RU2203773C2 - Method of producing metal powders - Google Patents

Abstract

FIELD: powder metallurgy; production of powders of chemically active metals. SUBSTANCE: powder with particle linear sizes within 0.1-6.0 mm is produced by milling of cylindrical blank rotating round its axis parallel to milling cutter rotating axis by varying of ratio of rotational speeds blank and milling cutter, milling cutter feed rate and size of its cutting edge. In this case, ratio of blank rotational speed and cutting mill rotational speed is maintained within 1/100-1/1000. EFFECT: higher process efficiency, possible variation of geometry and sizes of powder particles and reduced fire and explosion hazards. 1 dwg, 1 ex

Description

 The proposed method relates to the field of metallurgy, and in particular to the production of metal powders, including chemically active ones, by the milling method.

 Existing methods for producing powders are divided into mechanical and physicochemical ("Technology of metals and materials science." Edited by Usova L.F. - M .: Metallurgy, 1987). Of the physicochemical methods for producing powders of chemically active metals, electrolysis of molten salts is most suitable. However, the separation of the obtained metal particles from the electrolyte, for example, by washing with water or salt solutions for metals such as calcium, magnesium and others, is often unsuitable due to their chemical activity.

 Of the mechanical methods currently used such as spraying a jet of molten metal (RF patent 2199734, bull. 15, 05/27/2000) and metal processing by cutting to produce particles, rather than drain chips.

 The disadvantage of the method of spraying the melt is the high energy consumption for heating and melting the metal, as well as the need to create a protective atmosphere for the melt.

 Various powders are also used to obtain powders by metal cutting using mills and grinders (Gert Schubert "Aufbereitung metallischer Sekundarrohstoffe", VEB Deutscher Verlag fur Grundstoffindustrie, Leipzig, 1984).

 A known method selected as the closest analogue is in which the preparation of metal powder is carried out by milling a workpiece (S. S. Kiparisov et al. Powder metallurgy. - M .: Metallurgy, 1991, p. 22). The disadvantages of this method are: high fire and explosion hazard of the process of obtaining a powder of a chemically active metal, particles of which have arbitrary linear dimensions, as well as a low yield of metal in powder.

 The high fire hazard of the process is due to the fact that this method uses high metal cutting speeds. In this case, most of the energy spent on heating the reactive metal, especially at the end of the process, when heat removal from the remainder of the ingot deep into the metal is impossible. In addition, the resulting fine particles with sizes up to 90 microns are prone to the formation of explosive dusty air mixture.

 In addition, the use of a vertical end mill in this method makes it difficult to obtain particles with predetermined linear dimensions due to different cutting and shaping patterns of chips in the peripheral and internal (with respect to the ingot) sections of the cut layer.

 With the reciprocating movement of the original ingot for its reliable fastening to the table requires at least 1/10 of its height. Therefore, the yield of metal into powder due to the large milling residue is not more than 90%.

 The technical result consists in reducing the fire and explosion hazard of the process of obtaining powders of chemically active metals having predetermined linear particle sizes, as well as increasing the yield of metal into powder.

In the proposed method for producing metal powders by milling a workpiece according to the invention, a powder with linear particle sizes in the range of 0.1-6.0 mm is obtained by milling a cylindrical workpiece rotating around an axis parallel to the axis of rotation of the mill, by changing the ratio of the speeds of rotation of the workpiece and mill the feed speed of the cutter and the size of its cutting edge, while the ratio of the workpiece rotation speeds - n _workpiece and cutter - n _cutter support in the interval n _workpiece / n _cutter = 1/100 - 1/1000.

 In order to increase the productivity of the cutting process, the length of the generatrix of the cylindrical cutter may be greater than the length of the workpiece.

 With a parallel arrangement of the rotation axes of the workpiece and the cylindrical cutter, the area of the surface to be treated increases significantly and, accordingly, the productivity of the process increases in terms of the volume of powder obtained.

 A diagram of the grinding process is presented in figure 1.

By changing the ratio of the rotation speeds of the workpiece (n _workpiece ) and the cutter (n _cutter ), as well as the feed rate (υ _feed ), the particle size of the powder is regulated in the range of 0.1-6.0 mm. The particles formed during milling have the shape shown in FIG. 2. The length of the powder particles a is determined by the ratio of the rotational speeds of the cutter and the workpiece according to the formula
a = K • (n _blanks / n _cutters ), [mm], (1)
where K is a coefficient taking into account the diameters of the cutter and the workpiece, the location and geometry of the cutters and other parameters. K, is determined empirically and can vary from 50 to 1500 [mm].

The thickness of the particles in is determined by the value of the tool feed per revolution of the workpiece (υ _feed ) according to the formula
B = υ _feed / n _workpiece [mm]. (2)
The width of the particles C is determined by the size of the cutting edge of the tool.

 Since the method is intended for the processing of chemically active metals, the production of finer powders (less than 0.1 mm) leads to an increase in the fire hazard of the process. Particles of larger size should be obtained by other methods indicated in the analogues.

 Reliable fastening of the original workpiece in the proposed method is carried out due to the elements of the mandrel inside it. Therefore, the remaining milling is determined by the strength of the source metal. In practice, the process of obtaining the powder is carried out before the destruction of the residue, the mass of which is not more than 2% of the mass of the workpiece. The yield of metal in powder is not less than 97%.

 In the analyzed sources of patent and scientific and technical information, the set of essential features of the claimed invention was not identified.

 Example.

 A cylindrical calcium ingot with a diameter of 350 mm and a mass of 65.0 kg was used as the initial preform. Obtaining a metal powder was carried out according to the scheme shown in figure 1.

When the initial workpiece and the cylindrical mill were rotated at a speed of 2 rpm and 600 rpm, respectively, the feed rate of the tool was 1.6 mm / min per revolution of the workpiece. Thus, the ratio of rotational speeds was (n _blanks / n _cutters ) = 1/300 (coefficient K = 660). In the process of obtaining the powder, a cutter with a cutter edge width of 2 mm was used.

 The powder formed during milling was easily removed from the cutting zone and poured into the container along the gutter.

 The performance of the powder process was 45 kg / h. The cylindrical metal residue after milling had a mass of 0.9 kg, which was ~ 1.4%, respectively, the yield was ~ 98.6%. The resulting calcium powder had a particle size of from 0.1 to 3.0 mm. The bulk of the powder (~ 85%) was represented by particles having a length a = 2.0-2.4 mm, a thickness b = 1.5-1.7 mm and a width c = 1.9-2.1 mm, which corresponds to the above formulas (1) and (2).

 The inventive method is shown in the example of obtaining calcium powder. However, this does not limit its scope. The method can be used to obtain powders of chemically active metals, such as magnesium, zirconium, titanium and others, as well as their alloys.

Claims (1)

A method of producing metal powders by milling a workpiece, characterized in that a powder with linear particle sizes in the range of 0.1-6.0 mm is obtained by milling a cylindrical workpiece rotating around an axis parallel to the axis of rotation of the mill, by changing the ratio of the speeds of rotation of the workpiece and mill, speed the feed of the cutter and the size of its cutting edge, while the ratio of the workpiece rotation speeds — n _blanks and cutters — n _{cutters is} maintained in the interval n _blanks / n _cutters = 1 / 100-1 / 1000.

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