Preparation method for flexible compound corrosion-resistant grounding material

A corrosion-resistant and flexible technology, which is applied in the field of preparation of flexible composite corrosion-resistant grounding materials, can solve problems such as poor corrosion resistance and flexibility, difficult transportation and construction, and large soil gaps, so that it is not easy to be stolen and solves corrosion resistance. And the problem of poor flexibility, the effect of simple preparation steps

Inactive Publication Date: 2016-11-30
LULIANG UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0003] The technical problem to be solved by the present invention: Aiming at the disadvantages of current grounding materials such as poor corrosion resistance and flexibility, difficult transportation and construction, large gap with the soil, easy to be stolen and high cost, it provides a method for mixing iron powder, silicon powder, etc. reaction, and then hot-rolled into billets, wire drawing, annealing to obtain alloy fibers, mixed with polyvinyl chloride resin, octadecylamine, etc. Wrapped on the outside of the resin, and then rolled into a billet, after cooling, it is soaked with alkali leaching and deionized water, mixed with copper sulfate and absolute ethanol, and dried to obtain a flexible composite corrosion-resistant grounding material.
The preparation steps of the present invention are simple, and the flexible composite corrosion-resistant grounding material is obtained by fully utilizing the resin-coated alloy fiber, and then coated with graphite, which is highly targeted and effectively solves the problems of poor corrosion resistance and flexibility; the obtained product is easy to transport and construct. High degree of adhesion to the soil, low cost, not easy to be stolen

Method used

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Examples

Experimental program
Comparison scheme
Effect test

example 1

[0016] Firstly, according to parts by weight: take 3 parts of iron powder, 6 parts of silicon powder, 6 parts of manganese powder, 8 parts of copper powder, 30 parts of aluminum powder, and 15 parts of zinc powder, respectively add them into the arc melting furnace, Under 10MPa, react for 2 hours to obtain a mixed molten liquid; then hot-roll the above mixed molten liquid to obtain a billet with a diameter of 3mm, and draw the billet to control the number of wire drawing for 3 times, and use castor oil as a lubricant during wire drawing to control the wire drawing The compression rate is 50%. After the wire drawing is completed, place the wire-drawn alloy in a well-type furnace, control the annealing temperature to 700°C, and carry out annealing treatment in a vacuum state. Then, the wire-drawn alloy obtained after annealing is deionized Wash 3 times, dry naturally to obtain alloy fibers; successively weigh 10g of polyvinyl chloride resin and 2g of acrylic acid into the reactio...

example 2

[0018]Firstly, by weight parts: take 4 parts of iron powder, 7 parts of silicon powder, 9 parts of manganese powder, 12 parts of copper powder, 35 parts of aluminum powder, and 18 parts of zinc powder, and add them to the arc melting furnace respectively. Under 15MPa, react for 3 hours to obtain a mixed molten liquid; then hot-roll the above mixed molten liquid to obtain a billet with a diameter of 4 mm, and draw the billet to control the number of wire drawing for 4 times. The compression ratio is 55%. After the wire drawing is completed, place the wire-drawn alloy in a well-type furnace, control the annealing temperature to 750°C, and perform annealing treatment in a vacuum state, and then wash the wire-drawn alloy obtained after annealing with deionized water Wash 4 times, dry naturally to obtain alloy fibers; successively weigh 15g of polyvinyl chloride resin and 3g of acrylic acid into the reaction kettle, control the temperature at 340°C, stir and react for 2h, then add 0...

example 3

[0020] First of all, according to parts by weight: take 5 parts of iron powder, 8 parts of silicon powder, 12 parts of manganese powder, 15 parts of copper powder, 40 parts of aluminum powder, and 20 parts of zinc powder, and add them to the arc melting furnace respectively, Under 20MPa, react for 3 hours to obtain a mixed molten liquid; then hot-roll the above mixed molten liquid to obtain a billet with a diameter of 5 mm, and draw the billet to control the number of wire drawing for 5 times, and use castor oil as a lubricant during wire drawing to control the wire drawing The compression rate is 60%. After the wire drawing is completed, place the wire-drawn alloy in a well-type furnace, control the annealing temperature to 800°C, and perform annealing treatment in a vacuum state, and then wash the wire-drawn alloy obtained after annealing with deionized water Wash 5 times, dry naturally to obtain alloy fibers; successively weigh 20g of polyvinyl chloride resin and 3g of acryl...

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Abstract

The invention discloses a preparation method for a flexible compound corrosion-resistant grounding material, and belongs to the technical field of grounding material preparation. According to the method, mixed reaction is carried out on iron powder, silicon powder and so on; the materials are prepared into a blank through hot rolling; wire drawing and annealing are carried out to obtain alloy fibers; mixed reaction is carried out on the alloy fibers, polyvinyl chloride resin, octadecylamine and so on; the alloy fibers are wrapped by resin; expanded graphite and coupling reagent are added to the alloy fibers wrapped by the resin, and stirring reaction is carried out; the resin is wrapped by the graphite; the resin wrapped by the graphite is rolled into the blank; the blank is cooled, is leached by alkaline and is washed by deionized water; mixed soaking is carried out on the purified blank, copper sulfate and absolute ethyl alcohol; and the finally processed blank is dried in the air, thereby preparing the flexible compound corrosion-resistant grounding material. According to the method, the preparation steps are simple; the alloy fibers are wrapped through full utilization of the resin; the flexible compound corrosion-resistant grounding material is prepared by wrapping the resin through the graphite; the pertinence is high; the corrosion-resistance and low flexibility problems are solved effectively; there is no corrosion phenomenon after the material is employed for 10-12 years; the obtained product is easy to transport and construct; the clearance between the product and soil is little; the cost is low; and the material is not liable to steal.

Description

technical field [0001] The invention relates to a method for preparing a flexible composite corrosion-resistant grounding material, which belongs to the technical field of grounding material preparation. Background technique [0002] Grounding is an important means to ensure the safety of electric power, communication, microelectronic equipment and other equipment, buildings and personal safety. With the advancement of electricity, microelectronics and cutting-edge science, the requirements for grounding systems are getting higher and higher. In recent years, equipment damage accidents caused by poor grounding systems have occurred frequently, especially in thunderstorm seasons, when the grounding device is corroded, which increases the grounding resistance and reduces the thermal stability of the grounding system, resulting in frequent equipment damage due to lightning strikes. occur. With the continuous increase of the capacity of the power system, the requirements f...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): H01B13/00H01R43/16
CPCH01B13/00H01R43/16
Inventor 雷春生盛海丰孟浩影
Owner LULIANG UNIV
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