发现微孔扩散是控制活性炭吸附速度的决定因素。
The activated carbon adsorption rate was found to be governed by the microporous diffusion.
第二和第三阶段分别是中孔和微孔扩散过程,颗粒内扩散为速率控制步骤。
The second and third fractions were mesopore and micropore diffusion respectively, and the intraparticle diffusion was the control step.
当肥料颗粒接触潮湿土壤时,肥料便会吸收水蒸气,于是水溶养分开始透过包衣上的微孔缓慢而不断地扩散。
When the fertilizer particle contacts the moist soil, the fertilizer will absorb the vapor, and water dissolves nutrients begin to spread but constantly slow through the capillary on the capsule.
用h_2 - n_2二元混合气体通过微孔金属膜进行了扩散分离实验,实验结果与计算值符合很好。
The experiments of diffusional separation were made with H_2-N_2 binary gas mixtures through microporous metal membranes. The experimental results agreed well with the calculated values.
本文讨论了二元混合气体通过微孔金属膜扩散分离的过程。
The diffusional separation processes of binary gas mixtures through microporous metal membranes were discussed in this paper.
通过模拟计算,分析了气体流速、微粒粒径、泡沫陶瓷微孔参数对微粒扩散拦截和惯性碰撞拦截效率的影响。
The diffusion trapping efficiency and inertia collision trapping efficiency are calculated under different gas flowing velocity, particulate size and ceramic foam parameter using the numerical model.
结果显示,随着水蒸气活度的增加,膜内水分子簇尺寸增大,并在膜的微孔内产生多层吸附甚至毛细管冷凝,导致扩散系数迅速降低。
With the increase of mean cluster size(MCS)at different water activities, multi-layer sorption and capillary condensation occur, which lead to the diminution of diffusion coefficients in P…
概述了气体扩散层中水和反应气的传质、GDL的双层结构、微孔层的“水管理”机制以及GDL的研究进展。
The mass transport of water and reactant gas in GDL, the two-layer structure of GDL and the "water management" mechanism of the micro-porous layer, and the research progress in GDL were reviewed.
然而,到目前为止多孔金属-有机骨架一直限制在微孔范围,其较小的孔道不利于物质扩散和传输,从而限制其实际应用。
However, to date porous MOFs are still largely restricted to the microporous regime despite negative impact of their small pore size on diffusion and mass transfer for their practical applications.
介孔允许大分子进入孔道同时具有较小的扩散限制,微孔则作为小分子的吸附场所,使小分子能够很好的择型催化。
The mesoscale pores are benefit to the diffusion of larger molecules with low resistance, while the micro-scale pores can provide effective catalytic sites of small molecules with high selectivity.
通过模拟计算,分析了气体流速、微粒粒径、泡沫陶瓷微孔参数对微粒扩散拦截和惯性碰撞拦截效率的影响。
The diffusion trapping efficiency and inertia collision trapping efficiency are calculated under different gas flowing velocity, particulate size and ceramic foam parameter using the numerical mode...
通过模拟计算,分析了气体流速、微粒粒径、泡沫陶瓷微孔参数对微粒扩散拦截和惯性碰撞拦截效率的影响。
The diffusion trapping efficiency and inertia collision trapping efficiency are calculated under different gas flowing velocity, particulate size and ceramic foam parameter using the numerical mode...
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