An investigation of heat transfer in a three-dimensional chimney with consideration of the flow compressibility is studied numerically.The finite difference is adopted and the computational approaches could be divided into two parts. One is the inviscid terms The Roe scheme is utilized to deal with the flux of inviscid terms and the preconditioning matrix is added to let the scheme to be more effective for all speed filed. The other is viscous term and the central difference of second order is utilized to handle it. The temporal term is solved by LUSGS. Non-reflection conditions at the outlet is derived in order to resolve reflections induced by acoustic waves. The result shows that the convergent chimney construction can accelerate flow velocities by changing the area of cross section ,and the superior enhancement of heat transfer rates of the center of the heat wall are achieved. With the decreasing of the angle between the walls, velocities of the fluids sides by wall decrease due to the friction and the heat transfer efficiency decrease. Moreover, the heat transfer efficiency increase with increasing Reynolds number. In order to improve the efficiency of CFD program,CUDA platform is employed for paralleled program in graphic hardware and shows significantly advantage over the CPU implementation.