这是使用吸附等温线的五种方式。
测定了吸附等温线并探讨了吸附机理。
The adsorption isotherm and the mechanism for the adsorption were investigated respectively.
染料吸附可以用多层吸附等温线来描述。
Dye adsorption can be described by a multilayer adsorption isotherm curve.
吸附等温线是平衡方程序。
钼酸根在针铁矿上的吸附等温线为S型。
S shape isotherms were observed for the adsorption of molybdate on goethite.
计算了相应的吸附等温线参数和吸附动力学参数。
The parameters of adsorption isotherm and kinetics are calculated.
论文最后对柱层析的有关吸附等温线理论进行了探讨。
The related theory of adsorptive isotherm was studied about columniation layer analyse in the last of thesis.
此外还研究了吸附等温线、吸附动力学和吸附热力学。
In addition to this, the isotherms, kinetics and thermodynamics of the biosorption were also studied.
用高真空重量法测取了自制吸附剂NA和NB的吸附等温线;
The adsorption isotherms of adsorbents (NA and NB) were obtained by high vacuum gravimetric method.
由于沸石微孔扩张,脱附等温线与原先的吸附等温线有所不同。
As a result of the expansion of micropore in zeolites, the desorption isotherm is different from the adsorption isotherm.
结果表明,吸附等温线很好的符合兰缪尔模型和佛兰德利希模型。
It was observed that the adsorption isotherms are well represented by both the Langmuir and Freundlich isotherm models.
前沿分析法是测定吸附等温线的较为准确、快速和经济的方法之一。
Frontal analysis method is one of the accurate, precise, fast and economic method to determine the adsorption isotherm.
前沿分析法是测定吸附等温线的较为准确、快速和经济的方法之一。
Frontal analysis method is one of the most accurate, precise, fast and economic method to determine adsorption isotherm.
吸附实验确定了HPW12在载体上的吸附平衡时间及吸附等温线方程。
The balance time and isotherm equation for the adsorption of HPW12 on the carrier are determined.
土壤对多环芳烃的吸附去除效果明显,其中苊和菲的吸附等温线呈线性。
The sorption of acenaphthene and phenanthrene was characterized by linear isotherm indicating solute partition between water and the organic phase in soil.
浓度大于0.1%,油砂表面的吸附与脱附达成平衡,吸附等温线出现平台。
When the concentration of surfactant is above 0.1%, the adsorption and desorption on the reservoir sand are balanced, in which the adsorption isotherm is level.
氟化后活性炭纤维的孔结构和比表面积变小,氮低温吸附等温曲线明显降低。
The pore size and specific surface area of ACFs were decreased after fluorination. The adsorption isotherm of nitrogen on ACFs were evidently reduced.
本文首次提出77K下CO_2对干空气的吸附等温线,并给出了实验结果。
The adsorption isotherm of dry air on CO2 forst at 77k is presented with experimental results given.
测定了酯化硅胶的物理结构、水蒸气吸附等温线、润湿热、差热分析和红外光谱。
The physical structure, water vapor adsorption isotherms, heat of wetting, DTA and IR for esterified silica gel were determined.
采用序贯实验设计法对正葵烷在5A分子筛上的吸附等温线实验进行了实验设计。
A sequential experimental design procedure was applied to optimize parameter estimation for adsorption isotherm of n -decane on 5A molecular sieves.
将吸附速率方程、吸附等温方程与物料衡算相结合预测了其他条件下的穿透曲线。
The breakthrough curve inside the bed under another operation is predicted by the adsorption rate equation, the adsorption isotherm equation and the material balance equation.
利用静态模拟实验研究河滩砂砾石对油类的静态吸附特性,确定平稳吸附等温方程。
Through the static simulating experiment which was designed to study the static adsorption of petroleum pollutant by gravel, the equilibrium isothermal adsorption equation was determined.
最后对于静态吸附实验中单组分、二组分竞争吸附等温以及吸附的动力学方程进行了探讨。
At last, the adsorptive isotherm and kinetic models of single, binary component in static adsorptive experiment were studied.
通过对ACF与ACFP的氮气吸附等温线的分析,表明ACFP的吸附机理仍然是微孔体积填充。
The adsorption principle of ACFP is micropore volume filling according to Nitrogen adsorption isotherm plot.
从吸附剂表面能量分布的不均匀性导出一个新吸附等温线方程,其形式简单并符合单分子层吸附机理。
A new isotherm equation is derived from the heterogeneity of adsorbent surface. It is simple in form and compatible physically with the mechanism of monolayer adsorption.
采用吸附仪测定了所制负载金属活性碳纤维的吸附等温线,然后用不同理论方法对孔径分布进行表征分析。
The pore distribution of metal coating activated carbon fibers were analyzed by HK, BJH and Dubinin theories from the nitrogen adsorption isotherms measured by auto adsorption meter.
测定了两种活性炭纤维(acf)的氮气、水吸附等温线和XPS,研究了ACF的微孔结构和表面性质。
The nitrogen and water adsorption isotherms and XPS of two activated carbon fibers (ACF) are determined. The micropore structures and surface properties of ACF are investigated.
得到的吸附等温线分为三个不同区域:低压区等温线对压力轴呈凹形,高压区呈凸形,中间部分近似为直线。
The isotherm was devided into three different sections, at low pressure it is concave, at high pressure it is convex and the middle section it is nearly linear.
得到的吸附等温线分为三个不同区域:低压区等温线对压力轴呈凹形,高压区呈凸形,中间部分近似为直线。
The isotherm was devided into three different sections, at low pressure it is concave, at high pressure it is convex and the middle section it is nearly linear.
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