AA2024 ALAŞIMINDA SIMA YÖNTEMİ İLE TİKSOTROPİK YAPI ÜRETİMİ ÜZERİNE YENİDEN ISITMA SICAKLIĞININ ETKİSİ

Bu çalışmada, bir dövme alüminyum alaşımı olan AA2024 alaşımında gerinimin neden olduğu sıvı aktivasyonu(strain induced melt activated-SIMA) yöntemi ile yarı-katı şekillendirme için gerekli tiksotropik mikroyapıüretimi araştırılmıştır. Bu amaçla ekstrüze halde AA2024 alaşımı %20 oranında soğuk deformasyona tabitutulmuş ve takiben %30, %40 ve %50 sıvı oranına karşılık gelen yarı-katı sıcaklıklara ısıtılarak oda sıcaklığınasahip suda soğutulmuştur. Mikroyapı analizleri metalografik inceleme ve nicel ölçüm yöntemleri ile yapılmıştır.Deneysel sonuçlar, SIMA yöntemiyle AA2024 alaşımında, yarı katı şekillendirme için gerekli olan küreselşekilli tiksotropik mikroyapıların üretilebileceğini göstermiştir. Artan yarı-katı sıcaklıkla tane boyutu artarkenşekil faktöründe belirgin bir değişim gözlenmemiştir. SIMA yöntemi ile tiksotropik yapı üretimi için yarı-katısıcaklıklarda izotermal bekletmeye gerek olmadığı tespit edilmiştir.

Anahtar Kelimeler:

Yarı-katı şekillendirme, Yarı-katı sıcaklık, AA2024 alaşımı, Tiksotropik yapı, SIMA.

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Spencer, D.B., Mehrabian, R. and Flemings,
M.C., “Rheological Behavior of Sn-15 pct Pb in
the Crystallization Range”, Metallurgical
Transaction A, 3A:1925-1932 1972.
Flemings, M.C., Riek R.G. and Young K.P.,
“Rheocasting”, Materials Science and
Engineering, 25:103-117 1976.
Zoqui, E.J., Paes, M., Es-Sadiqi, E., “Macro- and
microstructure analysis of SSM A356 produced
by electromagnetic stirring” Journal of
Materials Processing Technology, 120: 365–
2002.
Tzimas, E., “Evolution of microstructure and
rheological behavior of alloys in the semi solid
state”, Ph.D. Thesis, Drexel University, USA,
-12 1997.
Kapranos, P., Ward P.J., Atkinson H.V. and
Kirkwood D.H., “Near net shaping by semi-solid
metal processing” Materials and Design, 21
(4): 387-394 2000.
Li, D. N., Luo, J. R., Wu, S. S., Xiao, Z. H.,
Mao, Y. W., Song, X. J., Wu, G. Z., “Study on
the semi-solid rheocasting of magnesium alloy
by mechanical stirring”, Journal of Materials
Processing Technology, 129 (1-3): 431-434
-
Hirt, G., and Kopp, R., “Semi-solid Metal
Processing” WILEY-VCH Verlag GmbH &
Co, Weinheim 2009.
Czerwinski F. “Semisolid Processing—Origin of
Magnesium Molding”, Magnesium Injection
Molding, Springer US, USA, 81-145 2007.
Abramov, V. O., Abramov, O. V. Abramov, B.
B. Straumal and W. Gust, “Hypereutectic Al-Si
based alloys with a thixotropic microstructure
produced by ultrasonic treatment”, Materials
and Design, 18: 323-326 1997.
Taghavi, F., Ghassemi, A., “Study on the effects
of the length and angle of inclined plate on the
thixotropic microstructure of A356 aluminum
alloy”, Materials and Design 30:1762–1767
-
Liu, D., Atkinson, H.V., Kapranos, P.,
Jirattiticharoean W. and Jones, H.,.
“Microstructural evolution and tensile
mechanical properties of thixoformed high
performance aluminium alloys”, Materials
Science and Engineering A, 361 (1-2): 213-224
-
Nafisi, S., Lashkari, O., Ghomashchi, R.,
Ajersch, F., Charette, A., “Microstructure and
rheological behavior of grain refined and
modified semi-solid A356 Al–Si slurries”, Acta
Materialia, 54: 3503–3511 2006.
Doutre, D, Hay, G., Wales, P. and Gabathuler,
J.P. “SEED: A new process por semi solid
forming”, Canadian Metallurgical Quarterly,
(2): 265-272, 2004.
Birol Y., “Internal Cooling to produce
aluminium alloy slurries for rheocasting”,
Journal of Alloy and Compounds, 480 (2):
-368 2009.
Birol Y., “Production of Al-7Si-0.3Mg slurry for
rheocasting via internal cooling of the melt
below liquidus temperature”, Metallic
Materials, 47 (9): 401-407 2009.
Martinez, R.A. and Flemings, M.C., “Evolution
of particle morphology in the semisolid
processing”, Metallurgical and Materials
Transactions A, 36 (8): 2205-2210 2005.
Atkinson, H.V., Liu, D., “Microstructural
coarsening of semi-solid aluminium alloys”,
Materials Science and Engineering A, 496 (1-
:439-446 2008.
Young, K.P., Curtis, P.K. and James,.C., “Fine
Grained Metal Composition”, United States
Patent, Patent No: 4415374, USA 1983.
Sirong, Y., Dongcheng, L., Kim, N.,
“Microstructure evolution of SIMA processed
AA2024”, Materials Science and Engineering
A, 420 (1-2):165-170 2006.
Choi, J. C., Park, H. J. “Microstructural
characteristics of aluminum 2024 by cold
working in the SIMA process.” Journal of Materials Processing Technology, 82: 107–116
-
Kopp, R., Winning G. and Möller T.,
“Thixoforging of aluminium alloys” METEC,
Düsseldorf 1999.
Jung, H.K. Kang C.G. “Reheating process of
cast and wrought aluminum alloys for
thixoforging and their globularization
mechanism”, Journal of Materials Processing
Technology, 104: 244-253 2000.
Guo, H., Yang, X.,” Preparation of semi-solid
slurry containing fine and globular particles for
wrought aluminum alloy 2024” Trans.
Nonferrous Met. Soc. China 17: 799-804 2007.
Akar, N., Mutlu, I., “Effect of Predeformation
Rate in SIMA Process on Thixotropic Structure
of AA2024 Aluminium Alloy”, Journal of The
Faculty of Engineering and Architecture of
Gazi University, 25(4): 663-670 2010.
Chayong, S., Atkinson, H.V. and Kapranos, P.,
“Multistep induction heating regimes for
thixoforming 7075 aluminium alloy”, Materials
Science and Technology, 20 (4): 490-496 2004.
Figueredo, A., “Science and technology of semisolid
metal processing” North America Die
Casting Associtation, USA, 1-17, 2001.
Tzimas, E. and Zavaliangos, A., “Evaluation of
volume fraction of solid in alloys formed by
semisolid processing”, Journal of Materials
Science, 35 (21): 5319-5329 2000.
Zoqui E.J. “Morphological analysis of SSM Al–
5 wt.% Cu measured by the rheocast quality
index”, Journal of Materials Processing
Technology, 143–144: 195–201 2003.
Jiang, H., Lu, Y., Huang, W., Li, X., Li, M.,
“Microstructural evolution and mechanical
properties of the semisolid Al–4Cu–Mg alloy”,
Materials Characterization, 51: 1– 10 2003.
Jiang, H., Li, M., “Microscopic observation of
cold-deformed Al–4Cu–Mg alloy samples after
semi-solid heat treatments”, Materials
Characterization, 54: 451– 457 2005.
Jiang, H. and Li, M., “Grain growth of Al-4Cu-
Mg alloy during isothermal heat treatment”,
Journal of University of Science and
Technology Beijing, 13(1): 67-72 2006.
Jiang, H., Mi, Z., Tang, D., and Li, M.,
“Microstructure evolution of Al-4Cu-Mg alloy
during semi-solid treatment”, Journal of
University of Science and Technology Beijing,
(2): 151-156 2007.
Wang, S., Li, Y., Chen, W., Zheng, X.,
“Microstructure evolution of semi-solid 2024
alloy during two-step reheating process”,
Transactions of Nonferrous Metals Society of
China, 18 (4): 784-788 2008.
Atkinson, H.V., Kapranos, P., Liu, D., Chayong
S.A. and Kirkwood D.H. Thixoforming of
normally wrought aluminium alloys”, Materials
Science Forum, 396-402 (3): 131-136 2002.
Atkinson, H.V., “Modelling the semisolid
processing of metallic alloys”, Progress in
Materials Science, 50 (3): 341-412 2005.
Fan, Z., “Semisolid metal processing”
International Materials Reviews, 47(2): 49-85
-
Zhang, L., Liu, Y.B., Cao, Z.Y., Zhang, Y.F.,
Zhang, Q.Q. “Effects of isothermal process
parameters on the microstructure of semisolid
AZ91D alloy produced by SIMA”, Journal of
Materials Processing Technology, 209: 792–
2009.
Verhoeven, J.D., “Fundamentals of physical
metallurgy”, John Wiley & Sons Inc., Canada,
, 200, 347 1975.
Porter, D.A., and Easterling K.E. “Phase
transformation in metals and alloys” CRC
Press, UK, 131 2001.
Kim, N.S. and Kang, C.G., “An investigation of
flow characteristics considering the effect of
viscosity variation in the thixoforming process”,
Journal of Materials Processing Technology,
: 237-246 2000.
Birol, Y., “Thermomechanical processing of
AA6061 billets for semi-solid forming”,
International Journal of Materials Research,
(1): 53-59, (2007).
Atkinson, H.V., Burke K. and Vaneetveld G.,
“Recrystallization in the semi-solid state in 7075
aluminium alloy”, Materials Science and
Engineering A, 490 : 266-276 2008.
Önsel, M., “The influence of heating conditions
on semi-solid forming of aluminum alloys”,
Yüksek Lisans Tezi, Boğaziçi Üniversitesi Fen
Bilimleri Enstitüsü, İstanbul, 90 2005.