The present study considers steady laminar two-dimensional incompressible flow over both in-line and staggered flat tube bundles used in heat exchanger applications. The effects of various independent parameters, such as Reynolds number (Re), Prandtl number (Pr), length ratio (L/Da), and height ratio (H/Da), on the pressure drop and heat transfer were studied. A finite volume based FORTRAN code was developed to solve the governing equations. The scalar and velocity variables were stored at staggered grid locations. Scalar variables (pressure and temperature) and all thermophysical properties were stored at the main grid location and velocities were stored at the control volume faces. The solution to a one-dimensional convection diffusion equation was represented by the power law. The locations of grid points were generated by the algebraic grid generation technique. The curvilinear velocity and pressure fields were linked by the Semi-Implicit Method for Pressure Linked Equations (SIMPLE) algorithm. The line-by-line method, which is a combination of the Tri-Diagonal Matrix Algorithm (TDMA) and the Gauss-Seidel procedure, was used to solve the resulting set of discretization equations. The result of the study established that the flow is observed to attain a periodically fully developed profile downstream of the fourth module. The strength increases and the size of the recirculation gets larger as the Reynolds number increases. As the height ratio increases, the strength and size of the recirculation decreases because the flow has enough space to expand through the tube passages. The increase in length ratio does not significantly impact the strength and size of the recirculation. The non-dimesionalized pressure drop monotonically decreased with an increase in the Reynolds number. In general, the module average Nusselt number increases with an increase in the Reynolds number. The results at Pr = 7.0 indicate a significant increase in the computed module average Nusselt number when compared to those for Pr = 0.7. The overall performance of in-line configuration for lower height ratio (H/Da = 2) and higher length ratio (L/Da = 6) is preferable since it provides higher heat transfer rate for all Reynolds numbers except for the lowest Re value of 25. As expected the staggered configurations perform better than the in-line configuration from the heat transfer point of view.
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机译:本研究考虑了在换热器应用中使用的直列和交错扁平管束上的稳定层流二维不可压缩流。研究了雷诺数(Re),普朗特数(Pr),长度比(L / Da)和高度比(H / Da)等各种独立参数对压降和传热的影响。开发了基于有限体积的FORTRAN代码来求解控制方程。标量和速度变量存储在交错的网格位置。标量变量(压力和温度)和所有热物理特性存储在主网格位置,速度存储在控制体积面。一维对流扩散方程的解由幂定律表示。网格点的位置是通过代数网格生成技术生成的。曲线速度场和压力场通过压力链接方程的半隐式方法(SIMPLE)算法链接。逐行方法是三对角矩阵算法(TDMA)和高斯-塞德尔方法的组合,用于求解离散化方程组。研究结果表明,观察到的流量在第四模块的下游获得了周期性充分展开的轮廓。随着雷诺数的增加,强度增加,再循环量变大。随着高度比的增加,再循环的强度和尺寸减小,因为流具有足够的空间以通过管通道膨胀。长度比的增加不会显着影响再循环的强度和大小。随着雷诺数的增加,无尺寸的压降单调减少。通常,模块平均努塞尔数随雷诺数的增加而增加。 Pr = 7.0时的结果表明,与Pr = 0.7时相比,计算得到的模块平均Nusselt数显着增加。对于较低的高度比(H / Da = 2)和较高的长度比(L / Da = 6),串联配置的总体性能是可取的,因为它为所有雷诺数提供了更高的传热速率,除了最低的Re值。 25.如预期的那样,从传热的角度来看,交错配置的性能要优于串联配置。
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