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Investigating the hydrodynamic performance of carbonation sumps in High Rate Algal Pond (HRAP)raceways using computational fluid dynamics (CFD)

机译：利用计算流体动力学（CFD）研究高速藻池（HRap）水道中碳化池的水动力性能

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The production of microalgae requires carbonation and deoxygenation which is commonly supplied through a sump. This needs to be designed to minimise the energy loss to ensure a high net energy gain from the biofuel. Computational fluid dynamics was used to evaluate different sump designs and flow velocities in terms of energy loss and flow distribution to find the optimum configuration. It was established that increasing the radius of curvature of the corners to 0.1 m and the implantation of one flow deflector resulted in a reduction in hydraulic power of 73% compared to the basic setup. It was apparent that the central baffle resulted in considerable energy loss and when this was removed then a power saving of 95% was possible. There was, however, a much reduced flow around the sump leading to shortened contact time between the gas and fluid which could in turn decrease the carbonation of the fluid. It was also apparent that the use of standard formulas for the calculation of head loss was not applicable

机译：微藻的生产需要碳化和脱氧，这通常是通过集水槽提供的。需要对此进行设计以最大程度地减少能量损失，以确保从生物燃料中获得较高的净能量。计算流体动力学用于评估能量损失和流量分布方面的不同油底壳设计和流速，以找到最佳配置。已经确定，与基本设置相比，将拐角的曲率半径增加到0.1 m并植入一个导流板会导致液压功率降低73％。显然，中央挡板导致了相当大的能量损失，如果将其卸下，则可以节省95％的电能。但是，油底壳周围的流量大大减少，导致气体与流体之间的接触时间缩短，进而可以减少流体的碳化。同样明显的是，使用标准公式计算水头损失是不适用的

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Musgrove, Edward; Heaven, Sonia;
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年度 2015
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1. Investigating the hydrodynamic performance of carbonation sumps in High Rate Algal Pond (HRAP) raceways using computational fluid dynamics (CFD) [J] . Edward Musgrove, Sonia Heaven Biofuels . 2014,第6期

机译：使用计算流体力学（CFD）研究高速率藻类池（HRAP）跑道中碳化池的水动力性能
2. An integrated growth kinetics and computational fluid dynamics model for the analysis of algal productivity in open raceway ponds [J] . Amini Hossein, Wang Lijun, Hashemisohi Abolhasan, Computers and Electronics in Agriculture . 2018,第期

机译：开放滚道池塘藻类生产率分析的综合生长动力学与计算流体动力学模型
3. Comparing the energy efficiency of different high rate algal raceway pond designs using computational fluid dynamics [J] . Kurt Liffman, David A. Paterson, Petar Liouic Chemical Engineering Research & Design: Transactions of the Institution of Chemical Engineers . 2013,第2期

机译：使用计算流体动力学比较不同大速率藻类轨道池塘设计的能效
4. Development and Validation of a Computational Fluid Dynamics Model of Pond Temperature and Algal Growth [C] . J.L. Drewry, C.Y. Choi Annual International Meeting of the American Society of Agricultural and Biological Engineers . 2013

机译：池塘温度和藻类生长计算流体动力学模型的开发与验证
5. Performance Portability Strategies for Computational Fluid Dynamics (CFD) Applications on HPC Systems [D] . Lin, Pei-Hung 2013

机译：HPC系统上计算流体动力学（CFD）应用程序的性能可移植性策略
6. The Hydrodynamic Study of the Swimming Gliding: a Two-Dimensional Computational Fluid Dynamics (CFD) Analysis [O] . Daniel A. Marinho, Tiago M. Barbosa, Abel I. Rouboa, 2011

机译：游泳滑翔的水动力研究：二维计算流体动力学（CFD）分析
7. We conducted experiments using a Solar-Sea-Oasis (SSO) and a microbubble generator (MB) toimprove hypoxic condition at mooring place in Tokyo University of Marine Science and Technology. We looked intoeffects of these apparatuses by computational fluid dynamics (CFD). When we operated SSO, the effect of dissolvedoxygen (DO) supply was only confirmed near the water outlet. This was suggested by computational fluid dynamicsthat water that came out from water outlet rising upward without staying in the bottom was the causes. Then, weconducted experiments using a MB to aerate bottom of the sea more directly. Vertical distributions of DO showedoxygen was supplied horizontally, but DO concentration increased about 0.24 mg L-1 that was lower than SSOexperiment. This was suggested by CFD that water came out from MB generator spread horizontally without stayingnear the MB generator was the cause. Therefore, it is necessary to improve of making the MB water staying morenear the MB generator. [O] . 遠矢亮, 小島諒子, 石丸隆, 2010

机译：我们使用solar-sea-Oasis（ssO）和微泡发生器（mB）进行了实验，以改善东京海洋科技大学系泊处的低氧条件。我们通过计算流体动力学研究了这些能力的影响（ CFD）。当我们操作ssO时，溶解无氧（DO）供应的影响仅在出水口附近得到证实。这是通过计算流体动力学提出的，从出水口出来的水不会停留在底部是然后，我们利用mB进行实验，更直接地对海底进行曝气.DO的垂直分布显示水平供给无氧，但DO浓度增加约0.24 mg L-1，低于ssO nexperiment。这是CFD建议的，水从mB发生器中流出，水平传播而不停留在mB发生器的原因。 mB发电机。
8. CFD (Computational Fluid Dynamics) in the Context of IHPTET (High Perrformance Turbine Engine Technology) Integrated High Performance Turbine Technology Program [R] . Simoneau, R. J., Hudson, D. A. 1989

机译：IHpTET（高性能涡轮发动机技术）集成高性能涡轮技术计划背景下的CFD（计算流体动力学）

Investigating the hydrodynamic performance of carbonation sumps in High Rate Algal Pond (HRAP)raceways using computational fluid dynamics (CFD)

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