Papers by Keyword: Biofluid

Abstract: This study focuses on the performance and mechanical characteristics response of pure Canola oil and Canola oil with existence of Hyaluronic Acid. Numerous studies show that plant-based substances are infrequently used in synthetic synovial fluid. The sort of bio-fluid that derives from plant-based oil and can function as a synthetic synovial fluid is the focus of this work. Three samples of a bio-fluid made of Canola oil with three different concentrations of Hyaluronic Acid (HA) are 0 ml, 5 ml, and 10ml, respectively. The 500 mm x 500 mm x 4 mm Polylactic Acid (PLA) biomaterial disc was chosen in the pin on disc wear and friction test rig experiment in conjunction with a canola-based oil tested lubricant to simulate the mechanical principles on the knee. To obtain accurate findings for the wear rate and friction coefficient, the samples will be put through a tribology test. The experiment was conducted to measure the tribology of the stainless pin to observe the effect of coefficient of friction and wear rate on the pin. The reliable outcome may open up new avenues for future research on synthetic synovial fluid. On the other hand, this study is beneficial to medical technology for future treatment of any diseases related to synovial fluid and allows the manufacturer to improve understanding in the optimization of these lubricants in ensuring a long-term application in the human body.

Abstract: Gasification is one of the technologies for utilization of biomass. Gasification is a transformation process that converts solid fuels into gaseous fuels. The gaseous fuel may be subsequently applied in other technologies with all the benefits that gaseous fuels provide. The principle of biomass gasification is a common knowledge. It is thermochemical decomposition oof the fuel in presence of gasification agent. Heat from the endothermic reaction is obtained by a partial combustion of the fuel (autothermal gasification) or the heat is supplied into a gasifier from the outside (allothermal gasification). Oxygen for the partial combustion is supplied in the gasification medium. Quality, composition and amount of the producer gas depend on many factors which include type of the gasifier, operating temperature and pressure, fuel properties (moisture content) and type and amount of gasification medium. Commonly, air, steam and oxygen and their combinations are used as a gasification medium. Every kind of gasification agents has its significant advantages and disadvantages.Research and analysis of the gasification process must pay special attention to all operating parameters which affect quality and amount of the producer gas that is the efficiency of the conversion itself. Composition of the producer gas, calorific value, and content and composition of impurities are especially observed as these are the basic characteristics directly affecting subsequent application of the gas. Steam addition has a significant impact on gas composition. Steam decomposition into hydrogen and oxygen, and their subsequent reactions increases amount of combustibles, hydrogen, methane and other hydrocarbons. Steam addition in the gasification also affects amount and composition of tar and has a negative impact on heat balance.Energy Institute at the Brno University of Technology has a long tradition in research of biomass gasification in atmospheric fluidized bed reactors. Air was used as a gasification medium. This paper describes our experience with gasification using a mixture of air and steam. We analysed the whole process and in this paper we wish to describe the impact of temperature on outputs of the process, especially temperature of leaving steam and temperature of gasification reactions.

Abstract: A key factor for the efficiency in nanostructured devices is charge transport. Despite considerable attention to this subject, the precise nature of transport processes in these systems has remained unresolved. To understand the microscopic aspects of carrier dynamics, we suggest a method for the calculation of correlation functions. They can be expressed as the Fourier transform of a kernel containing the frequency-dependent conductivity (). We present results for the velocity correlation functions , the mean square deviation of position R2 = <[R(t)-R(o)]2> and the diffusion coefficient D = (R2/t) in materials, like TiO2, ZnO, Si, for which a Drude-Lorentz description or its generalizations applies with a good agreement with experiments. We find that D = 0, indicating absence of diffusion at long times, except in the Drude case (o = 0). For small times t/ < 1, however, diffusion can occur even when o 0, within a limited region of size increasing with the value of o. The quantum mechanical extension of this method allows applications for the nanodiffusion in nanostructured, porous and cellular materials, as for biological, medical and nanopiezotronic devices.