This pa per pres ents the ex per i men tal in ves ti ga tion of tur bu lent struc tures of flow around a sphere. The mean ve loc ity field and the tur bu lence quan ti ties are ob tained in a small low speed wind tun nel us ing, la ser-Dopp ler anemometry, for the flow around a sphere at subcritical Reynolds num ber of 50,000. The re sults of la ser-Dopp ler mea sure ments are com pared with results ob tained by large eddy sim u la tion. In this pa per also flow vi su al iza tion around sphere in the big ger wind tun nel and wa ter chan nel for Reynolds num bers be tween 22,000 and 400,000 have been done.
Although the countries of the Western Balkans are mostly electrified, there are still regions which do not have access to the electricity network or where the network capacity is insufficient. For the most part such areas are under special care of the state (i. e. underdeveloped, devastated by war, depopulated), on islands or in mountainous regions. Since the decentralized energy generation covers a broad range of technologies, including many renewable energy technologies that provide small-scale power at sites close to the users, such concept could be of interest for these locations. This paper identifies the areas in Western Balkans where such systems could be applied. Consideration is given to geographical locations as well as possible applications. Wind, hydro, solar photovoltaic, and biomass conversion systems were taken into consideration. Since the renewable energy sources data for Western Balkans region are rather scarce, the intention was to give a survey of the present situation and an estimate of future potential for decentralized energy generation based on renewable energy sources. The decentralized energy generation based on renewable energy sources in Western Balkans will find its niche easier for the users that will produce electricity for their own needs and for the users located in remote rural areas (off-grid applications).
The technical analysis of a hybrid wind-photovoltaic energy system with hydrogen gas storage was studied. The market for the distributed power generation based on renewable energy is increasing, particularly for the standalone mini-grid applications. The main design components of PV/Wind hybrid system are the PV panels, the wind turbine and an alkaline electrolyzer with tank. The technical analysis is based on the transient system simulation program TRNSYS 16. The study is realized using the meteorological data for a Typical Metrological Year (TMY) for region of Novi Sad, Belgrade cities and Kopaonik national park in Serbia. The purpose of the study is to design a realistic energy system that maximizes the use of renewable energy and minimizes the use of fossil fuels. The reduction in the CO2 emissions is also analyzed in the paper. [Acknowledgment. This paper is the result of the investigations carried out within the scientific project TR33036 supported by the Ministry of Science of the Republic of Serbia.
This paper presents the experimental results for the flow around a sphere: a smooth sphere in flow with low inlet turbulence, a sphere with trip wire and a sphere in flow with high free stream turbulence, at sub critical Reynolds number. The mean velocity field and the turbulence quantities are obtained using laser-Doppler anemometry. Comparison of velocity field and turbulence character is tics for different flow configuration are given.
The behavior of the mast is non-linear due to its slenderness and compliant
guy-support system, having a tendency to lose stability and even crush
suddenly. Wind load is one of the main factors affecting the stability of the
structure of the mast. Structural assessment of the different mast
configurations has been investigated in the past. Furthermore, European
standards EN 1993-3-1:2006 and EN 1993-1-6:2007 already provides some
guidelines about the basis of structural analysis of masts and towers. This
paper presents the results of numerical simulations of a guyed mast exposed
to wind action using finite element method. Structural analyses were
performed for three different constant wind loads, modal analysis provides
the values of natural frequency and mode shapes, while the stability analysis
was performed for the first three buckling load factor values. The motivation
for this study is to investigate the contribution of finite element method to
structural analysis of a lattice structure such as guyed mast as an
alternative and/or improvement to the literature and codes. [Projekat
Ministarstva nauke Republike Srbije, br. TR33036]
The processes of vaporization in porous structures, working with the excess
of liquid are investigated. With regard to the thermal power plants new
porous cooling system is proposed and investigated, in which the supply of
coolant is conducted by the combined action of gravity and capillary forces.
The cooling surface is made of stainless steel, brass, copper, bronze,
nickel, alundum and glass, with wall thickness of (0.05-2)?10-3 m.
Visualizations of the processes of vaporization were carried out using
holographic interferometry with the laser system and high speed camera. The
operating conditions of the experiments were: water pressures (0.01-10) MPa,
the temperature difference of sub-cooling (0-20)?C, an excess of liquid
(1-14) of the steam flow, the heat load (1-60)?104 W/m2, the temperature
difference (1-60)?C and orientation of the system (? 0 - ? 90) degrees.
Studies have revealed three areas of liquid vaporization process
(transitional, developed and crisis). The impact of operating and design
parameters on the integrated and thermal hydraulic characteristics was
defined. The optimum (minimum) flow rate of cooling fluid and the most
effective type of mesh porous structure were also defined.
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