RU2802689C1 - Method for the production of working bodies of soil-cultivating implements with a cutting part - Google Patents

Abstract

FIELD: mechanical engineering; metallurgy; agricultural production.

SUBSTANCE: method for production of cast-iron working bodies of soil-cultivating implements using heat treatment. The method includes smelting, alloying and modifying cast iron, obtaining a casting in a sand, metal or ceramic mold, removing the casting from the mold at a given temperature, moving it into a liquid bath with a given temperature, characterized in that the casting is made from cast iron having the following chemical composition, %: C 3.2-3.3, Si 1.8-2.0, Mn 0.9-1.0, Ni 2.8-3.0, Mo 1.6-1.7, Cr 0.9- 1.1, Cu 1.0-1.2, Mg 0.12-0.14, Co 0.1-0.15, Ba 0.04-0.06, S≤ 0.08, R≤ 0.08, Fe - the rest, removed from the mold at a temperature of 950-1020° C and transferred to a bath with water at a temperature of 20° C, moreover, heat treatment is carried out by five cycles of immersion and extraction of the cutting part of the working body, and in the first cycle the cutting part is immersed in water and held for 3.5 seconds, then removed and kept in air for 2.5 seconds, in the second cycle it is immersed in water and held for 3.0 seconds, then removed and held in air for 3.0 seconds, in the third cycle immersed in water and held for 2.0 seconds, then removed and held in air for 5.5 seconds, in the fourth cycle immersed in water and held for 2.0 seconds, then removed and held in air for 12.5 seconds, in the fifth cycle immersed in water and held for 1.0 seconds, then removed and held in air until completely cooled, and in the first cycle the cutting part is immersed in water by 50%, in the second cycle the cutting part is immersed in water by 85%, and in the third and subsequent cycles the cutting part is immersed in water by 100%, while the values of the minimum section of the working body are in the range of 27-32 mm.

EFFECT: increased hardness and wear resistance of working bodies, zonal distribution of metallographic structures in functional zones.

1 cl, 1 dwg, 1 tbl

Description

The invention relates to the fields of mechanical engineering, metallurgy and agricultural production, in particular to a method for increasing the wear resistance of cast iron working bodies of soil-cultivating machines using heat treatment.

One of the main problems that currently arise during soil cultivation is the low service life of the working parts of soil-cultivating machines. To increase the service life, various options for hardening technologies and obtaining wear-resistant structures and their combinations are used.

There is a known method for producing wear-resistant structures in the cutting edge of a plow share, which includes making a sand-clay mold, installing refrigerators in the mold, pouring cast iron into the mold and subsequent cooling of the crystallizing metal, while installing steel refrigerators with a volume of 1.5⋅10 ^-8 m ³ per square millimeter of casting surface to be bleached, cast iron with a carbon content of 3.3-3.6%, silicon 1.27-1.59%, manganese 0.4-0.7%, magnesium 0.4-0.6% and sulfur ≤ 0.02% is poured into a damp sand-clay mold at a temperature of 1360-1430°C, and the cutting edge of the plow share is whitened to a depth of 2-3 mm (RF Patent for invention No. 2677326, published 01/16/2019).

There is a known method for producing wear-resistant structures in the working body of a chisel plow. (Motorin V.A., Conceptual basis for the use of high-carbon alloys in technologies for strengthening the working bodies of soil-cultivating machines, Dissertation for the degree of Doctor of Technical Sciences, Federal State Budgetary Educational Institution of Higher Education "Volgograd State Agrarian University", 2021).

There is a known method of electrocontact thermal hardening of the blade of a soil-cultivating implement made of high-strength cast iron VCh50 with a thickness of at least 7 mm, which includes heating the surface of the back side of the blade of a soil-cultivating implement with an electric arc of reverse polarity by moving the electrode along a curved path formed by linear movement parallel to the sharp edge of the blade of the soil-cultivating implement and rotation around a vertical axis , while the surface of the back side of the blade is heated with a tungsten electrode using direct current, while the diameter of rotation of the electrode around the vertical axis is set equal to the width of the blade, and for one revolution of the electrode around the vertical axis, the linear movement is 5 mm, and the rotation speed is set to 25 min ^-1 ( RF patent for invention No. 2678723, published 01/31/2019).

There is a known method of strengthening the blade of the working body of a soil-cultivating tool made of high-strength cast iron, which includes heating the surface of the back side of the blade of the soil-cultivating tool with an electric arc of reverse polarity and moving the electrode, which is carried out along a curved path formed by linear movement parallel to the sharp edge of the blade of the soil-cultivating tool and rotation around a vertical axis, with In this case, the surface of the back side of the blade is heated with a tungsten electrode connected to a direct current source, while the linear movement of the electrode along the blade per revolution around its axis is 3 mm, the rotation speed is 25 min ^-1 , and the trajectory of rotation around its axis is elliptical, larger the parameter of which corresponds to the blade width L, and the smaller one is 0.37L (RF patent for invention No. 2711391, published 01/17/2020).

There is a known method for treating the surface of the working bodies of soil-cultivating implements made of high-strength cast iron, which includes laser exposure on the surface of the tool, the formation of a spot of a laser beam with a given beam power on the sample, while the surface of the cutting parts and blades of the working tools made of high-strength cast iron HF 50 is treated with multi-channel CO ₂ - laser with a continuous operating mode, while forming a spot of a laser beam with a power of P = 2.0 kW on the sample, then processing is carried out with a radiation spot diameter in the processing zone equal to d = 9 mm, with a laser moving speed ν = 470 mm/s and laser beam spot overlap coefficient is 0.3 (RF patent for invention No. 2711389, published 01/17/2020).

There is a known method for producing a casting of the working body of a soil-cultivating machine, which includes making a sand-clay mold, installing refrigerators in the mold, pouring cast iron into the mold and subsequent cooling of the crystallizing metal, while installing steel refrigerators with a volume of 3⋅10 ^-8 per square millimeter of the bleached surface in a wedge-shaped cutting parts of the casting, the section thickness of which increases from 2-3 to 25-35 mm, and use cast iron with a carbon content of 3.3-3.6%, silicon 1.21-1.53%, manganese 0.4-0.7 %, magnesium 0.4-0.6% and sulfur ≤0.02%, which is poured into a wet sand-clay mold at a temperature of 1360...1430°C (RF patent for invention No. 2649190, published 03/30/2018).

There is a known method of strengthening the blades of the working bodies of soil-cultivating implements made of high-strength cast iron, which includes heating the surface of the back side of the blade with an electric arc of reverse polarity using an electrode by moving it along a curved path formed by linear movement parallel to the sharp edge of the blade and rotation around a vertical axis, while heating the surface of the back the sides of the blade are carried out with a tungsten electrode with direct current, while the diameter of rotation of the electrode around the vertical axis is set equal to the width of the blade, and for one revolution of the electrode around the vertical axis, the linear movement is 3 mm, and the rotation frequency co is determined by the dependence ω=k⋅30 min ^-1 , where k=1.5 with a blade thickness of 2.0≤δ≤3.0 mm, k=1.0 with a blade thickness of 3.1≤δ≤5.0 mm, k=0.8 with a blade thickness of 5, 1≤δ≤7.0 mm (RF patent for invention No. 2679673, published 02/12/2019).

There is a known method of laser thermal hardening, which includes laser exposure on the surface of a tool, while forming a spot of a laser beam with a certain beam power, while treating the surface of the cutting parts and blades of the working parts of the tool made of high-strength cast iron HF50 with a multi-channel CO ₂ laser with continuous operation, forming a spot laser beam with a beam power of P = 1.8 kW, while the diameter of the laser beam spot in the processing area is formed equal to d = 9 mm, processed at a moving speed of ν = 450 mm/s and a laser beam spot overlap coefficient of 0.3 (Patent for invention of the Russian Federation No. 2700903, published 09/23/2019).

There is a known method of heat treatment of cutting tools made of high-strength cast iron for soil development, including laser exposure on the surface of the tool, while forming a spot of a laser beam with a certain beam power, while treating the surface of the cutting parts and blades of the working parts of the cutting tool made of high-strength cast iron HF50 with multi-channel CO ₂ - laser with a continuous operating mode, form a laser beam spot with a beam power of P = 2.1 kW, while the diameter of the laser beam spot in the processing area is formed equal to d = 9 mm, processed with a moving speed ν = 480 mm/s and a spot overlap coefficient laser beam 0.3 (RF patent for invention No. 2700900, published 09/23/2019).

The disadvantages of these methods include the fact that heat treatment is carried out only for cast iron; a highly labor-intensive technological process is used.

There is a known method of hardening the cutting part of the working parts, including the use of an arc discharge plasma of reverse polarity between the electrode and the surface being hardened with the electrode moving along the hardened surface with a pulsating arc, while the cutting part of the working parts made of high-strength cast iron HF50 is strengthened, a tungsten electrode is used as an electrode, which carries out axial longitudinal vibrations with a frequency of 4-8 Hz and moves along the hardened surface at a speed of 0.4-1.5 cm/s, while the time of each contact of the tungsten electrode with the hardened surface is 0.06-0.07 s (Patent for invention of the Russian Federation No. 2717443, published 03/23/2020).

The disadvantages of this method include the fact that heat treatment is carried out only for high-grade cast iron; a highly labor-intensive technological process is used.

There is a known method of electrocontact thermal hardening of the cutting part of the working parts, including the use of an arc discharge plasma of reverse polarity between the electrodes of the surface being hardened with the movement of the electrode along the hardened surface by a pulsating arc, while the cutting part of the working parts is strengthened, made of high-strength cast iron HF50, and a tungsten electrode is used as the electrode , which carries out axial longitudinal vibrations with a frequency of 3-6 Hz and which is moved along the surface being hardened at a speed of 0.3-1.0 cm/s, while the time of each contact of the tungsten electrode with the surface being hardened is 0.15 s (Patent for the invention RF No. 2718522, published 04/08/2020).

The disadvantages of this method include the fact that heat treatment is carried out only for high-grade cast iron; a highly labor-intensive technological process is used.

There is a known method of strengthening the cutting part of the working parts of tools for the development of soils, including hardening with a pulsating arc using an arc discharge plasma of reverse polarity between the electrodes of the surface being strengthened and moving the electrode along the hardened surface, while strengthening the cutting part of the working parts made of high-strength cast iron HF 60, containing wt.%: C 3.5, Si 2.8, Mn 0.5, Ni 0.4, S 0.015, P 0.05, Cr 0.15, Cu 0.3, Fe - the rest, while serving as an electrode a tungsten electrode is used, which carries out axial longitudinal vibrations with a frequency of 3-5 Hz, while the electrode is moved along the surface to be hardened at a speed of 0.4-1.5 cm/s, and the time of each contact of the tungsten electrode with the surface to be hardened is set to 0.1- 0.13 s (RF patent for invention No. 2722959, published 06/05/2020).

The disadvantages of this method include the fact that heat treatment is carried out only for high-grade cast iron and a highly labor-intensive technological process is used.

There is a known method of thermal hardening of the cutting part of the working parts, including the use of an arc discharge plasma of reverse polarity between the electrode and the surface being hardened with the electrode moving along the hardened surface by a pulsating arc, while the cutting part of the working parts made of high-strength cast iron HF50 is strengthened, and a tungsten electrode is used as an electrode , which carries out axial longitudinal vibrations with a frequency of 4-8 Hz and which is moved along the surface being hardened at a speed of 0.3-1.0 cm/s, while the time of each contact of the tungsten electrode with the surface being hardened is 0.1 s (Patent for the invention RF No. 2722958, published 06/05/2020).

The disadvantages of this method include its narrow focus and high labor intensity of the technological process.

There is a known method of hardening the blades of the working bodies of tools for the development of soils, including the use of an arc discharge plasma of reverse polarity between the electrodes of the surface being hardened with the movement of the electrode along the hardened surface, while the hardening is carried out with a pulsating arc, while the cutting part of the blades of the working bodies made of high-strength cast iron is hardened HF60 of the following composition, wt. %: C - 3.4, Si - 2.7, Mn - 0.7, Ni - 0.2, S - 0.015, P - 0.05, Cr - 0.1, Cu - 0.2, Fe - the rest, using a tungsten electrode, involves axial longitudinal vibrations of the electrode with a frequency of 3-5 Hz and its movement along the surface being hardened at a speed of 0.4-1.5 cm/s, and the time of each contact of the tungsten electrode with the surface being hardened is 0 .08-0.09 s (RF patent for invention No. 2726051, published 07/08/2020).

The disadvantages of this method include its narrow focus and high labor intensity of the technological process.

There is a known method of hardening the cutting part of the working bodies, including the use of an arc discharge plasma of reverse polarity between the electrode and the surface to be hardened with the electrode moving along the hardened surface by a pulsating arc, while the cutting part of the working bodies made of high-strength cast iron HF 60 of the following composition,%, is strengthened: C - 3.3, Si - 2.6, Mn - 0.5, Ni - 0.3, S - 0.015, P - 0.05, Cr - 0.1, Cu - 0.2, Fe rest, as an electrode a tungsten electrode is used, which carries out axial longitudinal vibrations with a frequency of 3-5 Hz and moves along the surface being hardened at a speed of 0.4-1.5 cm/s, while the time of each contact of the tungsten electrode with the surface being hardened is 0.06-0, 07 s (RF patent for invention No. 2733879, published 10/07/2020).

The disadvantages of this method include its narrow focus and high labor intensity of the technological process.

There is a known method of hardening the blades of working bodies, including the use of arc discharge plasma of reverse polarity between the electrodes of the hardened surface of the blade with the movement of the electrode along the hardened surface by a pulsating arc, while the blades of working bodies made of high-strength cast iron HF50 are strengthened, and a tungsten electrode is used as an electrode, which carries out axial longitudinal vibrations with a frequency of 4-8 Hz and which is moved along the hardened surface at a speed of 0.4-1.5 cm/s, while the time of each contact of the tungsten electrode with the hardened surface is 0.08 s (RF Patent for Invention No. 2718521, published 04/08/2020).

The disadvantages of this method include the generation of internal stresses in the strengthened layer due to the peculiarities of the technological process.

The closest technical solution, chosen as a prototype, is a method for producing a workpiece from high-strength cast iron with nodular graphite with a different structure of the metal matrix in a cast state, including smelting, alloying and modifying cast iron, obtaining a casting in a sand, metal or ceramic mold, extracting it from molds at a given temperature, moving into a liquid bath with a given temperature, holding at this temperature and subsequent cooling in air, while the castings are removed from the mold at 900-1000 ° C and quickly moved into a liquid bath at a temperature determined by the required structure of the metal matrix, kept in the bath for a certain time, depending on the configuration of the workpiece and the required type of metal matrix structure, while by changing the temperature of the liquid bath, a wide range of metal matrix structures can be obtained, each of which corresponds to the recommended temperature of the quenching medium: ferrite - 750-850 ° C; pearlite - 650-740°C; sorbitol - 550-640°C; troostite - 450-540°C; upper bainite - 350-440°C; lower bainite - 290-340°C. (RF patent for invention No. 2196835, published 01/20/2003).

The disadvantages of this method are the use of heat treatment using salt baths, which increases the cost and does not provide an environmental component of the technological process.

The objective of the invention is to increase the wear resistance of cast iron working bodies of soil-cultivating machines.

The technical result of the invention is the zonal distribution of metallographic structures among the functional zones of the working bodies of soil-cultivating machines in accordance with the type of prevailing loads due to thermal cyclic hardening.

The technical result is achieved by a method for the production of working bodies of soil-cultivating machines with a cutting part, including smelting, alloying and modifying cast iron, obtaining it in a sand, metal or ceramic form, removing the casting from the mold at a given temperature, moving it into a liquid bath at a given temperature, while castings from cast iron containing,%: C 3.2-3.3, Si 1.8-2.0, Mn 0.9-1.0, Ni 2.8-3.0, Mo 1.6-1.7 , Cr 0.9-1.1, Cu 1.0-1.2, Mg 0.12-0.14, Co 0.1-0.15; Va 0.04-0.06; S≤0.08, P≤0.08; Fe - the rest, is removed from the mold at a temperature of 950-1020 ° C and moved into a bath of water with a temperature of 20 ° C, and the heat treatment is carried out by five cycles of immersion and removal of the cutting part of the working element, and in the first cycle the cutting part is immersed in water and kept for 3.5 seconds, then removed and kept in air for 2.5 seconds, in the second cycle immersed in water and kept for 3.0 seconds, then removed and kept in air for 3.0 seconds, in the third cycle immersed in water and kept for 2.0 seconds, then removed and kept in air for 5.5 seconds, in the fourth cycle immersed in water and kept for 2.0 seconds, then removed and kept in air for 12.5 seconds, in the fifth cycle immersed in water and held for 1.0 seconds, then removed and kept in air until completely cooled, and in the first cycle the cutting part is immersed in water by 50%, in the second cycle the cutting part is immersed in water by 85%, and in the third and subsequent cycles the cutting part is immersed part into the water by 100%, while the values of the minimum cross-section of the working body are in the range of 27-32 mm.

Depending on the functional purpose of the product zones, they perceive different external loads: the nose part perceives frontal impact loads caused by the process of interaction with the abrasive; the transition zone of the product is loaded with dynamic bending moments; the fastening zone is a rigid embedment subject to bond reactions.

The distribution of hardness over zones of various functional purposes is possible due to the following structures: in the front cutting part a bainite structure is obtained, in the transition zone - a pearlite structure, in the fastening part of the working bodies - a ferrite-pearlite metallographic structure, indicated in the figure, which shows the distribution of metallographic structures in cast iron working body of tillage machines according to functional zones, where 1 - bainite; 2 - transition zone, perlite; 3 - ferrite-pearlite structure.

The technology involves the following stages: the working bodies of soil-cultivating machines made of cast iron at a temperature of 950-1020°C are placed in a hardening installation, the cutting part is placed in special movable fixing frames facing the hardening liquid.

Experimental studies have confirmed sufficient heat accumulation in the main part of the working body for several self-heatings of the cutting part in the temperature range of bainite transformation from 350°C to 450°C.

In this case, the cooling rate of the main part of the working body is much lower than the critical cooling rate, therefore, in the main part, a structure consisting of pearlite with the formation of ferrite is formed. The ferrite-pearlite structure is characterized by relatively low hardness and the ability to withstand dynamic loads.

Volumetric quenching of the cutting part of the wedge-shaped working body, with sharp cooling in the quenching liquid to a temperature of 20°C, will lead to the formation of quenching concentration stresses in the martensitic structure, a significant difference in hardness values, and the formation of microcracks.

The use of thermocyclic hardening, with heating and cooling of the cutting part in the temperature range of bainitic transformation (350°C to 450°C), will make it possible to obtain structures in accordance with the required properties in functional zones with one heating, and also eliminate concentration temperature stresses in the nose part of the workpiece a body experiencing dynamic loads along with intense abrasive wear. Accordingly, the formation of a ferrite-pearlite structure in the attachment zone of the working body, and a bainitic structure in the nose part, occurs due to one volumetric heating of the cast iron workpiece and several cycles of interaction of its cutting part with the quenching liquid.

Heat treatment modes were selected based on the properties of the cooling medium, geometric parameters of the working body, physical properties of the material being processed, etc.

An example of a specific implementation.

The method for producing the working bodies of soil-cultivating machines with a cutting part involves using the temperature of the extracted castings of the working bodies for thermal cycling. Castings made of cast iron having the following chemical composition,%: C 3.2-3.3; Si 1.8-2.0; Mn 0.9-1.0; Ni 2.8-3.0; Mo 1.6-1.7; Cr 0.9-1.1; Cu 1.0-1.2; Mg 0.12-0.14; Co 0.1-0.15; Va 0.04-0.06; S≤0.08, P≤0.08; Fe - the rest.

At a temperature of 950-1020°C, the working parts are moved into a bath of water with a temperature of 20°C. Cooling is carried out by cyclic immersion and removal of the working part from the bath water to the depth of the cutting part, and in the first cycle the cutting part is immersed in water and held for 3.5 seconds, then removed and kept in air for 2.5 seconds, in the second cycle it is immersed in water and held for 3.0 seconds, then removed and kept in air for 3.0 seconds, in the third cycle immersed in water and kept for 2.0 seconds, then removed and kept in air for 5.5 seconds, in the fourth cycle immersed in water and held for 2.0 seconds, then removed and kept in air for 12.5 seconds, in the fifth cycle immersed in water and held for 1.0 seconds, then removed and kept in air until completely cooled, and in the first cycle the cutting part is immersed in water by 50%, in the second cycle the cutting part is immersed in water by 85%, and in the third and subsequent cycles the cutting part is immersed in water by 100%. Data on the cyclic heat treatment mode are given in the table.

Cyclic heat treatment modes are designed for the minimum cross-section of the working body in the range of 27-32 mm.

As a result of cyclic heat treatment in the cutting part of the working body, hardness values are in the range of 400-420 HB along its entire length and a bainite structure is observed. In the transition part of the working body, a pearlite structure with hardness values of 200-260 HB is observed. In the attachment area of the working body, metallographic analysis shows the presence of a ferrite-pearlite structure of the metal base with a hardness of 124-138 HB, with the presence of 40 to 45% ferrite.

As a result, the wear resistance of working bodies of soil-cultivating machines made of cast iron of the specified composition, subject to cyclic heat treatment for rational structuring during soil cultivation, in comparison with similar working bodies without rational structuring, increased on average by 1.2-1.25 times.

Thus, the claimed method for producing the working bodies of soil-cultivating machines with a cutting part zonally distributes metallographic structures among the functional zones of the working bodies of soil-cultivating machines in accordance with the type of prevailing loads due to thermal cyclic hardening.

Claims (1)

A method for producing working bodies of soil-cultivating machines with a cutting part, including smelting, alloying and modifying cast iron, obtaining it in a sand, metal or ceramic form, removing the casting from the mold at a given temperature, moving it into a liquid bath at a given temperature, characterized in that the castings are made of cast iron , containing,%: C 3.2-3.3, Si 1.8-2.0, Mn 0.9-1.0, Ni 2.8-3.0, Mo 1.6-1.7, Cr 0.9-1.1, Cu 1.0-1.2, Mg 0.12-0.14, Co 0.1-0.15, Va 0.04-0.06, S≤0.08 , P≤0.08, Fe - the rest, is removed from the mold at a temperature of 950-1020 ° C and moved into a bath of water at a temperature of 20 ° C, and the heat treatment is carried out by five cycles of immersion and removal of the cutting part of the working element, and in the first cycle immerse the cutting part in water and hold for 3.5 seconds, then remove and hold in air for 2.5 seconds, in the second cycle, immerse in water and hold for 3.0 seconds, then remove and hold in air for 3.0 seconds, in in the third cycle, they are immersed in water and kept for 2.0 seconds, then removed and kept in air for 5.5 seconds, in the fourth cycle, immersed in water and kept for 2.0 seconds, then removed and kept in air for 12.5 seconds, for In the fifth cycle, they are immersed in water and held for 1.0 seconds, then removed and kept in air until completely cooled, and in the first cycle, the cutting part is immersed in water by 50%, in the second cycle, the cutting part is immersed in water by 85%, and on In the third and subsequent cycles, the cutting part is 100% immersed in water, while the values of the minimum cross-section of the working body are in the range of 27-32 mm.

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