JP2013528705A - Powder metallurgy steel - Google Patents

Abstract

A method for producing powder metallurgical steel is described. The method comprises the following steps: in particular the production of a steel powder having a predetermined structure, the formation of a plastically deformable raw material mass by mixing the steel powder with a binder, and the formation of the raw material mass. , Formation of a blank having a predetermined three-dimensional shape, and sintering of the blank.
[Selection] Figure 2

Description

Field of Invention

  The present invention relates to a method for producing powder metallurgy steel by powder metallurgy technology, a lump of raw materials for producing steel, powder metallurgy steel for producing a tool, and steel.

Background of the Invention

  In the prior art, cylindrical bars made of HSS or HSS-E for manufacturing cutting tools are manufactured by rolling or stretching.

  Heretofore, manufacturing blanks for making tools from HSS or HSS-E has been done by rolling or stretching the steel in repeated processing cycles. Such processing steps require expensive equipment and complicated processes, and are time consuming and expensive.

  In contrast, manufacturing a blank from cemented carbide or cermet can be done with much cheaper equipment and less complicated processes. The blank can be produced from cemented carbide or cermet by performing a sintering process after the extrusion process. Related production methods are described, for example, in documents US 2,422,994, DE 36 01 385 A1, EP 465 946 A1, EP 1 017 527 B1, EP-A-0 340 495, EP-A-0 458 774, WO-A-92. / 22390 or US-A-4 779 440.

  Advantageously, the extrusion process can produce a continuous bar. This continuous bar is advantageous for making drilling tools, milling machines, reamers or counterbore tools. This is because the raw material (green compact / green mold) can already be formed into a desired cylindrical shape by extrusion. This cylindrical shape can be considered as an ideal starting point for manufacturing drilling tools, milling machines, reamers or counterboring tools.

  It is also advantageous that the extrusion process can be arranged, for example, in an extruded path within the extruded rod, by simply expanding the extrusion nozzle already during the extrusion process. These internal paths are utilized in the finished tool to allow refrigerant and / or lubricant to pass through the tool and to the member performing the cutting action of the tool.

  The problem is therefore that it is possible to easily obtain a rod for manufacturing a tool from HSS or HSS-E. A further problem resides in providing a mass of raw material that allows the above-described tool to be manufactured efficiently.

  These problems are solved by the method according to claim 1, the raw material mass according to claim 12, and the steel according to claim 13 or 14, which can be produced by the raw material mass.

  According to the invention, it is possible to produce components or semi-finished products having a very complex shape from tool steel in a very efficient manner. The manufacturing method of powder metallurgy steel (especially tool steel such as HSS or HSS-E steel) according to the present invention is characterized in that steel powder having a certain predetermined structure is first generated. The steel powder is mixed with a binder such as wax or paraffin to produce a deformable raw material mass having plasticity. This raw material mass can preferably be immediately subjected to the forming process by appropriately selecting the particle size and / or particle distribution of the steel powder. In this way, it is possible to produce a blank having any complex three-dimensional shape for steel components without interrupting the process.

  The original structure is formed when sintering a blank that has been previously subjected to a special step to remove the binder. That is, steel particles, preferably having a substantially spherical shape, to facilitate the extrusion process, melt together and are closely bonded. Thereby, a high-density and high-strength steel member can be obtained. The internal structure of the steel powder particles is substantially preserved, which results in predictable material properties. It has been shown that the pressure generated by the nozzle during extrusion is already sufficient to produce blanks consisting of a mass of steel / binder raw material. This blank has a sufficient density and strength after a sintering process performed at approximately atmospheric pressure. As a matter of course, the structure can be further improved by the superposition process or by performing a subsequent HIP (high temperature isostatic pressing) process.

  In order to better prepare the raw material mass for the forming process, the shape of the powder particles is homogenized in the steel powder during and / or before the mixing process with the binder. It is advantageous to apply a processing process for the purpose.

  According to a further configuration of claim 4, the steel powder is subjected to a classification process prior to mixing. As a result, the steel powder is sent to the mixing process with a predetermined particle size and / or particle size distribution, which can further affect the strength of the steel structure.

  If steel powder is obtained by grinding and grinding steel particles, the initial structure of the steel powder can be freely selected regardless of the powder production process.

  If the steel powder is further mixed with a metal binder such as cobalt, the material properties of the produced steel can be affected in a wider range.

  In particular, in order to supply a high-density material, it is advantageous to subject the blank to HIP (high temperature isostatic pressing) before, during or after the sintering process.

  It is particularly advantageous to perform a heat treatment, for example a hardening treatment, on the blank while a sintering treatment is being carried out to control the steel structure. This is done by executing an appropriate temperature / time management program that can be selected according to material technical standards as required.

  According to the method for sorting steel powder according to the present invention, it is possible to perform a continuous extrusion process on a deformable lump having plasticity, and it is possible to obtain a very good structural density of the steel material. It can be guaranteed. Thereby, the deformable mass having plasticity is preferably extruded into a continuous bar by means of an extruder having a nozzle. The bar is then cut to the required dimensions. In this way, blanks can be produced very efficiently.

  According to the present invention, powder metallurgy steel can be easily obtained. Powdered steel is processed with the addition of binder, as in the manufacture of cemented carbide. Thereafter, the powdered steel containing the binder is extruded and sintered.

  According to a further aspect of the invention, a raw material mass for producing steel according to claim 12 is provided.

  Further advantageous configurations of the invention are the subject of other dependent claims.

  According to an exemplary embodiment of the present invention, there is additionally provided a method using cobalt as a metal binder.

  In a further embodiment according to the present invention there is provided a method wherein the pressing step is performed by an extruder having a nozzle. This makes it possible to extrude the raw material mass into a continuous bar.

  In accordance with a further embodiment of the present invention, a method is provided for providing at least one internal path in part during extrusion. The internal path is for introducing refrigerant and / or lubricant into the rod.

  According to an exemplary embodiment of the present invention, a method is provided in which the internal path is at least partially configured in a spiral or straight line.

  In yet another embodiment according to the present invention, a steel is provided that can be produced from the raw material mass defined in claim 6.

  The following points are considered as significant advantages of the present invention. That is, it is possible to manufacture powder metallurgy steel easily and at low cost. As an initial material, for example, high alloy stainless steel may be used in addition to tool steel such as HSS-E. The powder may be obtained by spraying a melted steel or obtained by grinding. The method for producing powder metallurgical steel according to the present invention does not require large-scale production equipment. Therefore, compared with the prior art, it becomes possible to hold down the cost concerning production. Moreover, according to the manufacturing method of the powder metallurgy steel which concerns on this invention, it becomes possible to achieve high productivity compared with the manufacturing method of a prior art.

  Individual features can of course be combined between each feature. As a result, it is possible to partially achieve advantageous effects that exceed the total of the effects obtained from the individual features.

  Further details and advantages of the invention will be described with reference to the embodiments shown in the drawings.

FIG. 4 is a diagram for explaining a method step according to the present invention. These are figures which show the nozzle for extruding the continuous stick | rod by powder metallurgy.

  In the prior art, it is known to use powdered steel to produce powder metallurgy steel. This steel is typically a highly alloyed steel and can contain, for example, 0.46% carbon and 13% chromium. In this case, the powdered steel is compressed by repeated rolling. A tool can then be generated from the resulting mass. During the initial rolling process, the coolant path can be arranged by drilling in the already partially compressed steel. Overall, this powder metallurgical steel manufacturing method requires high costs for manufacturing equipment. Moreover, the manufacturing method according to this prior art takes a long time.

  FIG. 1 shows the course of a method for producing a powder steel according to the invention, in particular a tool steel such as HSS or HSS-E-steel. In that case, first, steel powder is produced | generated in a 1st method process. The steel powder preferably has a previously selected structure, for example a cast high-speed working steel, or a structure of high-speed working steel that has already been greatly deformed.

  Subsequent mixing with a binder such as paraffin or wax results in a deformable raw material mass having plasticity, which can be further processed directly in the molding process. Variations are indicated by broken lines. Accordingly, the steel powder is further mixed with a metal binder such as cobalt.

  During mixing with the binder and / or prior to mixing with the binder, the steel powder is subjected to a homogenization treatment in the form of powder particles, for example in a ball mill. The corners of the powder particles are removed in this way, and the particles become nearly spherical, which facilitates the subsequent molding process.

  Furthermore, it is possible and advantageous that the steel powder is subjected to a classification process before mixing with the binder, and the steel powder of a predetermined particle size and / or particle size distribution can be subjected to a mixing process. .

  The resulting raw material mass is then formed, preferably in an extruder unit, into a blank having a predetermined three-dimensional shape, resulting in a blank having an arbitrarily complex three-dimensional structure.

  The binder is removed at a selected temperature during the subsequent sintering, but prior to that. Then the actual sintering process takes place, at which time the steel structure is finally produced. The blank can be subjected to a HIP (High Temperature Isostatic Press) treatment before, during or after sintering. This optional method step is indicated by broken lines in FIG.

  Similarly, the blank can also be selected such that it undergoes a heat treatment, such as a hardening process, during the sintering process for control of the steel structure. At that time, the sintering facility performs a predetermined temporally controlled temperature profile, so that the steel finally has the desired structural quality.

  Steel powder can be obtained by grinding and grinding steel particles.

  The plastically deformable mass is subjected to continuous extrusion, in particular, when the plastically deformable mass is relatively low compressed by an extruder having a nozzle (102), the continuous bar It can be seen that high quality steel parts can be produced from HSS or HSS-E.

  Blanks (compact / green) produced as a steel / binder mixture produced in the extrusion step can be processed in a manner similar to the production of cemented carbide or cermet. Processing by an extruder (which may be equipped with a nozzle for extrusion) and subsequent sintering steps make it possible to produce powder metallurgy steel easily, quickly and advantageously. The extrusion shape during extrusion, which is a continuous bar, is also advantageous because it already has the rough shape of a drilling tool, milling machine, reamer or counterbore tool. That is, according to the present invention, powdered steel, such as tungsten carbide, is treated and processed as an initial material for producing cemented carbide (adding a binder such as cobalt).

  According to the present invention, it is possible to produce using an extrusion process, and it is even more convenient to easily form an internal path in the extruded bar. This internal path, in particular, its dimensions (diameter, circular or elliptical cross section) is not significantly changed by further processing steps, for example sintering. Compared with this, the change of the said dimension may arise in the process by rolling of a prior art. Therefore, it is possible to ensure high accuracy in the production of the internal path of powder metallurgy steel.

  FIG. 1 shows an example of a nozzle for extruding a continuous bar. Here, a mass of raw material is pushed into the nozzle through the inflow openings 103, 104. The inflow openings 103 and 104 may have an annular surface. According to the invention, the raw material mass comprises powdered steel. The steel may be a high alloy and may have at least one additional metal binder (eg, cobalt). The raw material masses merge at region 105, and a plurality of internal channels 101 can be formed that are twisted into the extruded raw material mass, for example, by continuously rotating bars 107. . Thereafter, a continuous bar 106 having an internal passage 101 can be discharged from the nozzle 102. If the bar 107 is not rotating and stopped, a continuous bar 106 with a linear internal path can be formed.

  Such extrusion nozzles or related nozzles that can be used are known, for example, the following documents: US 2,422,994, DE 36 01 385 A1, EP 465 946 A1, EP 1 017 527 B1, EP-A- 0 340 495, EP-A-0 458 774, WO-A-92 / 22390, or US-A-4 779 440. These disclosures are expressly incorporated herein by reference.

  The present invention thus implements a method for producing powder metallurgical steel. The method preferably comprises the steps of producing a steel powder of a predetermined structure, mixing the steel powder with a binder to form a deformable raw material mass having plasticity, and forming the raw material mass. Forming a blank having a predetermined three-dimensional shape and sintering the blank.

  Note that the term “comprising” does not exclude other components or other processing steps. Similarly, the term “a” does not exclude a plurality of components and a plurality of steps.

  The symbols used here are used only for the purpose of improving the ease of understanding, and should not be interpreted in a limited way. The scope of protection of the present invention is set forth in the appended claims.

101 Internal path 102 Nozzle 103 Inflow opening 104 Inflow opening 105 Mixing area 106 Extruded rod 107 Bar

Claims (15)

In a process for the production of powder metallurgy steel, in particular tool steel such as HSS or HSS-E-steel:
Producing a steel powder having a predetermined structure;
Mixing a binder with the steel powder to form a deformable raw material mass having plasticity;
Forming a mass of the raw material to form a blank having a predetermined three-dimensional shape; and
A method for producing powder metallurgy steel, comprising a step of sintering the blank.   The method according to claim 1, characterized in that the steel powder is subjected to a homogenization treatment of the shape of the powder particles during mixing with the binder.   The method according to claim 1, characterized in that the steel powder is subjected to a homogenization treatment of the shape of the powder particles before mixing with the binder.   4. The steel powder according to claim 3, wherein the steel powder is subjected to a classification process before mixing with a binder, and the steel powder having a predetermined particle size and / or particle size distribution is subjected to a mixing process. Method.   The method according to any one of claims 1 to 4, wherein the steel powder is obtained by grinding and grinding steel particles.   6. A method according to any one of the preceding claims, wherein the steel powder is mixed with a binding metal such as cobalt.   The method according to claim 1, wherein the blank is subjected to a HIP (high temperature isostatic pressing) process before, during or after sintering.   The method according to claim 1, wherein the blank is subjected to a heat treatment such as a hardening treatment during a sintering treatment for controlling the steel structure.   The plastically deformable mass is particularly subject to continuous extrusion, and the plastically deformable mass is extruded into a continuous bar by an extruder having a nozzle (102). 9. A method according to any one of claims 1 to 8, characterized in that   10. The internal path (101) for guiding the refrigerant and / or lubricant into the rod (106) at least partly during the extrusion process. Method.   11. A method according to claim 10, characterized in that the internal path (101) is at least partly configured in a spiral or straight line. In the raw material mass for the production of powder metallurgy steels, in particular tool steels such as HSS or HSS-E-steel,
Steel powder having a predetermined structure, and
Raw material mass characterized in that the raw material mass comprises a binder mixed so as to be suitable for extrusion and subsequent sintering.   A powder metallurgy steel for the manufacture of a tool, the steel being manufacturable by the method according to any one of claims 1 to 11.   14. Steel according to claim 13, characterized in that it can be produced from the raw material mass according to claim 12.   A member or semi-finished product produced by the method according to any one of claims 1 to 11, or from the raw material mass according to claim 12 or the steel according to claim 13 or 14.

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