E120C-GH4 METAL ÖZLÜ VE ER120S-G MASİF TELİN TEL ARK EKLEMELİ İMALATI (WAAM) İÇİN KARŞILAŞTIRMALI PROSES PARAMETRE OPTİMİZASYONU

Year 2024, EARLY VIEW, 1 - 1

Mustafa Harman , Cemil Çetinkaya , Oğuzhan Yılmaz , Nevzat Bol

https://doi.org/10.2339/politeknik.1478172

Abstract

Tel ark eklemeli imalat (WAAM) yöntemi, parçaya özel CAD modeli dikkate alınarak büyük ve orta karmaşıklıktaki parçaların katman katman üretilmesine olanak sağlayan bir metal eklemeli imalat yöntemidir. Proses parametreleri, minimum ısı girdisi, daha az üretim süresi, daha yüksek metal biriktirme hızı ve duvar geometrisi elde etmek üzere optimize edildi. 1,2 mm çapında E120C-GH4 metal özlü dikişsiz yüksek mukavemetli tel ve aynı çapta ER120S-G masif tel, (düşük, orta, yüksek) ısı girdili farklı tel besleme hızlarında kullanıldı. Bu tellerin her birine tek ve çift katmanlı 18 tane duvar biriktirildi. Makro kesit incelemesi ve makro sertlik ölçümü işlemleri için numuneler hazırlandı. Benzer biriktirme hacimlerine sahip numuneler duvar geometrisi, mikrosertlik, penetrasyon derinliği, biriktirme süresi ve eşit ısı girdisinde metal biriktirme hızı açısından karşılaştırıldı. Taguchi yöntemi yardımıyla örnekler çoklu regresyon analizine tabi tutuldu. Böylece analizler ve gerçek deneyler karşılaştırmalı deneysel çalışmalara olanak sağladı. Sonuç, ekonomi ve zaman dikkate alındığında, metal özlü telin WAAM endüstrisi için daha çok tercih edileceğini göstermektedir çünkü metal özlü tel, masif telden %43 daha az üretim süresine ve %74 daha yüksek metal biriktirme oranına sahiptir.

Keywords

Metal özlü tel, Taguchi metodu, zırh çeliği, WAAM, Makro kesit

Ethical Statement

Bu makalenin yazar(lar)ı çalışmalarında kullandıkları materyal ve yöntemlerin etik kurul izni ve/veya yasal-özel bir izin gerektirmediğini beyan ederler.

Supporting Institution

GAZİ ÜNİVERSİTESİ BİLİMSEL ARAŞTIRMA PROJELERİ KOORDİNASYON BİRİMİ

Project Number

FDK-2022-8106

Thanks

Intecro Robotik A.Ş'ye sunmuş olduğu makine parkı ve tezgah altyapısı için teşekkür ederiz.

Comparative Process Parameter Optimization For Wire Arc Additive Manufacturing (WAAM) of E120C-GH4 Metal Cored and ER120S-G Solid Wire

Abstract

Wire arc additive manufacturing (WAAM) method is a metal additive manufacturing method that allows the production of large and medium complexity parts layer by layer by considering the part-specific CAD model. Process parameters were optimized to achieve minimum heat input, less production time, and higher metal deposition rate and bead geometry. E120C-GH4 metal-cored seamless high-strength wire with a diameter of 1.2 mm and an ER120S-G solid wire of the same diameter were used at different wire feeding speeds with heat input (low, medium, high). Single and double layer 18 beads were deposited with each of these wires. Samples were prepared for macro section examination and macro hardness measurement processes. Samples with similar deposition volumes were compared in terms of bead geometry, microhardness, penetration depth, deposition time, and the metal deposition rate at the equal heat input. With the aid of the Taguchi method and the samples were subjected to multiple regression analyses. So, the analyses and real experiments allowed comparative experimental studies. Considering the economy and time, the result shows that metal-cored wire will be much preferable for the WAAM industry because metal-cored wire has 43% less production time and 74% higher metal deposition rate than solid wire.

Keywords

Metal cored wire, Taguchi method, Armor steel, WAAM, macro section.

Project Number

FDK-2022-8106

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