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"Telah dilakukan penelitian tentang minimalisasi tegangan sisa dan peningkatkan sifat mampu bentuk Baja JTS G-3141 SPCC dengan proses anil. Sampel bahan uji adalah baja karbon sangat rendah produk PT. Krakatau Steel tebal 0,7 mm, hasil pengerolan dingin dari keluran rol panas tebal 2,25 mm. Proses anil dialiri gas argon secara kontinyu dan dilakukan dengan variasi temperatur ( 550, 600, 650, 670, 690, 710 dan 750) °C dan variasi waktu (15, 30, 45, 60 dan 75) menit. Hasil pengujian tarik menunjukkan adanya peningkatan indikasi mampu bentuk yaitu peningkatan nilai koefisien pengerasan regang (n), peningkatan nilai koefisien anisotropi (r), peningkatan nampak mulai optimum pada panas anil 710 °C, serta adanya peningkatan elongation.Hasil uji kemampuan ubah mampu bentuk, yaitu uji penarikan rentang (streching), pada panas anil 710 °C dengan waktu 30 menit didapat hasil kedalaman streching sebesar 19,35 mm (kedalaman ini sudah optimum karena untuk pemanasan lebih tinggi peningkatannya tidak begitu beda). Pengujian tegangan sisa dengan teknik difraksi sinar-X, didapatkan adanya penurunan tegangan sisa, dimana tegangan sisa mulai minimum juga pada pemanasan anil 710 °C dengan waktu tahan 30 menit. Hasil uji metalografi memperkuat hasil uji tegangan sisa dimana pada temperatur 710 °C dengan waktu tahan 30 menit, butir-butir permukaan sudah mengindikasikan adanya bebas regangan, sedangkan pada waktu tahan 15 menit masih terdapat bentuk pipih memanjang (indikasi belum bebas regangan). Disamping kenaikan ubah bentuk dan turunnya tegangan sisa kenaikan panas anil juga diikuti turunnya kuat tarik, kuat luluh, dan kekerasan, penurunan optimum juga pada temperatur 710 °C.

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An investigation on minimalization of residual stress and formability improvement of JIS G-3141 SPCC steel by annealing has been carried out. The samples are low carbon steel produced by PT. Krakatau Steel as thick as 0.7 mm. Cold rolling of the samples resulted from hot rolling produced a thickness of 2.25 mm. The annealing process was done at various temperatures, i.e. 550, 600, 650, 670, 690, 710 and 750 °C, and for a variety of time, i.e. 15, 30, 45, 60 and 75 minutes. The tensile test of the samples showed that there was an indication of formability improvement, e.g. strain hardening coefficient (n), unisotrophy coeficient (.r), and elongation improvement, the optimum values of which are reached at 710 °C.

The formability test was done by stretching, and the optimum stretching was at 710 °C for 30 minutes resulted in a stretch depth of 19.35 mm. The residual stress test was done by X-Ray diffraction technique and indicated residual stress decrease; the minimum residual stress was reached at the annealing temperature of 710 °C for 30 minutes. Metallographic examination of the samples also showed that there was an indication of strain free for the annealing stress decrease, the increasing annealing temperature also resulted in decrease in tensile strength, yield strength, and hardness, the lowest values of which was reached at the annealing temperature 710 °C."

"Lithium titanate, Li4Ti5O12 (LTO) is a promising candidate as lithium ion battery anode material. In this investigation, LTO was synthesized by a solid state method using TiO2 xerogel prepared by the sol-gel method and lithium carbonate (Li2CO3). Three variations of Li2CO3 content addition in mol% or Li2CO3 molar excess were fabricated, i.e., 0, 50 and 100%, labelled as sample LTO-1, LTO-2 and LTO-3, respectively. The characterizations were made using XRD, FESEM, and BET testing. These were performed to observe the effect of lithium excess addition on structure, morphology, and surface area of the resulting samples. Results showed that the crystallite size and surface area of each sample was 50.80 nm, 17.86 m2/gr for LTO-1; 53.14 nm, 22.53 m2/gr for LTO-2; and 38.09 nm, 16.80 m2/gr for LTO-3. Furthermore, lithium excess caused the formation of impure compound Li2TiO3, while a very small amount of rutile TiO2 was found in LTO-1. A near-pure crystalline Li4Ti5O12 compound was successfully synthesized using the present method with stoichiometric composition with 0% excess, indicating very little Li+ loss during the sintering process."