Manufacture of lightweight metal matrix composites with controlled structure

a technology of metal matrix composites and controlled structure, which is applied in the field of manufacturing of lightweight metal matrix composites with controlled structure, can solve the problems of low dynamic mechanical properties that limit the application of immc, weak at high temperatures, and insufficient flexure, fatigue and impact strength of infiltrated mmc (immc), and achieves the effects of increasing mechanical properties such as elongation, toughness, flexure and impact strength or fatigue resistan

Inactive Publication Date: 2003-07-17
ADMA PRODS
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

0016] It is therefore an object of the invention to form an homogeneous, essentially uniform structure of the metal matrix composites p...

Problems solved by technology

However, infiltrated MMC (IMMC) are usually brittle, weak at high temperatures, and exhibit insufficient flexure, fatigue, and impact strengths.
Low dynamic mechanical properties limit the application of IMMC especially in aircraft, automotive, and rocket industries.
All of these new processes as well as conventional powder metallurgy techniques impose certain limitations with respect to the characteristics of the produced IMMC.
Besides, low porosity results in the incomplete infiltration of small porous channels by magnesium.
Even long holding time does not help, and the final structure has a remaining porosity in the central part of the block.
This randomly distributed porosity and heterogeneous structure of dense titanium skeleton decrease mechanical properties of the obtained IMMC, especially impact strength and toughness.
But ceramic matrix composites have significantly lower elasticity and impact strength than the projected IMMC.
Besides, it is technically difficult to organize high pressure evenly distributed on the area of large size porous blanks such as plates, sheets, and the like.
However, this method does not improve any mechanical characteristics of the final prod...

Method used

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  • Manufacture of lightweight metal matrix composites with controlled structure
  • Manufacture of lightweight metal matrix composites with controlled structure

Examples

Experimental program
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example 1

[0048] The CP titanium powder having a particle size of -100 mesh was loose sintered at 1100.degree. C. (2000 F) in the flat preform having sizes of 6".times.12".times.0.125". The skeleton structure, having a density of 35% obtained after loose sintering was cold rolled to an average density of .about.50%. The infiltrating alloy with a composition of Mg-50 wt. %Al was placed on the preform in a graphite crucible and heated in vacuum to 600.degree. C. (1110 F) to infiltrate said titanium skeleton structure. The obtained composite material was fully dense with a measured density of 2.87-2.89 g / cm.sup.3.

[0049] Specimens 3".times.0.5" were cut out from the edge and central part of the sheet to measure hardness and flexure strength. The thickness of specimens was in the range of 0.078-0.125" depending on the preset deformation.

[0050] The particle size of titanium powder, sizes of initial powder preforms, loose sintering temperature, and sizes of specimens for mechanical testing were the ...

example 2

[0052] The same skeleton structure as in Example 1 was manufactured and infiltrated with the same Mg--50Al alloy melt. The infiltrated sheet was cold rolled to a 30% reduction. The resulting composite material had a measured density of 3.03-3.07 g / cm.sup.3 with a fully dense textured microstructure.

example 3

[0053] The same skeleton structure as in Example 1 was manufactured and infiltrated with the same Mg--50Al alloy melt. The infiltrated sheet was annealed for 4 h at 400.degree. C. (760 F) in vacuum to promote the formation of strengthening intermetallic phases. Measured density of the resulting composite was 2.86-2.89 g / cm.sup.3.

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Abstract

Lightweight metal matrix composites containing a skeleton structure of titanium, titanium aluminide, or Ti-based alloy are manufactured by low temperature infiltration with molten Mg-based alloy or Mg-Al alloy at 450-750° C., with molten In, Pb, or Sn at 300-450° C., or with molten Ag and Cu at 900-1100° C. The skeleton structure with a density of 25-35% is produced by loose sintering of Ti or Ti-based alloy powders. A primary deformation of the Ti skeleton structure before the infiltration is carried out by cold or hot rolling or forging to obtain a porous flat or shaped preform with a porosity <50% and pores drawn out in one direction such as the direction of future rolling of the composite plate. A secondary deformation of the infiltrated preform is carried out by multistage cold, or especially hot rolling, to refine the microstructure of the infiltrated skeleton structure and transform it into the textured microstructure strengthened by intermetallic phases such as TiAl, Ti3Al, and TiAl3. Subsequent re-sintering or diffusion annealing form a fully dense final structure of the resulting material having improved mechanical properties. The molten Mg-based infiltrate is alloyed with Al, Si, Zr, Nb, and/or V with the addition of TiB2, SiC, and Si3N4 sub-micron particles as infiltration promoters. The molten Ag- or Cu-based infiltrate can be alloyed with elements depressing its melting point. The method allows for control of the microstructure of composite materials by changing parameters of deformation, infiltration, and heat treatment. The method is suitable for the manufacture of flat or shaped metal matrix composites having improved ductility, such as lightweight bulletproof plates and sheets for aircraft and automotive applications, composite electrodes, heat-sinking lightweight electronic substrates, sporting goods such as helmets, golf clubs, sole plates, crown plates, etc.

Description

[0001] The present invention relates to metal matrix composites (MMC) manufactured by methods of powder metallurgy especially by infiltrating a loose sintered solid metal powder with low-melting liquid metal or alloy. More particularly, the invention is directed to MMC containing at least one component (solid powder or infiltrating melt) based on lightweight metals such as titanium and magnesium.[0002] Metal matrix composites manufactured by infiltrating with molten metal are attractive materials for structural applications not only due to their excellent properties such as stiffness, light weight, high abrasion and oxidation resistance but mainly due to the opportunity to compose materials containing combinations of metals that can be difficult or cost prohibitive when produced by methods of conventional metallurgy and machining.[0003] However, infiltrated MMC (IMMC) are usually brittle, weak at high temperatures, and exhibit insufficient flexure, fatigue, and impact strengths. Low...

Claims

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Application Information

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IPC IPC(8): B22F3/26C22C1/04
CPCB22F3/26B22F2998/10C22C1/0475C22C1/0491B22F3/04B22F3/15B22F3/18B22F3/17C22C1/047
Inventor MOXSON, VLADIMIR S.IVANOV, EUGENE
Owner ADMA PRODS
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