(C) 2011 American Institute of Physics. [doi: 10.1063/1.3535439]“
“The effects of dioctyl
phthalate and inorganic filler, mica, on the sound insulation property of poly(vinyl chloride) (PVC) were investigated in this work. The stiffness and mass laws, which are the common theoretic tools to predict the soundproof properties of materials, were used to analyze the sound transmission loss (STL). The experimental results revealed that the stiffness and LCL161 purchase mass laws can describe well the sound insulation property of PVC/mica composites. The stiffness and surface density are important factors influencing the improvement of STL. With the increase of content of mica, STL and resonance frequency, f(mn), of PVC/mica composites increase. Moreover, the change of STL in the stiffness-controlled region is more obvious than that in the mass-controlled region, because the addition of mica in PVC leads to a greater increase in the stiffness. (C) 2011 Wiley Periodicals, Inc. J Appl Polym Sci 122: 1427-1433, 2011″
“An analysis of the performance of a bit patterned media data storage system composed of nanoscale Semaxanib concentration islands with variations in position and magnetic properties has been carried out. The statistical model of write errors includes adjacent track erasure and error
rates are computed according to the down-track synchronization of the write head switching position and cross-track head position variations. Two-dimensional maps of bit error rates reveal that distributions of position and anisotropy have a severe impact on the BMS-754807 concentration performance of the system. Results show that head field cross-track gradients needs to be tightly controlled to minimize the effects of adjacent track erasure. (C) 2011 American Institute of Physics. [doi: 10.1063/1.3562869]“
“To model the melt-spinning process of biodegradable as-spun linear aliphatic-aromatic copolyester fibers, a fraction factorial experimental design and appropriate statistical
analysis for the 32 screening trials involving five control parameters were used. Because of their central role in the production processes and end use textiles, it is important to simulate the mechanical and thermal shrinkage properties of AAC fibers. Concise statistical models of fiber behavior are based on factorial experimental design data. Process’s data are collected, analyzed, and mathematical models created to predict the diameter, tenacity, elongation at break, modulus, and thermal shrinkage of the spun fiber in terms of random variables and their associated probability distributions. The theoretical regression models obtained form the main source code in the enhanced forecasting program, which presents the melt-spinning process of aromatic-aliphatic copolyester fibers.