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Bu çalışmada, Ti-6Al-4V alaşımının kaba taneli ve eşit kanallı açısal presleme (EKAP) ile üretilen ultra ince taneli durumda, quasi-statik tek eksenli çekme yüklemesi altında (yaklaşık 10-3 s-1 deformasyon hızı ile) sergilediği mekanik davranış ve makroskobik deformasyon modu (homojen vs. lokalize) karakterize edilmiştir. EKAP işleminin ve farklı kanal iç açılarının çekme dayanımı, kopma uzaması (süneklik), üniform uzama ve sertlik gibi malzemenin mekanik özelliklerine etkisi kapsamlı bir şekilde incelenmiştir. Dijital görüntü korelasyon (DIC) tekniği ile tüm çekme testleri esnasında yüzey deformasyon alanları in-situ olarak ölçülmüştür. Çift paso EKAP işlemi sonrası malzemenin çekme dayanımı, akma dayanımı ve sertliğinin sırasıyla 795,8 MPa, 660 MPa ve 255 HV’den, 120° kanal iç açılı kalıpla EKAPlanmış numunede 918,3 MPa, 850 MPa, 303 HV ve 90° kanal iç açılı kalıpla EKAPlanmış numunede ise 990,5 MPa, 890 MPa, 343 HV değerlerine ulaştığı görülmüştür. Ancak, tanelerin EKAP prosesi neticesinde incelmesi, malzemenin müteakip kırılmasını tetikleyebilecek olan erken zamanlı deformasyon lokalizasyonuna bağlı olarak üniform uzama ve kopma uzamasında önemli bir gerilemeyi beraberinde getirmektedir. DIC verileri, başlangıç numunesinde (EKAP öncesi) deformasyonun homojen olarak ilerlediğini; çift paso EKAP işlemi sonrası çekme yüklemesine tabi tutulan numunede ise deformasyonun daha ziyade inhomojen/lokalize bir mod eğilimi sergilediğini açıkça ortaya koymaktadır. Bu çalışma kapsamında elde edilen sonuçlar, EKAP sonrası plastik deformasyona tabi tutulan malzemenin makroskobik deformasyon modu ile sünekliği arasındaki ilişkiye dair yeni bakış açıları kazandırmaktadır.
In this study, the Ti-6Al-4V alloy has characterized the mechanical behavior and macroscopic deformation mode (homogene vs. localized) displayed under a quasi-static single-axis drawing load (with about 10-3 s-1 deformation speed) in the ultra-finest deformation case produced with crude and equal canal angle pressing (EKAP). The impact of the ECAP process and the mechanical characteristics of the material, such as the drawing resistance of the different inner corners of the channel, the break-out extension (sweating), uniform extension and hardness, has been thoroughly studied. With the digital image correlation (DIC) technique, the surface deformation fields are measured in-situ during all drawing tests. The drawing resistance, flow resistance and hardness of the material after the double pass ECAP process, respectively, from 795,8 MPa, 660 MPa and 255 HV, 120° channel internal corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner corner. However, the scanning of the tanes as a result of the ECAP process leads to a significant decline in the uniform extension and break extension due to the early deformation localization that could trigger reverse breakdown of the material. DIC data clearly show that in the starting sample (pre-ECAP) deformation progresses homogeneously; in the sample subject to double pass ECAP post-tracking load, the deformation shows a more inhomogeneous/localized mode tendency. The results obtained in this study provide new perspectives on the relationship between the macroscopic deformation mode and the synchronousness of the material subject to post-ECAP plastic deformation.
In this study, the mechanical behavior and the macroscopic deformation mode with respect to localized vs. homogenous deformation under quasi-static uniaxial tensile loading (at the strain rate of about 10-3 s-1) of Ti-6Al-4V alloy in the as-received (coarse-grained) and the ultrafine-grained (UFG) state produced by equal-channel angular pressing (ECAP) are characterized. The effect of ECAP process and different intersecting channel angles on the mechanical properties such as the tensile strength, the ultimate strain (ductility), the uniform elongation and the hardness is studied extensively. Digital image correlation (DIC) is used to document the surface strain fields in situ during all the tensile tests. It is shown that the tensile strength, the yield strength and the hardness of the material increased from 795,8 MPa, 660 MPa and 255 HV to 918,3 MPa, 850 MPa, 303 HV and 990,5 MPa, 890 MPa, 343 HV by applying two passes of ECAP using a mold with an intersecting channel angle of 120° and 90°, respectively. However, a refinement of the grains by ECAP leads to a significant decrease in the uniform elongation and ultimate strain due to the early stage strain localization, which may provide the nuclei for subsequent fracture of the material. DIC-images clearly indicate that in the as-received state, the deformation proceeds homogeneously, whereas after two passes of ECAP, the deformation tends to an inhomogeneous/localized macroscopic mode. The results presented in this work provide new insights into the relationship between the macroscopic deformation mode and the ductility of the ECAPed material.
Field : Fen Bilimleri ve Matematik; Mühendislik
Journal Type : Ulusal
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