Patent ID: 12221528

DESCRIPTION OF EMBODIMENTS

Example 1

Example 1 of the present invention provided a nanocomposite material for toe cap production, which included the following raw materials in parts by weight:

20 parts of graphene, 10 parts of carbon nanotubes, 50 parts of a fiber composition, 5 parts of a silane coupling agent, 2 parts of acetic acid, 40 parts of acrylate rubber, 1 part of a dispersant, 100 parts of polyethylene resin, 10 parts of nano silicon carbide, 5 parts of calcium stearate, 5 parts of zinc stearate, 10 parts of talcum powder, 10 parts of modified boron nitride and 60 parts of a curing agent.

The preparation method of the nanocomposite material included the following steps:(1) preparing materials;(2) preparing graphene into graphene oxide by a Hummers method;(3) immersing graphene oxide, carbon nanotubes and nano silicon carbide in the silane coupling agent, and reacting at 80° C. for 1 hour;(4) putting the mixture obtained in the step (3) and the ground talcum powder into a high-speed stirrer to be stirred for 10 min, and adding the acetic acid into the talcum powder under stirring;(5) continuously adding the dispersant, the calcium stearate, the zinc stearate, the modified boron nitride and the curing agent for full and uniform mixing;(6) adding the acrylate rubber and the polyethylene resin into an internal mixer for internal mixing, and then putting an internally mixed rubber compound and 50% of the mixture prepared in step (4) into an open mill for mixing at 100° C. for 6 min;(7) coating the remaining 50% of the mixture prepared in the step (4) on a surface of a fiber composition with a reticular structure and curing at a temperature of 20° C. for 2 h; and

(8) putting the mixed fiber material prepared in the step (7) into a mold, and injecting the mixed rubber compound mixed in the step (6) to form a toe cap-shaped nanocomposite material.

The fiber composition was configured to have a reticular structure formed by interweaving a plurality of composite fibers, and each composite fiber was twisted together by glass fiber, carbon fiber and asbestos fiber. The glass fiber was alkali-free glass fiber; the diameter of glass fiber was 10 microns, the diameter of carbon fiber was 10 microns and the diameter of asbestos fiber was 50 microns.

The preparation method of the modified boron nitride was as follows:

putting hexagonal boron nitride and 5-aminovaleric acid into ball milling equipment, adding ethanol, implementing ball milling, followed by filtering and drying, subsequently adding the mixture into a concentrated sulfuric acid solution, and then adding aminophenyl diazonium salt for a coupling reaction to obtain the modified boron nitride.

The silane coupling agent was a composition of vinyl trimethoxysilane, γ-glycidyl ether oxypropyl trimethoxysilane and γ-aminopropyl triethoxysilane, and the mass ratio of the three was 1:2:1.

The dispersant was vinyl bisstearamide. The curing agent waster t-butyl peroxybenzoate. The mesh number of talcum powder was 800 mesh.

Example 2

Example 2 of the present invention provided a nanocomposite material for toe cap production, which included the following raw materials in parts by weight:

30 parts of graphene, 15 parts of carbon nanotubes, 80 parts of fiber composition, 8 parts of a silane coupling agent, 3 parts of acetic acid, 60 parts of acrylate rubber, 3 parts of a dispersant, 120 parts of polyethylene resin, 15 parts of nano silicon carbide, 8 parts of calcium stearate, 8 parts of zinc stearate, 15 parts of talcum powder, 15 parts of modified boron nitride and 70 parts of a curing agent.

The preparation method of the nanocomposite material included the following steps:(1) preparing materials;(2) preparing graphene into graphene oxide by a Hummers method;(3) immersing graphene oxide, carbon nanotubes and nano silicon carbide in the silane coupling agent, and reacting at 80-90° C. for 1 hour;(4) putting the mixture obtained in the step (3) and the ground talcum powder into a high-speed stirrer to be stirred for 10 min, and adding the acetic acid into the talcum powder under stirring;(5) continuously adding the dispersant, the calcium stearate, the zinc stearate, the modified boron nitride and the curing agent for full and uniform mixing;(6) adding the crylate rubber and the polyethylene resin into an internal mixer for internal mixing, and then putting an internally mixed rubber compound and 50% of the mixture prepared in step (4) into an open mill for mixing at 100° C. for 7 min;(7) coating the remaining 50% of the mixture prepared in the step (4) on a surface of a fiber composition with a reticular structure and curing at a temperature of 30° C. for 3 h; and(8) putting the mixed fiber material prepared in the step (7) into a mold, and injecting the mixed rubber compound mixed in the step (6) to form a toe cap-shaped nanocomposite material.

The fiber composition was configured to have a reticular structure formed by interweaving a plurality of composite fibers, and each composite fiber was twisted together by glass fiber, carbon fiber and asbestos fiber. The glass fiber was alkali-free glass fiber; the diameter of glass fiber was 20 microns, the diameter of carbon fiber was 20 microns and the diameter of asbestos fiber was 60 microns.

The preparation method of the modified boron nitride was as follows:

putting hexagonal boron nitride and 5-aminovaleric acid into ball milling equipment, adding ethanol, implementing ball milling, followed by filtering and drying, subsequently adding the mixture into a concentrated sulfuric acid solution, and then adding aminophenyl diazonium salt for a coupling reaction to obtain the modified boron nitride.

The silane coupling agent was a composition of vinyl trimethoxysilane, γ-glycidyl ether oxypropyl trimethoxysilane and γ-aminopropyl triethoxysilane, and the mass ratio of the three was 1:3:2.

The dispersant was vinyl bisstearamide. The curing agent was tert-butyl peroxybenzoate. The mesh number of talcum powder was 1000 mesh.

Example 3

Example 3 of the present invention provided a nanocomposite material for toe cap production, which included the following raw materials in parts by weight:

40 parts of graphene, 20 parts of carbon nanotubes, 100 parts of fiber composition, 10 parts of a silane coupling agent, 5 parts of acetic acid, 80 parts of acrylate rubber, 5 parts of a dispersant, 150 parts of polyethylene resin, 20 parts of nano silicon carbide, 10 parts of calcium stearate, 10 parts of zinc stearate, 20 parts of talcum powder, 20 parts of modified boron nitride and 80 parts of a curing agent.

The preparation method of the nanocomposite material included the following steps:(1) preparing materials;(2) preparing graphene into graphene oxide by a Hummers method;(3) immersing graphene oxide, carbon nanotubes and nano silicon carbide in the silane coupling agent, and reacting at 90° C. for 2 hour;(4) putting the mixture obtained in the step (3) and the ground talcum powder into a high-speed stirrer to be stirred for 40 min, and adding the acetic acid into the talcum powder under stirring;(5) continuously adding the dispersant, the calcium stearate, the zinc stearate, the modified boron nitride and the curing agent for full and uniform mixing;(6) adding the crylate rubber and the polyethylene resin into an internal mixer for internal mixing, and then putting an internally mixed rubber compound and 50% of the mixture prepared in step (4) into an open mill for mixing at 110° C. for 8 min;(7) coating the remaining 50% of the mixture prepared in the step (4) on a surface of a fiber composition with a reticular structure and curing at a temperature of 40° C. for 4 h; and(8) putting the mixed fiber material prepared in the step (7) into a mold, and injecting the mixed rubber compound mixed in the step (6) to form a toe cap-shaped nanocomposite material.

The fiber composition was configured to have a reticular structure formed by interweaving a plurality of composite fibers, and each composite fiber was twisted together by glass fiber, carbon fiber and asbestos fiber. The glass fiber was alkali-free glass fiber; the diameter of glass fiber was 30 microns, the diameter of carbon fiber was 30 microns and the diameter of asbestos fiber was 80 microns.

The preparation method of the modified boron nitride was as follows:

putting hexagonal boron nitride and 5-aminovaleric acid into ball milling equipment, adding ethanol, implementing ball milling, followed by filtering and drying, subsequently adding the mixture into a concentrated sulfuric acid solution, and then adding aminophenyl diazonium salt for a coupling reaction to obtain the modified boron nitride.

The silane coupling agent was a composition of vinyl trimethoxysilane, γ-glycidyl ether oxypropyl trimethoxysilane and γ-aminopropyl triethoxysilane, and the mass ratio of the three was 1:4:3.

The dispersant was vinyl bisstearamide. The curing agent was tert-butyl peroxybenzoate. The mesh number of talcum powder was 1250 mesh.

Example 4

Example 4 of the present invention provided a nanocomposite material for toe cap production, which included the following raw materials in parts by weight:

35 parts of graphene, 18 parts of carbon nanotubes, 90 parts of fiber composition, 10 parts of a silane coupling agent, 2 parts of acetic acid, 60 parts of acrylate rubber, 5 parts of a dispersant, 150 parts of polyethylene resin, 20 parts of nano silicon carbide, 5 parts of calcium stearate, 5 parts of zinc stearate, 20 parts of talcum powder, 10 parts of modified boron nitride and 65 parts of a curing agent.

The preparation method of the nanocomposite material included the following steps:(1) preparing materials;(2) preparing graphene into graphene oxide by a Hummers method;(3) immersing graphene oxide, carbon nanotubes and nano silicon carbide in the silane coupling agent, and reacting at 80° C. for 1 hour;(4) putting the mixture obtained in the step (3) and the ground talcum powder into a high-speed stirrer to be stirred for 35 min, and adding the acetic acid into the talcum powder under stirring;(5) continuously adding the dispersant, the calcium stearate, the zinc stearate, the modified boron nitride and the curing agent for full and uniform mixing;(6) adding the crylate rubber and the polyethylene resin into an internal mixer for internal mixing, and then putting an internally mixed rubber compound and 50% of the mixture prepared in step (4) into an open mill for mixing at 110° C. for 6 min;(7) coating the remaining 50% of the mixture prepared in the step (4) on a surface of a fiber composition with a reticular structure and curing at a temperature of 40° C. for 3 h; and(8) putting the mixed fiber material prepared in the step (7) into a mold, and injecting the mixed rubber compound mixed in the step (6) to form a toe cap-shaped nanocomposite material.

The fiber composition was configured to have a reticular structure formed by interweaving a plurality of composite fibers, and each composite fiber was twisted together by glass fiber, carbon fiber and asbestos fiber. The glass fiber was alkali-free glass fiber; the diameter of glass fiber was 15 microns, the diameter of carbon fiber was 20 microns and the diameter of asbestos fiber was 60 microns.

The preparation method of the modified boron nitride was as follows:

putting hexagonal boron nitride and 5-aminovaleric acid into ball milling equipment, adding ethanol, implementing ball milling, followed by filtering and drying, subsequently adding the mixture into a concentrated sulfuric acid solution, and then adding aminophenyl diazonium salt for a coupling reaction to obtain the modified boron nitride.

The silane coupling agent was a composition of vinyl trimethoxysilane, γ-glycidyl ether oxypropyl trimethoxysilane and γ-aminopropyl triethoxysilane, and the mass ratio of the three was 1:3:3.

The dispersant was vinyl bisstearamide. The curing agent was tert-butyl peroxybenzoate. The mesh number of talcum powder was 900 mesh.

The materials of Examples 1-4 per cubic decimeter were tested, and the test data are shown in Table 1 below.

ExampleExampleExampleExample1234Tensile strength (Mpa)189210250193Tensile growth rate (%)2.862.942.992.90Hardness161168175163Impact strength (Kj/m2)274280289276Water resistance-mass loss0.190.140.10.16(%)Binding force-mass loss0.080.050.020.06(%)Bending strength (Mpa)190215256197Abrasion resistanceoneoneoneone(grade)

As can be seen from Table 1, the nanocomposite material has high toughness and strength, good water resistance, wear resistance and aging resistance, good bonding effect between all materials and fiber composition, and thus has good mechanical properties.

The above examples are preferred embodiments of the present invention, but the embodiments of the present invention are not limited by the above embodiments, and any other changes, modifications, substitutions, combinations and simplifications made without departing from the spirit and principle of the present invention shall be equivalent substitutions, which shall be included in the protection scope of the present invention.