Specialized metallurgical processes – compositions for use therei – Compositions – Consolidated metal powder compositions
Patent
1997-12-04
1999-01-05
Mai, Ngoclan
Specialized metallurgical processes, compositions for use therei
Compositions
Consolidated metal powder compositions
75246, 75252, 419 31, 419 38, C22C 3300
Patent
active
058566252
DESCRIPTION:
BRIEF SUMMARY
BACKGROUND OF THE INVENTION
This invention relates to atomised high alloy powders of compositions which when used to manufacture sintered articles, provide metal articles having a good corrosion resistance, compared with components produced from conventional stainless steel powders, and in addition having exceptionally good wear resistance.
Stainless steels can be classified in a variety of ways. However, the key differences in properties are determined by the type of matrix created in the steel after processing and possibly, heat treatment. Alloys based around predominantly ferritic, austenitic, and martensitic matrices are all in common use. In addition, duplex steels, typically having a matrix containing 50/50 mix of austenite and ferrite, are available.
Martensitic stainless steels are essentially ferrous alloys containing chromium and carbon. They can be made fairly hard and wear resistant by development of a martensitic matrix, sometimes strengthened by precipitates, but are generally only resistant to corrosion in relatively mild environments due to their low chromium contents.
Austenitic stainless steels are ferrous based alloys containing moderate additions of chromium but with very little carbon. In addition liberal amounts of austenite stabilising elements, such as nickel, manganese and nitrogen, are added. The common austenitic grades contain a minimum of 6% nickel. In general, these alloys achieve better corrosion resistance than the martensitic grades. This is due primarily to their higher chromium contents. However, powder metallurgy produced austenitic stainless steels are susceptible to fairly severe crevice type corrosion at certain sintered densities. In addition since the austenitic grades are generally soft they cannot achieve good wear resistance.
Conventional ferritic stainless steels are ferrous based alloys containing primarily large additions of chromium with low concentrations of carbon and nickel. These alloys show excellent corrosion resistance especially at the higher chromium levels (superferritic) with a reduced tendency to the crevice type corrosion found in austenitic stainless steels. However, the ferritic type matrix is extremely soft and has a poor work hardening response. Consequently these alloys develop poor wear characteristics.
In summary, austenitic grades provide good corrosion resistance but have a tendency towards crevice type corrosion in powder metallurgy produced components. In addition, these materials tend to be more highly alloyed than ferritic grades, with a similar level of corrosion performance, due to the requirement for large additions of nickel to stabilise the austenitic matrix. Martensitic grades provide good wear resistance but only moderate corrosion resistance. Finally ferritic grades offer potentially excellent corrosion resistance but poor wear resistance due to the poor mechanical properties of ferrite.
In general it has been the practice when producing conventional stainless steel materials for applications requiring good corrosion resistance and ease of fabrication to avoid the use of chromium in large quantities due to the fact that a fully austenitic matrix cannot be maintained without large nickel or manganese contents also being present. In the practice of this invention no nickel or manganese is required to provide a material with excellent corrosion properties and powder metallurgy processing avoids any problems with ease of fabrication. Furthermore, in conventional austenitic or ferritic stainless steels the addition of large quantities of carbon is also to be avoided due to a reduction in corrosion resistance by the well known phenomenon of sensitisation (reduction of the matrix chromium content in the vicinity of the grain boundary by carbide precipitation at the grain boundaries).
PRIOR ART
A number of workers in this field have previously investigated the addition of high chromium levels to alloys containing various other elements. (U.S. Pat. No. 3,993,445) teaches that when high chromium levels (12-30 wt %) are used to prod
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Brewin Peter Ronald
Nurthen Paul Dudfield
Saunders John
Trilk Nigel Craig
Wood John Vivian
Mai Ngoclan
Powdrex Limited
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