This present survey aims to obtain a bioclimatic building, made from a double external envelope in straws, with natural cooling and heating. The building is designed with double walls, double terraces and double floors in straws bullets. The doors and the windows are supposed insulating, using the polystyrene. The three-dimensional modelling of heat and mass transfers is led, in transient response and simultaneously, within the air of the cell, considered at the instruction temperature, and through its internal partitions. To model the building, considered in laminar regime, the Navier Stokes equations, the coupling between the three modes of thermal transfers and the method of the average radiant temperature, are adopted. The numerical values of model when compared to the results of experiences appeared very satisfactory. The theoretical and experimental survey proved that buildings with double envelope in straws bullets are bioclimatic and with homogeneous distribution in temperature and in humidity.
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Real Estate Blog - Real Estate News: The house with straw. http://blog.bmykey.com. Accessed August 2011.

A bioclimatic house made of straw with frame wood. http://domoscom.blogspot.com . Accessed August 2011.

Atelier Werner Schmidt: Experimenting the straw. http://www.atelierwernerschmidt.ch/. Accessed August 2011.

Tabarki, M., Ben Mabrouk, S., Numerical modeling of heat and mass transfer phenomena in heated enclosures, (2012) International Review of Mechanical Engineering (IREME), 6 (2), pp. 291-301.

Ben Snoussi, L., Chouikh, R., Abid, R., Simulation of laminar natural convective heat transfer in a three-dimensional rectangular enclosure, (2010) International Review of Mechanical Engineering (IREME), 4 (3), pp. 297-304.

N. Tadj, T. Bartzanas, B. Draoui, C. Kittas, Experimental and Numerical Investigation of Convective Heat Transfer in a Tunnel Greenhouse, (2008) International Review of Mechanical Engineering (IREME), 2 (6), pp. 872 – 878.

S.V. Patankar and D.B. Spalding, A calculation procedure for heat, mass and momentum transfer in three dimensional parabolic flows, International Journal Heat and Mass Transfer, 15:1787 – 1802, 1972.

Benachour, E., Draoui, B., Rahmani, L., Mebarki, B., Belloufa, L., Asnoune, K., Imine, B., Effect of positioning the heating element on natural convection in a square cavity (habitat Type), (2010) International Review of Mechanical Engineering (IREME), 4 (5), pp. 476-481.

Ashrae, ASHRAE handbook, HVAC systems and equipment, ASHRAE, Atlanta, U.S., 1996.

W. Kast and M. Klan, Design and testing of floor heating systems, VDI reports, 464:39–49, 1982.

F. Allard, Contribution to the study of the heat transfers in the cavities thermally driven to big number of Rayleigh, State Thesis, INSA Lyon, University Claude Bernard Lyon1, 1987.

C. Inard, Contribution for thermal coupling study between a transmitter of heating and a room, Ph.D. dissertation, Univ. Claude Bernard Lyon 1, INSA Lyon, France, 1988.

A. Howarth, Temperature distribution and air movements in rooms with a convective heat source, Ph.D. dissertation , Univ. of Manchester, Manchester, England, U.K., 1980.

J. Lebrun, Physiological requirements and physical methods of cooling by concentrated static source, Ph.D. dissertation, Univ. of Liege, Liege, Belgium, 1970.

G.N. Walton, A new algorithm for radiant exchange in room loads calculation, ASHRAE Transactions, 86 (2): 190 – 208, 1980.