CN105060385A - Method for selectively removing Mn ions in aqueous solution - Google Patents

Abstract

The invention discloses a method for selectively removing Mn ions in an aqueous solution. The method comprises the following steps: (1) soaking a chloromethylated bead in dioxane till the chloromethylated bead is sufficiently swollen, wherein dioxane serves as a reaction solvent; (2) adding isopropanolamine which serves as a ligand into the substance obtained in step (1), and carrying out stirring at 100-120 DEG under the nitrogen protection condition for a 10-12 hours' reaction, wherein the amount-of-substance ratio of isopropanolamine to -CH2Cl is (3.8-4.2):1; (3) filtering the substance obtained in step (2) to obtain a filter cake, washing the filter cake for 3-4 times with dioxane serving as the reaction solvent, carrying out washing with distilled water, acetone, ethyl ether and absolute ethyl alcohol in sequence, and carrying out vacuum drying at 40-60 DEG C till the constant weight is achieved; (4)adding the substance obtained in step (3) into an acetic acid-sodium acetate buffer solution for 24 hours' soaking, adding a heptavalent Mn ion solution, and carrying out stirring at 15-35 DEG C for a reaction till adsorption equilibrium is achieved. Through the adoption of the method, the capability to selectively absorb the Mn (VII) ions is relatively high.

Description

A kind of method of mn ion in selective removal aqueous solution

Technical field

The present invention relates to adsorption of metal ions technology, be specifically related to the method for mn ion in a kind of selective removal aqueous solution.

Background technology

Suitability for industrialized production potassium permanganate (KMnO ₄) process in, the residue after water drop is got is called manganese mud.Manganese mud goes out of use and is not only the waste of promoter manganese, and causes alkali pollution and " red water " pollution.The generation of red water is because the absorption of manganese mud, the potassium manganate solution generation disproportionation reaction of carrying secretly generate caused by potassium permanganate solution.When finding leaching manganese mud in experimental study, manganese and iron all have higher leaching yield, therefore, when producing manganese goods by method for separating and concentrating from leach liquor, also face the problem of iron ion interference.Conventional method for separating and concentrating has many kinds: as membrane separation process, solvent extration, electrochemical reducing, chemical deposition method, ion-exchange-resin process, chelate adsorption concentration method etc.The Master Cost that membrane separation process uses is higher; The operating process of solvent extration is very loaded down with trivial details, and the easy volatile of organic solvent, toxicity and high cost also make its practical application be restricted; The energy consumption of electrochemical reducing is too high; Chemical deposition method is comparatively common, but its precipitation agent used is often expensive, and when processing the metal ion of low concentration poor effect; Ion exchange resin treatment method is simple to operate, and cost is lower but selectivity is poor; Because having, loading capacity is large, enrichment times is high, selectivity is good, easy and simple to handle, resin easily regenerates and the advantage such as acid and alkali-resistance and the trace metal ion be widely used in the selective separation enrichment aqueous solution for chelating adsorption functional material.

Summary of the invention

In order to solve the problems of the technologies described above, the invention provides the method for mn ion in a kind of selective removal aqueous solution.

In order to reach above-mentioned technical purpose, the invention provides the method for mn ion in a kind of selective removal aqueous solution, comprising the following steps:

1), using chlorine ball be immersed in as in the dioxane of reaction solvent, until chlorine ball is fully swelling;

2), in step 1) gains in add α-amino isopropyl alcohol as part, under the condition of nitrogen protection at 100 ~ 120 DEG C stirring reaction 10 ~ 12 hours, wherein ,-the CH in described α-amino isopropyl alcohol and chlorine ball ₂the ratio of the amount of substance of Cl is 3.8 ~ 4.2:1;

3), filtration step 2) gains, obtain filter cake, filter cake be used as the dioxane washing by soaking 3 ~ 4 times of reaction solvent, then use distilled water, acetone, ether, absolute ethanol washing successively; 40 ~ 60 DEG C of vacuum-dryings are to constant weight;

4), in step 3) gains in add after NaAc_HAc buffer solution soaks 24 hours, add septivalency mn ion solution, at 15 ~ 35 DEG C, stirring reaction is to adsorption equilibrium.

Preferably, described step 1) in: the amount ratio of chlorine ball and dioxane is: the dioxane of 1mg chlorine ball/1 ~ 2ml, and soak time is 22 ~ 26 hours.

Preferably, described step 2) in ,-the CH in described α-amino isopropyl alcohol and chlorine ball ₂the ratio of the amount of substance of Cl is 3:1.

Preferably, described step 2) in, temperature of reaction is 100 DEG C.

Preferably, described step 2) in, the reaction times is 10 hours.

Preferably, described step 4) in, the pH value of HAc-NaAc buffered soln is 5.0.

The present invention, compared to prior art, has following advantage:

1, the present invention is chlorine ball for the raw material of the chelating adsorption function resin of adsorbing mn ion, has higher physical strength and physical stability wide material sources, cheap, has obvious economic benefit.

2, the present invention utilizes chemical graft process by the modification of chlorine ball, makes it have larger chemical stability, and enhances opposing acid, the ability of alkali and organic solvent and adsorptive power thereof.

3, in the present invention, PS-IPA has higher selective adsorption to Mn (VII), and adsorptive capacity is large, and rate of adsorption is fast, does not substantially adsorb Fe (III).

The chelating adsorption function resin chemical stability of 4, adsorbing mn ion in the present invention is good, can wash-out, reduces secondary pollution, is convenient to reuse.

The preparation method of 5, adsorbing the chelating adsorption function resin of mn ion in the present invention is easy and simple to handle, and productive rate is high.

Accompanying drawing explanation

Below in conjunction with the drawings and specific embodiments, the present invention is further detailed explanation.

Fig. 1 is reaction principle figure of the present invention;

Fig. 2 is that reaction mol ratio is on the impact of chlorine ball function base transformation efficiency;

Fig. 3 is the impact of reaction times on chlorine ball function base transformation efficiency;

Fig. 4 is the impact of temperature of reaction on chlorine ball function base transformation efficiency;

Fig. 5 be under different pH value PS-IPA on the impact of the loading capacity of metal ions M n (VII), Fe (III);

Fig. 6 be at different time and temperature PS-IPA on the impact of the adsorptive capacity of metal ions M n (VII).

Embodiment

Describe the present invention further below in conjunction with specific embodiment, but content of the present invention is not limited to this.

Remarks: the washing in following examples is washs with distilled water.

Embodiment 1

A method for mn ion in the selective removal aqueous solution, comprises the following steps:

(1) under room temperature, the chlorine ball accurately taking 20.0 ㎎, in the three-necked bottle of 100ml, adds dioxane 30ml, and soaked overnight (about 24 hours) makes chlorine ball fully swelling;

(2) in the gains of step (1), the α-amino isopropyl alcohol (IPA) as part is added, α-amino isopropyl alcohol (IPA) and-CH on chlorine ball ₂the ratio of the amount of substance of Cl is 3:1, keeps the temperature of reaction of 100 DEG C to stir (rotating speed is 100r/min) and react 10 hours under the protective condition of nitrogen;

(3) gains of step (2) filter after terminating by reaction, the filter cake dioxane washing by soaking 3 ~ 4 times (each consumption is 40ml) of gained, then distilled water, acetone, ether, absolute ethanol washing is used successively, 4 times repeatedly (each, the consumption of distilled water is 40ml, the consumption of acetone is 40ml, the consumption of ether is 40ml, the consumption of dehydrated alcohol be 40ml); 50 DEG C of vacuum-dryings, to constant weight, obtain chelating adsorption function resin (referred to as PS-IPA);

(4) the PS-IPA resin of 30.0mg is taken, add in 50mlHAc-NaAc buffered soln (pH is 5.0) and soak after 24 hours, add 10.0ml, Mn (VII) solion (for adopting potassium permanganate formulated) of 0.700mg/mL, adsorb with the speed constant temperature oscillation of 100r/min at 35 DEG C, the measured in solution concentration of metal ions that taking-up quantitative after separated in time is a small amount of, until adsorption equilibrium.

Reaction principle figure as shown in Figure 1.Wherein, macroporous type chloroethyl crosslinked polystyrene microballoon (also name macroporous type chloroethyl crosslinked polystyrene, PS-CH ₂cl, hereinafter referred to as chlorine ball) belong to prior art, such as can purchased from Chemical Plant of Nankai Univ. etc., degree of crosslinking 8%.

Experiment 1

Accurately taking every part is that 4 parts, the chlorine ball of 20.0 ㎎ is placed in 100ml iodine flask, and the dioxane adding 30ml soaks 24h makes chlorine ball fully swelling, then adds a certain amount of α-amino isopropyl alcohol as the part (-CH in α-amino isopropyl alcohol and chlorine ball respectively ₂the ratio of the amount of Cl is respectively 2:1,3:1,4:1,5:1), under nitrogen protection condition at 100 DEG C stirring reaction 10h.After reaction terminates, filter, the filter cake of gained dioxane washing by soaking 3 ~ 4 times, then use distilled water, acetone, ether, dehydrated alcohol repetitive scrubbing for several times (such as 4 times) successively, at 50 DEG C, vacuum-drying is to constant weight.According to following formula computing function base transformation efficiency, draw the optimum synthesis condition of resin of the present invention.Function base transformation efficiency is calculated as follows:

$N\%=\frac{1\×{\mathrm{aM}}_N{F}_{0x}}{1000+1\×F_0\mathrm{\Δ}Mx}$

Wherein, F ₀(5.39mmol/g) be chlorine ball function base (-CH2Cl) content, Fc is PS-IPA resin functional group content (mmole/gram); X is resin function base transformation efficiency (%); n _nbe the number of the nitrogen-atoms of ligand molecular, Nc is the nitrogen content (%) of PS-IPA resin; M ₁and M ₂be weight be the quality (mol/g) of nitrogen-atoms in part and chlorine ball respectively.

Experimental result as shown in Figure 2, according to Fig. 2, is learnt: when mol ratio is lower, and the function base transformation efficiency of resin increases with the rising of mol ratio; But along with the continuation of mol ratio increases, resin function base transformation efficiency has no obvious rising, and this may be because the avtive spot of parent fully contacts the state of reaching capacity with part, so continue to improve the transformation efficiency that concentration is also difficult to improve function base.So, finally determine that the optimum response mol ratio of PS-IPA is 3:1; I.e. α-amino isopropyl alcohol (IPA) and-CH in chlorine ball ₂ratio the best of the amount of substance of Cl is 3:1.

Experiment 2

Accurately taking every part is that 5 parts, the chlorine ball of 20.0 ㎎ is placed in 100ml iodine flask; the dioxane adding 30ml soaks 24h makes chlorine ball fully swelling; add a certain amount of α-amino isopropyl alcohol as part (α-amino isopropyl alcohol is respectively 3:1 with the ratio of the amount of-CH2Cl in chlorine ball) more respectively, stirring reaction 6h, 8h, 10h, 12h at 100 DEG C respectively under nitrogen protection condition.After reaction terminates, leached by resin, with dioxane washing by soaking 3 ~ 4 times, then use distilled water, acetone, ether, dehydrated alcohol repetitive scrubbing for several times (such as 4 times) successively, at 50 DEG C, vacuum-drying is to constant weight.

Wherein, the account form of function base transformation efficiency is with reference to described in experiment 1.The result of this experiment as shown in Figure 3.

According to Fig. 3, learn: when temperature of reaction is constant, the transformation efficiency of resin function base increase in time and raising; But after exceeding certain hour, continue time expand and can not continue the transformation efficiency significantly improving function base, decrease on the contrary.The consideration of Comprehensive Experiment condition and combined coefficient, finally determines that the best generated time of PS-IPA is 10h.

Experiment 3

Accurately taking every part is that 5 parts, the chlorine ball of 20.0 ㎎ is placed in 100ml iodine flask, and the dioxane adding 30ml soaks 24h makes chlorine ball fully swelling, then adds a certain amount of α-amino isopropyl alcohol as the part (-CH in α-amino isopropyl alcohol and chlorine ball respectively ₂the ratio of the amount of Cl is respectively 3:1), stirring reaction 10h at 70 DEG C, 80 DEG C, 90 DEG C, 100 DEG C, 110 DEG C, 120 DEG C, 130 DEG C respectively under nitrogen protection condition.After reaction terminates, leached by resin, with dioxane washing by soaking 3 ~ 4 times, then use distilled water, acetone, ether, dehydrated alcohol repetitive scrubbing for several times (such as 4 times) successively, at 50 DEG C, vacuum-drying is to constant weight.According to following formula computing function base transformation efficiency, draw the optimum synthesis condition of resin.

Wherein, the account form of function base transformation efficiency is with reference to described in experiment 1.The result of this experiment as shown in Figure 4.

According to Fig. 4, learn: when temperature of reaction is lower, the transformation efficiency of resin function base raises with the rising of temperature; But after reaching certain temperature, continue raised temperature and can not continue the transformation efficiency significantly improving function base.The consideration of Comprehensive Experiment condition and combined coefficient, finally determines that the optimum synthesising temperature of PS-IPA is 100 DEG C.

Experiment 4

Accurately take the PS-IPA resin 7 parts that every part is 15.0mg and be placed in 100ml iodine flask, the corresponding pH=3.0 adding 20ml respectively, pH=3.5, pH=4.0, pH=4.5, pH=5.0, pH=5.5, pH=6.0, after the HAc-NaAc buffered soln immersion 24h of pH=6.5, every part adds 5.0mL, Mn (VII) solion (for adopting potassium permanganate formulated) of 0.700mg/mL and 5.0mL, constant temperature oscillator is placed under Fe (III) solion (for the adopting iron trichloride formulated) 298K of 0.700mg/mL, with the rotating speed constant temperature jolting of 100r/min, residual metal ions concentration in determination and analysis aqueous phase at regular intervals, until balance.As stated above, can show that pH is on the impact of modified chelating function resin on septivalency mn ion and ferric ion absorption property.Acquired results as shown in Figure 5.

According to Fig. 5, learn: the optimal adsorption pH value of PS-IPA resin to Mn (VII) solion is 5.0, can from substantially not adsorbing Fe (III) containing selective adsorption Mn (VII) the mixing solutions of Fe (III), Mn (VII) simultaneously.

Experiment 5

Accurately take the PS-IPA resin 3 parts that every part is 30.0mg, add respectively in 50mlHAc-NaAc buffered soln (pH is 5.0) and soak after 24 hours, add 10.0ml, Mn (VII) solion (for adopting potassium permanganate formulated) of 0.700mg/mL, adsorb with the speed constant temperature oscillation of 100r/min at 15 DEG C, 25 DEG C, 35 DEG C respectively, the measured in solution concentration of metal ions that taking-up quantitative after separated in time is a small amount of, until adsorption equilibrium.Acquired results as shown in Figure 6.

According to Fig. 6, learn: all larger in the adsorption rate of initial stage resin; Along with the carrying out of absorption, speed reduces gradually; Finally reach balance.And along with the adsorptive capacity of rising resin heavy metal ion Mn (VII) of temperature also increases, PS-IPA resin is 35h to the time of equilibrium adsorption of septivalency mn ion as seen from Figure 6.

In sum, in the present invention, the optimum synthesis condition of PS-IPA resin is :-the CH in α-amino isopropyl alcohol and chlorine ball ₂the ratio of the amount of substance of Cl is 3:1, and synthesis reaction temperature is 110 DEG C, and synthesising reacting time is 10 hours, and the chlorine ball function base transformation efficiency of gained is 56.03%; Optimal adsorption condition is: optimal adsorption pH value is 5.0, and the adsorption effect of gained is: 37.3mg/g.

Experiment 6

Accurately take the PS-IPA resin 3 parts that every part is 15.0mg, every part of Mn (VII) solion adding 0.700mg/mL (for adopting potassium permanganate formulated) 5ml, HAc-NaAc buffered soln (pH is 5.0) 25ml, cumulative volume is that 30ml is in 15 DEG C, vibration absorption under the rotating speed of 100r/min, after adsorption equilibrium; By resin filter, use HAc-NaAc (pH is 5.0) respectively, distilled water wash successively 3 times (each, the consumption of HAc-NaAc is 40ml, the consumption of distilled water is 40ml), add 30ml concentration and be respectively 0.5mol/l, 1.0mol/l, 2.0mol/l, the sodium hydroxide stripping liquid of 5.0mol/l, 6mol/l, resolves completely and surveys concentration of metal ions.

The desorption efficiency of sorbent material is calculated as follows:

$E\left(\%\right)=\frac{\left(C_d{V}_d\right)}{(C_0-C_e)V}\×100\%$

C in formula _dfor the equilibrium concentration (mgmL of metal ion in strippant ^-1); V _dfor stripping liquid volume (mL) used.C _oand C _ebe respectively the starting point concentration (mgmL of metal ion in aqueous phase ^-1) and equilibrium concentration (mgmL ^-1); V is liquid phase volume (mL).

Acquired results is as shown in table 1.

The desorption efficiency of PS-IPA under table 1 different N aOH concentration

Comparative example 1

Change the PS-IPA resin as sorbing material in embodiment 1 into chitosan (CTS).The other the same as in Example 1.

Detected according to the method for experiment 4 by CTS, its optimal adsorption condition is: optimal adsorption pH value is 3.0, and the optimal adsorption effect of gained to Mn (VII) is: 11mg/g.Adsorptive capacity is far below the PS-IPA resin in embodiment 1.

Comparative example 2

The α-amino isopropyl alcohol as part in embodiment 1 is made into 4-AA (AATP), 2-amido-6-chloropurine (ACP), 2-mercaptobenzothiazole (MPTZ), lamotrigine (LMTG), modification is carried out to chlorine ball, the other the same as in Example 1.

4 kinds of material modified methods according to experiment 4 in comparative example are detected, they to Mn (VII) all without obvious adsorption effect.

Above-described embodiment does not limit the present invention in any way, and the technical scheme that the mode that every employing is equal to replacement or equivalent transformation obtains all drops in protection scope of the present invention.

Claims (6)

1. the method for mn ion in the selective removal aqueous solution, is characterized in that, comprise the following steps:

1), using chlorine ball be immersed in as in the dioxane of reaction solvent, until chlorine ball is fully swelling;

2), in the gains of step 1), add α-amino isopropyl alcohol as part, under the condition of nitrogen protection at 100 ~ 120 DEG C stirring reaction 10 ~ 12 hours, wherein ,-the CH in described α-amino isopropyl alcohol and chlorine ball ₂the ratio of the amount of substance of Cl is 3.8 ~ 4.2:1;

3), filtration step 2) gains, obtain filter cake, filter cake be used as the dioxane washing by soaking 3 ~ 4 times of reaction solvent, then use distilled water, acetone, ether, absolute ethanol washing successively; 40 ~ 60 DEG C of vacuum-dryings are to constant weight;

4), add after NaAc_HAc buffer solution soaks 24 hours in the gains of step 3), add septivalency mn ion solution, at 15 ~ 35 DEG C, stirring reaction is to adsorption equilibrium.

2. method according to claim 1, is characterized in that, in described step 1): the amount ratio of chlorine ball and dioxane is: the dioxane of 1mg chlorine ball/1 ~ 2ml, and soak time is 22 ~ 26 hours.

3. method according to claim 1, is characterized in that, described step 2) in ,-the CH in described α-amino isopropyl alcohol and chlorine ball ₂the ratio of the amount of substance of Cl is 3:1.

4. method according to claim 1, is characterized in that, described step 2) in, temperature of reaction is 100 DEG C.

5. method according to claim 1, is characterized in that, described step 2) in, the reaction times is 10 hours.

6. method according to claim 1, is characterized in that, in described step 4), the pH value of HAc-NaAc buffered soln is 5.0.