Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution

BULDUK, MUSTAFA ENES; KOÇ, EBUBEKIR; Khan, Hamaid; TARAKÇI, Gürkan

doi:10.14744/ytu.jame.2021.00001

Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution

Hamaid Mahmood KHAN, (Fatih Sultan Mehmet Vakıf Üniversitesi, Alüminyum Testi Eğitim ve Araştırma Merkezi, İstanbul, Türkiye)

Gürkan TARAKÇI, (Fatih Sultan Mehmet Vakıf Üniversitesi, Alüminyum Testi Eğitim ve Araştırma Merkezi, İstanbul, Türkiye)

Mustafa Enes BULDUK, (Fatih Sultan Mehmet Vakıf Üniversitesi, Alüminyum Testi Eğitim ve Araştırma Merkezi, İstanbul, Türkiye)

Ebubekir KOÇ (Fatih Sultan Mehmet Vakıf Üniversitesi, Alüminyum Testi Eğitim ve Araştırma Merkezi, İstanbul, Türkiye)

journal of advances in manufacturing engineering (Online)

2 0

Yıl: 2021 Cilt: 2 Sayı: 1 Sayfa Aralığı: 1 - 6 Metin Dili: İngilizce DOI: 10.14744/ytu.jame.2021.00001 İndeks Tarihi: 02-05-2023

Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution

Öz:

Selective laser sintering (SLS) is a process of fabrication of three-dimensional structures by fusing powder particles using a guided laser source. The uncertainty in the mechanical properties of the SLS parts fabricated at the same time and with the same process parameters can affect the repeatability of the SLS process. A vast difference in the mechanical properties of the concurrently processed parts can lower the production quality of the batch. Therefore, the parameters are required to be design based on the most probable outcome of the desired properties. Weibull distribution is one such statistical-based probability distribution method to measure the likelihood of the occurrence of a value of any random variable falling within a particular range of values. Here, the Weibull distribution was used to measure the relative likelihood (90% probability) of the surface roughness and the compressive strength values of the SLS-built polyamide PA2200 components in the given sample space that was obtained from 20 random samples. The results show that the variance in the surface roughness (scan and built plane) and the compressive strength values were in the range of 6–7 μm and around 10 MPa, respectively. Moreover, the surface roughness of the two orthogonal planes with 90% reliability was measured at 14.81 μm (scan plane) and 12.15 μm (built plane). Similarly, the yield strength and the compressive strength with 90% reliability were found 25.87 MPa and 62.64 MPa, respectively.

Anahtar Kelime:

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

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APA	Khan H, TARAKÇI G, BULDUK M, KOÇ E (2021). Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. , 1 - 6. 10.14744/ytu.jame.2021.00001
Chicago	Khan Hamaid,TARAKÇI Gürkan,BULDUK MUSTAFA ENES,KOÇ EBUBEKIR Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. (2021): 1 - 6. 10.14744/ytu.jame.2021.00001
MLA	Khan Hamaid,TARAKÇI Gürkan,BULDUK MUSTAFA ENES,KOÇ EBUBEKIR Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. , 2021, ss.1 - 6. 10.14744/ytu.jame.2021.00001
AMA	Khan H,TARAKÇI G,BULDUK M,KOÇ E Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. . 2021; 1 - 6. 10.14744/ytu.jame.2021.00001
Vancouver	Khan H,TARAKÇI G,BULDUK M,KOÇ E Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. . 2021; 1 - 6. 10.14744/ytu.jame.2021.00001
IEEE	Khan H,TARAKÇI G,BULDUK M,KOÇ E "Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution." , ss.1 - 6, 2021. 10.14744/ytu.jame.2021.00001
ISNAD	Khan, Hamaid vd. "Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution". (2021), 1-6. https://doi.org/10.14744/ytu.jame.2021.00001

APA	Khan H, TARAKÇI G, BULDUK M, KOÇ E (2021). Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. journal of advances in manufacturing engineering (Online), 2(1), 1 - 6. 10.14744/ytu.jame.2021.00001
Chicago	Khan Hamaid,TARAKÇI Gürkan,BULDUK MUSTAFA ENES,KOÇ EBUBEKIR Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. journal of advances in manufacturing engineering (Online) 2, no.1 (2021): 1 - 6. 10.14744/ytu.jame.2021.00001
MLA	Khan Hamaid,TARAKÇI Gürkan,BULDUK MUSTAFA ENES,KOÇ EBUBEKIR Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. journal of advances in manufacturing engineering (Online), vol.2, no.1, 2021, ss.1 - 6. 10.14744/ytu.jame.2021.00001
AMA	Khan H,TARAKÇI G,BULDUK M,KOÇ E Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. journal of advances in manufacturing engineering (Online). 2021; 2(1): 1 - 6. 10.14744/ytu.jame.2021.00001
Vancouver	Khan H,TARAKÇI G,BULDUK M,KOÇ E Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution. journal of advances in manufacturing engineering (Online). 2021; 2(1): 1 - 6. 10.14744/ytu.jame.2021.00001
IEEE	Khan H,TARAKÇI G,BULDUK M,KOÇ E "Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution." journal of advances in manufacturing engineering (Online), 2, ss.1 - 6, 2021. 10.14744/ytu.jame.2021.00001
ISNAD	Khan, Hamaid vd. "Estimation of the compression strength and surface roughness of the as-built SLS components using weibull distribution". journal of advances in manufacturing engineering (Online) 2/1 (2021), 1-6. https://doi.org/10.14744/ytu.jame.2021.00001