偕胺肟吡啶树脂对含盐体系中Cu（Ⅱ）的去除

doi:10.19965/j.cnki.iwt.2020-1287

摘要/Abstract

摘要：

以氯球为基体，加入2-氨基-5-氰基吡啶反应得到树脂APN，然后在碱性条件下APN与盐酸羟胺发生胺肟化反应，制备得到偕胺肟吡啶螯合树脂（APO）。探究了不同酸度、不同盐度条件下制备的APO树脂对溶液中Cu（Ⅱ）的吸附性能。实验结果表明，当溶液pH为5和2时，Langmuir模型模拟得到的最大吸附量分别为1.21、0.33 mmol/g。随着酸度的升高，吸附量略有降低；随着盐度的增加，吸附量会逐渐增大。APO树脂主要是通过吡啶N原子和肟基中的O原子对Cu（Ⅱ）进行螯合去除，其具有较好的抗盐和抗酸特性。

关键词: 螯合树脂, 吸附, 重金属

Abstract:

Pyridine-functionalized beads APN were obtained by taking chloromethylated crosslinking polystyrene microspheres and 2-amino-5-cyanopyridine as raw materials. Then through an amidoxime reaction with hydroxylamine hydrochloride under alkaline conditions, amidoxime pyridine chelating beads (APO) was prepared. The adsorption properties of APO towards Cu(Ⅱ) were investigated in various acidic and salty concentration. Experimental results showed that at pH=5 and 2, the maximum adsorption capacities simulated by Langmuir model were 1.21 mmol/g and 0.33 mmol/g, respectively. With increase the concentration of H+, the adsorption amount decreased, however, the adsorption amount gave an elevation as the salty concentration increased. The removal of Cu(Ⅱ) was mainly accomplished through the chelation between N atoms(pyridine groups), O atoms(oxime groups) and Cu(Ⅱ), showing salient salt-tolerance and acid-tolerance properties.

Key words: chelating beads, adsorption, heavy metal

中图分类号:

TQ316.6
X703

陈广源,孙诗书,张小朋,史载锋. 偕胺肟吡啶树脂对含盐体系中Cu（Ⅱ）的去除[J]. 工业水处理, 2021, 41(10): 78-82.

Guangyuan CHEN,Shishu SUN,Xiaopeng ZHANG,Zaifeng SHI. Removal of Cu(Ⅱ) ions from salty systems by amidoxime pyridine resin[J]. Industrial Water Treatment, 2021, 41(10): 78-82.

https://www.iwt.cn/CN/Y2021/V41/I10/78

图/表 9

图1 APO的制备路线

Fig.1 The preparation of APO beads

表1 APO中的各元素含量

Table 1 Elemental composition of APO

材料类型	C/%	H/%	N/%	O/%
APO	70.36	12.90	12.12	4.62

图2 APN与APO的红外光谱

Fig.2 FTIR spectra of APN and APO

图3 不同pH条件下APO对Cu（Ⅱ）的吸附量（a）及吸附方式（b）

Fig.3 Adsorption amounts(a)and chelating modes(b) of APO for Cu(Ⅱ) as a function of pH

图4 APO对Cu（Ⅱ）的吸附等温线

Fig.4 Adsorption isotherm of APO for Cu(Ⅱ)

表2 APO对Cu（Ⅱ）吸附等温线拟合参数

Table 2 Fitting parameters of adsorption isotherm models of APO for Cu(Ⅱ)

离子	pH	Langmuir模型			Freundlich模型
离子	pH	Q_m/(mmol·g^-1)	b	R_L²	K_F	n	R_F²
Cu(Ⅱ)	5	1.21	0.34	0.9995	0.31	1.710	0.9914
Cu(Ⅱ)	2	0.33	1.47	0.9829	0.20	3.884	0.9377

图5 APO对Cu（Ⅱ）的动力学吸附行为

Fig.5 Kinetic adsorption behaviors of APO for Cu(Ⅱ)

表3 APO对Cu（Ⅱ）的吸附动力学拟合参数

Table 3 Fitting parameters of adsorption kinetics of APO for Cu(Ⅱ)

pH	准一级动力学模型			准二级动力学模型
pH	k₁/min^-1	Q_e/（mmoel·g^-1）	R²	k₂/(g·mmol^-1/·min^-1)	Q_e/(mmol·g^-1)	R²
5	0.116	0.277	0.6493	0.743	0.285	0.9067
2	0.044	0.176	0.9625	0.349	0.185	0.9804

图6 不同无机盐（a）和不同浓度NaNO₃（b）对吸附效果的影响

Fig.6 Adsorption amounts of Cu(Ⅱ) with different inorganic salts(a)and different concentrations of NaNO₃(b)

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