Not applicable.
The invention relates to powder metal parts. In particular, this invention relates to an aluminum alloy powder metal bulk chemistry formulation for powder metal parts, specifically in the example given, for camshaft bearing caps.
Camshaft bearing caps or “cam caps” are conventionally used to secure a camshaft bearing assembly to an engine block. Cam caps come in various shapes, but typically include a portion of an arch with bolt holes on both sides. The camshaft bearing assembly is held in place in the engine by the arch of the cam cap when the cam cap is secured to the block by fastening bolts through the bolt holes of the cam cap to the block. As the camshaft rotates to engage the valve train, the cam caps must be able to withstand cyclic loading. It has become more common to form various engine components, including cam caps, from aluminum alloys because many aluminum alloys have excellent strength to weight ratios.
Many of these aluminum cam caps have been formed by die casting in the past. However, because the cam caps must provide a precision fit around the camshaft bearings when bolted to the block, many of the dimensions for cam caps have tight tolerances. Because die cast cam caps do not have the needed dimensional precision after casting, die cast cam caps must be subsequently machined. Machining the cam cap adds time and cost to the production of the cam cap. Further, some cam caps may have fine levels of detail, such as oil passageways, which are not easily formed by die casting.
To avoid many of these problems and to provide a cam cap that is more dimensionally accurate prior to machining, some aluminum cam caps are fabricated using powder metal processing. However, because cam caps fabricated by powder metal processing have higher levels of porosity when compared to die cast cam caps (which are typically fully dense), powder metal cam caps often have somewhat compromised mechanical properties in comparison to die cast cam caps.
Hence, there is a need for powder metal parts, such as cam caps, that have improved mechanical properties.
A powder metal mixture is disclosed that provides improved mechanical properties for parts made from powder metal, such as cam caps. The powder metal mixture, upon sintering, forms an S phase intermetallic in the Al—Cu—Mg alloy system. The S phase is present in a concentration that results in an enhanced response to cold work strengthening of the powder metal part. Further, by minor adjustments to certain alloy elements, such as tin, the tensile properties of the resultant part may be adjusted.
The foregoing and advantages of the invention will appear in the detailed description which follows. In the description, reference is made to the accompanying drawings which illustrate preferred embodiments of the invention.
According to one aspect of the present invention, a powder metal mixture is provided for production of a powder metal part such as a cam cap. This powder metal mixture includes air atomized aluminum powder, an aluminum-copper (50/50) master alloy, and atomized magnesium powder. The air atomized aluminum powder and the aluminum-copper (50/50) master alloy powders can be obtained from Ecka Granules and the atomized magnesium powder can be obtained from Tangshan Weihao Magnesium Powder Company. These three powder metals, along with 1.5% weight percent P/M-grade Licowax® C (available from Clariant®) are be prepared using Turbala blending or other blending methods to mix the powders.
The powders are preferably mixed to form a powder metal part having a Al-4.4Cu-1.5Mg general bulk composition by weight percent. As used herein, the Al-4.4Cu-1.5Mg mixture will be referred to as “Dal-2324”. Although an aluminum alloy having 4.4 wt % copper and 1.5 wt % magnesium with minimal inclusion of other alloying elements is preferred, alloying elements and other impurities may have a bulk chemistry within the ranges shown in Table II below.
The powder metal mixture has a simple chemistry. Notably, no silicon addition is needed. Further, there are minimal iron impurities.
The Dal-2324 powder metal mixture has a flow rate and an apparent density that is comparable to commercial powders available for making cam caps as can be seen in Table III. When compared to Alumix 123 (manufactured by Ecka Granules) and AMB 2712A (manufactured by Ampal, Inc.), the Dal-2324 has a nearly equivalent flow rate and apparent density in powder form.
The Dal-2324 powder metal mixture is formed into a cam cap using conventional powder metal processing. The air atomized aluminum powder, the aluminum-copper (50/50) master alloy powder, the atomized magnesium powder, and a binder/lubricant are mixed together to form the powder metal mixture. This powder metal mixture is then filled into a compaction form such as a die cavity having upper and lower rams, punches, and/or core rods. The powder metal mixture is compacted at a compaction pressure to form a “green” preform. The green preform is then sintered for a length of time at a sintering temperature that is just below the liquidus temperature of the powder metal mixture to form the sintered part. As the green preform is sintered, the binder/lubricant are boiled off and the particles of the preform neck into one another via diffusion. During this process, the pores between the particles reduce in size and are often closed. As the porosity of the part decreases, the density of the part rises and the part “shrinks” dimensionally. Other phenomena may also play a role in the densification of the part. For example, during liquid phase sintering, capillary action may play a more dominant role in determining the rate at which the pores are filed and the part is densified.
In most sintered parts, the mechanical properties of the sintered part are largely dependent on the density of the part. If the part has a high density (close to or approaching full density), that usually means the part will have, for example, increased apparent hardness and tensile strength. Density could be further increased by slightly increasing the temperature (while still keeping it below the liquidus point) or increasing the sintering time-at-temperature. However, for most powder metal powder compositions, it is thermodynamically and kinetically difficult to obtain a density that approaches full density. As the pores close, the mechanism for reducing porosity changes from necking of the particles together to vacancy diffusion through the part. When the diffusion of vacancies from the pores to the outer surface of the part become the predominant mechanism for densification, only marginal increases in density can be obtained by increasing the sintering time and/or temperature. Further, keeping parts at sintering temperatures for a longer time can have undesirable effects on the dimensions of the part. If the part is subjected to a heat gradient or high temperatures for too long, it could shrink more in some areas than in others. As a result, the part would be less dimensionally accurate.
However, it has been found that the powder metal mixture described above has an improved sinter response. Thus, with similar heat treatment to other commercially available powders (Alumix 123 and AMB 2712A), the Dal-2324 powder metal mixture obtains a higher density. This increase in sintered density, along with the formation of a unique intermetallic phase, has been found to strengthen the part relative to comparable powders for production of cam caps.
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Table IV lists the mechanical properties of some of the samples that were prepared without any substantial amount of tin in the alloy.
Notably, the parts made from Dal-2324 exhibit greater yield strength, ultimate tensile strength (UTS) and hardness over the parts made from Alumix 123. The Dal-2324 powder provides gains of 30-50% in apparent hardness and tensile strength compared to standard AC2014-type powder metal alloys in use today.
To understand the difference in mechanical properties, it is helpful to understand the microscopic behavior of the Dal-2324 components and how it differs from the standard powder metal alloys. Most high performance aluminum alloys are strengthened by a dispersion of fine intermetallics formed through appropriate heat treatment procedures. The type of intermetallic(s) formed is, at least in part, a function of the bulk chemistry of the material. For example in Alumix 123 or Ampal 2712A, there is a high ratio of copper to magnesium (usually in the range of 8-9:1). In these conditions, the dominant strengthening intermetallic phase is the θ phase (CuAl2) and metastable variants thereof.
The Al-4.4Cu-1.5Mg composition, by means of bulk chemistry and morphology of the powder metals in the mixture, is tweaked to promote the formation of an intermetallic S phase (CuMgAl2) and metastable variants thereof. The S phase intermetallic exhibits a more potent strengthening effect in cold worked aluminum alloys than does the θ phase. It is harder for dislocations to pass the S phase intermetallic than the θ phase intermetallic and, as a result, the alloy having the S phase intermetallic is harder and exhibits improved tensile properties. It is contemplated that this powder metal mixture may be even more beneficial after being subjected to cold working operations as are common in a “press-sinter-size”-type production sequence.
Minor adjustments may be made to the raw power blend to achieve the same or substantially similar result having formation of the S phase intermetallic. For example, the aluminum copper master alloy powder could have a composition other than 50/50 by weight percent. Further, minor adjustments could be made to the quantities of the powders mixed to control the amount of each alloying element in the bulk chemistry within the ranges shown in Table II, sometimes with an additional advantage.
Tin is one such example of an alloying element that may be adjusted to change the microstructure, phase development, and mechanical and chemical properties of the alloy up to a small percentage, for example up to 1.2 wt % Sn. Referring now to
However, at about or after approximately 0.2 wt % of tin, additional amounts of tin in the Dal-2324 alloy begin to have a different effect. Above approximately 0.2 wt %, the addition of more tin causes the ultimate tensile strength (UTS) and yield strength to decrease, although the percent elongation continues to rise. This change in the trend is believed to be a result of tin additions above approximately 0.2 wt % suppressing the formation of the S phase intermetallic. This helps to illustrate the benefit of the presence of the S phase in increasing the hardness of the sintered alloy as a comparison between 0 wt % tin and 1.0 wt % tin show that despite having similar ultimate tensile strengths, at 1.0 wt % tin the yield strength is approximately 30 MPa less than the yield strength at 0.0 wt % tin.
It is also contemplated that ceramic or intermetallic reinforcement could be added to the powder metal. Such reinforcement could include, but are not limited to, Al2O3, SiC and AlN. As these reinforcements are stable at sintering temperatures for the aluminum alloy, they could be included in the powder metal mixture so that they are evenly dispersed throughout the bulk of the part after sintering. This reinforcement could be added up to 15% by volume in the part. Such reinforcement would increase the modulus, wear resistance, and strength of the material. For example, in one set of samples comprising Dal-2324 powder plus 5 vol % SiC, measureable improvements in were found in a number of properties of the resultant material. Around ten percent gains in the yield strength, the ultimate tensile strength, and the Young's modulus were observed in the parts including 5 vol % SiC reinforcement.
While there have been shown and described what is at present considered the preferred embodiments of the invention, it will be obvious to those skilled in the art that various changes and modifications can be made therein without departing from the scope of the invention defined by the appended claims.
This application claims priority to U.S. provisional patent application Ser. No. 61/104,572 titled “ALUMINUM ALLOY POWDER METAL BULK CHEMISTRY FORMULATION” and filed on Oct. 10, 2008. The full contents of that application is incorporated by reference as if set forth in its entirety herein.
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PCT/US2009/059675 | 10/6/2009 | WO | 00 | 3/8/2011 |
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WO2010/042498 | 4/15/2010 | WO | A |
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