CN113174039A - Hyperbranched polymer for efficiently recovering boron and ultrafiltration process - Google Patents

Abstract

The invention belongs to the technical field of membrane filtration, and particularly relates to a hyperbranched polymer for efficiently recovering boron and an ultrafiltration process. The hyperbranched polymer is a hyperbranched polyhydroxylated polymer, and the hyperbranched polyhydroxylated polymer is one of hyperbranched polyglycidyl glycerol and Diol-HPEI polymer; the hyperbranched polyglycidyl is synthesized by anion ring-opening polymerization of glycidol on pentaerythritol (THME) nucleus, wherein NaOCH3 is used as a catalyst, and 1, 4-dioxane is used as a reaction medium; the Diol-HPEI polymer is synthesized by grafting glycidol onto Hyperbranched Polyethyleneimine (HPEI) molecules through epoxy amine nucleophilic addition reaction. Also discloses an ultrafiltration process of the hyperbranched polymer for efficiently recovering boron, which comprises the following steps: s1: dissolving the hyperbranched polymer in a solution containing boric acid, and adjusting the pH value; s2: and after the adjustment is finished, stirring for 50-70 minutes, and then filtering the solution by using an ultrafiltration membrane.

Description

Hyperbranched polymer for efficiently recovering boron and ultrafiltration process

Technical Field

The invention belongs to the technical field of membrane filtration, and particularly relates to a hyperbranched polymer for efficiently recovering boron and an ultrafiltration process.

Background

Boron, a ubiquitous element in nature, is distributed in various bodies of water mainly in the form of boric acid. Industrially, boron compounds are mainly used in the production of glass fibers, detergents, fuel cells, and the like. However, it is also toxic when its content reaches a certain level. Therefore, boron is a potential pollutant in water and an important industrial raw material, and needs to be recycled from wastewater and seawater urgently. Due to the complex morphology of boron, there is currently no efficient and economical method for separating boron from wastewater, particularly from neutral solutions, because the undissociated boric acid molecule behaves very similar to a water molecule. To date, techniques including Reverse Osmosis (RO), Electrodialysis (ED), ion exchange and electro/chemical coagulation have shown potential for separating boron from water. However, most of these techniques have certain limitations. For example, the boron rejection of reverse osmosis membranes is very sensitive to feed characteristics (e.g., pH, salinity, etc.) and operating pressure, achieving high boron rejection rates of 99% only at very high pH and low salinity, and also creates problems with high energy consumption, high caustic usage, membrane fouling, etc. Also, the presence of other ions such as Cl-and NO 3-in the electrodialysis may have a negative effect on the boron separation. Furthermore, it is very challenging to increase the current efficiency of boric acid transport and to reduce the boron concentration in the dialysate to acceptable levels. The chemical precipitation method can be used for treating high-concentration boron solution, but has the problems of long operation time, high reaction temperature, generation of a large amount of solid waste and the like.

Due to the difficulties and limitations of the above-mentioned prior art methods, new methods need to be explored to identify simpler, more economical methods. An advanced separation process combining complexation and membrane separation, namely a polymer-enhanced hybrid ultrafiltration (PEUF) process, has thus been proposed. The unwanted substances can be individually concentrated and recovered by using specific chelating polymers (i.e. chelating agents based on their complexing chemistry). The process has been widely used to separate and concentrate many inorganic species including cadmium, copper, mercury, lead, zinc, and the like.

Various water-soluble polymers have been reported in the literature as polychelants. Since commercially available polymers such as polyvinyl alcohol and polyethyleneimine show extremely low boron rejection, they must be grafted with highly effective functional groups to improve their boron chelating ability. N-methylglucamine (NMG) is a well-known functional group and has provided reactive sites in boron adsorption resins. Some researchers grafted NMG and its derivatives onto water soluble polymers used in the PEUF process and observed improved boron rejection. Recently, Yilmaz and coworkers synthesized two new boron chelating polymers, hydroxyethylamino glycerol grafted polyglycidyl methacrylate (PNS) and polyethylene-ethylene glycol-co-vinyl alcohol (COP). The maximum boron rejection was about 55% when PNS was used at a polymer loading of 1000g/g boron and a pH of 9.0. The performance is poor due to the negative effects of the carboxylate group or the lack of proton acceptors. To overcome this problem, the research group has further designed a new group of polymers, namely polyvinylamino-N, N-dipropylene glycol and its derived copolymers, which show high boron rejection of 92% and 96%, respectively. These pioneering studies on chelating polymers are indeed encouraging. However, with the exception of limited research, defects of low kinetics or low boron rejection may be found in most of the developed polymers. In order to make PEUF a viable process for boron separation, the search for new polymers is one of the most important tasks.

Disclosure of Invention

To design high performance multi-chelating agents, hyperbranched polymers may be more advantageous than linear polymers; due to its unique spherical characteristics and low intermolecular entanglement properties, hyperbranched polymers have lower solution viscosities, can eliminate membrane fouling problems, and can employ higher polymer concentrations in the PEUF process; therefore, the prepared hyperbranched polymer can realize high chelating capacity to the maximum extent by utilizing the functional groups with high density.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows:

a hyperbranched polymer for efficiently recovering boron is a hyperbranched polyhydroxylated polymer, and the hyperbranched polyhydroxylated polymer is one of hyperbranched polyglycidyl glycerol and Diol-HPEI polymer;

the hyperbranched polyglycidyl is synthesized by anionic ring-opening polymerization of glycidol on pentaerythritol (THME) nuclei, using NaOCH₃1, 4-dioxane as a catalyst is used as a reaction medium;

the Diol-HPEI polymer is synthesized by grafting glycidol onto Hyperbranched Polyethyleneimine (HPEI) molecules through epoxy amine nucleophilic addition reaction.

As a preferable proposal of the invention, the preparation method of the hyperbranched polyglycidyl comprises the following steps,

a1: pentaerythritol (THME) and NaOCH₃Dissolving in methanol to obtain a mixture;

a2: heating the mixture obtained from A1 to 75 +/-1 ℃, keeping the temperature, and vacuumizing for 4-5 hours to remove methanol and water and generate sodium alkoxide;

a3: after the sodium alkoxide obtained in A2 is cooled, mixing 1, 4-dioxane with the cooled sodium alkoxide, and carrying out ultrasonic treatment for 20-25 minutes to obtain a uniform solution;

a4: continuously introducing argon gas into the uniform solution obtained from A3 for 10 minutes to remove dissolved oxygen, keeping the solution in an inert atmosphere, stirring the solution, heating to 95 +/-1 ℃, slowly injecting argon-purified glycidol into the solution at the temperature, completely adding the glycidol solution, keeping the mixture at 95 +/-1 ℃, continuously stirring for 12-12.5 hours, dissolving the stirred sediment in methanol, precipitating the sediment in diethyl ether, and taking the sediment;

a5: and (3) drying the precipitate product obtained in the step (S4) in vacuum at 80 ℃, re-dissolving the dried product in deionized water, dialyzing for 3 days by using a membrane tube with the MWCO range of 6000-8000 Da, and drying to obtain the hyperbranched polyglycidyl glycerol.

As a preferred embodiment of the present invention, the method for preparing the Diol-HPEI polymer comprises the following steps,

b1: diluting an aqueous Hyperbranched Polyethyleneimine (HPEI) solution with deionized water to a solid concentration of 10 wt% at room temperature, and purging with argon for 10 minutes;

b2: slowly adding glycidol into a Hyperbranched Polyethyleneimine (HPEI) solution at room temperature, stirring the solution at room temperature for 3 hours after the addition is finished, and heating the solution in a water bath at 60 ℃ for 3 hours;

b3: after the B2 is heated, cooling at room temperature, and dialyzing the cooled solution by using a membrane tube with the MWCO range of 6000-8000 for 3 days for purification;

b4: the purified solution was concentrated by vacuum distillation in a rotary evaporator to obtain a viscous solution, and the concentrated solution was freeze-dried overnight to obtain Diol-HPEI polymer.

An ultrafiltration process for efficiently recovering a boron hyperbranched polymer comprises the following steps:

s1: dissolving the hyperbranched polymer in a solution containing boric acid, and adjusting the pH value;

s2: and after the adjustment is finished, stirring for 50-70 minutes, and then filtering the solution by using an ultrafiltration membrane.

In a preferred embodiment of the present invention, the mass ratio of the hyperbranched polymer to boron is 10:1 to 100: 1.

In a preferable embodiment of the invention, the pH of the solution in S1 is 6.9 to 9.0.

The invention has the following beneficial effects:

the hyperbranched polyhydroxy polymer is synthesized, and the chelating agent enhanced ultrafiltration process method is adopted, so that the hyperbranched polyhydroxy polymer is applied to the high-efficiency recovery of boron in water and is used as a polychelating agent for boron recovery, and the interception efficiency of boron is improved.

Detailed Description

In order that those skilled in the art can better understand the present invention, the following embodiments are provided to further illustrate the present invention.

Example 1

A preparation method of Hyperbranched Polyglycidyl Glycerol (HPG) comprises the following steps,

a1: 1.5mmol of pentaerythritol (THME) and 0.5mmol of NaOCH₃Dissolved inIn 100mL of methanol to obtain a mixture;

a2: heating the mixture obtained in A1 to 75 +/-1 ℃, and keeping the temperature for vacuumizing for 4 hours to remove methanol and water and generate sodium alkoxide;

a3: after the sodium alkoxide obtained in A2 is cooled, mixing 1, 4-dioxane with the cooled sodium alkoxide, and carrying out ultrasonic treatment for 20 minutes to obtain a uniform solution;

a4: continuously introducing argon gas into the homogeneous solution obtained in A3 for 10 minutes to remove dissolved oxygen, keeping the solution under an inert atmosphere, stirring the solution and heating to 95 +/-1 ℃, slowly injecting 150mmol of argon-purified glycidol into the solution at the temperature at the speed of 1.8ml/h by an autosampler, keeping the mixture at 95 +/-1 ℃ after completely adding the glycidol solution, continuously stirring for 12 hours, stirring the obtained sediment, dissolving the sediment in methanol and precipitating the sediment in ether, and taking the sediment;

a5: and (3) drying the precipitate product obtained in the step (S4) in vacuum at 80 ℃, re-dissolving the dried product in deionized water, dialyzing for 3 days by using a membrane tube with the MWCO range of 6000-8000 Da, and drying to obtain the hyperbranched polyglycidyl glycerol.

The chemical formula of the synthesis of the hyperbranched polyglycidyl is expressed as follows:

example 2

A method for preparing a Diol-HPEI polymer comprises the following steps,

b1: diluting 20g of an aqueous Hyperbranched Polyethyleneimine (HPEI) solution with deionized water to a solid concentration of 10 wt% at room temperature, and purging with argon for 10 minutes;

b2: slowly adding 40g of glycidol into a Hyperbranched Polyethyleneimine (HPEI) solution within 20 minutes at room temperature, stirring the solution for 3 hours at room temperature after the addition is finished, and heating the solution for 3 hours in a water bath at 60 ℃;

b3: after the B2 is heated, cooling at room temperature, and dialyzing the cooled solution by using a membrane tube with the MWCO range of 6000-8000 for 3 days for purification;

b4: the purified solution was concentrated by vacuum distillation in a rotary evaporator to obtain a viscous solution, and the concentrated solution was freeze-dried overnight to obtain Diol-HPEI polymer.

The chemical formula for Diol-HPEI polymer synthesis is expressed as:

an ultrafiltration process for efficiently recovering a boron hyperbranched polymer comprises the following steps:

s1: dissolving the hyperbranched polymer in a solution containing boric acid, and adjusting the pH value;

s2: and after the adjustment is finished, stirring for 50-70 minutes, and then filtering the solution by using an ultrafiltration membrane.

The products obtained in example 1 and example 2 were used for boric acid filtration;

an ultrafiltration process for efficiently recovering a boron hyperbranched polymer comprises the following steps:

s1: dissolving the hyperbranched polymer in a solution containing boric acid, and adjusting the pH value; wherein the mass ratio of the polymer to boron is fixed to 100:1, pH value is 6.9;

s2: after completion of the adjustment, the mixture was stirred for 60 minutes, and then the solution was filtered with an ultrafiltration membrane.

After the ultrafiltration membrane treatment, analyzing the original solution and the filtrate by using ICP-OES and TOC, and calculating the retention rate of boron and organic matters; the calculation formula is as follows:

the retention rate (R) is obtained by the following formula:

wherein Cp is the solute content of the permeate and Cf is the solute content of the feed solution;

wherein the solute refers to a chelating agent or boric acid.

According to the scheme, the temperature of the boric acid solution is adjusted, and then the rejection rate of boron and organic matters at the temperature is calculated; table 1 was obtained;

	temperature of	Membrane flux (LMH/bar)	Retention rate of chelating agent%	Boric acid retention%
					HPG	25	54	99.6	50.5
HPG	45	68	99.6	68.0
					HPG	65	75	99.9	89.8
Diol-HPEI	25	48	99.8	53.9
					Diol-HPEI	45	74	99.7	78.6
Diol-HPEI	65	98	99.9	94.7

Table 1: detection data of hyperbranched polymer processed at different temperatures

From table 1, it can be seen that there is a tendency for the permeation flux to increase with increasing temperature; this is due to the agglomeration of polymer molecules caused by boric acid, which can eliminate pore plugging; the attachment of boron to the polymer chain can also alter the interaction between the polymer and the negatively charged membrane surface, thereby avoiding the formation of a fouling layer on the membrane surface; (ii) a The boron rejection capacity also increases with temperature, which means that high temperatures will effectively promote the chelation process;

however, these two polymers behave differently in terms of boron rejection and flux reduction; the boron rejection rate of the Diol-HPEI solution is far higher than that of the HPG solution; this is mainly due to the differences in their polymer structures; in order to complex effectively with boron, the chelating polymer must satisfy the following conditions: (1) having an inert skeleton; (2) containing an ortho diol consisting of two hydroxyl groups occupying ortho cis positions; (3) providing a proton acceptor group that neutralizes protons during the complexation process; (4) high running capacity with fast dynamics. The main structural difference between these two polymers is the proton acceptor. As proton acceptor groups, tertiary amine groups on the Diol-HPEI branches are clearly superior to ether groups on the HPG chains in terms of their protonating ability. In addition, the high chelating ability of the Diol-HPEI polymer may be due to its large number of hydroxyl groups. Also, the clustering of polymers in the Diol-HPEI solution may be more sensitive to temperature, and thus the flux in the Diol-HPEI solution shows a steeper trend.

In the case of the other process being unchanged, the mass ratio of the polymer to boron was changed to be fixed (i.e., the chelating agent loading amount), and then the detection was performed, and the obtained data is shown in table 2:

	chelating agent loading	Boric acid retention%
			HPG	1	59.1
HPG	10	85.6
			HPG	20	88.3
HPG	100	89.8
			Diol-HPEI	1	68.2
Diol-HPEI	10	89.9
			Diol-HPEI	20	93.6
Diol-HPEI	100	94.7

Table 2: detection data under different chelating agent loading

The flux of both polymer solutions tended to decrease with increasing polymer loading, meaning that the fouling tendency was more pronounced; as the polymer loading increases, the active sites for chelation also increase, so the boron rejection rate rises a step in the early stage and then slowly increases as the polymer loading increases; when the HPG loading is greater than 20, the rejection does not increase significantly, indicating that higher HPG loadings may not achieve better separation performance; the low boron rejection may be due to the slow rate of chelation reaction between HPG and boron; in contrast, when the load amount of Diol-HPEI is higher than 100, the boron rejection rate can be further increased.

Under the condition that other processes are not changed, the pH values of the polymer and the boron solution are changed, and then the detection is carried out, and the obtained data are shown in the table 3:

table 3: detection data at different pH values

As can be seen from Table 3, the pH is most effective at neutral pH.

The foregoing embodiments are merely illustrative of the principles of the present invention and its efficacy, and are not to be construed as limiting the invention. Any person skilled in the art can modify or change the above-mentioned embodiments without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which can be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (6)

1. A hyperbranched polymer for efficiently recovering boron is characterized in that: the hyperbranched polymer is hyperbranched polyhydroxylated polymer, and the hyperbranched polyhydroxylated polymer is one of hyperbranched polyglycidyl glycerol and Diol-HPEI polymer;

the hyperbranched polyglycidyl is synthesized by anionic ring-opening polymerization of glycidol on pentaerythritol (THME) nuclei, using NaOCH₃1, 4-dioxane as a catalyst is used as a reaction medium;

the Diol-HPEI polymer is synthesized by grafting glycidol onto Hyperbranched Polyethyleneimine (HPEI) molecules through epoxy amine nucleophilic addition reaction.

2. The hyperbranched polymer for efficiently recovering boron according to claim 1, wherein: the preparation method of the hyperbranched polyglycidyl comprises the following steps,

a1: pentaerythritol (THME) and NaOCH₃Dissolving in methanol to obtain a mixture;

a2: heating the mixture obtained from A1 to 75 +/-1 ℃, keeping the temperature, and vacuumizing for 4-5 hours to remove methanol and water and generate sodium alkoxide;

a3: after the sodium alkoxide obtained in A2 is cooled, mixing 1, 4-dioxane with the cooled sodium alkoxide, and carrying out ultrasonic treatment for 20-25 minutes to obtain a uniform solution;

a4: continuously introducing argon gas into the uniform solution obtained from A3 for 10 minutes to remove dissolved oxygen, keeping the solution in an inert atmosphere, stirring the solution, heating to 95 +/-1 ℃, slowly injecting argon-purified glycidol into the solution at the temperature, completely adding the glycidol solution, keeping the mixture at 95 +/-1 ℃, continuously stirring for 12-12.5 hours, dissolving the stirred sediment in methanol, precipitating the sediment in diethyl ether, and taking the sediment;

a5: and (3) drying the precipitate product obtained in the step (S4) in vacuum at 80 ℃, re-dissolving the dried product in deionized water, dialyzing for 3 days by using a membrane tube with the MWCO range of 6000-8000 Da, and drying to obtain the hyperbranched polyglycidyl glycerol.

3. The hyperbranched polymer for efficiently recovering boron according to claim 1, wherein: the preparation method of the Diol-HPEI polymer comprises the following steps,

b1: diluting an aqueous Hyperbranched Polyethyleneimine (HPEI) solution with deionized water to a solid concentration of 10 wt% at room temperature, and purging with argon for 10 minutes;

b2: slowly adding glycidol into a Hyperbranched Polyethyleneimine (HPEI) solution at room temperature, stirring the solution at room temperature for 3 hours after the addition is finished, and heating the solution in a water bath at 60 ℃ for 3 hours;

b3: after the B2 is heated, cooling at room temperature, and dialyzing the cooled solution by using a membrane tube with the MWCO range of 6000-8000 for 3 days for purification;

b4: the purified solution was concentrated by vacuum distillation in a rotary evaporator to obtain a viscous solution, and the concentrated solution was freeze-dried overnight to obtain Diol-HPEI polymer.

4. An ultrafiltration process of the hyperbranched polymer for efficiently recovering boron, which is based on any one of claims 1 to 3, is characterized in that: the method comprises the following steps:

s1: dissolving the hyperbranched polymer in a solution containing boric acid, and adjusting the pH value;

s2: and after the adjustment is finished, stirring for 50-70 minutes, and then filtering the solution by using an ultrafiltration membrane.

5. The ultrafiltration process of hyperbranched polymer for efficient recovery of boron according to claim 4, wherein: the mass ratio of the hyperbranched polymer to boron is 10: 1-100: 1.

6. The ultrafiltration process of hyperbranched polymer for efficient recovery of boron according to claim 4, wherein: the pH value of the solution in the S1 is 6.9-9.0.