Publications

2012
Boudouda M, Naceri F, Belkacem S. Simulation and determination of the laws control of the SRM for the integrated starter generator application.; 2012.
Chahrazed B, Samir R. Simulation of heat transfer in a square cavity with two fins attached to the hot wall. Energy ProcediaEnergy Procedia. 2012;18 :1299-1306.
BENSEGHIR C, RAHAL S. Simulation of heat transfer in a square cavity with two fins attached to the hot wall,.; 2012.
BENSEGHIR C, RAHAL S. Simulation of heat transfer in a square cavity with two fins attached to the hot wall. Energy procedia (Elsevier)Energy procedia (Elsevier). 2012;Vol. 18 :pp. 1299 - 1306.
LEBCHEK K, OUTTAS T. Simulation of the dynamic behavior of rotors by introducing hysteresis parameters for the control of vibration amplitudes,Dec. 13-15. Dubai - UAE.; 2012.
Amimeur H, Aouzellag D, Abdessemed R, Ghedamsi K. Sliding mode control of a dual-stator induction generator for wind energy conversion systems. International Journal of Electrical Power & Energy SystemsInternational Journal of Electrical Power & Energy Systems. 2012;42.
BEGHAMI Y, KALLA M, Thinon M, BENMESSAOUD H. Spatiotemporal dynamics of forest and mountain formations in Aurès area, Algeria. Journal of Life SciencesJournal of Life Sciences. 2012;6 :663.
Khamsa M, H M, R AH, A B, Soraya T. Spondylodiscites infectieuses, à propos de 59 cas.; 2012.
Kamel L, OUTTAS T. Stabilité dynamique des rotors de turbomachines.Application aux rotors de turbines industrielles. 2012.
Kada M, Rebiai S-E. Stability radii of infinite-dimensional systems subjected to unbounded stochastic perturbations. Systems & control lettersSystems & control letters. 2012;61 :24-30.
Boukrous H. Stéatose hépatique aigue gravidique (a propos d’un cas).; 2012.
Yettou F, Azoui B, Malek A, Gama A. Study and simulation of concentrating irradiance in box solar cooker with tracking reflectors. Revue des Energies Renouvelables, http://www.cder.dzRevue des Energies Renouvelables, http://www.cder.dz. 2012;15 :661 – 670.
Mouni S, Leila H, Mohamed A. Study of the Glucidic Fraction of Celtis Australis L, Crataegus Azarolus L, Crataegus Monogyna Jacq., Elaeagnus Angustifolia L. and Zizyphus Lotus L. Fruits. Proceedings of World Academy of Science, Engineering and Technology. 2012 :1126.
DEMAGH Y, BENMOUSSA H, LACHI M, NOUI S, BORDJA L. Surface particle motions in rotating cylinders: Validation and similarity for an industrial scale kiln,.; 2012 pp. pp. 260-272.
Douak F, Melgani F, Pasolli E, Benoudjit N. SVR active learning for product quality control. 2012 11th International Conference on Information Science, Signal Processing and their Applications (ISSPA). 2012 :1113-1117.
Abid M, Hammani M, Hammani A. Technique de mise en place d&⋕39;un site implantable pour chimiothérapie. Algérie; 2012.
Rafik M, Hayet ML, Djamel MM, Ouahiba C. The Temporal Neuro-Fuzzy Systems Learning Using Artificial Immune Algorithm. International Review of Mechanical EngineeringInternational Review of Mechanical Engineering. 2012;6 :918-922.
BENMOUSSA H, ABDENEBI H, ZITOUNI B, Zeroual M, HADDAD D, MEBARKI B, OULMI K. Thermal Field in SOFC Fed By CH4: Gas Temperature Effect. Sousse, Tunisia; 2012.
HADDAD DJ, ABDENEBI H, ZITOUNI B, BENMOUSSA H, OULMI K. Thermal field in SOFC fed by Hydrogen. Inlet gases temperature effect In pressInlet gases temperature effect In press. 2012;6.
MESMOUDI K, BOUGOUL S, BOURNET PE. Thermal Performance of an Unheated Greenhouse under Semi-Arid Conditions during the Night. Bournet. Acta HorticulturaeBournet. Acta Horticulturae. 2012;vol. 952 :pp: 417-424.Abstract
The aim of this work is to analyze the thermal performance of a greenhouse exposed to semi-arid conditions by investigating experimentally the heat transfers occurring through the walls and ground. A closed unheated Venlo greenhouse without crop in the area of Batna (southern Mediterranean basin) was considered. The study focuses on the effects of (i) the thermal inertia of the soil, (ii) the radiative losses through the cover, and (iii) the convection mode and flow regime on the heat transfer coefficients. Experiments were conducted from January to March 2008 under clear or cloudy skies, and low or high wind velocities. From the results, it is concluded that the heat stored in the ground of the greenhouse represents a significant heat source which can compensate the energy losses through the walls, especially during a night preceded by a high diurnal insulation. This process can maintain an average inside - outside temperature difference during the night within the range [1.59-2.81] K. Results also show that the radiation losses are the main component of the energy losses of the greenhouse, mainly through the outside wall surface of the cover. Conversely, the radiative heat exchange along the inner wall represents the main heat supply to this wall. The convection mode inside the greenhouse induced by the air movement seems to play a significant role on the convective exchange coefficient inside the greenhouse. These coefficients both inside and outside the greenhouse were estimated and analyzed, and a good agreement with the models reported in the literature was found. This study could help growers define and adapt their heating strategy to avoid undesired low temperatures which may damage their crops at night.

Pages