RU2296317C1 - Method of determination of the current capacity for the hearth blocks - Google Patents

Abstract

FIELD: electric engineering; methods of determination of the current capacity for the hearth blocks.

SUBSTANCE: the invention is pertaining to the electrical engineering and may be used at operation of the hearth blocks being a part of the electrical current conductive unit of the cathode of the aluminum electrolyzers. The technical result of the invention is the increased accuracy of determination of the current capacity at operation of the blocks in the aluminum electrolyzers, that ensures optimization of their current consumption at operation in the conditions corresponding to their properties, and accordingly the increased service life of the aluminum electrolyzers approximately by 15 %. The main point of the offered method consists, that for determination of the current capacity for the hearth blocks of the aluminum electrolyzers and being the part of the electrically conductive unit of the cathode of the electrolyzer they first measure the specific electric resistance and the ultimate bending strength. Then additionally measure the heat stability, the specific elongation in the cryolite-alumina smelt and the real density of the carbonic material structure. Then determine the level of the defectiveness of the carbonic material structure and the quality criterion according to the offered formulas. On the base of the quality criterion determine the operational current capacity.

EFFECT: the invention ensures the increased accuracy of determination of the current capacity at operation of the blocks in the aluminum electrolyzers, optimization of their current consumption at operation in the conditions corresponding to their properties, the increased service life of the aluminum electrolyzers approximately by fifteen percent.

1 ex, 1 tbl, 1 dwg

Description

The invention relates to electrical engineering and can be used in the operation of the hearth blocks included in the conductive node of the cathode of aluminum electrolysis cells.

It is known that one of the main characteristics of electric current conductors is the permissible current strength (Koshkin NI, Shirkevich MG Handbook of elementary physics. M: Nauka, 1988, p.153). In industrial electric furnaces for the production of steel, alloys, non-ferrous metals, carbon materials are used to introduce current into the working space, which are produced in the form of graphitized electrodes (in arc steel-smelting furnaces) or carbon-graphite and graphitized hearth blocks (in aluminum electrolytic cells). Graphite electrodes and carbon-graphite and graphite hearth blocks are products of one purpose and one class of materials (Chalykh E.F. Technology and equipment of electrode and electric-coal production, M .: Metallurgy, 1972, pp. 12-16).

It is known that for electrode products, the permissible current substantially depends on the quality of carbon materials - for graphite electrodes, the permissible current is 2 times higher than for coal (ibid., Fig. 4, p. 15).

The same dependencies can be used for hearth blocks, which are products of the same purpose and one class of materials with graphitized electrodes.

A known method of determining the permissible current for graphitized electrodes, in which measure the electrical resistivity ρ _e , which determines the permissible operating current (Electrodes and nipples graphite. GOST 4426-80. 1980, table 9).

The disadvantage of this method is its lack of accuracy, due to the fact that the determination is made according to one physical quantity that does not fully characterize the current leads - specific electrical resistance.

A known method for determining the permissible current, including measuring the physical values of the reference group of electrodes, comparing the found values by finding the quality criterion, determining the permissible current from the found dependence (USSR author's certificate No. 1341563, class G 01 N 27/104, 1987).

The disadvantage of this method is its lack of accuracy, due to the fact that the determination is made by a limited number of physical quantities that do not fully characterize the current leads.

Known method for determining the allowable current (the prototype), in which the measured resistivity ρ _e electrode, mechanical bending strength σ _izg.n nipples, nipples modulus E _n, deviation limit thread diameter threaded socket T _DR, deviation limiting step in the whole make-up length T _w , find the probability of obtaining unsatisfactory results of acceptance tests according to the standard of individual indicators of flexural strength of nipples p, determine the quality criterion of electrodes p about the formula

by which the permissible operating current is determined (RF patent 2031552, CL N 05 V 7/08, 1995).

The disadvantage of this method is its lack of accuracy, due to the fact that the determination is made according to a limited number of physical quantities that do not fully characterize the current leads in industrial electric furnaces, in particular, work in aggressive environments of aluminum electrolytic cells and elevated temperatures. In addition, the hearth blocks do not contain nipple joints connecting the two blocks into one, as is the case with graphite electrodes.

At the same time, the conditions of aggressive environments, as well as elevated temperatures in aluminum electrolytic cells, have a significant impact on the life of the bogie blocks and their premature failure. Thus, an analysis of the causes of premature failure of aluminum electrolytic cells shows that among the most important factors negatively affecting the service life is the mismatch of the quality of individual units to the conditions of their operation as current leads (Ragozin L.V., Efimov A.A., Lyubushkin V.A., Sergeev V.A., Bakhtin A.A., Chernykh AE Analysis of the causes of premature failure of aluminum electrolyzers // Current trends in the development of metallurgy of light metals: Collection of scientific papers. All-Russian alum. Institute of St. Petersburg: Juventa. 2001, p. .89-97, 1 ill. Bibl. 7).

The objective of the invention is to increase the accuracy of determining the permissible current during operation of the blocks in aluminum electrolytic cells, which ensures optimization of their consumption by operating under conditions corresponding to their properties, and, accordingly, increasing the service life of aluminum electrolytic cells by approximately 15%.

The essence of the proposed method lies in the fact that in the method of determining the permissible current for the bottom blocks of aluminum electrolytic cells included in the conductive node of the cathode of the electrolyzer, in which the electrical resistivity and ultimate tensile strength are measured, they determine the value of the quality criterion by which the permissible operating current is determined , according to the claimed. Additionally, heat resistance, elongation in the cryolite-alumina melt and the actual density of the structure of the carbon material are measured, the level of defectiveness of the structure of the carbon material is found by the formula:

where: Dteor is the theoretical density of the structure of the carbon material,

Di is the actual density of the structure of the carbon material, and the value of the quality criterion is found by the formula

where: σ _mfd - flexural strength, MPa

τ - heat resistance, s,

ρ is the electrical resistivity of the blocks, μΩ · m,

ΔL is the elongation in the cryolite-alumina melt,%,

UD - the level of imperfection of the structure of the carbon material,%.

The inventive method differs from the prototype in that the measured value is the ratio of the product of the flexural strength and heat resistance to the product of electrical resistivity and elongation in the cryolite-alumina melt taking into account a correction factor that takes into account the relative deviation of the actual density of the structure of real carbon materials of the bogie blocks various brands from theoretical, by defining the indicator "level of defectiveness", and the quality criterion and finding of the inventive formula.

A comparative analysis of the features of the proposed solution and the characteristics of the analogue and prototype indicates that the solution meets the criterion of "novelty."

Improving the accuracy of the proposed method is ensured by combining in one indicator the values characterizing, along with electrical and mechanical properties, the resistance of the blocks to aggressive chemical environments of cryolite-alumina melt aluminum electrolysis cells and resistance to thermal shock (heat resistance), taking into account the correction factor, taking into account the relative deviation of the actual the density of the structure of real carbon materials hearth blocks of various grades from theoretical the definition of the indicator "level of defectiveness", which in some cases leads to chemical erosion of the hearth blocks, current leads and the formation of cracks that contribute to the destruction of the blocks and lead to failure of the entire cell.

The use of the proposed method as a measured quantity, the ratio of the product of the flexural strength and heat resistance to the product of the electrical resistivity and elongation in the cryolite-alumina melt blocks, taking into account the correction factor, taking into account the relative deviation of the actual density of the structure of real carbon materials of the hearth blocks of various grades from theoretically by introducing the indicator "level of defective structure of the carbon material", ha akterizuyuschih passage of current through the hearth blocks in aggressive environments aluminum electrolysis cells and elevated temperatures, improves the accuracy of determining the allowable current for bottom blocks.

The use in the proposed method as a measured value of the heat resistance index provides the use of one indicator instead of the elastic modulus, temperature coefficient of linear expansion, tensile strength and thermal conductivity, since these indicators limit the heat resistance of materials (Sorlier M., Oia H.A. Cathodes in aluminum electrolyzer / Transl. from the English Polyakova P.V. Krasnoyarsk: Publishing House of the Krasnoyarsk State University, Krasnoyarsk, 1997. P.264), which simplifies the proposed method.

The main trend of modern aluminum production is a significant increase in the current strength of both modernized and newly designed aluminum electrolytic cells, which leads to a corresponding increase in the requirements for the operational characteristics of the bottom blocks. These issues are of particular importance for new generations of powerful electrolyzers with a current strength of 300 kA and more. For these electrolyzers, there are cases when the magnitude of the cathode current for blooms can fluctuate almost 2 times, which requires an appropriate reliability resource for the permissible current (Arkhipov G.V., Tretyakov Y.A., Gorin D.A., Zavadyak A.V. Diagnostic complex KD-300 for monitoring the current load, temperature and deformation of the electrolyzer RA-300 // Aluminum of Siberia -2004: Collection of reports of the X international conference / Krasnoyarsk, 2004.

Comparison of the proposed solution not only with the prototype, but also with other technical solutions in this technical field did not allow to identify in them the features that distinguish the claimed solution from the prototype, which makes it possible to conclude that the criterion of "inventive step".

As the studies and analysis of statistical data showed, the new measurable “defect level of the carbon material structure” correlates with the operational stability of the hearth blocks during the passage of current in aggressive environments of aluminum electrolytic cells and elevated temperatures.

Industrial tests of hearth blocks with the characteristics given in the table in aluminum S8-BM electrolyzers for a current strength of 165 kA showed that determining the permissible current from the indicated ratio provides an increase in the life of electrolyzers by 15% by improving the accuracy of the proposed method, which optimizes the consumption of hearths blocks.

Determining the permissible current according to the claimed ratio of determining the value of the quality criterion is made according to the standardized physicomechanical parameters of the hearth blocks in accordance with TU 1913-109-021-2003 "Hearth blocks for aluminum electrolytic cells", determined during acceptance inspection of the blocks, the heat resistance is determined in accordance with the MVI 66-223-2004 "Methodology for measuring the heat resistance of carbon materials (bottom blocks, anodes, bottom and anode mass) for aluminum electrolytic cells."

Example. To determine the permissible current value for bogie blocks when used in aluminum S8-BM electrolyzers at a current strength of 165 kA for the reference groups of bogie blocks, the values of electrical resistivity, ultimate bending strength, heat resistance, elongation in cryolite-alumina melt, and the actual density of the structure are measured carbon material.

According to the results of determining the actual density, the level of imperfection of the structure of the carbon material is found as the relative deviation of the indicator of the actual density of the structure of real carbon materials from the bottom blocks of various grades from the theoretical density (2.267 g / cm ³ ) by the formula:

Then they find the value of the quality criterion of blocks according to the specified formula. Find experimentally acceptable current for the reference group. To do this, the blocks of the reference groups formed the bottom of the electrolytic cells with different current strengths and determined the maximum service life of the electrolytic cells provided by each group of blocks. The dependences of permissible values obtained experimentally during the operation of the reference groups of hearth blocks on the value of the quality criterion for these reference groups of blocks are built. The table shows the dependence of permissible currents on the value of the quality criterion.

Depending on the operating conditions (current strength of the electrolyzer), the necessary criterion for the quality of the blocks is determined by a pre-built nomogram or the allowable current of operation is determined by the criterion of quality of the blocks.

Using the proposed method in comparison with the known one allows with high accuracy to determine the permissible current during operation of the blocks in aluminum electrolytic cells, which ensures optimization of their consumption by operating under conditions corresponding to their properties, and, accordingly, increasing the service life of aluminum electrolytic cells by approximately 15%.

Table Indicators Test batches Known method The proposed method one 2 3 four 5 6 7 8 9 10 Bending Strength, MPa 13,2 7.0 14.0 12.0 9.0 11.0 10.0 8.6 9.0 10.0 Heat resistance, s 26 22 twenty 26 22 22 22 12 10 Resistivity, μOhm 40 13 fifteen eighteen fifteen thirty 25 28 38 38 Relative extension, % 0.3 0.3 0.25 0.3 0.35 0.3 0.3 0.4 0.6 Defective rate,% 4.7 7.3 7.8 4.7 12.0 8.7 10.8 13.9 16.6 Quality criterion, rel. units 0.33 ×
30 * = 9.9 44.5 57.1 49.2 49.6 19.0 26.8 20.1 6.1 3,7 Permissible current, kA 165 320 380 295 298 165 214 158 61 37 The service life of electrolyzers, months 50,4 72 75 65 67 57 56 54.8 49.0 40.7 * - the number of blocks in the S8-BM electrolyzer

Claims (1)

The method for determining the allowable current for the bogie blocks of aluminum electrolytic cells included in the conductive node of the cathode of the electrolyzer, in which the electrical resistivity and ultimate tensile strength are measured, they determine the value of the quality criterion by which the allowable operating current is determined, characterized in that they also measure heat resistance, the relative elongation in the cryolite-alumina melt and the actual density of the structure of the carbon material, find the level of imperfection of the carbon structure material-stand by the formula

where Dteor is the theoretical density of the structure of the carbon material; Di is the actual density of the structure of the carbon material, and the value of the quality criterion is found by the formula

where σ _izg - ultimate bending strength, MPa; τ - heat resistance, s; ρ is the electrical resistivity of the blocks, μΩ · m; ΔL is the elongation in the cryolite-alumina melt,%; UD - the level of imperfection of the structure of the carbon material,%.