Preparation method of electromagnetic-driven hydrogel antifouling coating layer material

An antifouling coating and electromagnetic drive technology, applied in antifouling/underwater coatings, coatings, paints containing biocide, etc., can solve the complex process of magnetic hydrogel, large industrial application restrictions, and insufficient sample repetition rate To achieve good adhesion and desorption inhibition performance, low temperature and environment requirements, and the effect of inhibiting the adhesion of fouling organisms

Inactive Publication Date: 2019-01-15
725TH RES INST OF CHINA SHIPBUILDING INDAL CORP
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Problems solved by technology

[0004] At present, the preparation of hydrogel or magnetic hydrogel in other fields mainly adopts the method of repeated freezing and thawing. For example, the prior art discloses three kinds of hydrogels: the first is to pour a certain concentration of polyvinyl alcohol aqueous solution into the mold , freeze and form at ~10°C to ~40°C, then thaw at room temperature, and then put it back into the freezer. Repeat this cycle for 3 to 5 times, and you can get a transparent hydrogel with good elasticity, general mechanical strength, but this method The application in the paint industry is relatively limited; the second is to mix the activated agate particles with chitosan and acrylic acid, and add a crosslinking agent and an initiator to react under ultraviolet light to obtain a gel solution. Blend with ferroferric oxide magnetic particles, freeze and form at ~10°C to ~40°C after mixing, and cycle 3 to 5 times by thawing at room temperature and freezing in a freezer, which is not easy to cause agglomeration and precipitation, and the obtained magnetic water The mechanical properties of the gel are good, but the industrial application is relatively limited; the third is to use methacrylic acid and mercaptoacrylic acid under the action of the photoinitiator benzophenone to initiate polymerization with ultraviolet radiation to form a polymerized hydrogel, and then FeCl 2 and FeCl 3 Add ammonia water to the raw material to react to generate ferric hydroxide, then calcine and magnetize to obtain magnetized ferric iron tetroxide, then mix and stir the hydrogel with magnetized ferric ferric oxide and Bacillus subtilis to obtain magnetic hydrogel. Methods The process of preparing magnetic hydrogel is complicated, the sample repetition rate is not enough, and the magnetic properties are poor

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  • Preparation method of electromagnetic-driven hydrogel antifouling coating layer material
  • Preparation method of electromagnetic-driven hydrogel antifouling coating layer material
  • Preparation method of electromagnetic-driven hydrogel antifouling coating layer material

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preparation example Construction

[0031] A method for preparing an electromagnetically driven hydrogel antifouling coating material, the specific embodiment of which is: comprising the following preparation steps:

[0032] Step 1. Preparation of component A: According to the parts by weight, add 5-10 parts of polyvinyl alcohol resin, 50-90 parts of deionized water and 0.5-1 part of defoamer into the dispersion tank for high-speed dispersion for 8-12 minutes After the polyvinyl alcohol resin is completely dissolved in deionized water, add 15-50 parts of magnetic powder and 1-2 parts of thixotropic agent, and then add 30-40 parts of glass beads for sanding until the fineness of the above mixture is less than 80 μm. 100-mesh filter screen to filter out the material, spare;

[0033] Step 2. Preparation of component B: According to parts by weight, add 0.5-2 parts of binary aldehyde and 80-100 parts of deionized water into the dispersion tank for high-speed dispersion, and the concentration after dispersion is 0.5%...

Embodiment 1

[0046] Step 1. Preparation of component A: According to parts by weight, add 5 parts of polyvinyl alcohol resin with material type 1788, 50 parts of deionized water and 0.5 part of water-based silicone defoamer into the dispersion tank for high-speed dispersion for 8 minutes , the dispersion speed is 500rpm, after the polyvinyl alcohol resin is completely dissolved in deionized water, add 15 parts of ferric iron tetroxide with a fineness of 20 μm and 1 part of hydrophilic fumed silica, and then add glass with a diameter of 0.4mm Sand mill 30 parts of the beads until the fineness of the above mixture is less than 80 μm, filter the material with a 100-mesh filter screen, and set aside;

[0047] Step 2. Preparation of component B: According to parts by weight, add 0.5 parts of glutaraldehyde and 80 parts of deionized water into the dispersion tank and disperse at a high speed at a speed of 500 rpm. After the dispersion is uniform, the concentration of 0.5% is obtained. Binary ald...

Embodiment 2

[0051] Step 1. Preparation of component A: According to parts by weight, add 8 parts of polyvinyl alcohol resin, 70 parts of deionized water and 0.8 part of water-based polyether defoamer to the dispersion Disperse at high speed for 10 minutes in a cylinder, and the dispersion speed is 750rpm. After the polyvinyl alcohol resin is completely dissolved in deionized water, add 35 parts of magnetic powder mixed with nickel-zinc ferrite and zinc-chromium ferrite with a fineness of 35 μm. and 2 parts of hydrophilic fumed silica, and then add 35 parts of glass beads with a diameter of 0.7 mm for sand grinding until the fineness of the above mixture is less than 80 μm, filter the material with a 100-mesh filter, and set aside;

[0052] Step 2. Preparation of component B: According to parts by weight, add 1.4 parts of o-phthalaldehyde and 90 parts of deionized water into the dispersion tank and disperse at a high speed at a speed of 750 rpm. The concentration after the dispersion is uni...

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Abstract

Provided is a preparation method of an electromagnetic-driven polyvinyl alcohol magnetic hydrogel antifouling coating layer including three components: a component A, a component B and a component C.The component A is obtained by taking polyvinyl alcohol resin as a base material and deionized water as a dispersion medium, adding magnetic powder, a thixotropic agent and a defoamer, dispersing thematerials through a sanding process and mixing evenly, wherein the fineness is less than 80 [mu]m. The component B is prepared by dispersing dialdehyde in deionized water to obtain an aldehyde solution with a certain concentration. The component C is prepared by dispersing proton acid in deionized water to prepare an acid solution with a certain concentration. An externally applied alternating magnetic field can make a micro-morphology dynamic change generated on the surface of the magnetic hydrogel. By simulating the dynamic epidermal characteristics of marine organisms, the adhesion of fouling organisms can be inhibited and an anti-fouling role is played. Experiments of biological inhibition of absorption and desorption of indoor navicula tenera show that the magnetic hydrogel coating layer has good absorption inhibition and desorption performance on the fouling organisms under the alternating magnetic field.

Description

technical field [0001] The invention belongs to the technical field of coating material preparation, and in particular relates to a preparation method of an electromagnetically driven hydrogel antifouling coating material. Background technique [0002] In the process of human development and utilization of the ocean, marine biofouling will bring great harm to ships, such as increasing ship navigation resistance, increasing hull weight, increasing fuel consumption, accelerating hull corrosion, and increasing times of docking maintenance. The most economical, effective and common method to solve fouling organisms is to apply antifouling paint on the surface of marine facilities. At present, the most widely used antifouling coatings on the market are mainly tin-free self-polishing antifouling coatings, and their resin base materials are mainly divided into three categories: zinc acrylate resin, copper acrylate resin, and silanized acrylic resin. The main antifouling agent is c...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C09D129/04C09D5/16C09D7/63C09D7/65C09D7/20
CPCC08K2003/2275C08K2201/014C08L2205/025C08L2205/03C09D5/1662C09D5/1687C09D7/20C09D129/04C08L83/04C08K13/02C08K3/22C08K3/36C08K5/07C08K5/09C08L29/04C08L71/00C08K3/16C08K3/28C08K3/34
Inventor 邓冰锋谢志鹏吴新华
Owner 725TH RES INST OF CHINA SHIPBUILDING INDAL CORP
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