Assessing wind energy potential for electricity generation using WECS in eight selected stations of Ethiopia

Wind utilisation for effective electricity generation has dated since last two decades by means of the modern wind turbines and has proved as a mature, reliable and efficient technology. This paper integrates the wind characteristics and performance of selected wind energy conversion systems (WECSs) from eight selected stations within Tigray region in Ethiopia. The wind speed data were collected over a period between 2002 and 2014. Based on the Paci?c Northwest Laboratory (PNL) classification, all the selected stations fall into Class 1. Therefore, these stations may be advised for small-scale power applications. Furthermore, the highest annual energy output achieved was 3902.31?MWh using VESTAS V110 – 2.0 at Mekele.     

Two new species of Platygastrinae (Platygastridae) and the unknown female of Isolia indica (Sceliotrachelinae) from South India

Two new species, Trichacoides ranganabettensis sp. nov. Veenakumari & Buhl and Platygaster neostriatitergitis sp. nov. Veenakumari & Buhl are described from South India. The unknown female of Isolia indica is also described.     

Selective Laser Melting of Al-7Si-0.5 Mg-0.5Cu: Effect of Heat Treatment on Microstructure Evolution,Mechanical Properties and Wear Resistance

Al-7Si-0.5 Mg-0.5Cu alloy specimens have been fabricated by selective laser melting (SLM). In this study, the effects of solution treatment, quenching, and artificial aging on the microstructural evolution, as well as mechanical and wear properties, have been investigated. The as-prepared samples show a heterogeneous cellular microstructure with two different cell sizes composed of α-Al and Si phases. After solution-treated and quenched (SQ) heat treatment, the cellular microstructure disappears, and coarse and lumpy Si phase precipitates and a rectangular Cu-rich phase were observed. Subsequent aging after solution-treated and quenched (SQA) heat treatment causes the formation of nanosized Cu-rich precipitates. The as-prepared SLMs sample has good mechanical properties and wear resistance (compressive yield strength: 215 ± 6 MPa and wear rate 2 × 10^-13 m³/m). The SQ samples with lumpy Si particles have the lowest strength of 167 ± 13 MPa and the highest wear rate of 6.18 × 10^-13 m³/m. The formation of nanosized Cu-rich precipitates in the SQA samples leads to the highest compressive yield strength of 233 ± 6 MPa and a good wear rate of 5.06 × 10^-13 m³/m.     

Enhanced reaction kinetics and impact strength of cyanate ester reinforced with multiwalled carbon nanotubes

In this work, the effect of multiwalled carbon nanotubes on the properties of a unique, low viscosity bisphenol E cyanate ester (BECy) resin is characterized during various stages of nanocomposite preparation. The effect of surface functionalization, with nanotubes containing hydroxyl groups (OH CNTs) and carboxylic acid groups (COOH CNTs), on the rheological, cure, thermal, and impact properties of the nanocomposite properties are also examined. Based on rheology measurements prior to cure, the unfunctionalized nanotube suspensions are found to exhibit the highest viscosity and the most dramatic shear thinning behavior. Cure characterization using differential scanning calorimetry (DSC) reveals that the nanotubes catalyze the cure of BECy and the OH CNTs exhibiting the most dramatic catalytic effect. The DSC data is well described by an nth order autocatalytic model. The impact strength of fully cured BECy is found to increase by 91% and 63% upon incorporation of 1 wt% COOH and OH CNTs, respectively. While incorporation of 1 wt% unfunctionalized nanotubes results in an 8 degrees C decrease in the glass transition temperature (T(g)) of BECy, chemical functionalization greatly mitigates the magnitude of the reduction.     

Effect of Wear Debris Entrapment on the Tribological Performance of AlCoCrFeNi Produced by Selective Laser Melting or Spark Plasma Sintering

Metallurgical and Materials Transactions A - This study aimed to investigate the microstructure and tribological properties of the equiatomic AlCoCrFeNi high-entropy alloys (HEAs) fabricated using...     

Enhanced dielectric properties and energy storage density of surface engineered BCZT/PVDF-HFP nanodielectrics

Polymer nanocomposites have proved to be promising energy storage devices for modern power electronic systems. In this work we have studied the dielectric properties and dielectric energy storage densities of 0–3 type BCZT/PVDF-HFP polymer nanocomposites with different filler volume concentrations. BCZT nanopowder was synthesized by solgel method through citrate precursor method. The structural and morphological features of the BCZT nanopowder were examined by X-ray diffraction and transmission electron microscopy. For better polymer ceramic interface coupling, BCZT was surface functionalized with extended aromatic ligand, naphthyl phosphate (NPh). The surface functionalization was validated and quantified by thermogravimetric analysis and X-ray photoelectron spectroscopy. The dielectric constant of surface passivated BCZT nanoparticles was estimated to be ~?155 using slurry technique, while the dielectric permittivity of pristine BCZT nanopowder could not be assessed due to high innate surface conductivity. BCZT/PVDF-HFP polymer nanocomposite thin films were fabricated using solution casting technique. The dispersion quality of the ceramic fillers in the polymer matrix was examined by scanning electron microscopy. Due to better polymer ceramic interface, At 5 vol% filler concentration, NPh modified nanoBCZT/PVDF-HFP films showed enhanced dielectric breakdown strength and energy storage density than untreated nanoBCZT/PVDF-HFP and even pure polymer films. Maximum energy storage density of 8.5 J cm^?3 was obtained at an optimum filler concentration of 10 vol% for surface functionalized BCZT/PVDF-HFP composite films of 10 μm thickness.     

Three-dimensional assembly of single-walled carbon nanotube interconnects using dielectrophoresis

We present a hybrid approach that combines top-down fabrication with bottom-up directed assembly for making single-walled carbon nanotube (SWNT) based three-dimensional interconnects. The SWNTs are assembled using dielectrophoresis at room temperature on a microfabricated 3D platform. The two-terminal resistance of the assembled SWNTs at 10?Vpp assembly voltage is approximately 545?Ω. Simulation of the dielectrophoretic assembly is carried out to understand the behavior of the SWNTs during assembly. Encapsulation of these devices using a conformal pinhole-free parylene layer resulted in a decrease of the total resistance.     

Processing and characterization of chemically modified wood sawdust reinforced (diospyros,dialium) epoxy composites

Polymer composite materials based on natural fiber such as wood had been widely used for research purposes and engineering interests. The interest in wood reinforced polymer composites had grown quickly due to their better performance in aspects of mechanical properties compared to pure wood. In this study, wood sawdust of diospyros (kayu malam) and dialium (keranji) were chosen to be incorporated into an epoxy-based polymer composite. The wood is made into sawdust, which was treated with boric acid and hydrogen peroxide. Surface treatment with these reagents was used to improve the mechanical properties of the polymer composite compared to untreated wood polymer composite. Sawdust reinforced epoxy composite that was fabricated are with different weight percentages from 0 % (no wood), 5 %, 10 %, 15 % to 20 % wt % for comparison on their tensile, flexural, and impact strength properties. Tensile, flexural, and impact tests were performed to determine the changes in mechanical properties where it was found that tensile strength had increased by 34 percent with an optimum keranji and kayu malam fiber weight of 15 wt % for both boric acid and hydrogen peroxide treatments. For flexural strength, in both wood fibers, the optimum fiber weight was found to 15 wt %, and the addition of wood had increased the strength by 57 percent. As for impact strength, it decreased as the weight of fiber increased, where it was assumed that the addition of wood might have increased the crack initiation. Adhesive bonding between hydrophilic wood sawdust and the hydrophobic epoxy polymer was the phenomenon that was focused on this research. The range of optimum weight percentage of sawdust would be determined from the experiment result.     

Swell Potential of Pulverized Coal Combustion Bottom Ash Amended with Sodium Bentonite

Within the last decade several studies have been conducted to evaluate the geotechnical properties of bottom ash obtained from electric utilities burning pulverized coal amended with admixtures such as clay, bentonite, and lime. Most of these studies concentrated on evaluating strength and stiffness characteristics of the mixtures. Because of the high volume change characteristics of bentonite and clay, improper and/or excessive use of these admixtures can impart significant swelling characteristics to the mixtures. This study was conducted to evaluate the swelling properties of two bottom ash-bentonite mixtures compacted at various initial moisture contents. Results from this detailed investigation show that the swelling potential increased with the increase in bentonite content and decreased with the increase in initial moisture content. Mixtures with 20% bentonite were observed to have volume change characteristics that may not be suitable for some lightly loaded structures. Mixtures with 15% bentonite; compacted at initial moisture contents of 18% or higher; were observed to have less than 4% free swell, whereas for mixtures compacted at an initial moisture content of 16% or lower, the percent increase in free swell was observed to be greater than 7%.