m. shavandi

Liquid hydrogen is a solution for storing and transmitting electricity that is produced by renewable energy sources such as geothermal energy. In this paper, a Rankine cycle with a proton exchange membrane electrolyzer, an ammonia absorption refrigeration cycle, and a hydrogen liquefaction cycle are simulated and analyzed for storing geothermal energy as liquid hydrogen. The power generated by the Rankine cycle is used to produce hydrogen gas in the electrolyzer. Additionally, the cooling obtained from the absorption refrigeration cycle is used to pre-cool the hydrogen gas to a temperature of -9.26 ℃, and then the hydrogen is liquefied at -253 ℃ by a mixed refrigeration cycle. The innovation of this study is based on using the cold energy obtained from the absorption refrigeration cycle in the liquid hydrogen production cycle and integrating the liquid hydrogen production process with the geothermal energy system. By using energy, exergy, and economic analysis, the final cycle efficiency was improved compared to the initial system. The special energy consumption of the liquefaction unit is 81.8 kWh per kilogram of hydrogen. In a three-year payback period, using economic analysis, the minimum selling price is calculated to be $2.11, which is lower than a similar liquid hydrogen production cycle presented in the past.

Tissue-engineering scaffolds provide biological and mechanical frameworks for cell adhesion, growth, and differentiation. Nanofibrous scaffolds mimic the native extracellular matrix (ECM) and play a significant role in formation and remodeling of tissues and/or organs . One way to mimic the desired properties of fibrous ECM is adding nanoparticles into the polymer matrix. In the current study, the uniform fibers of poly (ε-caprolactone) (PCL) enriched with different layered double hydroxide (LDH) contents (ranging from 0.1 wt.% to 10 wt.%) were successfully fabricated by electrospinning method. The LDH nano particles were randomly dispersed in the fibers, as confirmed by Energy Dispersive X-ray analysis (EDX). Scaffolds were analyzed from morphological, physical and mechanical view. Biological assessments of scaffolds in terms of cellular attachment and adipogenic differentiation of mouse adipose derived stem cells (mADSCs) were performed. The results showed that inclusion of LDH nanoparticles reduced the average fiber diameter and enhanced the tensile strength and elongation at break values of the PCL scaffold. The LDH-enriched electrospun PCL scaffolds had remarkable effects on cell adhesion. Moreover, a significant increase in adipogenic differentiation of mADSCs was observed. The PCL/LDH nanofibrous scaffolds showed great potential in application for soft tissue engineering.

Infill panels are used in buildings for architectural purposes. It is proven that they change the stiffness, strength and damping of a building, but they are ignored in the analysis and design phases, because of many uncertainties and complications. They have a lack of ductility, which is normally required in earthquakes, and, therefore, scientists have focused on new types of infill panel with high ductility. One of these infills has recently been proposed, which has a frictional sliding fuse at mid-height. This type of infill is called an engineered infill panel, and its high strength and ductility have been confirmed by experimental and numerical research. The strength of engineered infill panels rises by increasing the sliding strength of their fuses, which can be adjusted for different values easily through some bolts.The effects of applying such infill panels are investigated on the seismic behavior of the buildings and compared with regular concrete infills, isolated infills and shear walls. For this, moment frame structures of 1, 3, 5 and 7 story buildings, designed on the basis of Iranian codes, are considered. Then, nonlinear time history analyses are carried out for one frame of each building. IDARC 2D Version 7.0 is applied for the analyses.Five earthquake records, including Kobe, Tabas, Elcentro, Northridge and Manjil, are applied in the analyses and the damage indices of the buildings are compared. The Park and Ang formula is chosen for the damage index. The results show that application of the fused infill panels improves the seismic behavior of the buildings and are superior to other considered elements e.g. shear walls, regular infills and isolated walls.