Determination of Local Gas Holdup and Volumetric Mass Transfer Coefficient in a Bubble Column by Means of an Ultrasonic Method and Neural Network

M. D. Supardan; A. Maezawa; S. Uchida

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Determination of Local Gas Holdup and Volumetric Mass Transfer Coefficient in a Bubble Column by Means of an Ultrasonic Method and Neural Network

机译：超声法和神经网络法测定鼓泡塔中的局部持气量和体积传质系数

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Gas holdup and the volumetric mass transfer coefficients are very important parameters for mass transfer operation in bubble columns. Up to now, a number of investigations on gas holdup and the volumetric mass transfer coefficient of bubble column systems have been reported. Previous research work by Akita and Yoshida [1], Shah et al. [2], Kawase et al. [3-4]; Kumar et al. [5] amongst others, has proposed empirical and semi theoretical equations to determine gas holdups and volumetric mass transfer coefficients according to experiment data. However, most research is limited to the measurement and the development of mechanical or theoretical models in the conventional manner. It is important to develop a novel method to acquire a good understanding of gas-liquid mass transfer behavior in a bubble column.

机译：气体滞留率和体积传质系数是气泡塔传质操作的重要参数。迄今为止，已经报道了许多关于气体滞留率和鼓泡塔系统的体积传质系数的研究。秋田和吉田[1]，Shah等人以前的研究工作。 [2]，Kawase等。 [3-4]; Kumar等。 [5]除其他外，提出了经验和半理论方程式，根据实验数据确定气体滞留率和体积传质系数。但是，大多数研究仅限于以常规方式进行机械模型或理论模型的测量和开发。重要的是要开发一种新颖的方法，以更好地理解气泡塔中的气液传质行为。

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《Chemical Engineering & Technology: Industrial Chemistry -Plant Equipment -Process Engineering -Biotechnology》 |2003年第10期|共4页
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M. D. Supardan; A. Maezawa; S. Uchida;
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1. Determination of Local Gas Holdup and Volumetric Mass Transfer Coefficient in a Bubble Column by Means of an Ultrasonic Method and Neural Network [J] . M. D. Supardan, A. Maezawa, S. Uchida Chemical Engineering & Technology: Industrial Chemistry -Plant Equipment -Process Engineering -Biotechnology . 2003,第10期

机译：超声法和神经网络法测定鼓泡塔中的局部持气量和体积传质系数
2. Local Gas Holdup and Mass Transfer in a Bubble Column Using an Ultrasonic Technique and a Neural Network [J] . Akinori Maezawa, Muhammad Dani Supardan, Shigeo Uchida, Journal of Chemical Engineering of Japan . 2004,第8期

机译：使用超声波技术和神经网络在鼓泡塔中进行局部气体滞留和传质
3. GAS HOLDUP AND VOLUMETRIC LIQUID-PHASE MASS TRANSFER COEFFICIENT IN BUBBLE COLUMN WITH DRAUGHT TUBE AND WITH GAS DISPERSION INTO ANNULUS [J] . HIROYUKI SATO, KOZO KOIDE, SHINJI IWAMOTO Journal of Chemical Engineering of Japan . 1983,第5期

机译：带气泡管和气体扩散入环状结构的鼓泡塔中的气体滞留和体积液相流传质系数
4. Artificial neural networks for pattern recognition of volumetric gas-liquid mass transfer coefficient [C] . Fang Baishan Asia-Pacific biochemical engineering conference;APBIOCHEC'97 . 1997

机译：人工神经网络模式识别气液传质系数
5. Modeling of the phase behavior of light (C2 and C3) olefins in liquid phase epoxidation systems and experimental determination of gas/liquid mass transfer coefficients. [D] . Ghanta, Madhav. 2008

机译：轻质（C2和C3）烯烃在液相环氧化系统中的相行为建模和气/液传质系数的实验确定。
6. Ultrasonic Transmission Tomography Sensor Design for Bubble Identification in Gas-Liquid Bubble Column Reactors [O] . Nan Li, Mingchen Cao, Kun Xu, 2018

机译：用于气液泡塔反应器中气泡识别的超声波透射层析成像传感器设计
7. Effects of alcohols on gas holdup and volumetric liquid-phase mass transfer coefficient in gel-particle-suspended bubble column. [O] . Jonathan L. Salvacion, Mitsuhiro Murayama, Kazuhisa Ohtaguchi, 1995

机译：醇对凝胶颗粒悬浮气泡塔气体堆积和体积液相传质系数的影响。

Determination of Local Gas Holdup and Volumetric Mass Transfer Coefficient in a Bubble Column by Means of an Ultrasonic Method and Neural Network

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