LU102508B1 - Chitosan-grafted Amino Acid Magnetic Composite Microsphere As Well As Preparation and Application - Google Patents

Abstract

The invention discloses a chitosan-grafted amino acid magnetic composite microsphere. The microsphere is provided with a core-shell structure which takes a chitosan-amino acid complex as a shell, and takes a magnetic material as a core, wherein the complex is obtained by a grafting method of chitosan and amino acid; the amino acid is one of glutamine, glutamic acid and ornithine; in the complex, the amino acid accounts for 5-80 wt%; and the magnetic material is Fe or Fe3O4, and accounts for 10-20% of the total weight of the chitosan and amino acid. The chitosan-grafted amino acid magnetic composite microsphere can be used as a water treatment agent, so that harmful substances (such as dye substances and metal ions) in water can be effectively eliminated, various functions such as good flocculation, metal ion adsorption, deodorization, discoloration and effective reduction of a COD value can be realized.

Description

DESCRIPTION Chitosan-grafted Amino Acid Magnetic Composite Microsphere As Well As Preparation and Application

TECHNICAL FIELD The invention relates to a novel composite material and application thereof in the field of water environment treatment, in particular to a chitosan-grafted amino acid magnetic composite microsphere as well as preparation and application.

BACKGROUND In recent years, water, which is a basic need for people's life, has been polluted more and more seriously with rapid development of economy and industry. At the same time, people demand water of higher quality with the improvement of living conditions. With regard to the characteristics of current water pollution, soluble organic substances and refractory biodegradable compounds in water are increasing year after year, and are not removed remarkably with current conventional water treatment means; and moreover, current water treatment agents mostly can generate secondary pollution substances harmful to the environment, which are undoubtedly harmful for environmental pollution, sustainable development and the like. Therefore, it is the research focus in the current water treatment field that efficient, environment-friendly, economical and secondary-pollution-free water treatment agents need to find.

Natural polymers are macromolecules in animals, plants and microbiological resources in nature, are easily decomposed into water, carbon dioxide, and the like after being discarded, are widely sourced, nontoxic and environment-friendiy. In addition, it is worth mentioning that natural polymer materials are renewable resources that are completely irrelevant to petroleum resources, which can be inexhaustible. With the above-mentioned excellent properties, the natural polymer materials have been widely used in many fields such as biology, medicine and food processing. In the water treatment field, the natural polymer materials have been regarded as one of the best alternative materials for water treatment agents because of their massive reactive groups such as free hydroxyl groups and amine groups distributed on natural polymer molecular chains as well as their flocculation.

As one of the most excellent natural polymer materials, chitosan is a deacetylated product of chitin, contains reactive groups -NHz and -OH in the molecular chains, and forms a cationic polyelectrolyte in an acidic solution, showing good flocculation performance. The chitosan, namely a chitosan precursor, is widely found in crustaceans such as shrimps and crabs, insects and algae, and it is the second natural polymer compounds only to cellulose. In addition, chitosan can complex with transition metal ions, humic acids and surfactants in water to remove water-soluble organic pollutants because of its good complexation. Undoubtedly, it is one of the important directions in the current water treatment field that a water treatment agent is developed by taking chitosan as a base material because of its comprehensive performances such as flocculation, metal ion adsorption and water-soluble organic matter removal.

In order to obtain a large specific surface area to improve its adsorption performance, the chitosan, as an adsorbent material, is difficult to separate from water quickly because of its very small particle size after adsorbing and removing pollutants. In addition, a large number of other active functional groups are grafted or compounded onto a chitosan chain on the premise of ensuring its biocompatibility so as to improve water treatment performance of the chitosan; in order to overcome the defect that the chitosan is not easy to separate from the water quickly, a simple and quick separating method is searched to prepare an efficient water treatment agent with good separation effect, which is undoubtedly of great significance for deep application of chitosan in water treatment.

SUMMARY An objective of the invention is to provide a chitosan-grafted amino acid magnetic composite microsphere as well as preparation and application. The microsphere material can effectively remove harmful substances in the water by adsorption, complexation, etc., and can be effectively separated from the water by a magnetic separation technology for recycling.

The technical solution for realizing the invention is as follows:

A chitosan-grafted amino acid magnetic composite microsphere is provided with a core-shell structure which takes a chitosan-amino acid complex as a shell, and takes a magnetic material as a core, where the composite is obtained by a grafting method of chitosan and amino acid; the amino acid is one of glutamine, glutamic acid and ornithine; in the complex, the amino acid accounts for 5-80 wt%; the magnetic material is Fe or FesO4, and accounts for 10-20% of the total weight of the chitosan and amino acid. The magnetic composite microsphere is prepared by a reverse phase suspension crosslinking method, where the chitosan/ the amino acid and the magnetic material are mixed and dispersed into an aqueous solution, and then is crosslinked by glutaraldehyde by taking cyclohexane as an oil phase.

A preparation method for the chitosan-grafted amino acid magnetic composite microsphere specifically includes the following steps: firstly dissolving chitosan and amino acid to prepare an aqueous solution with 2-10 wt% of chitosan and amino acid; and then ultrasonically dispersing a magnetic material into the solution, adding cyclohexane, uniformly mixing, and crosslinking by glutaraldehyde, thereby forming a polymer magnetic composite microsphere.

Adding amount of the cyclohexane and volume of a chitosan-amino acid mixed aqueous solution are in proportion of 1-10.

Usage amount of glutaraldehyde accounts for 0.1-10% of that of the chitosan.

In a cross-linking process, a pH value of a reaction solution is controlled to be 7-10, a cross-linking temperature is controlled to be 35-65 C and cross-linking time is controlled to be 0.5-3 hours.

The chitosan-grafted amino acid magnetic composite microsphere is applied as a water treatment agent in removing harmful substances in dye wastewater.

The chitosan-grafted amino acid magnetic composite microsphere adsorbs heavy metal ions in water, preferably but not limited to Cu“*, such as lead, zinc, iron, cobalt, nickel, manganese, cadmium, mercury, tungsten, molybdenum, gold, silver and other heavy metal ions, which also have the same adsorption effect.

After water treatment, the chitosan-grafted amino acid magnetic composite microsphere is enriched and recycled by a magnetic separation technology to recycle.

Compared with the prior art, the chitosan-grafted amino acid magnetic composite microsphere has the following remarkable advantages: Firstly, the chitosan-grafted amino acid magnetic composite microsphere material can be used as a water treatment agent, so that harmful substances (such as dye substances and metal ions) in water can be effectively eliminated, various functions such as good flocculation, metal ion adsorption, deodorization, discoloration and effective reduction of a COD value can be realized, and can be accomplished within a short time, and thus, use efficiency of the material can be improved. It has certain universality and is applicable to wastewater in dyeing enterprises, electroplating enterprises and the like.

Secondly, both chitosan and amino acid are biodegradable materials, are nontoxic and free of secondary pollution, are extensively applied, and can be effectively separated and enriched to recycle after being treated by the magnetic separation technology, thus further reducing cost.

Thirdly, compared with pure chitosan, the chitosan-grafted amino acid complex has active groups such as a carboxylic acid group and an amide group in addition to an amino group and a hydroxyl group active group on a molecular chain, and has very strong adsorption removal effect for contaminants having affinity with carboxylic acid groups and amide groups. Thus, the chitosan-grafted amino acid composite microsphere has dual effects of chitosan and amino acid, thereby greatly improving its practical sewage treatment ability. Besides, both chitosan and amino acid are biodegradable materials, so that the material is nontoxic, free of secondary pollution, and the like.

Fourthly, the chitosan-grafted amino acid magnetic composite microsphere material, as an efficient water treatment agent for different contaminated water, is especially suitable for deeply treating water that still has harmful substances after being conventionally treated. Moreover, a practical process is relatively simple such that the original water treatment process does not need to greatly change for current water deep treatment and only one process needs to additionally add.

Fifthly, the preparation method for the chitosan-grafted amino acid magnetic composite microsphere material is simple in operation, is short in synthesis time, mainly adopts raw materials which are natural polymer products rich in source, is low in cost, is suitable for industrial production, and is an economical preparation method for obtaining the high-quality water treatment agent.

BRIEF DESCRIPTION OF THE FIGURES Fig. 1 is an infrared spectrum showing the magnetic composite microsphere made of two different polymer materials: a chitosan microsphere (a), and a chitosan-grafted glutamine magnetic composite microsphere (b).

Fig. 2 is a diagram showing comparison of removal of methylene blue (MB) and crystal violet (CV) impurities in water by the magnetic composite microsphere made of two different polymer materials, MB (m{/n: chitosan microsphere / chitosan-grafted glutamine magnetic composite microsphere), CV (e/c: chitosan microsphere/chitosan-grafted glutamine magnetic composite microsphere).

Fig. 3 is a diagram showing the separation effects of the chitosan-grafted amino acid magnetic composite microsphere after removal of two dyes without and with external magnetic fields in 1 minute.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The following further describes the invention with reference to the specific embodiments, but the invention is not limited by the embodiments.

Embodiment 1 Chitosan and glutamine (in a weight ratio of 2:1) were mixed and dissolved into an aqueous solution to prepare a 3% solution, magnetic particles Fe304, which accounted for 10% of the total weight of chitosan and glutamine, were dispersed into the polymer solution by ultrasonication after the solution was uniform, cyclohexane (the cyclohexane and a chitosan/ glutamine mixed solution being in a volume ratio of 5:1) was added, and a glutaraldehyde aqueous solution (glutaraldehyde accounting for 1% of weight of the chitosan) was added after a pH value was regulated to 8, and cross-linking was performed for one hour at a temperature of 50 C, so that a chitosan-grafted glutamine magnetic composite microsphere sample was obtained. Saw the infrared spectrum of the pure chitosan microsphere and the chitosan-grafted glutamine magnetic composite microsphere in Fig. 1. From Fig. 1(b), saw a characteristic absorption peak with a wavenumber of 3250 cm” and wide peaks of O-H and N-H as well as a carbonyl characteristic absorption peak with a wavenumber of 1560 cm’, thereby demonstrating that glutamine had been grafted onto the chitosan molecular chain.

By taking the microsphere as a water treatment agent, and taking methylene blue and crystal violet as simulated dye sewage, a removal condition of dye impurities in the water was measured by a spectrophotometer at wavelengths of 662 nm and 585 nm. As shown in Fig. 2, the magnetic composite microsphere was used as a water treatment agent for detecting a removal condition of methylene blue and crystal violet impurities in the water, and was greatly improved in adsorption amount in comparison with a pure chitosan microsphere. Besides, the chitosan-grafted amino acid magnetic composite microsphere was completely separated from water within one minute through the magnetic separation technology under action of external magnetic fields, where a diagram showing a quick magnetic separation effect is as shown in Fig. 3.

Besides, a removal condition for Cu?" in water was measured through atomic absorption spectroscopy by taking the microsphere as the water treatment agent and taking Cu?*-containing sewage as simulated sewage. A removal rate was 90% or more one hour later.

Embodiment 2 Chitosan and glutamic acid (in a weight ratio of 19:1) were mixed and dissolved into an aqueous solution to prepare a 2% solution, magnetic particles FesQ4, which accounted for 10% of the total weight of chitosan and glutamic acid, were dispersed into the polymer solution by ultrasonication after the solution was uniform, cyclohexane (the cyclohexane and a chitosan/ glutamic acid mixed solution being in a volume ratio of 1:1) was added, and a glutaraldehyde aqueous solution (glutaraldehyde accounting for 3% of weight of the chitosan) was added after a pH value was regulated to 9, and cross-linking was performed for three hours at a temperature of 65 °C, so that a chitosan-glutamic acid magnetic composite microsphere sample (glutamic acid accounting for 5% of the total weight of the polymer material) was obtained. Its performances were similar to those of the Embodiment 1.

Embodiment 3 Chitosan and ornithine (in a mass ratio of 1:4) were mixed and dissolved into an aqueous solution to prepare a 10% solution, magnetic particles FesOa, which accounted for 20% of the total weight of chitosan and ornithine, were dispersed into the polymer solution by ultrasonication after the solution was uniform, cyclohexane (the cyclohexane and a chitosan/ ornithine mixed solution being in a volume ratio of 10:1) was added, and a glutaraldehyde aqueous solution (glutaraldehyde accounting for 0.1% of weight of the chitosan) was added after a pH value was regulated to 10, and cross-linking was performed for 0.5 hour at a temperature of 35 C, so that a chitosan-ornithine magnetic composite microsphere sample (ornithine accounting for 80% of the total weight of the polymer material) was obtained. Its performances were similar to those of the Embodiment 1.

Embodiment 4 Chitosan and glutamic acid (in a mass ratio of 1:2) were mixed and dissolved into an aqueous solution to prepare a 6% solution, magnetic particles FesO4, which accounted for 15% of the total weight of chitosan and glutamic acid, were dispersed into the polymer solution by ultrasonication after the solution was uniform, cyclohexane (the cyclohexane and a chitosan/ glutamic acid mixed solution being in a volume ratio of 7:1) was added, and a glutaraldehyde aqueous solution (glutaraldehyde accounting for 7% of weight of the chitosan) was added after a pH value was regulated to 8 and cross-linking was performed for 2 hours at a temperature of 45 C, so that a chitosan-glutamic acid magnetic composite microsphere sample was obtained. Its performances were similar to those of the Embodiment 1.

Embodiment 5 Chitosan and glutamine (in a mass ratio of 1:1) were mixed and dissolved into an aqueous solution to prepare a 1% solution, magnetic particles FesQa, which accounted for 10% of the total weight of chitosan and glutamine, were dispersed into the polymer solution by ultrasonication after the solution was uniform, cyclohexane (the cyclohexane and a chitosan/ glutamine mixed solution being in a volume ratio of 2:1) was added, and a glutaraldehyde aqueous solution (glutaraldehyde accounting for 10% of weight of the chitosan) was added after a pH value was regulated to 10 and cross-linking was performed for 2.5 hours at a temperature of 60°C, so that a chitosan-glutamine magnetic composite microsphere sample was obtained. Its performances were similar to those of the Embodiment 1.

Although the invention has been described in details through the above preferred embodiments, it should be realized that the above description should not be considered as a limit to the invention. After any person skilled in the art reads the description, any modifications and variations will be apparent to him or her.

The present invention shall fall within the protection scope defined in the following claims.

Claims (10)

1. A chitosan-grafted amino acid magnetic composite microsphere, characterized by being provided with a core-shell structure which takes a chitosan-amino acid complex as a shell, and takes a magnetic material as a core, wherein the complex is obtained by a grafting method of chitosan and amino acid; the amino acid is one of glutamine, glutamic acid and ornithine; in the complex, the amino acid accounts for 5-80 wt%; and the magnetic material is Fe or Fe30a, and accounts for 10-20% of the total weight of the chitosan and amino acid.

2. The chitosan-grafted amino acid magnetic composite microsphere according to claim 1, wherein the magnetic composite microsphere is prepared by a reverse phase suspension crosslinking method, specifically the chitosan/ the amino acid and the magnetic material are mixed and dispersed in an aqueous solution, and then is crosslinked by glutaraldehyde by taking cyclohexane as an oil phase

3. A preparation method for the chitosan-grafted amino acid magnetic composite microsphere, characterized by specifically comprising the following steps:

firstly dissolving chitosan and amino acid to prepare the aqueous solution with 2-10wt% of chitosan and amino acid; and then ultrasonically dispersing a magnetic material into the solution, adding cyclohexane, uniformly mixing, and crosslinking by glutaraldehyde, thereby forming a polymer magnetic composite microsphere.

4. The preparation method for the chitosan-grafted amino acid magnetic composite microsphere according to claim 3, wherein adding amount of the cyclohexane and volume of a chitosan-amino acid mixed aqueous solution are in proportion of 1-10.

5. The preparation method for the chitosan-grafted amino acid magnetic composite microsphere according to claim 3, wherein usage amount of glutaraldehyde accounts for 0.1-10% of that of the chitosan.

6. The preparation method for the chitosan-grafted amino acid magnetic composite microsphere according to claim 3, wherein in a cross-linking process, a pH value of a reaction solution is controlled to be 7-10, a cross-linking temperature is controlled to be 35-65 © and cross-linking time is controlled to be 0.5-3 hours.

7. Application of the chitosan-grafted amino acid magnetic composite microsphere in treating dye wastewater as a water treatment agent.

8. A chitosan-grafted amino acid magnetic composite microsphere is used for adsorbing heavy metal ions in water.

9. The chitosan-grafted amino acid magnetic composite microsphere according to claim 8 is used for adsorbing Cu?*.

10. The chitosan-grafted amino acid magnetic composite microsphere according to claim 1, wherein the complex microsphere is separated and enriched to recycle after being treated by the magnetic separation technotogy.