PL191806B1 - Method of obtaining shaped workpieces - Google Patents

Abstract

The invention concerns a method of getting shaped elements by pressing, sintering and cold-compacting of powder mixtures of steel with alloy additions, being used for production of machine parts, e.g. gears, bearings and others of high surface pressure strength and wear resistance. The method is characterized in that a preformed semi-final product is treated with presintering, preferably in dissociated-ammonia atmosphere at temperature 700 - 750 DEG C, preferably 720 - 730 DEG C during 20 - 40 min, preferably 30 min, and first compacting under pressure 700 - 800 MPa, preferably 750 MPa, and then second compacting with simultaneous calibration under pressure 900 - 1000 MPa, preferably 950 MPa, then is treated with final sintering at temperature 1100 - 1200 DEG C, preferably 1120 - 1150 DEG C, during 40 - 50 min, preferably 45 min.

Description

Description of the invention

The subject of the invention is a method of obtaining shaped elements by pressing, sintering and cold densification of powder mixtures, steel with alloy additives, applicable to the production of machine parts, e.g. gears, bearings and others, with high resistance to abrasion and surface pressure.

In the known solutions, the production of structural parts from powder mixtures with alloying additives is carried out by pressing and sintering at a temperature of 1100: 1150 ° C in a protective atmosphere. Products obtained by this method are characterized by high porosity, up to 12% of the volume, and low compressive strength.

In another method, a product made of powder alloy steel is pressed twice and sintered twice at 800 ° C and 1150 ° C.

In this solution also the obtained products do not achieve the required high strength parameters.

There is also a known method of obtaining parts from powder mixtures of structural steels with alloying additives, consisting in pressing, preliminary sintering at the temperature of 800: 850 ° C, deformation of the pre-sintered semi-finished product and final sintering at the temperature of 1120: 1180 ° C in a protective atmosphere.

The parts obtained in this way have insufficient strength parameters, in particular low bending strength.

In addition, there is known a method of obtaining parts from metal powders with alloying additives, in which pressing, pre-sintering at a temperature of 650 ° C, repeated pressing and repeated sintering at a temperature of 1150 ° C are known.

The parts obtained in this way are characterized by low strength parameters, and in particular a low susceptibility to compression of the annular products under radial force.

The methods of obtaining products from powder mixtures of steel with alloying additives presented above do not specify the values of pressures that should be exerted on the shaped part, nor do they precisely determine the time in which sintering should take place, while providing a very wide temperature range.

The compaction of the powders in the closed compression die under pressure occurs as a result of the mutual displacement of the material particles and their plastic deformation. At a certain stage of compaction, the mutual displacement of the particles is stopped by their wedging together. A further increase in the density of products under the influence of the pressure force of the press can only take place due to the deformation of individual particles. The intense crushing of the pressed particles and the further increase of the pressing force are used to overcome the external friction forces at the contact between the powder material and the pressing tools. The result is a high porosity after a single pressing ranging from 15% to 20%.

A further increase in the density of the product can be obtained by increasing the plasticity of the compact, which occurs during pre-sintering at temperatures equal to the annealing temperature of the ordinary metal. The pre-sintering process at the annealing temperature increases the plasticity of the powder material, making it possible to increase the density of the product through its plastic deformation.

Plastic shaping of the pre-sintered blank, as in solid material, takes place as a result of the formation and movement of dislocations through the crystal lattice along specific surfaces and dislocation forces. The plasticity of the sintered product, and especially the density of the finished product, increases if the first sintering process eliminates the formation of such factors that inhibit the movement of dislocation, such as the formation of: hard solution, fine particles, secondary phases, etc.

Therefore, the first sintering should be performed under recrystallization annealing conditions at AcI temperature. The structure of the compacts from metal powders of structural steels is a mixture of separate components (if the matrix is iron powder with graphite additives) or alloyed ferrite (if the matrix is iron powder with alloying additives). The optimal pre-sintering temperature should be between 720 ° C and 730 ° C. At this temperature, the solubility of carbon in a-iron is about 0.03% and after sintering in the recrystallization annealing state, the product is characterized by low hardness factors due to the absence of strengthening factors such as secondary phases, particle dispersibility, etc.

It is known that the diffusive movement of iron atoms in carbon steels in the state before transformation (in structural steels, with an admixture of Cr, Mo, Ni, Cu) at 720: 730 ° C is approximately the same amount as in the g-iron compound at 1100 : 1200 ° C.

The incorrect, diffusive mobility of iron atoms in the temperature range of 720: 730 ° C leads to the formation of interaction centers during sintering of powder materials, the concentration of which is determined by the sintering time. The point of interaction can be generally defined by the positions of the atoms belonging to both powder particles, separated between the partial boundaries - the points of contact. The point of interaction defined by the above definitions is convergent with the "spatial contact grid", and its growth takes place not only as a result of the movement of the "spatial contact grid" along the border surface, but also by bringing the parameters of the "spatial contact grid" to the crystal lattice of the matrix. If dissolution of carbon and alloying elements in iron does not occur at 720-730 ° C, then by changing the sintering time at the above temperatures, the parameters of the "spatial contact mesh" can be changed within a wide range.

After a specified sintering time, the intermolecular contact points form a system of slip planes which, at ambient (room) temperature, is used just like the system of slip planes inside the grains and particles. Under the action of external pressure, sliding occurs along the intermolecular connections, which are important for the plastic deformation process. A similar model can be called the "super dislocation model" because it is based on efficient sliding over particle boundaries as a result of a particular type of "spatial mesh contact shift". This leads to an additional, significant increase in the plasticity of the sintered blanks, since it is known that the ductility of metal materials increases significantly if some additional plastic deformation mechanism is introduced into the metal plastic flow process, in addition to the sliding displacement.

Taking into account the above conditions, the method being the subject of the invention has been developed.

The essence of the invention, which is the method of obtaining shaped elements by pressing, sintering and densifying powder mixtures of steel with alloying additives, consists in the fact that the pre-shaped element is subjected to preliminary sintering, preferably in an atmosphere of dissociated ammonia at a temperature of (700: 750) ° C, preferably (720: 730) ° C, during 20:40 min, preferably 30 min, and the first densification under pressure (700: 800) MPa, preferably 750 MPa, and then the second densification with simultaneous calibration under pressure (900: 1000) MPa, preferably 950 MPa, followed by final sintering at a temperature of (1100: 1200) ° C, preferably (1120: 1150) ° C, for (40-50) min, preferably 45 min.

Due to the application of the method according to the invention, the following technical and operational effects were obtained:

- high resistance to abrasion, crushing, shearing and compression of the product obtained,

-high deformation resistance coefficient,

-density of the obtained product above 7.6 g / cm ³ ,

-2-3

- low flow index of the material, on the order of 10 ^-2 : 10 ^-3 mm

- reduction of energy consumption in production,

- can be used for products of any shape, for any purpose, especially for products with the required high strength, such as gears, bearings, etc.

The subject of the invention in an exemplary embodiment is shown in the following examples:

Example I.

A pre-shaped semi-finished product made of a steel powder mixture with alloy additives of brass, nickel, copper and others, is subjected to initial sintering in an atmosphere of dissociated ammonia at the temperature of 725 ± 5 ° C for 30 minutes and compacted at a pressure of 750 MPa. Then it is subjected to a second densification under the pressure of 950 MPa and calibration, followed by final sintering at 1130 ° C for 45 minutes.

Example II

The pre-shaped semi-finished product made of a steel powder mixture with alloy additives of brass, nickel, copper and others is subjected to initial sintering in an atmosphere of dissociated ammonia at the temperature of 740 ± 5 ° C for 25 minutes and the first densification under the pressure of 780 MPa.

PL 191 806 B1

The element prepared in this way is subjected to the second densification under the pressure of 980 MPa and calibration, and then finally sintering at the temperature of 1180 ° C for 40 minutes.

Example III

The pre-shaped semi-finished product made of a steel powder mixture with alloy additives of brass, nickel, copper and others is subjected to initial sintering in an atmosphere of dissociated ammonia at the temperature of 710 ± 5 ° C for 35 minutes and the first densification under a pressure of 710 MPa, then subjected to the second densification under the pressure of 910 MPa and calibration, and then subjected to final sintering at 1100 ° C for 50 minutes.

The attached table shows the results of strength tests of parts made of a steel powder blend with alloying additives, made by the method according to the invention at different first sintering temperatures, compared to a reference sample made by the current method.

No p / p Composition chemical powder Way performance Temperature preliminary sintering ° C Bending strength of gear teeth ^x i kG / mm ² The ^x- factor at 720 ° C is a new standard 1 0.55-0.62% C Template 650 200.0 2 3.80-4.20% Ni New 715 360.0 3 1.80-2.20% Cu 720 370.0 1.85 4 0.30-0.50% Mo 725 370.0 5 700 280.0 6 750 300.0 7 800 280, 8 0.35-0.42% C Template 650 198.0 9 1.80-2.20% Ni New 715 350.0 10 1.80-2.20% Cu 720 356.0 1.8 11 0.30-0.50% Mo 725 356.0 12 700 270.0 13 750 300.0 14 800 275.0 15 0.55-0.62% C Template 650 178.0 16 0.80-1.00% Cr New 715 268.0 17 1.80-2.20% Ni 720 286.0 1.6 18 0.30-0.80% Mn 725 286.0 19 700 220.0 twenty 750 238.0 21 800 214.0 22 0.25-0.32% C Template 650 167.0 23 1.50-2.10% Ni New 715 238.0 24 0.30-0.50% Mo 720 259.0 1.55 25 725 259.0 26 700 222.0 27 750 235.0 28 800 230.0

PL 191 806 B1

Claims (1)

A method of obtaining shaped elements by sintering and pressing powder mixtures of steel with alloying additives, characterized in that the pre-shaped semi-finished product is subjected to pre-sintering in an atmosphere of preferably dissociated ammonia at a temperature of (700 ± 750) ° C, preferably 720: 730 ° C during 20 : 40 min, preferably 30 min and the first densification at 700: 800 MPa, preferably 750 MPa, followed by a second densification with simultaneous calibration at 900: 1000 MPa, preferably 950 MPa, followed by final sintering at 1100: 1200 ° C, preferably 1120: 1150 ° C during 40:50 min, preferably 45 min.