한국해양대학교

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Microstructural Analysis on the High-temperature Mechanical and Electrochemical Behaviors of AlSi10MnMg die-cast alloy for Automobile Applications

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dc.contributor.advisor 이은경 -
dc.contributor.author 안철민 -
dc.date.accessioned 2022-04-08T17:43:01Z -
dc.date.available 2022-04-08T17:43:01Z -
dc.date.created 20210311144404 -
dc.date.issued 2021 -
dc.identifier.uri http://repository.kmou.ac.kr/handle/2014.oak/12608 -
dc.identifier.uri http://kmou.dcollection.net/common/orgView/200000376090 -
dc.description.abstract High-pressure die-casting (HPDC) AlSi10MnMg (AA365) has been used widely in the manufacturing of automotive components because it has excellent castability, good mechanical property, and lightweight. Particularly, this alloy must be capable of enduring exposure to high temperatures and corrosive environments in the long term with a view to using these automobile parts efficiently. Therefore, the high-temperature tensile property, the viscoelastic behavior, and the corrosion characteristic of AA365 alloys were examined with the aim of certifying with reliability and safety in various industries. At first, the excellent mechanical property of HPDC AA365 alloy was revealed through the comparison of as-cast and T4/T6 heat treated AA365 alloys due to the significant refinement of grain size. Then the high-temperature tensile test was conducted in the range of temperatures from 273 K to 737 K. The tensile and yield strengths of this alloy were declined from 299 MPa to 10 MPa, but the tensile strain was increased from 12.4 % to 44.6 %, as the temperature increased. However, the yield strength unusually increased from 146 MPa at 373 K to 181 MPa at 473 K due to the strengthening effect that intermetallic compounds block the movement of dislocations. Additionally, the creep test of HPDC AA365 alloy was performed in the temperature range of 373 K to 573 K with a constant applied stress of 64 to 217 MPa. Firstly, the micro-hardness test before the creep test showed 93.5 HV, whereas it decreased to 64.0 HV and 49.9 HV for the gauge and grip sections, respectively, after the creep test. The recovery and recrystallization caused a decrease in the hardness after the test. Furthermore, the difference in the grain size led to the discrepancy of micro-hardness in the gauge and grip sections. Based on the minimum creep strain rate through the creep test, true stress exponents (n) were presented as 1 to 90.7, indicating various creep mechanisms, such as the Harper-Dorn, dislocation, and power-law breakdown (PLB). Considering the high n (22.4 to 90.7) and the apparent activation energy (259.08 kJ/mol), the threshold stress of AA365 alloy could be proved on certain experimental conditions, indicating the high creep resistance with a comparison of other Al alloys and Al-based composites. All failures of the alloys were stimulated by micro-void, cracked-brittle intermetallics and Si particles. In addition to the characteristic of the alloy under high temperatures, the electrochemical property of AA365 alloy was investigated with the aim of understanding the effect of T4 (813 K for 8hours) heat treatment (ST) on the electrochemical properties of AA365 alloy with various cooling media, i.e., furnace (E), air (A), forced air (FA), and water (WQ). In terms of the microstructure, the amount and size of intermetallics and eutectic Si strongly depend on the cooling rate after heat treatment, predicting that ST-WQ AA365 alloy would be less harmful to the corrosion with few intermetallics and eutectic-Si particles by a rapid cooling rate. By conducting the immersion test in 3.5 wt.% NaCl at first, it was found that ST-WQ AA365 alloy showed 1.66 mpy of the lowest corrosion rates and 1.40 of a low fitting factor rather than the values of the alloys cooled at other media. Through the cyclic potentiodynamic polarization (CPDP) and electrochemical impedance spectroscopy (EIS) tests in 3.5 wt.% NaCl, ST-WQ AA365 alloy had the lowest corrosion current density (0.394 x 10-6 Acm-2) and the highest value of corrosion potential (-707.8 mVSCE), and this also showed a larger value of impedance more than the as-cast and other AA365 alloys cooled with furnace and air after T4 heat treatment. Consequently, this research could prove the excellent high-temperature mechanical property of HPDC AA365 alloy and recognize the effect of the cooling rate after T4 heat treatment on AA365 alloys, authenticating the superior corrosion resistance of the alloys. Based on the results of this study, the excellence of this alloy's parts can contribute to improving the reliability and safety of application in various industries. -
dc.description.tableofcontents 1. Introduction 1.1 Trends of Automotive Industry 1 1.2 Research Trend of Al-Si alloy in Automotive Industry 5 1.3 Objectives of Research 7 2. Theoretical Background 2.1 Characteristics of Aluminum alloy 9 2.1.1 Classification of Aluminum alloy 10 2.1.2 Alloying elements of Aluminum alloy 12 2.2 Manufacturing Process of Aluminum alloy 16 2.2.1 Casting 16 2.2.2 High-pressure die-casting (HPDC) 18 2.3 Heat treatment of Aluminum alloy 19 2.3.1 Annealing 22 2.3.2 Solution heat treatment 22 2.3.3 Aging heat treatment 23 2.4 Fe-rich intermetallic compounds in Al-Si alloy 25 2.4.1 β-Al5FeSi intermetallic phase 27 2.4.2 α-Al15(Fe,Mn)3Si2 intermetallic phase 28 2.5 Creep 29 2.5.1 Creep deformation 29 2.5.2 Creep deformation mechanism 32 2.6 Corrosion 35 2.6.1 Pitting corrosion of Aluminum alloy 35 2.6.2 Galvanic corrosion of Aluminum alloy 36 3. Mechanical Property of High-pressure die-casting(HPDC) AlSi10MnMg alloy 3.1 Objective 38 3.2 Experimental Methods 39 3.2.1 Materials 39 3.2.2 Heat treatment process 40 3.2.3 Tensile test 42 3.2.4 High-temperature tensile test 42 3.2.5 Micro-hardness test 42 3.2.6 Creep test 42 3.2.7 Characterization of microstructure in AA365 43 3.3 Results and Discussion 44 3.3.1 Microstructure of as-cast, T4/T6 heat treated, and HPDC AA365 44 3.3.2 Tensile property of as-cast, T4/T6 heat treated and HPDC AA365 53 3.3.3 High-temperature tensile property of HPDC AA365 55 3.3.4 Micro-hardness property of HPDC AA365 58 3.3.5 Creep behavior of HPDC AA365 62 3.3.6 Fracture surface of HPDC AA365 72 3.4 Conclusions 74 4. Electrochemical Property of as-cast and T4 heat treated AlSi10MnMg alloy with various Cooling Media 4.1 Objective 78 4.2 Experimental Methods 79 4.2.1 Materials 79 4.2.2 Heat treatment process 81 4.2.3 Immersion test 82 4.2.4 Electrochemical measurements 84 4.2.5 Characterization of microstructure in AA365 86 4.3 Results and Discussion 87 4.3.1 Microstructure of as-cast and T4 heat treated AA365 alloy with various cooling rates 87 4.3.2 Corrosion mechanism of AA365 alloy 93 4.3.3 Immersion test of AA365 alloy in 3.5 wt.% NaCl for 30 days 96 4.3.4 Open circuit potential (OCP) of as-cast and T4 heat treated AA365 alloys 101 4.3.5 Cyclic potentiodynamic polarization (CPDP) of as-cast and T4 heat treated AA365 alloys 103 4.3.6 Electrochemical impedance spectroscopy (EIS) of as-cast and T4 heat treated AA365 alloys 107 4.4 Conclusions 113 5. Conclusions 116 References 119 Acknowledgment -
dc.language kor -
dc.publisher 한국해양대학교 대학원 -
dc.rights 한국해양대학교 논문은 저작권에 의해 보호받습니다. -
dc.title Microstructural Analysis on the High-temperature Mechanical and Electrochemical Behaviors of AlSi10MnMg die-cast alloy for Automobile Applications -
dc.title.alternative 자동차 부품용 AlSi10MnMg 다이캐스트 합금의 고온 기계적 및 전기 화학적 거동에 관한 미세구조적 분석 -
dc.type Dissertation -
dc.date.awarded 2021. 2 -
dc.embargo.liftdate 2021-03-11 -
dc.contributor.department 대학원 조선기자재공학과 -
dc.contributor.affiliation 한국해양대학교 대학원 조선기자재공학과 -
dc.description.degree Master -
dc.identifier.bibliographicCitation [1]안철민, “Microstructural Analysis on the High-temperature Mechanical and Electrochemical Behaviors of AlSi10MnMg die-cast alloy for Automobile Applications,” 한국해양대학교 대학원, 2021. -
dc.subject.keyword AlSi10MnMg aluminum alloy -
dc.subject.keyword High-pressure die-casting -
dc.subject.keyword High-temperature tensile property -
dc.subject.keyword Creep -
dc.subject.keyword Corrosion resistance -
dc.subject.keyword Microstructure -
dc.identifier.holdings 000000001979▲200000001935▲200000376090▲ -
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