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"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."

"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."

"ABSTRAKSeiring dengan perkembangan ilmu pengetahuan dan teknologi banyak sifat-sifat dari alam yang sebenarnya bisa direplika untuk dimanfaatkan, seperti terumbu karang yang ternyata mempunyai porositas yang bisa dimanfaatkan pada bidang heat exchanger dan diaplikasikan pada Loop heat pipe, proses fabrikasi dengan menggunakan metode powder mettalurgy dengan material tembaga dan polyprophylene diharapkan mampu untuk menciptakan porositas yang menyerupai terumbu karang. Metode Powder mettalurgy yang dilakukan pada penelitian ini bertujuan untuk mendapatkan nilai porositas dengan menggunakan, Proses mixing material, proses kompaksi serta 3 variabel temperatur dan waktu tahan pada proses debinding dan sintering untuk menentukan nilai porositasnya. hasil dari penelitian menunjukkan bahwa semakin tinggi temperatur dan lamanya waktu tahan pada proses sintering maka nilai dari densitasnya akan semakin tinggi akan tetapi nilai dari porositasnya semakin turun. Ikatan dari material serbuk tembaga yang membentuk neck formed pada proses sintering akan menentukan ukuran nilai porositas dan kemampuan permeabilitasnya

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ABSTRACTAlong with the development of science and technology many of the attributes of nature that can actually be replicated to be used, such as coral reefs which have a porosity that can be used in the field of heat exchangers and applied to the Loop heat pipes, the fabrication powder mettalurgy process using the material copper and polypropylene expected to be able to create porosity like a coral reefs. Powder mettalurgy method performed in this study purpose to obtain porosity values using, material mixing process, the process of compaction and 3 variable temperature and holding time on debinding and sintering process to determine the value of porosity. the results of the study showed that the higher the temperature and the length of holding time at the sintering process, the value of the density will be higher but the value of porosity getting down. Bonding of copper powder material that forms the neck formed in the sintering process will determine the size of the porosity value and capabilities permaeabilitas"

"Zirkonium-Niobium paduan (Zr-Nb paduan) memiliki potensi untuk menggantikan implant Titanium kontemporer dengan mempertimbangkan sitotoksisitas nya, suseptibilitas magnetik dan ketahanan korosi. Metalurgi serbuk sebagai salah satu metode pembentukan dapat digunakan dalam produksi implant dengan desain rumit dan struktur mikro yang fleksibel, baik dalam komposisi dan porositas. Pemadatan dan sintering dilakukan untuk menghasilkan produk yang padat dengan porositas. Pengamatan morfologi porositas akan diamati dengan mikroskop optik dan jumlah porositas dalam paduan akan diamati dengan pengujian porositas. Sedangkan struktur kristal diamati dengan dan X-Ray Diffraction (XRD). Konstituen fasa mikro sangat tergantung pada komposisi Niobium. Pengujian kekerasan menunjukkan peningkatan seiring dengan penambahan jumlah Niobium. Sementara itu penambahan Niobium akan menurunkan jumlah porositas dan mengubah morfologi porositas menjadi berbentuk jaring. Penambahan Niobium dalam jumlah besar membutuhkan temperature sintering yang jauh lebih tinggi dibandingkan paduan dengan jumlah Niobium lebih kecil.

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Zirconium-Niobium alloy (Zr-Nb alloy) has potency to replace the contemporary Titanium bioimplant by considering its cytotoxicity, magnetic susceptibility and corrosion resistance. Powder metallurgy as one of the forming methods could be used in production of bioimplant with intricate design and flexible microstructure, both in composition and porosity. Compaction and sintering is carried out to produce solid product with remained porosity. Resulting porosity of Zr-Nb alloy produced by powder metallurgy method will be characterized by density measurements and optical microscopy. Crystalline structure is observed by X-Ray Diffraction (X-RD). The microphase constituent is highly dependent on Niobium composition. The density of alloy will decrease as the addition of Niobium. In contrary, the hardness of alloy will increase as the addition of Niobium."

"Logam berstruktur busa ini dikembangkan untuk perancah jaringan tulang untuk memperbaiki tulang yang patah. Material dengan biokompatibilitas, sifat mekanis, kemampuan degradasi yang baik, tidak beracun, dan osointegrasi yang baik dibutuhkan. Penelitian sebelumnya menggunakan kalium karbonat (K2CO3) sebagai agen pembentuk busa untuk Fe-35Mn-0,5C menghasilkan poros berbentuk tak beraturan.Pada penelitian ini, carbamide berbentuk bulat berukuran diameter 1-2 mm dicampur dengan Fe-35Mn-0,5C untuk menghasilkan porositas yang berbentuk bulat. Fabrikasi sampel menggunakan proses metalurgi serbuk dengan penambahan 5% dan 10% carbamide untuk Fe-35Mn-0,5C. Dua percobaan dalam atmosfer gas argon dilakukan pada temperatur 200⁰C selama dua jam untuk mendekomposisi carbamide kemudian dinaikkan ke 1100⁰C selama 1,5 jam untuk pemadatan sampel, dan pada temperatur 250⁰C selama 3 jam untuk melihat dekomposisi carbamide.Hasil sinter dikarakterisasi oleh pengujian densitas dan porositas, mikroskop dan makroskop optik, dan XRD. Semakin banyak carbamide yang ditambahkan, densitas semakin menurun dan porositas meningkat. Hal ini juga membuktikan bahwa carbamide dapat membentuk porositas bulat dengan ukuran masih dalam rentan diameter carbamide. Fasa pada sampel 5% dan 10% carbamide adalah austenit, ferit, dan MnO.

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The metal foam has been developed for bone tissue scaffold to repair bone fracture. Material with good biocompatibility, mechanical properties, degradability, non-toxic, and good ossointegration is needed. Previous research used potassium carbonat as foaming agent for Fe-35Mn-0,5C produced irregular shape of porous.

In this research, spherical carbamide with diameter range of 1-2 mm was mixed with Fe- 35Mn-0,5C to produce spherical porosity. Fabrication of samples used powder metallurgy process by adding of 5% dan 10% weight percent of carbamide to Fe- 35Mn-0,5C. Two experiments in argon atmosphere were conducted at 200⁰C for 2 hour to decompose carbamide then at 1100⁰C for 1,5 hour to densify samples, and at 250⁰C for 3 hour to approving carbamide decomposition.

Sinter product characterized by density and porosity testing, optical microscope and macroscope, and XRD. Addition more content of carbamide resulted in lower density and higher porosity. It is also approved that carbamide produced spherical porosity with size within range of carbamide diameter. Phases of 5% and 10% carbamide samples are austenite, ferrite, and MnO."