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Al-Rashdi, D.J.
El-Sanabary: Carbohydrate Polymers Vol.86 (2011), p.491 [10] L.

. %] Al Mo V C O2 Ti 8.67 1.03 1.05 0.23 0.12 Balance Research results The tested alloy in initial state is characterized by microstructure consisting of alpha phase with small amount of beta phase particles distributed in the network throughout the a matrix (Fig. 1).
Mechanical properties of Ti-8Al-1Mo-1V-0.2C tested in ambient temperature Alloy State UTS [MPa] YS [MPa] EL [%] RA [%] Ti-8Al-1Mo-1V-0.2C DA 1181 1141 17.6 33.9 STA 1258 1222 13.7 18.7 Ti-8Al-1Mo-1V [14÷17] DA 896÷950 827÷890 10.0 - STA 1180 1070 17.0 26.0 Short-term creep tests (Fig. 5) carried out for the tested alloy at 500ºC and 300 MPa show that its creep resistance is higher in state after duplex annealing (DA).

Chen et al [5, 6] had deduced a model (Eq. 2) to illustrate the grinding power changes during a dressing life cycle, where the influence of grinding kinematics, dressing operation and wheel wear were taken into account
Acknowledgement: the author would like to express his acknowledgement to Peter Moran, Chen Jiang, Jianhui Zhu, Azaly Bin Buang and Aslam El-Moussaoui for their supports in carrying out the experiments.

Composition of aluminum alloy (% mass) Cu Mg Mn Si Fe Zn Ti Cr Al 4.00 1.50 0.60 0.50 0.50 0.25 0.15 0.10 Rest The Fatigue tests were performed in an Instron testing machine model R.R Moore.
El-Axir: Int.

Dyamant et al.[2] studied glasses in the system SiO2–Bi2O3–ZnO–B2O3 and concluded that glass formation was obtained within the composition range of 40–60 mol% SiO2, 1–30 mol% B2O3, 10–45 mol% Bi2O3, and 1–35 mol% ZnO, with glass transition temperature (Tg) in the range of 411–522℃, which decreased with the increase of Bi2O3 content, and dilatometric softening point ranging from 453 to 563℃.
Kim, E.L.

The workpiece material used for the experiments is AlMn1Cu whose chemical composition includes Si 0.6%, Fe 0.7%, Cu 0.2%, Mn 1.0%～1.6%, Mg 0.05%, Zn 0.1%, Ti 0.15% in addition to Al.
El-Axir, O.M.

Microstructure and Corrosion Resistance of Microarc Oxidation Coatings on AZ31 Magnesium Alloy Extrusion Profiles Jie Ma1, a, Yuansheng Yang2, b, Xiuchun Wang1, c, Jing Zhang1, d, Shuo Liu1, e Likun Jiang1, f and Xibin Yi1, g 1Institute of New Materials, Shandong Academy of Sciences, Jinan 250014, China 2Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China amajie8107@163.com, bysyang@imr.ac.cn, cwangxch@keylab.net, djingjing8207@sohu.com, el.spoon@yahoo.com.cn, fjianglikun919@163.com, gyixb@keylab.net Keywords: magnesium alloy, microarc oxidation, microstructure, corrosion resistance, polarization curve Abstract.
The chemical composition of AZ31 magnesium alloy is as follows (in wt. %): Al 3.0, Mn 0.15, Zn 0.47, Ca 0.04, Si 0.1, Cu 0.05, Ni 0.005, Fe 0.005 and Mg balance.

Such an interpretation is in good agreement with the results of Pirouz et al.[4-6].
El Bouayadi, and J.M.

Typically, these models have concentrated on the magnitude and profile of sump-depth (molten Al in Figure 1) in a casting [1-2], stress-strain in the casting during cast-start [3, etc.], deformation and cracking in the casting as a result of the stresses within the casting [for e.g. 4-5].
El-Demerdash in: Light Metals, edited by S.K.

The main output factors of model (4) should be the sum of EL (environmental losses in production), RRA (rate of return on assets), ER (equity ratio) and so on, which deal with the firm's profitability.
A Balance Sheet, an Income Statement or other financial reports of the enterprises should be analyzed or investigated to obtain the PE, CAP, FAP, TA and AL.