Intelligent Control for Voltage Regulation in the Distribution Network Equipped with PV Farm

A combined PSO-ANN control is proposed in this work to achieve the best voltage regulation in a distribution network, based on quick response and minimum average voltage deviation. The Jordanian Sabha Distribution Network (JSDN) with PV Farms is used as a real case study to examine a voltage variation issue. Two STATCOMs are used to solve the voltage fluctuation problem on the network’s three buses. The required reactive powers of STATCOMs for voltage regulation during load variation are calculated in offline mode using a particle swarm optimization (PSO) algorithm. Despite its high performance in solving voltage issue in the JSDN network, the PSO controller is unable to react promptly to dynamic changes in the network. An artificial neural network (ANN) is therefore suggested as an online mode controller for quick and efficient voltage regulation. The offline dataset is used to train the ANN for online voltage regulation utilizing the MATLAB-Tool Box. At an average voltage deviation (AVD) of 1.168%; (whereas an acceptable one is 6%), the results revealed the proposed ANN controller’s competence for voltage regulation in the distribution network. Moreover, to find the best position based on an efficient voltage regulation, many sites for STATCOMs are taken into consideration

Solar Hot Water Heating and Electricity Generation Using PV/T Hybrid System

Experimental work has been carried out to study the possibility of combining a conventional solar water collector with a hybrid device, developed previously and known as PV/T system, in order to obtain hot water with temperature above 40 °C. The effect of the combination on the productivity of hot water and the produced electricity was found. The formerly developed device, in which there was a multi-purpose solar collector, can produce hot water and electricity. It was connected to the conventional fin-tube collector in series in order to raise the product temperature to a higher level. This development was achieved for the first time as a combination between a PV/T and a conventional fin-tube collector. Instrumentation to measure temperatures, solar radiation, wind speed and flow rate was installed on the system. It was found that the water temperature was raised from 29 °C to 32 °C in the PV/T collector system and, after flowing through the conventional collector, it was raised to 50 °C and above. It was also found that the power efficiency in the case of water flow is always higher than in the case of no water flow

Knowledge of Jordanian women of reproductive age who underwent bariatric surgery and its effect on birth outcomes: A cross-sectional study

Objectives: This study aims at exploring the knowledge of women of reproductive age who underwent bariatric surgery in Jordan regarding its effect on birth outcomes. Methods: A cross-sectional study was conducted on 183 women (aged 15–49) who had undergone bariatric surgery at the Jordan University Hospital in Amman, Jordan, between 2016 and 2019, using telephone interviews with conveniently selected participants’ samples. The survey tool obtained data on women’s knowledge and other sociodemographic, obstetric health, and bariatric surgery information. Unfavorable birth outcomes include preterm delivery, small for gestational age, congenital abnormalities, low birth weight, and admission to the neonatal critical care unit. Results: More than half of the participants did not know about the possible unfavorable birth outcomes after bariatric surgery and related practice guidelines. This is shown in their median score of 3 (interquartile range: 2–4) out of a maximum possible score of 8. Women who had a good score (>4) had received counseling about unfavorable bariatric surgery outcomes from their surgeon ( p  < 0.013); those who had educational qualifications higher than secondary school ( p  < 0.001) as well as those who were employed ( p  < 0.008) and believed that the surgery would affect the newborn ( p  < 0.001). The median score was also unfavorably associated with the parity of the participants ( p  < 0.003). Conclusion: The extent of knowledge regarding the unfavorable birth outcome of bariatric surgery is low among women who underwent bariatric surgery at Jordan University Hospital in Jordan. Improving health literacy and information on bariatric surgery implications on pregnancy and birth outcomes amongst women of reproductive age is a recommendation from this study

Dexmedetomidine versus morphine infusion following laparoscopic bariatric surgery:effect on supplemental narcotic requirement during the first 24 h

The primary aim of this pilot study was to determine whether the dexmedetomidine infusion initiated immediately after laparoscopic bariatric surgery, offers an advantage over a morphine infusion with respect to rescue morphine and paracetamol requirements over the first 24 post-operative hours. Sixty morbidly obese adult patients scheduled for laparoscopic bariatric surgery were randomly assigned to receive an infusion of either 0.3 mcg/kg/h dexmedetomidine (Group D) or 3 mg/h Morphine (Group M) for 24 h immediately post-operatively. All patients received standardized general anesthesia and were evaluated and treated for pain in the intensive care unit by providers who were blinded to their treatment group. The primary outcome was the need for supplemental, "rescue" paracetamol (Dolargan. Hikma, Jordan) and morphine titrated to achieve visual analog scales (VAS) of <40 and <70, respectively. A total of 60 patients (77 % female, mean age 33.5 years +/- 9.5 and body mass index (BMI) 43.0 +/- 4.5) were randomized to Group M and 30 to Group D. There were no significant differences in mean rescue paracetamol and morphine requirements. Mean total morphine requirements in Group D were 6.1 +/- 3.1 mg, whereas 72.9 +/- 2.2 mg in Group M (p <0.0001). An intravenous infusion of dexmedetomidine, initiated and continued for 24 h following laparoscopic bariatric surgery, can decrease the overall morphine requirements during this period. This pilot study demonstrated that the post-operative initiation of dexmedetomidine can be morphine sparing following laparoscopic bariatric surgery

Productive and Sustainable H₂ Production from Waste Aluminum Using Copper Oxides-Based Graphene Nanocatalysts: A Techno-Economic Analysis

Hydrogen has universally been considered a reliable source of future clean energy. Its energy conversion, processing, transportation, and storage are techno-economically promising for sustainable energy. This study attempts to maximize the production of H2 energy using nanocatalysts from waste aluminum chips, an abundant metal that is considered a potential storage tank of H2 energy with high energy density. The present study indicates that the use of waste aluminum chips in the production of H2 gas will be free of cost since the reaction by-product, Al2O3, is denser and can be sold at a higher price than the raw materials, which makes the production cost more efficient and feasible. The current framework investigates seven different copper oxide-based graphene nanocomposites that are synthesized by utilizing green methods and that are well-characterized in terms of their structural, morphological, and surface properties. Reduced graphene oxide (rGO) and multi-layer graphene (MLG) are used as graphene substrates for CuO and Cu2O NPs, respectively. These graphene materials exhibited extraordinary catalytic activity, while their copper oxide composites exhibited a complete reaction with feasible techno-economic production. The results revealed that the H2 production yield and rates increased twofold with the use of these nanocatalysts. The present study recommends the optimum reactor design considerations and reaction parameters that minimize water vaporization in the reaction and suggests practical solutions to quantify and separate it. Furthermore, the present study affords an economic feasibility approach to producing H2 gas that is competitive and efficient. The cost of producing 1 kg of H2 gas from waste aluminum chips is USD 6.70, which is both economically feasible and technically applicable. The unit cost of H2 gas can be steeply reduced by building large-scale plants offering mass production. Finally, the predicted approach is applicable in large, medium, and small cities that can collect industrial waste aluminum in bulk to generate large-scale energy units

Productive and Sustainable H2 Production from Waste Aluminum Using Copper Oxides-Based Graphene Nanocatalysts: A Techno-Economic Analysis

Hydrogen has universally been considered a reliable source of future clean energy. Its energy conversion, processing, transportation, and storage are techno-economically promising for sustainable energy. This study attempts to maximize the production of H2 energy using nanocatalysts from waste aluminum chips, an abundant metal that is considered a potential storage tank of H2 energy with high energy density. The present study indicates that the use of waste aluminum chips in the production of H2 gas will be free of cost since the reaction by-product, Al2O3, is denser and can be sold at a higher price than the raw materials, which makes the production cost more efficient and feasible. The current framework investigates seven different copper oxide-based graphene nanocomposites that are synthesized by utilizing green methods and that are well-characterized in terms of their structural, morphological, and surface properties. Reduced graphene oxide (rGO) and multi-layer graphene (MLG) are used as graphene substrates for CuO and Cu2O NPs, respectively. These graphene materials exhibited extraordinary catalytic activity, while their copper oxide composites exhibited a complete reaction with feasible techno-economic production. The results revealed that the H2 production yield and rates increased twofold with the use of these nanocatalysts. The present study recommends the optimum reactor design considerations and reaction parameters that minimize water vaporization in the reaction and suggests practical solutions to quantify and separate it. Furthermore, the present study affords an economic feasibility approach to producing H2 gas that is competitive and efficient. The cost of producing 1 kg of H2 gas from waste aluminum chips is USD 6.70, which is both economically feasible and technically applicable. The unit cost of H2 gas can be steeply reduced by building large-scale plants offering mass production. Finally, the predicted approach is applicable in large, medium, and small cities that can collect industrial waste aluminum in bulk to generate large-scale energy units