Fluidity Investigation of Pure Al and Al-Si Alloys

Haga, Toshio; Imamura, Shinjiro; Fuse, Hiroshi

doi:10.3390/ma14185372

Cited by 16 publications

(6 citation statements)

References 23 publications

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“…However, the present results demonstrate that Al-25%Si has superior fluidity. Al-25%Si has notably higher latent heat than ADC12 due to its higher Si content [19]. As a result, the flow length of Al-25%Si is excellent and indicates potential for die casting of thin products.…”

Section: Flow Length Of Adc12 and Al-25%simentioning

confidence: 99%

“…The aluminum alloy was melted in an oxidizing atmosphere using a gas furnace. The spiral die used to investigate the flow length features a channel width of 7 mm and channel gaps of 0.5 and 1.0 mm, as shown in Figure 1 [19]. The shape and name of each part of the heat sink are shown in Figure 2.…”

Section: Experimental Conditionsmentioning

confidence: 99%

“…It is thought that an aluminum alloy with excellent fluidity can flow into thin die gaps, allowing for the casting of thin fins. In a previous study, it was shown that hyper-eutectic Al-25%Si has excellent fluidity compared to hypo-eutectic Al-Si alloys [19]. JIS ADC12 (similar to A383) [20] is a popular aluminum alloy for die casting, and it is typically used to cast heat sinks.…”

Section: Introductionmentioning

confidence: 99%

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Die Casting of Lightweight Thin Fin Heat Sink Using Al-25%Si

Haga,

Fuse

2024

Metals

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The demand for lightweight and cost-effective heat sinks is increasing. A typical method for economically manufacturing complex-shape heat sinks is die casting. To reduce the weight of the die-cast heat sinks, thinning the fins and base is common practice. We experimented with casting heat sinks using Al-25%Si in a conventional die casting machine with the aim of economically producing thinner fins and bases. Compared with the aluminum alloy used in conventional die casting, Al-25%Si has superior fluidity, which is proven to be very useful for reducing the thickness of the fins and base. As a result, we successfully reduced the heat sink weight using Al-25%Si and a conventional die casting machine. To investigate the properties of the produced Al-25%Si thin fin heat sink, we compared the effects of fin thickness, fin height, number of fins, and base thickness on heat dissipation and weight reduction. Additionally, we compared the weight and heat dissipation properties with those of a commercial heat sink and found that our Al-25%Si heat sink maintains the same heat dissipation performance but for 35% lower weight.

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Section: Flow Length Of Adc12 and Al-25%simentioning

confidence: 99%

Section: Experimental Conditionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Die Casting of Lightweight Thin Fin Heat Sink Using Al-25%Si

Haga,

Fuse

2024

Metals

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“…The Si addition makes the alloy of good strength, corrosion resistant, increased fluidity and free from hot shortness. Furthermore, the hard phase of Si contributes to transform the alloy into a highly wear resistant one [4,5]. Combining with other elements, the Si particles upgrade the strength and make the alloys heat treatable.…”

Section: Introductionmentioning

confidence: 99%

Role of silicon on the tribological performance of Al-based automotive alloys and the effect of used motor oil

Kaiser¹,

Khan²

2022

Finnish J. Trib.

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A wear test in a used motor oil sliding environment was performed on Al-based automotive alloys with Silicon doped in various levels. Where a pin-on-disc wear testing equipment was used at a normal pressure of 1.53 MPa and a sliding speed of 0.51 m/s, kept constant. For comparison of the wear performance, dry and fresh motor oil sliding environments were also considered. The results showed that as silicon content was increased in the alloys, the wear rate decreased up to the eutectic composition, followed by an increase for all the environments. It was mainly for higher levels of Si-rich intermetallic Mg2Si precipitates in the α-aluminum matrix and made the alloys’ strength superior, in addition to increased wear resistance. In the post eutectic composition, primary silicon particles which are coarse and polyhedral appeared weakening the matrix. The coefficient of friction also decreased because of the higher hardness and the Si particles' employment as solid lubricants. In a dry environment, the wear rate and friction coefficient were much greater for their direct contact but lower under motor oil due to the reduced roughness caused by the sealing effects of the contact surfaces. Conversely, in oil environment, the opposite phenomenon was observed where a higher coefficient of friction was added to the alloy because the oil formed a thin film working as a lubricant between the contact surfaces which controlled the wear properties. Used oil demonstrates some degree of higher wear rate along with friction coefficient due to heavy and harmful chemical compounds in it. Examined by optical microscopy and SEM analysis, worn surfaces have shown that Si added alloy improved wear resistance through mild and smooth abrasive grooves filled with oxides in dry sliding conditions. In case of oil sliding environment smooth surfaces are created by the resistance of the oil film to the direct contact between the surfaces.

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“…Fluidity is not a physical property, such as density, but a complicated behavior related to the fluid flow and solidification of the liquid or liquid-solid two-phase of an alloy under specific conditions of a casting practice. Therefore, fluidity can be affected not only by the thermodynamic characteristics of the alloy (alloy chemistry [1][2][3][4][5][6][7][8][9], melt temperature [7,10,11], and viscosity [12,13], etc.) but by various parameters of fluidity tests (measurement method [1,14], mold temperature [15,16], mold coating [17,18], etc.).…”

Section: Introductionmentioning

confidence: 99%

Experimental Investigation and Numerical Simulation of the Fluidity of A356 Aluminum Alloy

Bang

Kwon

Chung

et al. 2022

Metals

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The fluidity of A356 aluminum alloy was experimentally determined at the melt temperatures and vacuum degrees by a series of suction fluidity tests. In order to achieve different cooling rates during the test, quartz tubes, as well as stainless steel tubes, were employed as the fluidity channels. As the melt temperature increased from 650 to 730 ∘C, fluidity lengths either linearly increased from 26 to 36 cm or parabolically increased from 13 to 29 cm when quartz tubes or stainless steel tubes were employed, respectively. As the vacuum degree of the fluidity test increased from 0.005 to 0.03 MPa, fluidity increased from 25 to 43 cm in quartz tubes while the smaller increase in fluidity from 20 to 31 cm was observed in stainless steel tubes. Shorter fluidity lengths in stainless steel tubes than those in quartz tubes under the same fluidity measurement condition were due to faster solidification speed confirmed by microstructural analysis. In order to predict the fluidity of the A356 alloy obtained from the suction fluidity tests, a mathematical model was developed based on heat and mass transfer equations coupled with thermodynamic calculations by ChemApp software. The simulation results show good agreement with the fluidity length obtained in the present study. From a series of model calculations, the effects of casting parameters on the fluidity of the A356 melt were discussed.

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Fluidity Investigation of Pure Al and Al-Si Alloys

Cited by 16 publications

References 23 publications

Die Casting of Lightweight Thin Fin Heat Sink Using Al-25%Si

Die Casting of Lightweight Thin Fin Heat Sink Using Al-25%Si

Role of silicon on the tribological performance of Al-based automotive alloys and the effect of used motor oil

Experimental Investigation and Numerical Simulation of the Fluidity of A356 Aluminum Alloy

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