carried out by detonating an explosive, the sample is sawed so that the contact zone is accessible for examination and carry out the necessary sample preparation to remove residual abrasive material from the tool, examine the contact zone for the appearance of products of mechanochemical processes that took place in the loaded zone, judge the physicochemical processes at the boundary by the composition, quantity and morphology of products fixed in the contact zone.

In addition, the layer thickness and energy parameters of the explosive are selected so that the loading zone in physical and geometric parameters corresponds to the geometry of the real process, for example, the geometry of the contact zone of the copper belt of the cylinder with the surface of the piston or barrel.

To fix the products of mechanochemical processes during loading of the contact, one or both surfaces of the sample located in the zone of the forthcoming loading of the contact are applied with technological lubricant or adsorb fine particles or precipitate an aerosol.

Analysis of the sources (patents, copyright certificates, domestic and foreign monographs and articles) and verification of the operability of the proposed method in laboratory model experiments allow us to confirm its novelty, inventive step and industrial applicability.

An example implementation of the method:

The proposed method is implemented in laboratory conditions on the example of the study of physicochemical processes on a loaded steel-copper contact, simulating the flow of mechanochemical processes when moving a copper sealing ring on the inner surface of a steel cylinder, for example, an internal combustion engine or a bore.

During the experiment, the following technological operations were performed and the results were obtained.

1. A piece of steel pipe was prepared, the steel grade of which corresponds to the steel grade of the original cylinder.

2. A piece of copper pipe was prepared, the outer diameter of which corresponds to the inner diameter of the steel pipe, and whose length is equal to the length of the piece of steel pipe.

3. The surface treatment of both pipe sections was carried out to remove foreign impurities by known methods.

4. The surface treatment of both pipe sections for applying grease and / or aerosols by known methods was carried out.

5. A piece of copper pipe was introduced into a piece of steel to align the edges of the pieces.

6. The contact of the copper and steel pipe sections was sealed by coating with a thin layer of bitumen varnish.

7. The copper tube was filled with a damping substance, the composition (formula) of which was selected empirically in each specific study.

8. The ends of the test sample were sealed with copper plugs, the length of which exceeded their diameter from one and a half to two times.

9. The sample was surrounded by explosive, the layer thickness and energy parameters of which were chosen so that the loading zone was comparable in physical and geometric parameters with the parameters of the real process.

10. Spent explosive charge.

11. Saw the resulting sample into elements (see Fig. 1).

12. Removed mechanical impurities.

13. Investigated the steel-copper contact zone by electron microscopy and X-ray spectroscopy.

14. According to the redistribution of impurities at the phase boundary, a mechanism of physicochemical wear processes was established.

The experimental results in the form of photos and spectra are presented below.

For a “defect-free” border, the results are presented in the photo (Fig. 2) and in table 1.

Processing option: All elements analysed (Normalized). All results in atomic%.

For a “poorly defective” boundary, the results are presented in the photo (Fig. 3) and in table 2.

Processing option: All elements analysed (Normalized). All results in atomic%.

Spectra of characteristic x-ray radiation at the steel-copper boundary in the graph (Fig. 4) and photo (Fig. 5).

An example of the effect of water aerosols on the structure of the border "steel - copper" is presented in table 3 and in the photo (Fig. 6).

An example of the image of the boundary in the mode of secondary electrons is presented in table 4 and in the photo (Fig. 7). The brightness of the image is inversely proportional to the atomic number of the elements.

An example of abrasive elements, fixed at the place of occurrence as a result of physico-chemical processes at the border during loading, are presented in table 5 and in the photo (Fig. 8).

Based on the results of the analysis of experimental data, the physicochemical loading process at the steel – copper contact was investigated and the fracture mechanism was established when the copper o-ring was moved along the inner surface of a steel cylinder, for example, an internal combustion engine or a bore. It has been established that the mechanism is due to hydrodynamic phenomena occurring in the surface layers of both materials. In modern theory, such a mechanism has not yet been considered.

List of sources used

1. RU 2494368 (2012). A device for determining the wear of the barrel of an artillery weapon. The device contains sensors and a unit for measuring the velocity of the projectile, the magnitude of which judges on the "actual wear of the barrel."

2. RU 2494369 (2012). A device for determining the wear of the trunks of multi-barrel guns of artillery weapons. A device containing sensors and a unit for measuring the velocity of the projectile, characterized in that the sensors and logic elements that form the signals for the shot accounting unit are additionally introduced.

3. RU 2498266 (2012). A device for determining the wear of the barrel of an artillery weapon. The device contains two sensors and a projectile velocity measuring unit, an analog-to-digital converter, a memory unit, a transmitting device, a receiving device, an indicator of “actual barrel wear”. The device according to claim 1, characterized in that the unit for analyzing the velocity of the projectile contains several threshold devices.

4. RU 2245537 (2003). A method of controlling the degree of wear of engine parts operating in the presence of a lubricant. The method consists in the fact that during the operation of the engine, samples of the lubricant are taken and the concentrations of the elements of wear products are determined in them, characterized in that the wear of the parts is determined periodically in several places, predicting the residual life of the parts.

5. RU 2495400 (2011). A method for evaluating the frictional compatibility of friction pairs. The method consisting in tribological testing of friction pairs at various loads and determining the critical load and temperature at the time of setting, characterized in that during friction tests at critical loads, the time before the setting of friction pairs is set, based on the results obtained, the energy is estimated activation of fracture of the surface layer material and a structurally sensitive coefficient, and the calculated value of time is used as a criterion for frictional compatibility of friction pairs Meni to grasp at given operating conditions of the friction pair.

6. Mechanics and physics of processes on the surface and in contact of solids and machine parts: Interuniversity. Sat scientific tr / Ed. N.B. Demkina. Tver: TSTU, 2006.232 s. UDC 621.891

7. Derik DeVecchio, Bharat Bhushan, Use of a nanoscale Kelvin probe for detecting wear precursors, Review of scientific instruments (69), N10, 1998, p. 3618-3624

8. Dmitriev A.I., Smayain A.Yu., Popov V.L., Psakhie S.G., Multilevel modeling of friction and wear based on numerical methods of discrete mechanics and phenomenological theory / Physical Mesamechanics 11.4, 2008, from. 15-24.

9. T. Kasai, X.Y. Fu, D.A. Rigney, A.L. Zharin, Applications of a non-contacting Kelvin probe during sliding, Wear of Materials, (225-229), 1999, p. 1186-1204.

10. Torskaya E.V. Modeling the frictional interaction of bodies with coatings, dis. for the competition Doctorate in Physics and Mathematics, FGBUN IPM RAS A.Yu. Ishlinsky, Moscow, 2014.

11. Garkunov D.N. Tribotechnology (wear and tear), 4th ed., Revised. and add. - M.: Publishing House of the Moscow Artists Academy, 2001.616 p.

Claims (3)

1. A method for studying physical and chemical processes on a loaded contact, which consists in creating the ultimate mechanical load by an explosion, characterized in that a sample is prepared consisting of two plates or two coaxial pipe sections, the materials of which correspond to the materials of the tested contact, on one side of the sample a layer of explosive is applied; on the reverse side, the sample is in contact with a solid or damping medium; loading is carried out by detonating the explosive; so that the contact zone is accessible for research, and the necessary sample preparation is performed to remove the abrasive material residues from the tool, the contact zone is examined for the appearance of products of mechanochemical processes that took place in the loaded zone, and the physicochemical processes at the boundary are judged by composition , the number and morphology of products fixed in the contact zone. 2. The method according to p. 1, characterized in that the layer thickness and energy parameters of the explosive are selected so that the loading zone in physical and geometric parameters corresponds to the geometry of the real process, for example, the geometry of the contact zone of the copper belt of the cylinder with the surface of the piston or barrel. 3. The method according to PP. 1, 2, characterized in that on one or both surfaces of the sample located in the zone of the forthcoming contact loading, a technological lubricant is applied, or finely dispersed particles are adsorbed, or an aerosol is deposited.

Images