A genetic algorithm (GA) was used to optimize a multilayer electromagnetic shield of polyaniline (PANI)–polyurethane (PU) conducting composites in the microwave band. First, the electronic properties of freestanding films with different mass fractions of polyaniline were studied. A very low percolation threshold (0.2%) was found, with a maximum of conductivity of 104 S/m. Second, the electromagnetic shielding effectiveness of the films were investigated in the X and Ku bands (8.2–18 GHz), showing an attenuation increase of 1–40 dB with the mass fraction of polyaniline in the blends. Then, the electromagnetic shielding properties of multi‐layered PAni–PU composites were investigated in order to obtain an attenuation superior to 40 or 80 dB, depending on the application. To improve the performances of the electromagnetic shields, three‐layered PAni–PU composites were made, using an optimization method. The intrinsic physical parameters of the composites were used as a database for the optimization calculation. The optimization results showed that materials with a thickness of <500 µm could answer many industrial or military shielding applications. As the electronic properties can be tuned easily with the mass fraction of polyaniline in the blends, conducting multi‐layered composite materials can be made following the results of the optimization. Their electromagnetic shielding effectiveness was measured, showing good agreement between the measurements and modeling. These results demonstrated that the genetic algorithm allows us to conceive lightweight and high performance electromagnetic shields using intrinsically conducting polymers. The mass per unit of surface of the shield was <200 g/m2, giving potential applications in the aeronautics domain. Copyright © 2007 John Wiley & Sons, Ltd.
The catalytic effect of red mud on Vietnam anthracite’s combustion characteristics was investigated. The mineralogical composition of the red mud includes CaCO3, Fe2O3, FeO(OH), FeTiO3, and Al(OH)3. This red mud is rich in Na, Ca, Al, Fe, and Ti. The combustion characteristics were analyzed by the thermogravimetry method. The combustion effectiveness was assessed by thermogravimetric analysis. The results were derived from a combination of several parameters, such as the ignition temperature, the burnout efficiency, and the amount of heat release. The combustion characteristics of pulverized coal were improved by the introduction of red mud, and the greatest catalytic performance was achieved when the content reached 6%. With the optimal addition, the ignition temperature of anthracite was reduced by 12 °C, and the burnout efficiencies were increased by 2.59% compared to raw anthracite. The amount of heat released by anthracite was increased to 6.93 kJ/g by adding red mud.
In the PWR pressure water reactor (PWR), stainless steel is used in many important parts in both primary and secondary water circuits. There are not enough necessary condition to experiment in extremly conditons of nuclear reactor, such as high temperature, high pressure in radiation environment in Vietnam. Therefore, in order to study the world's technology for evaluating metal materials, it is necessary to have basic research on SS304 stainless steel objects. This study deals with SS304L stainless steel, which is low carbon steel used in nuclear power plants. The material used in this work was stainless steel 304 with low C content (SS304L). AISI stainless steel 304L plates were cut by wire-cutting machine into standard specimens and then heat-treated under different conditions. Finally, the post-treated specimens were tested by Rockwell hardness tester, tensile strength tester, and Charpy impact tester to verify the mechanical properties. The results showed that when heating the specimens in the range of 300÷900oC, cooling in the furnace to the room temperature, the value of hardness changed insignificantly. When increasing heating temperature, the yield strength and ultimate tensile strength values of the specimens decreased while the relative elongation values were almost unchanged. It means that under tested heat treatment conditions, the higher the heating temperature is, the worse mechanical properties are. The reason for this might be the appearance of the brittle sigma phase. Heat treatment results of SS304 specimens with the normalizing conditions at 900oC also shows the possibility to remove the sigma phase in the steel composition.
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