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W4283164015 abstract "Hydrogenations and air oxidations usually have low apparent reaction rate, generally controlled by mass transfer rate, and widely exist in the modern chemical manufacturing process. The key to increase the mass transfer rate is the reduction of the liquid film resistance 1/kLa. In this work, the original concept of microinterface intensification for mass transfer and then for these reactions has been proposed. We derived the regulation model and set up the mathematical calculation method of micron-scale gas–liquid interface structure on mass transfer and reaction, designed the mechanical energy exchange device that can produce gas–liquid microinterface system on a large scale, and established the OMIS system which is able on line to measure the diameter and distribution of millions of microbubbles, interface area a and mass transfer film thickness δM, as well as developed a series of microinterface intensified reactor systems (MIRs) for the applications of hydrogenation and air oxidation processes. It is believed that this research will provide an up-to-date development for the intensification of hydrogenation and air oxidation reactions." @default.
W4283164015 created "2022-06-21" @default.
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W4283164015 date "2022-10-01" @default.
W4283164015 modified "2023-10-15" @default.
W4283164015 title "Microinterface intensification in hydrogenation and air oxidation processes" @default.
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W4283164015 cites W1977482541 @default.
W4283164015 cites W1980030485 @default.
W4283164015 cites W1980633570 @default.
W4283164015 cites W1981538244 @default.
W4283164015 cites W1983251502 @default.
W4283164015 cites W1985108566 @default.
W4283164015 cites W1985150643 @default.
W4283164015 cites W1987296684 @default.
W4283164015 cites W1987780406 @default.
W4283164015 cites W1988567387 @default.
W4283164015 cites W1993010458 @default.
W4283164015 cites W1993142418 @default.
W4283164015 cites W1995261669 @default.
W4283164015 cites W2004279681 @default.
W4283164015 cites W2016236413 @default.
W4283164015 cites W2021890176 @default.
W4283164015 cites W2025014741 @default.
W4283164015 cites W2025181017 @default.
W4283164015 cites W2025408309 @default.
W4283164015 cites W2029084980 @default.
W4283164015 cites W2031011020 @default.
W4283164015 cites W2034860345 @default.
W4283164015 cites W2048523351 @default.
W4283164015 cites W2049204369 @default.
W4283164015 cites W2053041900 @default.
W4283164015 cites W2059714664 @default.
W4283164015 cites W2061509174 @default.
W4283164015 cites W2063614833 @default.
W4283164015 cites W2066198931 @default.
W4283164015 cites W2072811205 @default.
W4283164015 cites W2073602479 @default.
W4283164015 cites W2078118088 @default.
W4283164015 cites W2079824085 @default.
W4283164015 cites W2081306123 @default.
W4283164015 cites W2082698388 @default.
W4283164015 cites W2089573342 @default.
W4283164015 cites W2093297804 @default.
W4283164015 cites W2100915175 @default.
W4283164015 cites W2114648049 @default.
W4283164015 cites W2116470685 @default.
W4283164015 cites W2121731140 @default.
W4283164015 cites W2129235504 @default.
W4283164015 cites W2156231221 @default.
W4283164015 cites W2326642085 @default.
W4283164015 cites W2346711634 @default.
W4283164015 cites W2516199781 @default.
W4283164015 cites W2585855627 @default.
W4283164015 cites W2588986507 @default.
W4283164015 cites W2600069990 @default.
W4283164015 cites W2728435754 @default.
W4283164015 cites W2749060315 @default.
W4283164015 cites W2770716191 @default.
W4283164015 cites W2888048300 @default.
W4283164015 cites W2913371095 @default.
W4283164015 cites W2920955521 @default.
W4283164015 cites W3010649923 @default.
W4283164015 cites W3080274012 @default.
W4283164015 cites W3081784346 @default.
W4283164015 cites W3083613375 @default.
W4283164015 cites W3088408233 @default.
W4283164015 cites W3096825608 @default.
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W4283164015 doi "https://doi.org/10.1016/j.cjche.2022.05.022" @default.
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