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"Progress in the understanding of corrosion and corrosion resistance properties of sintered stainless steels has lead to new applications that benefit from net shape processing and more efficient material utilization."

"Powder Metallurgy merupakan proses manufaktur yang dapat di aplikasikan pada industri pada saat ini dengan menggabungkan proses produksi, pemrosesan (Pre Compaction dan Compaction) dan penguatan (Sintering) dari partikel ukuran kecil untuk pembuatan benda dari logam. Keuntungan utama dari proses Powder Metallurgy yaitu terletak pada penggunaan raw material yang lebih efisien karena produk Powder Metallurgy menghasilkan produk yang mendekati dimensi akhir. Proses manufaktur dengan Powder Metallurgy juga memangkas beberapa proses pemesinan seperti finishing. Selain itu keuntungan lain yang didapat yaitu proses produksi dengan Powder Metallurgy dapat membuat benda dengan bentuk yang rumit, yaitu dengan proses Selective Laser Sintering dan 3D Printing. Penelitian pembuatan serbuk Stainless Steel 316L dilakukan dengan metode plasma atomisasi. Proses plasma atomisasinya menggunakan mesin inverter plasma cutting sebagai sumber arus untuk elektroda penghasil plasma, alat pengumpan filler otomatis sebagai alat pengumpan bahan baku berupa batang SS316L dan alat pengumpan gouging otomatis untuk menjaga kesetabilan Arc Length. Berdasarkan penelitian ini diketahui variasi arus mempengaruhi particle size distribution D10 dan D30 pada metode otomatis atau manual. Variasi kecepatan umpan tidak berpengaruh terhadap distribution particle size pada metode otomatis dan manual. Variasi kecepatan gouging tidak berpengaruh terhadap distribution particle size pada metode otomatis dan manual. Hasil serbuk terbanyak pada ukuran mesh 100 dan 120 adalah dengan metode otomatis variasi A11 (25A, PWM 35, Delay 10000). Lima hasil serbuk dengan tingkat homogenitas terbaik adalah proses plasma atomisasi dengan metode otomatis variasi A7, A10, A11, A8 dan A12.

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Powder Metallurgy is a manufacturing process that can be applied to industry by combining the production, processing (Pre Compaction and Compaction) and strengthening (Sintering) processes of small particles for the manufacture of metal objects. The main advantage of the Powder Metallurgy process lies in the more efficient use of raw materials, because Powder Metallurgy products produce that are close to the final dimensions. The manufacturing process with Powder Metallurgy also cuts down on some machining processes such as finishing. In addition, another advantage obtained is that the production process with Powder Metallurgy can make objects with complex shapes, namely the Selective Laser Sintering and 3D Printing process. Research on the manufacture of 316L Stainless Steel powder was carried out using the plasma atomization method. The plasma atomization process uses an inverter plasma cutting machine as a current source for plasma producing electrodes, an automatic filler feeder as a raw material feeder in the form of SS316L rods and an automatic gouging feeder to maintain Arc Length stability. Based on this research, it is known that current variations affect the particle size distribution of D10 and D30 in automatic or manual methods. Variation of feed speed has no effect on particle size distribution in automatic and manual methods. Gouging speed variation has no effect on particle size distribution in automatic and manual methods. The highest yield of powder at mesh sizes of 100 and 120 is the automatic method of variation A11 (25A, PWM 35, Delay 10000). The five powders with the best homogeneity level were the plasma atomization process using the automatic variation method A7, A10, A11, A8 and A12.

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"Detailed discussions and over 250 graphs and charts describe the effects of microstructure on the properties of carburized stees. In-depth coverage clarifies the causes, interpretation, prevention, and consequences of various microstructural variations and defects in carburized parts. Also covered are the effects of post-hardening heat treatments, surface grinding, and shot peening. Contents: Internal Oxidation Decarburization Carbides Retained Austinite Grain size, Microsegregation, and Microcracking Core Properties and Case Depth Post Hardening Heat Treatments Post Carburizing Mechanical Treatments."

"This work in three parts presents a summary of the sintered manganese steel properties from 1948 to 2011 involving processing conditions and other characteristics. In the first and third part are given results attained by the authors based on their finding that manganese (cheapest element) during sintering evaporates and by this the vapour cleans the sintering atmospheres from humidity. The second part presents other positive properties of manganese steels in spite of the doubt of oxidation of manganese during sintering and by this excluding the sintering manganese steels what hinderd the use of manganese in production of sintered parts. All results confirm that only manganese vapour according to finding of the authors ensures effective sintering of manganese steels and parts independently on the authors mind. It follows finally from the work that manganese is possible to use for alloying of powder steels sintered also in practice in H/N atmospheres with low purity and also in pure nitrogen."

"Powder metallurgy (PM) is a popular metal forming technology used to produce dense and precision components. Different powder and component forming routes can be used to create an end product with specific properties for a particular application or industry. Advances in powder metallurgy explores a range of materials and techniques used for powder metallurgy and the use of this technology across a variety of application areas.Part one discusses the forming and shaping of metal powders and includes chapters on atomisation techniques, electrolysis and plasma synthesis of metallic nanopowders. Part two goes on to highlight specific materials and their properties including advanced powdered steel alloys, porous metals and titanium alloys. Part three reviews the manufacture and densification of PM components and explores joining techniques, process optimisation in powder component manufacturing and non-destructive evaluation of PM parts. Finally, part four focusses on the applications of PM in the automotive industry and the use of PM in the production of cutting tools and biomaterials."

"A collective effort of 53 recognized experts on aluminum and aluminum alloys. This book is a joint venture by world-renowned authorities and the Aluminum Association Inc. and ASM International."