CN113522254A

CN113522254A - Preparation method and application of nylon 65 material with porous structure

Info

Publication number: CN113522254A
Application number: CN202110842975.9A
Authority: CN
Inventors: 王训遒; 高智城; 张雷
Original assignee: Zhengzhou University
Current assignee: Zhengzhou University
Priority date: 2021-07-26
Filing date: 2021-07-26
Publication date: 2021-10-22
Anticipated expiration: 2041-07-26
Also published as: CN113522254B

Abstract

The invention discloses a preparation method and application of a nylon 65 material with a porous structure, wherein after a nylon 65 salt is synthesized by a patent CN108285532B, a nylon 65 raw material is prepared by melt polymerization of a patent CN112920401A, anhydrous formic acid is mixed with the nylon 65 material for dissolution, the nylon 65 formic acid solution which is fully dissolved is placed in a container with a proper size, and a sodium carbonate solution is added for liquid foaming to prepare the nylon 65 material with the porous structure and excellent adsorption performance. The nylon 65 material with the porous structure prepared by the process has strong adsorption property by virtue of the special structure, and has the characteristics of high temperature resistance, strong acid resistance, high efficiency in removing waste water dye, reusability and the like. The nylon 65 adsorbing material can be used for adsorbing dye wastewater, and has the advantages of environmental protection, economy and high efficiency.

Description

Preparation method and application of nylon 65 material with porous structure

Technical Field

The invention belongs to the field of chemical materials, and particularly relates to a preparation method and application of a nylon 65 material with a porous structure and excellent performance for treating dye wastewater.

Background

With the progress of society, people's lives are more colorful, the dye industry is also developed, China has become the first major country of printing and dyeing industry, the dye yield is 20-25 ten thousand t each year, but simultaneously along with the generation of dye wastewater, the dye wastewater has various hazards of complex components, deep color, high toxicity, strong acidity (alkalinity), large quantity of negative ions and the like. The main pollutants in the waste water dye include high suspended matters, chlorides, sulfates and other soluble substances. Although there is a large amount of water in the wastewater, residual dyes in the wastewater are accumulated, and thus, the concentration and color of the dyes are gradually increased, and since the dyes absorb sunlight and the color has a great influence on the absorption of the sunlight, plants beside the river are killed and the ecosystem is seriously affected.

In view of this, with the development and update of the dye industry, the pollution components in the waste water dye are more and more, the purification technology and method for the waste water dye also need to be continuously updated and developed, and it is also necessary to adopt a proper treatment method with lower cost efficiency for different kinds of dye waste water.

The various colors imparted by the dyes are affected by chromophores and auxochromes, and can be classified into acid dyes, basic dyes, disperse dyes, etc. according to the chromophore structure of the dyes, and can also be classified into cationic dyes, anionic dyes, and nonionic dyes by the difference in structure. At present, the common dye wastewater treatment methods in China are physical methods, chemical methods and biological methods. Although the biological method is economical, the treatment time is long, the microbial culture is slow, and the process flow is complex. The chemical method has small equipment and simple equipment management, but has complicated electrode materials, high cost and high operating cost. The adsorption method in the physical method has obvious decolorization, simple operation and high purification speed, and is a more suitable treatment method.

The mode of treating the waste water dye by the adsorption method is to carry out adsorption purification by the complexation, electrostatic interaction, hydrophobic interaction, hydrogen bond interaction and the like of the material and the dye. Eloisa Navarro et al found that nylon 65 has hydrogen bonds in two directions, and Naoya Ogata et al studied the adhesion of affinity groups (hydrogen bonds) of various polyamides to human platelets medically using the microsphere method, and the study showed that nylon 65 has better adhesion than other types of polyamides, indicating that nylon 65 has a special structure. In view of this, the nylon 65 material with the porous structure prepared by the invention has high efficiency and pertinence, the material has the advantages of special molecular structure, porosity and the like, and can adsorb a large amount of dye, the dye removal rate can reach more than 90%, and at present, research on adsorption of dye wastewater by the nylon 65 material with the porous structure is not reported.

Disclosure of Invention

In order to overcome the problems, the invention provides a preparation method and application of a nylon 65 material which has a porous structure and can absorb dye wastewater, wherein the nylon 65 material has a high cost performance, can obtain a material which has a mesoporous structure, is high temperature resistant, has low density and excellent absorption performance, and has a removal rate of dye wastewater of more than 90%.

In order to solve the technical problems, the invention adopts the following technical scheme:

a preparation method of a nylon 65 material with a porous structure comprises the following steps:

(1) adding the nylon 65 raw material into anhydrous formic acid, and stirring to fully dissolve;

(2) and (2) adding a sodium carbonate solution into the step (1) and carrying out liquid foaming to obtain the nylon 65 material with high adsorption performance and a porous structure.

Further, the nylon 65 raw material in the step (1) is firstly synthesized into nylon 65 salt by the patent CN108285532B, and then is prepared into the nylon 65 raw material by the melt polymerization of the published patent CN 112920401A.

Further, the mass ratio of the nylon 65 raw material to the anhydrous formic acid in the step (2) is 1:2-1:100, preferably 1:3-1: 10. If the raw material content in the solution is too low, foaming may be unsuccessful; the raw material content in the solution is too high, the solution viscosity is large, the fluidity is too poor, and the foaming is not facilitated.

Further, the mass fraction of the sodium carbonate solution in the step (3) is 1% -40%, preferably 1% -10%, and the addition amount of the sodium carbonate solution is based on foaming.

The specific surface area of the nylon 65 material with the porous structure prepared by the method is 2-40m²The mesoporous carbon material has a mesoporous structure, the aperture of mesopores is 1nm-7nm, the removal rate of anionic wastewater dye reaches more than 90%, and the mesoporous carbon material is high-temperature resistant and strong-acid resistant.

The nylon 65 material with the porous structure prepared by the method is used for adsorbing dye wastewater, namely the nylon 65 material adsorbs simulated dye wastewater under the conditions of certain temperature, pH and mechanical oscillation.

Further, the dye is one or more of anionic dye, cationic dye or nonionic dye. The dye wastewater is preferably anionic dye wastewater. According to the molecular structure of nylon 65, the adsorption of the anionic dye wastewater is larger than that of the cationic dye wastewater and the nonionic dye wastewater.

Further, the temperature for adsorbing the dye wastewater is 5-60 ℃, and preferably 20-50 ℃; the pH of the dye-adsorbing wastewater is 2-13, preferably 2-9.

Further, the speed of mechanical oscillation at the time of adsorbing the dye wastewater is 10 to 500rmp, preferably 50 to 200 rmp.

Further, the nylon 65 material with the porous structure can be made to have reusability by formulating a desorbent, wherein the desorbent is one or more of sodium hydroxide solution, potassium hydroxide solution, ethanol solution, sodium carbonate solution and sodium bicarbonate solution.

The invention has the beneficial effects that:

(1) the invention provides a preparation method and application conditions of a nylon 65 material with a porous structure and capable of efficiently adsorbing a large amount of dye wastewater.

(2) The adsorbent is economic and environment-friendly, has simple device and convenient operation, can be produced in large quantities, and can be repeatedly used and keep the adsorption performance unchanged under the condition of specific desorbent, thereby greatly improving the economic benefit.

(3) The adsorbent has a porous structure, can greatly improve the effect of adsorbing dye wastewater, has a removal rate of anionic wastewater dye of more than 90 percent, and is high-temperature resistant and strong-acid resistant.

Drawings

FIG. 1 is a thermogravimetric plot of a nylon 65 material having a cellular structure;

FIG. 2 is a Scanning Electron Microscope (SEM) image of a nylon 65 material having a cellular structure;

fig. 3 is a diagram showing the distribution of pore diameters of a nylon 65 material having a porous structure.

Detailed Description

In order to make the present invention more clear, the present invention is explained in more detail below with reference to some examples. All embodiments of the invention obtained by the person skilled in the art without going into any more creative work are within the scope of protection of the present invention.

In a specific example, after a series of dyes with different concentration gradients are prepared, the absorbance versus concentration is determined by a UV-Vis spectrophotometer. The relationship between absorbance and concentration can be calculated according to the following standard curve equations (1) (2) (3) (4).

(1) Standard curve equation for methyl orange:

(2) standard curve equation for methyl red:

(3) standard curve equation for acid fuchsin:

(4) standard curve equation for orange G:

wherein x represents the dye concentration (mg/L) and y represents the absorbance (Abs).

In a specific example, the dye removal rate is calculated using equation (5). The pH was adjusted using 0.1mol/L NaOH and 0.1mol/L HCl solution.

Wherein C is_iAnd C_fThe initial concentration (mg/L) and the final concentration (mg/L) of the dye wastewater are shown.

Example 1

The preparation method of the nylon 65 material with the porous structure and capable of adsorbing the dye wastewater comprises the following steps:

adding 2g of nylon 65 sample prepared by a melt polycondensation method into 8g of formic acid solution to prepare 20 wt% of nylon 65 formic acid solution, shaking or stirring at room temperature to fully dissolve the nylon 65 sample, transferring the sample solution into a prepared clean container with the size of 30ml, and continuously injecting Na into the container by using a pinhole syringe₂CO₃Aqueous solution (5 wt% Na)₂CO₃Aqueous solution) was reacted with formic acid to foam to prepare a nylon 65 material having a porous structure.

The prepared porous PA65 is ground and screened and collected by an 80-mesh sieve for subsequent experiments.

The application of the nylon 65 material with the porous structure capable of adsorbing the dye wastewater in the embodiment is as follows:

the prepared nylon 65 adsorbent was added to a 100mg/L methyl orange solution using a 50ml glass container, and further, the pH of the solution in the system was adjusted to 5, and the mixture was shaken at 30 ℃ for 1 hour at 100rmp using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 462nm at the maximum absorption wavelength of the dye using a UV-Vis spectrophotometer.

The nylon 65 adsorbent with the porous structure is repeatedly washed for 3-5 times by using a sodium hydroxide/ethanol solution (more than or equal to 2mol/L), then an adsorption experiment is repeatedly carried out for 10 times under the same condition, and the repeated effect of the nylon 65 adsorbent with the porous structure is measured.

Example 2

adding 4g of nylon 65 sample prepared by a melt polycondensation method into 8g of formic acid solution to prepare 33 wt% of nylon 65 formic acid solution, shaking or stirring at room temperature to fully dissolve the nylon 65 sample, transferring the sample solution into a prepared clean container with the size of 30ml, and continuously injecting Na into the container by using a pinhole syringe₂CO₃Aqueous solution (5 wt% Na)₂CO₃Aqueous solution) was reacted with formic acid to foam to prepare a nylon 65 material having a porous structure.

the prepared nylon 65 adsorbent was added to a 50mg/L methyl red solution using a 50ml glass container, and further, the pH of the solution in the system was adjusted to 4, and the mixture was shaken at 35 ℃ for 1 hour at 150rmp using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 410nm at the maximum absorption wavelength of the dye using a UV-Vis spectrophotometer.

The nylon 65 adsorbent with the porous structure is repeatedly washed for 3-5 times by using a sodium hydroxide solution (more than or equal to 2mol/L), and then an adsorption experiment is carried out for 10 times under the same condition, so that the repeated effect of the nylon 65 adsorbent with the porous structure is measured.

Example 3

to a solution of 8g of formic acidAdding 2g of nylon 65 sample prepared by a melt polycondensation method to prepare 20 wt% nylon 65 formic acid solution, shaking or stirring at room temperature to fully dissolve the nylon 65 sample, transferring the sample solution into a clean 30ml container prepared in advance, and continuously injecting Na by using a pinhole syringe₂CO₃Aqueous solution (3 wt% Na)₂CO₃Aqueous solution) was reacted with formic acid to foam to prepare a nylon 65 material having a porous structure.

the prepared nylon 65 adsorbent was added to a 100mg/L orange G solution using a 50ml glass container, further, the pH of the solution in the system was adjusted to 8, and the mixture was shaken at 30 ℃ for 1 hour at 150rmp using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 476nm at the dye maximum absorption wavelength using a UV-Vis spectrophotometer.

The nylon 65 adsorbent with the porous structure is repeatedly washed for 3-5 times by using potassium hydroxide solution (more than or equal to 2mol/L), and then 10 repeated adsorption experiments are carried out under the same conditions, and the repeated effect of the nylon 65 adsorbent with the porous structure is measured.

Example 4

adding 1g of nylon 65 sample prepared by a melt polycondensation method into 8g of formic acid solution to prepare 11 wt% of nylon 65 formic acid solution, shaking or stirring at room temperature to fully dissolve the nylon 65 sample, transferring the sample solution into a prepared clean container with the size of 30ml, and continuously injecting Na into the container by using a pinhole syringe₂CO₃Aqueous solution (5 wt% Na)₂CO₃Aqueous solution) was reacted with formic acid to foam to prepare a nylon 65 material having a porous structure.

the prepared nylon 65 adsorbent was added to a 100mg/L acid fuchsin solution using a 50ml glass container, further, the pH of the solution in the system was adjusted to 6, and the mixture was shaken at 200rmp for 1 hour at 40 ℃ using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 546nm at the dye maximum absorption wavelength using a UV-Vis spectrophotometer.

The nylon 65 adsorbent with the porous structure is repeatedly washed for 3-5 times by using a potassium hydroxide/ethanol solution (more than or equal to 2mol/L), then an adsorption experiment is repeatedly carried out for 10 times under the same condition, and the repeated effect of the nylon 65 adsorbent with the porous structure is measured.

Example 5

the prepared nylon 65 adsorbent was added to a 300mg/L methyl orange solution using a 50ml glass container, and further, the pH of the solution in the system was adjusted to 5, and the mixture was shaken at 50 ℃ for 1 hour at 100rmp using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 462nm at the maximum absorption wavelength of the dye using a UV-Vis spectrophotometer.

Example 6

the prepared nylon 65 adsorbent was added to a 100mg/L methyl red solution using a 50ml glass container, and further, the pH of the solution in the system was adjusted to 4, and the mixture was shaken at 35 ℃ for 1 hour at 200rmp using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 410nm at the maximum absorption wavelength of the dye using a UV-Vis spectrophotometer.

The nylon 65 adsorbent with the porous structure is repeatedly washed for 3-5 times by using a sodium hydroxide/potassium hydroxide solution (more than or equal to 2mol/L), then an adsorption experiment is repeatedly carried out for 10 times under the same condition, and the repeated effect of the nylon 65 adsorbent with the porous structure is measured.

Example 7

adding 2g of nylon 65 sample prepared by a melt polycondensation method into 8g of formic acid solution to prepare 20 wt% of nylon 65 formic acid solution, shaking or stirring at room temperature to fully dissolve the nylon 65 sample, transferring the sample solution into a prepared clean container with the size of 30ml, and continuously injecting Na into the container by using a pinhole syringe₂CO₃Aqueous solution (3 wt% Na)₂CO₃Aqueous solution) was reacted with formic acid to foam to prepare a nylon 65 material having a porous structure.

the prepared nylon 65 adsorbent was added to a 100mg/L orange G solution using a 50ml glass container, and further, the pH of the solution in the system was adjusted to 2, and the mixture was shaken at 30 ℃ for 1 hour at 150rmp using a mechanical shaker. After the reaction was completed, the adsorbent was filtered, and the filtrate absorbance was measured at 476nm at the dye maximum absorption wavelength using a UV-Vis spectrophotometer.

Comparison of Properties in the examples of Table 1

In conclusion, the nylon 65 adsorbing material with the porous structure is simple to prepare, easy to perform in adsorption conditions, economical and environment-friendly, and can effectively remove anionic dyes under acidic or neutral conditions.

Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The embodiments described above are some examples of the present invention, and are for illustrative purposes and not intended to limit the present invention. To those skilled in the art, the present invention is susceptible to a certain degree of modification and substitution without departing from the spirit and scope of the technical solution of the embodiments of the present invention. The invention is therefore limited only by the claims and not by the embodiments described above.

Claims

1. A preparation method of a nylon 65 material with a porous structure is characterized by comprising the following steps:

2. The method for preparing the nylon 65 material with the porous structure as claimed in claim 1, wherein the method comprises the following steps: the nylon 65 raw material in the step (1) is prepared by firstly synthesizing nylon 65 salt with patent CN108285532B, and then carrying out melt polymerization with published patent CN 112920401A.

3. The method for preparing the nylon 65 material with the porous structure as claimed in claim 1, wherein the method comprises the following steps: the mass ratio of the nylon 65 raw material to the anhydrous formic acid in the step (2) is 1:2-1: 100.

4. The method for preparing the nylon 65 material with the porous structure as claimed in claim 1, wherein the method comprises the following steps: the mass fraction of the sodium carbonate solution in the step (3) is 1-40%, and the addition amount of the sodium carbonate solution is based on reaching foaming.

5. The nylon 65 material with a cellular structure prepared by the method of any one of claims 1-4, wherein: the specific surface area of the nylon 65 material is 2-40m²The mesoporous material has a mesoporous structure, and the aperture of mesopores is 1nm-7 nm.

6. The nylon 65 material with a porous structure prepared by the method of any one of claims 1 to 4 is used for adsorbing dye wastewater, and is characterized in that: the nylon 65 material adsorbs the simulated dye wastewater under certain temperature, pH and mechanical oscillation conditions.

7. Use according to claim 6, characterized in that: the dye is one or more of anionic dye, cationic dye or nonionic dye.

8. Use according to claim 6, characterized in that: the temperature of the dye-adsorbing wastewater is 5-60 ℃, and the pH value of the dye-adsorbing wastewater is 2-13.

9. Use according to claim 6, characterized in that: the speed of mechanical oscillation when adsorbing the dye wastewater is 10-500 rmp.

10. Use according to claim 6, characterized in that: the nylon 65 material with a porous structure can be made to have reusability by formulating a desorbent, wherein the desorbent is one or more of sodium hydroxide solution, potassium hydroxide solution, ethanol solution, sodium carbonate solution and sodium bicarbonate solution.