비정상상태의 미세기포에 의한 산소 전달 특성 모사

Journal of Korean Society of Water and Wastewater Pub Date : 2018-10-30 DOI:10.11001/jksww.2018.32.5.381

Jai-Yeop Lee, Ilho Kim

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Abstract

Microbubbles oxygen transfer to water was simulated based on experimental results obtained from the bubbles generation operated under varying liquid supply velocity to the multi-step orifices of the generator. It had been known that liquid supply velocity and bubble size are inversely related. In the oxygen transfer, a non-steady state was assumed and the pseudo stagnation caused the slow movement of bubbles from the bottom to the water surface. Two parameters were considered for the simulation: They represent a factor to correct the pseudo stagnation state and a scale which represented the amount of bubbles in supply versus time. The sum of absolute error determined by fitting regression to the experimental results was comparable to that of the American Society of Civil Engineers (ASCE) model, which is based on concentration differential as the driving force. Hence, considering the bubbles formation factors, the simulation process has the potential to be easily used for applications by introducing two parameters in the assumptions. Compared with the ASCE model, the simulation method reproduced the experimental results well by detailed conditions.

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模拟非静态微气泡氧气传递的特性

根据在不同供液速度下对发生器多级孔的气泡生成实验结果，模拟了微气泡向水中的氧传递。已知供液速度与气泡大小成反比。在氧传递过程中，假定气泡处于非稳态状态，而伪停滞导致气泡从底部向水面缓慢运动。模拟中考虑了两个参数:它们代表了一个校正伪停滞状态的因子，以及一个代表供应中泡沫数量随时间变化的尺度。通过对试验结果的拟合回归确定的绝对误差总和与以浓度差为驱动力的美国土木工程师学会(ASCE)模型相当。因此，考虑到气泡的形成因素，通过在假设中引入两个参数，模拟过程有可能易于应用。与ASCE模型相比，该模拟方法在详细条件下较好地再现了实验结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Korean Society of Water and Wastewater

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