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"Pure Al/SiC metal matrix composites (MMC) have been successful produced by the Lanxide process with different processing temperature for 8 hours. The process is simply without aid externally pressure. However, N2 oxygen free was flushed during the process. Molten pure Al has fully infiltrated to the preform with Sl/1% Mg at 750, 800, 850, 900 and 1000°C§ but infiltration did not occur to the preform with 3Vj'% Mg. Voids exist above the infiltrated preform in the systems with higher temperature (900 °C and 1000°C) for 8 hours. Such voids were not formed in the systems with low temperature. This paper described the investigation into the production of pure Al matrix composites, the eject of processing temperature will be investigated and the resulting will be fully characterised."

"ABSTRAKPada penelitian ini telah disintesis material komposit berbasis logam atau metal matrix composite MMC . Komposisi Al/SiC, dan AlCu/SiC sebagai material komposit hasil peleburan dan pemadatan solidifikasi dilakukan proses lebih lanjut dengan menggunakan penekanan panas 5 ton hot press pada temperatur 300o C. Analisis data XRD merupakan fasa tunggal Al dengan sistem kristal FCC yang memiliki kontanta kisi 4.0560 dengan bidang kristal pada intensitas terbesar 111 , 002 , 022 , 113 , 222 dan telah terjadi perubahan arah bidang kristal secara signifikan akibat penekanan panas hot press dan pendinginan cepat arah sejajar yaitu pada bidang 111 dan 002 dan arah tegak lurus atau melintang pada bidang kristal 022 . Hasil foto SEM pada permukaan morfologi padatan Al, Al/SiC 4 berat, dan AlCu/SiC 4 , permukaan pada arah sejajar tampak lebih merata dan lebih homogen secara bentuk struktur. Sedangkan permukaan pada arah tegak lurus atau penampang melintang sampel memiliki bentuk struktur yang berbeda dan membentuk arah memanjang tegak lurus terhadap arah penekanan pada proses penekanan panas. Nilai kekerasan Vickers HV secara keseluruhan sampel komposit AlCu/SiC hasil penekanan panas hot press lebih besar dibandingkan dengan Al/SiC untuk pendinginan lambat dan cepat. Juga termasuk dimana posisi permukaan melintang atau tegak lurus perpendicular memiliki nilai HV yang lebih besar dibandingkan dengan permukaan sejajar in-plan . Laju korosi mulai dari yang terbesar sampai terkecil adalah Al 1,8986. 10-3 , Al/SiC 1,2509. 10-3 mm/tahun , AlCu 1,1716. 10-3 mm/tahun , AlCu/SiC 1,1144. 10-3 mm/tahun , dan Al2024 1,0648. 10-3 mm/tahun . Hal ini menunjukkan bahwa ketahanan korosi diperoleh pada sampel AlCu dan AlCu/SiC.

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ABSTRACT Hybrid aluminum metal or metal matrix composite MMC have been synthesized and characterized. The composition of Al SiC, and AlCu SiC as a composite material melting and solidification solidification process is carried further by using heat suppression 5 tons hot press at a temperature of 300oC. Analysis of x ray Diffraction XRD show that the spectrum indicates a single phase Al with crystal system face center cubic FCC which constants lattice 4.0560 and the crystal orientations are 111 , 002 , 022 , 113 , and 222 . The direction of the crystal orientations were influenced by compression heat hot press and fast cooling. It can be seen from the direction 111 and 002 . The SEM images on the surface morphology of solids Al, Al SiC 4 by weight, and AlCu SiC 4 , the surface in a direction parallel seems more equitable and more homogen in the form of the structure. While, the surface in the direction perpendicular or cross sectional sample has a form different structures and forming a longitudinal direction perpendicular to the direction of the emphasis on hot press process. The Hardness Vickers value HV overall composite sample AlCu SiC heat suppression results hot press is greater than the Al SiC for slow and fast cooling. Also included where the surface position of transverse or perpendicular perpendicular has a HV value greater than the surface parallel in plan . The corrosion rate starting from the largest to smallest is Al 1.8986 x10 3 mm y , Al SiC 1.2509 x 10 3 mm y , AlCu 1.1716 x 10 3 mm y , AlCu SiC 1.1144 x 10 3 mm y , and Al2024 1.0648 x 10 3 mm y . These indicated that the corrosion resistance obtained on the sample AlCu and AlCu SiC."

"Machining of metal matrix composites gives the reader information on machining of MMCs with a special emphasis on aluminium matrix composites. Chapter 1 provides the mechanics and modelling of chip formation for traditional machining processes. Chapter 2 is dedicated to surface integrity when machining MMCs. Chapter 3 describes the machinability aspects of MMCs. Chapter 4 contains information on traditional machining processes and chapter 5 is dedicated to the grinding of MMCs. Chapter 6 describes the dry cutting of MMCs with SiC particulate reinforcement. Finally, chapter 7 is dedicated to computational methods and optimization in the machining of MMCs."

"Ceramic matrix composites (CMCs) have proven to be useful for a wide range of applications because of properties such as their light weight, toughness and temperature resistance. Advances in ceramic matrix composites summarises key advances and types of processing of CMCs.After an introductory chapter, the first part of the book reviews types and processing of CMCs, covering processing, properties and applications. Chapters discuss nanoceramic matric composites, silicon carbide-containing alumina nanocomposites and advances in manufacture by various infiltration techniques including heat treatments and spark plasma sintering. The second part of the book is dedicated to understanding the properties of CMCs with chapters on finite element analysis, tribology and wear and self-healing CMCs. The final part of the book examines the applications of CMCs, including those in the structural engineering, nuclear and fusion energy, turbine, metal cutting and microelectronics industries."

"ABSTRAKPenelitian ini dilakukan untuk mengetahui pengaruh penambahan penguat Mikro-SiC pada komposit matriks aluminium. Aluminium dipilih dikarenakan performa mekanisnya yang baik, ringan, memiliki titik leleh yang rendah, dan mudah untuk difabrikasi melalui proses pengecoran. Aluminium seri 3 ADC12 digunakan dalam penelitian ini. Komposit akan difabrikasi melalui metode pengecoran aduk dimana proses pengadukan dilakukan secara mekanik dengan menggunakan batang pengaduk sebanyak 4 kali, dengan lama pengadukan 10 detik setiap kali pengadukannya dan dilakukan dengan interval 2 detik. SiC yang ditambahkan bervariasi dari 1, 3, 5, 7, hingga 10% Vf, dan kedalam komposit ditambahkan Mg sebanyak 5%wt untuk meningkatkan kemampubasahan dari komposit, Strontium sebanyak 0,04 %untuk merubah morfologi dari fasa eutektik silikon yang terbentuk menjadi bentuk yang halus sehingga dapat meningkatkan sifat mekanis dan TiB 0.15wt% sebagai penghalus butir. Hasil dari penelitian ini adalah semakin banyak SiC yang digunakan maka kekerasan komposit akan bertambah, kekerasan ini akan diimbangi oleh sifat ulet yang dimiliki oleh matriks ADC12 hingga titik optimum. Titik optimum yang didapat berada pada titik dimana nilai ketangguhannya tertinggi yaitu pada saat kadar SiC yang digunakan sejumlah 3 %vf, dimana kekuatan tariknya mencapai 236 Mpa dan kekerasannya mencapai 46 HRB.

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ABSTRACTThis research is performed to identify and recognize the effect from the addition of SiC reinforce on the metal composite with aluminium as the matrix. Aluminum is preferred since it has good mechanical performance, its lightweight, low melting temperature and easy to cast. Aluminium alloy series three ADC12 was used in this research. In this study, the composite will be fabricated through stir casting process where stirring is performed mechanically with a stirrer 4 times, 10 seconds each time with 2 seconds interval between them. Then, 1, 3, 5, 7 to 10%Vf SiC was added to each of the composite, the addition of 5%, 0,04%wt strontium, and 0,15%wt TiB were believed to enhance wettability, modify the silicon eutectic phase, and acts as the grain refiner respectively. The result obtained in this research showed increase in hardness ADC12 composite with higher SiC content. Hereby, it is believed that strengthening and weakening factors from reinforce particle and metal matrix could neutralize the effect of each other until the optimum point and thus, the composite containing 3% (volume fraction) SiC exhibits the maximum toughness, with tensile strength and hardness value of 236 MPa and 46 HRB respectively. "

"This research is to study the effects of _firing temperature and holding time on characteristics of Directed Metal Oxidation (DIMOAQ Ceramic Matrix Composites (CMCs) SiC /' A1 product. In this research, the firing temperature and holding time used are varied from 900° C to 1300° C with holding time 10 and 20 hours for each temperature. The characterizations of composite products are examined such as density and porosity test, micro hardness test, microstructure examination and chemical composition test. The results show that SiC preform has been infiltrated by Al liquid at tiring temperature of 1100"C for 20 hours. Composite product with the highest density (3,54 gram / cm3) can be obtained at firing temperature of 1100°C for 20 hours. Porosity tents to increase with increasing firing temperature. Composite product with highest micro hardness (1820 VHM can be obtained at firing temperature of 1300°C for 10 hours. At the some firing temperature, composite at products micro hardness for 20 hours tower than composite product with holding time I0 hours. Distribution of SiC particles spread over quite uniform on SiC/A1 composites product. Around SiC particles can be found Al, spinel (MgAl2O2). Al2O2, and possibility Mg,Si."

"Principally, metal ceramic bonding were determined by availability of forming oxide layer on the interface between metal and ceramic. Only a thin film of oxide layer that needed for provide sufficient adherence. Many investigations were done in order to increase this condition, for example kinds of treatment on the interface e.g. alternative oxidation, sandblasting and finishing metal direction. These investigations purposed to measure the magnitude of metal ceramic bonding through the kinds of test e.g. shear bonding and flexual biaxial testing. Besides, metal ceramic bonding might be detected by the amount of remained ceramic adherence. Treatment on the metal ceramic until investigated the influence of moisture environment to the metal ceramic bonding."

"Keramik merupakan material yang memiliki kekerasan yang sangat tinggi dan getas (getas). Untuk meningkatkan ketangguhan keramik,maka dikembangkan CMCs (Ceramic Matix Composite). Salah satu metode untuk memproduksi CMCs adalah dengan melalui proses DIMOX, yaitu cara mengoksida leburan logam dalam atmosfer dapur. Karakteristik produk CMCs yang dihasilkan melalui metode ini dipengaruhi oleh variabel waktu tahan, temperatur, dopant serta atmosfer tempat berlangsungnya proses pembentukan komposit.Penelitian ini bertujuan untuk mempelajari proses pembuatan CMCs C/Al melalui proses DIMOX dan pengaruh waktu tahan terhadap karakteristik produk CMCs yang dihasilkan. Pada penelitian ini dilakukan variasi waktu tahan, dimana digunakan waktu tahan 8, 10, 15, 20, 24 jam pada temperatur 1100 °C. Karakterisasi terhadap produk komposit yang dihasilkan dilakukan melalui pengujian densitas dan porositas, pengujian kekerasan mikro, pengamatan struktur mikro dengan menggunakan mikroskop optik dan SEM serta pegujian komposisi kimia.Infiltrasi prabentuk C oleh leburan Al dapat terjadi secara optimum pada waktu tahan 24 jam. Produk CMCs dengan densitas yang tertinggi, sebesar 3,17 gram/cm3, diperoleh pada waktu tahan 24 jam. Porositas produk CMCs cenderung meningkat seiring dengan penambahan waktu tahan. Produk CMCs dengan kekerasan mikro tertinggi, sebesar 14300 Mpa pada waktu tahan 24 jam. Laju keausan produk CMCs tertinggi, sebesar 2.03x10^-6 m3/mm terdapat pada waktu tahan 24 jam. Partikel C terdistribusi cukup merata pada produk CMC C/Al. Pada produk CMCs pada daerah sekitar partikel C dapat ditemui adanya Al, spinel (MgAl2O4), Al2O3.

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Ceramic is material which possed a very high hardness and brittle. To increase its toughness, then CMCs is developed. One of method to produce CMCs is DIMOX process. DIMOX involved oxidized molten metal in furnace atmosphere. The charateristic of CMCs product is effected by variables processes such as : holding time, temperature, dopant and the atmosphere where the process is held.

The aim of this research is to study the making process of CMCs C/Al itself through DIMOX process and the effect of holding time with variable : 8, 10, 15, 20, 24 hours at 1100 °C. The characterizations of CMCs are examined by density, porosity, hardness, wear and microstructure analysis.

It is found that Infiltration preform graphite by molten Al is optimal at the holding time of 24 hours. This variable produced highest density at 3,17 gr/cm3. The porosity of CMCs product tends to increase with increment of holding time. The highest porosity that obtained at holding time of 24 hours is 6.15 %. The highest hardness that can be obtained at holding time of 24 hours is 14300 MPa. This variable also produced the lowest wear rate, it is 2.03x10^-6 mm3/mm. Distribution of graphite particles spread over C / Al composite product and around graphite particles can be found Al, spinel ( MgAl2O4 ), and Al2O3. Based on EDS analysis, there are three phase in systems of CMCs product, they are C/Al, Al2O3/Al, and C/Al2O3."

"Dewasa ini, penggunaan material komposit polimer berpenguat serat karbon (carbon fiber reinforced polymer, CFRP) dalam berbagai bidang semakin populer dan berkembang. Hal ini dikarenakan nilai ekonomis serta sifat mekanik yang baik yang mampu dihasilkan oleh material komposit tersebut. Ada banyak faktor yang dapat mempengaruhi sifat/ karakteristik material komposit CFRP, diantaranya adalah arah orientasi serat karbon serta perlakuan panas. Penelitian ini membahas mengenai pengaruh orientasi serat anyam karbon dan temperatur perlakuan panas terhadap sifat mekanik material komposit laminate bermatrik polimer. Komposit CFRP dimanufaktur dengan menggunakan metode hand lay-up dengan variasi orientasi [00 or 900]s, [00 or 900]/[±450] dan [±450]s. Spesimen komposit selanjutnya dilakukan pemanasan pada variasi temperatur lalu dilakukan pengujian berupa pengujian tarik, tekuk, impak, dan FTIR. Kekuatan tarik tertinggi diperoleh pada orientasi [0o or 90o]s dengan pemanasan 200 oC selama 3 jam, kekuatan tekuk tertinggi diperoleh pada orientasi [0o or 90o]s dengan pemanasan 100 oC selama 3 jam, serta energi impak tertinggi diperoleh pada orientasi [0o or 90o]s dengan pemanasan 100 oC selama 3 jam. Hasil pengujian FTIR menunujukkan gugus fungsi polimer yang dihasilkan dari Unsaturated Polyester Resin setelah pemanasan pada temperature curing adalah ikatan C=O (ester) dan ikatan ikatan C=C (cincin aromatik).

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Nowadays, the use of carbon fiber reinforced polymer (CFRP) composite in various fields is getting more popular and fast growing. This is due to the economic value and good mechanical properties of the composite materials can produce. There are many factors that affect the characteristics of CFRP composite materials, including orientation of the carbon fiber and heat treatment. This study discusses the effect of the orientation of carbon woven fibers and the temperature of heat treatment on the mechanical properties of polymer matrix composite laminates. CFRP composites were manufactured using the hand lay-up method with various orientations [0 or 90o]s, [0 or 90o] / [± 45o] and [± 45o]s. The composite specimens were then heating at various temperatures. Characteristics of the composites were examined in the form of tensile test, bending test, impact test and FTIR analysis. The highest tensile strength was obtained at orientation [0o or 90o]s followed by heating at 200 oC for 3 hours. The highest bending strength was obtained at orientation [0o or 90o]s followed by heating at 100 oC for 3 hours, whereas the highest impact energy was obtained at orientation [0o or 90o]s followed by heating at 100 oC for 3 hours. FTIR test showed that the polymer functional groups from unsaturated polyester resin after heating at curing temperature are C=O bonds (ester) and C=C bonds (aromatic rings)."