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Method for preparing graphene high-oil absorption resin

An oleoresin, graphene technology, applied in separation methods, chemical instruments and methods, adsorption water/sewage treatment, etc., can solve the problems of no antibacterial properties, slow oil absorption rate, low oil absorption rate, etc., to achieve excellent hydrophobicity and affinity. Oily performance, high oil absorption rate, and the effect of improving lipophilicity

Active Publication Date: 2018-01-23
浙江卫星新材料科技有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0009] The purpose of the present invention is to provide a preparation method of graphene high oil-absorbing resin to solve the problem existing in the existing high oil-absorbing resin and to solve the problems existing in the existing high oil-absorbing resin and kitchen cleaning products containing the same. The shortcomings of poor lipophilicity, low oil absorption ratio, slow oil absorption rate and no antibacterial properties

Method used

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  • Method for preparing graphene high-oil absorption resin
  • Method for preparing graphene high-oil absorption resin
  • Method for preparing graphene high-oil absorption resin

Examples

Experimental program
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Effect test

Embodiment 1

[0050] Modified porous graphene oxide 20g obtained by polydimethylsiloxane modification, tea polyphenols 80g, sodium lauryl sulfate 0.2g, and made by the following steps:

[0051] Step 1. Add sodium lauryl sulfate into deionized water and stir evenly, then add tea polyphenols, raise the temperature to 40° C., and continue stirring for 5 minutes to obtain a mixed solution.

[0052] Step 2, adding modified porous graphene oxide to the mixed solution of step 1, so that the modified porous graphene oxide concentration is 1mg / mL, ultrasonically dispersed for 4h, to obtain a suspension containing modified porous graphene oxide.

[0053] Step 3. Put the suspension in step 2 through vacuum drying at -40° C. to 60° C. for 12-60 hours to obtain a modified porous graphene antibacterial composition loaded with tea polyphenols.

Embodiment 2

[0055] Modified porous graphene oxide 80g obtained by polydimethylsiloxane modification, chitosan 20g, sodium dodecylbenzene sulfonate 8g, and made by the following steps:

[0056] Step 1. Add sodium lauryl sulfate into deionized water and stir evenly, then add chitosan, heat up to 70° C., and continue stirring for 25 minutes to obtain a mixed solution.

[0057] Step 2, adding modified porous graphene oxide to the mixed solution of step 1, so that the modified porous graphene oxide concentration is 10mg / mL, and ultrasonically dispersed for 20h to obtain a suspension containing modified porous graphene oxide.

[0058] Step 3, putting the suspension in step 2 through vacuum drying at -60° C. for 60 h to obtain a chitosan-loaded modified graphene antibacterial composition.

Embodiment 3

[0060] Modified porous graphene oxide 50g obtained by polydimethylsiloxane modification, tea polyphenols 25g, chitosan 25g, sodium lauryl sulfonate 2.5g, and made by the following steps:

[0061] Step 1. Add sodium dodecylsulfonate to deionized water evenly, then add tea polyphenols and chitosan, heat up to 50°C, and continue stirring for 15 minutes to obtain a mixed solution.

[0062] Step 2, adding modified porous graphene oxide to the mixed solution of step 1, so that the modified porous graphene oxide concentration is 5mg / mL, and ultrasonically dispersed for 16h to obtain a suspension containing modified porous graphene oxide.

[0063] Step 3. Put the suspension in step 2 through vacuum drying at -50° C. for 36 hours to obtain a modified graphene antibacterial composition loaded with a natural antibacterial agent.

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Abstract

The invention relates to a method for preparing a graphene high-oil absorption resin. The method comprises the following steps: 1, putting modified porous graphene or modified porous graphene antibacterial composition into deionized water, and performing ultrasonic dispersion for 1-24 hours so as to obtain a modified porous graphene suspension; 2, stirring deionized water and an emulsifier in a reaction container, sufficiently dissolving, and adding an acrylic monomer so as to obtain a stable emulsion; 3, putting the modified porous graphene suspension into the emulsion in the step 2, performing continuous stirring emulsification for 30-60 minutes, further adding a chemical cross-linking agent and a pore-forming agent, and continuously stirring for 10-30 minutes; 4, heating to 40-70 DEG C,performing a reaction for 2-20 hours with an initiator so as to obtain porous high-oil absorption resin gel; 5, pelletizing the porous high-oil absorption resin gel, and drying in an oven at 105-180DEG C till a constant weight, so as to obtain the graphene high-oil absorption resin.

Description

technical field [0001] The invention belongs to the research field of high oil-absorbing resins, in particular to a preparation method of graphene high oil-absorbing resins. Background technique [0002] Super Oil-Absorbable Resin (SOAR) is a new type of functional polymer material and a general term for a class of polymers with high oil absorption properties. [0003] High oil-absorbing resin is a new type of polymer material developed in recent years for waste oil treatment. It is a self-swelling functional polymer material with both adsorption and absorption functions. It has high oil absorption ratio and can absorb many types of oil. With high selectivity and good oil retention under pressure conditions, it can not only replace traditional oil-absorbing materials for waste oil treatment, but also be suitable for the treatment of oil spills at sea and recovery of oil slicks on water surfaces. [0004] In the process of oil exploration and transportation, oil leakage inci...

Claims

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Application Information

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IPC IPC(8): B01J20/26B01J20/30B01D17/022C02F1/28C08F220/18C08F222/14C08F2/44
Inventor 洪锡全裴小苏周丕严刘若铎
Owner 浙江卫星新材料科技有限公司
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