CN106009370A - Compression and tension resistant computer mouse material and preparation method thereof - Google Patents

Compression and tension resistant computer mouse material and preparation method thereof Download PDF

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CN106009370A
CN106009370A CN201610375829.9A CN201610375829A CN106009370A CN 106009370 A CN106009370 A CN 106009370A CN 201610375829 A CN201610375829 A CN 201610375829A CN 106009370 A CN106009370 A CN 106009370A
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powder
computer mouse
parts
compression
tensile materials
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秦元
王彬彬
高岩
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Xuchang University
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    • C08K7/14Glass
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F3/00Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
    • G06F3/01Input arrangements or combined input and output arrangements for interaction between user and computer
    • G06F3/03Arrangements for converting the position or the displacement of a member into a coded form
    • G06F3/033Pointing devices displaced or positioned by the user, e.g. mice, trackballs, pens or joysticks; Accessories therefor
    • G06F3/0354Pointing devices displaced or positioned by the user, e.g. mice, trackballs, pens or joysticks; Accessories therefor with detection of 2D relative movements between the device, or an operating part thereof, and a plane or surface, e.g. 2D mice, trackballs, pens or pucks
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Abstract

The invention discloses a compression and tension resistant computer mouse material and a preparation method thereof. The compression and tension resistant computer mouse material comprises a matrix and a reinforcement, the matrix comprises ceramic powder, tungsten steel powder and glass fibers, the reinforcement comprises vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tin coated copper wires, iminodisuccinic acid, titanium dioxide nanopowder, and the compression and tension resistant computer mouse material concretely comprises, by weight, comprises 25-45 parts of ceramic powder, 15-30 parts of tungsten steel powder, 15-20 parts of glass fibers, 5-10 parts of vinyl chloride, 5-10 parts of acrylate, 2-8 parts of the magnesium oxide powder, 2-8 parts of the calcium chloride powder, 2-8 parts of tin coated copper wires, 0.1-0.5 parts of iminodisuccinic acid and 0.1-0.3 parts of the titanium dioxide nanopowder. The compression and tension resistant computer mouse material is optimized to substantially improve the compression and tension resistance of computer mice. The compressive strength of the compression and tension resistant computer mouse material prepared through the method is 20MPa or above, the tensile strength is 15MPa or above, and the bending strength is 6MPa or above.

Description

A kind of computer mouse resistance to compression tensile materials and preparation method thereof
Technical field
The present invention relates to a kind of field of material technology, specifically a kind of computer mouse resistance to compression tensile materials and preparation side thereof Method.
Background technology
Along with being widely used of PC, mouse the most more and more occurs in daily life.But often click on and long-term Use, various faults easily occur, be badly in need of the novel mouse that research and development ruggedness is strong.Therefore, computer mouse how is prepared Resistance to compression tensile materials, reduces its process costs simultaneously and improves resistance to compression tensile property, and this is that computer mouse resistance to compression resists all the time Draw the technical barrier of material popularization and application.
Summary of the invention
It is an object of the invention to provide a kind of computer mouse resistance to compression tensile materials and preparation method thereof, to solve the above-mentioned back of the body The problem proposed in scape technology.
For achieving the above object, the present invention provides following technical scheme:
A kind of computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, and described matrix includes ceramic powders, tungsten Powdered steel and glass fibre, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tin plating Copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 25-45 part, wolfram steel powder End 15-30 part, glass fibre 15-20 part, vinyl chloride 5-10 part, acrylate 5-10 part, magnesium oxide powder 2-8 part, Calcium chloride powder 2-8 part, tinned copper wire 2-8 part, iminodisuccinic acid 0.1-0.5 part, nano titanium dioxide powder 0.1-0.3 part.
As the further scheme of the present invention: described computer mouse resistance to compression tensile materials, it is made up of matrix and reinforcement, Described matrix includes ceramic powders, wolfram steel powder and glass fibre, and described reinforcement includes vinyl chloride, acrylate, oxidation Magnesium dust, calcium chloride powder, tinned copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, Ceramic powders 30-40 part, wolfram steel powder 18-27 part, glass fibre 19-26 part, vinyl chloride 6-9 part, acrylate 6-9 Part, magnesium oxide powder 4-6 part, calcium chloride powder 4-6 part, tinned copper wire 4-6 part, iminodisuccinic acid 0.2-0.4 Part, nano titanium dioxide powder 0.2-0.4 part.
As the further scheme of the present invention: the mesh number of described ceramic powders is 1200 mesh, described wolfram steel powder mesh number is 1400 Mesh, described magnesium oxide powder mesh number is 1200 mesh, and described calcium chloride powder mesh number is 800 mesh.
As the further scheme of the present invention: a diameter of 500-800nm of described glass fibre, a length of 400-500 μm.
As the further scheme of the present invention: a diameter of 100-200 μm of described tinned copper wire, a length of 600-800 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) by ceramic powders, wolfram steel powder and magnesium oxide powder, calcium chloride powder, nano titanium dioxide powder and tin plating Copper wire is melt into liquid, is subsequently placed in chemical vapor deposition stove and is incubated 1-2h at 1200-1400 DEG C, cold go after pulverize also Add iminodisuccinic acid, be thoroughly mixed till soilless sticking, then carry out crosslinking curing with glass fibre, To mixture I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, at catalysis and the height of organic platinum filament Carry out isobaric thermal gradient reaction under the protection of pure nitrogen gas, obtain mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1-2h;Then, then by after deaeration Mixtures II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with Precompressed 5-8 minute under the pressure of 320-340 DEG C and 5-10MPa, sinters 20-40 minute at 400-500 DEG C subsequently, then drops Temperature is to 125 DEG C, and with the pressure pressurize 45 minutes of 5-10MPa, i.e. obtains computer mouse resistance to compression tensile materials after the demoulding.
As the further scheme of the present invention: described concrete steps (1) are subsequently placed in chemical vapor deposition stove 1300 DEG C of insulation 1.5h.
As the further scheme of the present invention: with precompressed 8 points under the pressure of 330 DEG C and 8MPa in described concrete steps (3) Clock, sinters 30 minutes at 450 DEG C subsequently, then is cooled to 125 DEG C, and with the pressure pressurize 45 minutes of 8MPa.
Compared with prior art, the invention has the beneficial effects as follows:
The present invention, by being optimized the resistance to compression tensile materials of computer mouse, considerably improves computer mouse Resistance to compression tensile property.More than computer mouse resistance to compression tensile materials comprcssive strength 20MPa that the method for the present invention prepares, More than tensile strength 15MPa, more than bending strength 6MPa.
Detailed description of the invention
Below in conjunction with detailed description of the invention, the technical scheme of this patent is described in more detail.
Embodiment 1
A kind of computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, and described matrix includes ceramic powders, tungsten Powdered steel and glass fibre, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tin plating Copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 25 parts, wolfram steel powder 15 parts, glass fibre 15 parts, 5 parts of vinyl chloride, acrylate 5 parts, magnesium oxide powder 2 parts, 2 parts of calcium chloride powder, Tinned copper wire 2 parts, iminodisuccinic acid 0.1 part, nano titanium dioxide powder 0.1 part;The mesh number of described ceramic powders Being 1200 mesh, described wolfram steel powder mesh number is 1400 mesh, and described magnesium oxide powder mesh number is 1200 mesh, described calcium chloride Powder mesh number is 800 mesh;A diameter of 500-800nm of described glass fibre, a length of 400-500 μm;Described tin-coated copper A diameter of 100-200 μm of silk, a length of 600-800 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) by ceramic powders, wolfram steel powder and magnesium oxide powder, calcium chloride powder, nano titanium dioxide powder and tin plating Copper wire is melt into liquid, is subsequently placed in chemical vapor deposition stove and is incubated 1h at 1200 DEG C, cold go after pulverize and add Asia Amino disuccinic acid, is thoroughly mixed till soilless sticking, then carries out crosslinking curing with glass fibre, is mixed Thing I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, at catalysis and the height of organic platinum filament Carry out isobaric thermal gradient reaction under the protection of pure nitrogen gas, obtain mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1h;Then, mixed then by after deaeration Compound II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with 320 DEG C With precompressed under the pressure of 5MPa 5 minutes, sinter 20 minutes at 400 DEG C subsequently, then be cooled to 125 DEG C, and with 5MPa Pressure pressurize 45 minutes, i.e. obtain computer mouse resistance to compression tensile materials after the demoulding.
The computer mouse resistance to compression tensile materials that above-mentioned technique prepares, records its mechanical property parameters as follows: pressure resistance Degree 20MPa, tensile strength 15MPa, bending strength 6MPa.
Embodiment 2
A kind of computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, and described matrix includes ceramic powders, tungsten Powdered steel and glass fibre, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tin plating Copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 35 parts, wolfram steel powder 23 parts, glass fibre 18 parts, 8 parts of vinyl chloride, acrylate 8 parts, magnesium oxide powder 5 parts, 5 parts of calcium chloride powder, Tinned copper wire 5 parts, iminodisuccinic acid 0.3 part, nano titanium dioxide powder 0.2 part;The mesh number of described ceramic powders Being 1200 mesh, described wolfram steel powder mesh number is 1400 mesh, and described magnesium oxide powder mesh number is 1200 mesh, described calcium chloride Powder mesh number is 800 mesh;A diameter of 500-800nm of described glass fibre, a length of 400-500 μm;Described tin-coated copper A diameter of 100-200 μm of silk, a length of 600-800 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) by ceramic powders, wolfram steel powder and magnesium oxide powder, calcium chloride powder, nano titanium dioxide powder and tin plating Copper wire is melt into liquid, is subsequently placed in chemical vapor deposition stove and is incubated 1.5h at 1300 DEG C, cold go after pulverize and add Iminodisuccinic acid, is thoroughly mixed till soilless sticking, then carries out crosslinking curing with glass fibre, is mixed Compound I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, at catalysis and the height of organic platinum filament Carry out isobaric thermal gradient reaction under the protection of pure nitrogen gas, obtain mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1.5h;Then, then by after deaeration Mixtures II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with 330 DEG C With precompressed under the pressure of 8MPa 8 minutes, sintering minute at 450 DEG C, then was cooled to 125 DEG C subsequently, and with 8MPa's Pressure pressurize 45 minutes, i.e. obtains computer mouse resistance to compression tensile materials after the demoulding.
The computer mouse resistance to compression tensile materials that above-mentioned technique prepares, records its mechanical property parameters as follows: pressure resistance Degree 28MPa, tensile strength 18MPa, bending strength 7MPa.
Embodiment 3
A kind of computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, and described matrix includes ceramic powders, tungsten Powdered steel and glass fibre, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tin plating Copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 45 parts, wolfram steel powder 30 parts, glass fibre 20 parts, 10 parts of vinyl chloride, acrylate 10 parts, magnesium oxide powder 8 parts, calcium chloride powder 8 Part, tinned copper wire 8 parts, iminodisuccinic acid 0.5 part, nano titanium dioxide powder 0.3 part;Described ceramic powders Mesh number is 1200 mesh, and described wolfram steel powder mesh number is 1400 mesh, and described magnesium oxide powder mesh number is 1200 mesh, described chlorine Changing calcium powder mesh number is 800 mesh;A diameter of 500-800nm of described glass fibre, a length of 400-500 μm;Described plating A diameter of 100-200 μm of stannum copper wire, a length of 600-800 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) by ceramic powders, wolfram steel powder and magnesium oxide powder, calcium chloride powder, nano titanium dioxide powder and tin plating Copper wire is melt into liquid, is subsequently placed in chemical vapor deposition stove and is incubated 2h at 1400 DEG C, cold go after pulverize and add Asia Amino disuccinic acid, is thoroughly mixed till soilless sticking, then carries out crosslinking curing with glass fibre, is mixed Thing I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, at catalysis and the height of organic platinum filament Carry out isobaric thermal gradient reaction under the protection of pure nitrogen gas, obtain mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 2h;Then, mixed then by after deaeration Compound II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with 340 DEG C With precompressed under the pressure of 10MPa 8 minutes, sinter 40 minutes at 500 DEG C subsequently, then be cooled to 125 DEG C, and with 10MPa Pressure pressurize 45 minutes, i.e. obtain computer mouse resistance to compression tensile materials after the demoulding.
The computer mouse resistance to compression tensile materials that above-mentioned technique prepares, records its mechanical property parameters as follows: pressure resistance Degree 24MPa, tensile strength 17MPa, bending strength 6MPa.
Comparative example 1
A kind of computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, and described matrix includes ceramic powders and glass Glass fiber, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, iminodisuccinic acid, In terms of weight portion comes, ceramic powders 35 parts, glass fibre 18 parts, 8 parts of vinyl chloride, acrylate 8 parts, magnesia powder 5 parts of end, 5 parts of calcium chloride powder, iminodisuccinic acid 0.3 part;The mesh number of described ceramic powders is 1200 mesh, institute Stating magnesium oxide powder mesh number is 1200 mesh, and described calcium chloride powder mesh number is 800 mesh;Described glass fibre a diameter of 500-800nm, a length of 400-500 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) ceramic powders and magnesium oxide powder, calcium chloride powder are melt into liquid, are subsequently placed into chemical gaseous phase deposition Be incubated 1.5h at 1300 DEG C in stove, cold go after pulverize and add iminodisuccinic acid, be thoroughly mixed until soilless sticking Till, then carry out crosslinking curing with glass fibre, obtain mixture I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, at catalysis and the height of organic platinum filament Carry out isobaric thermal gradient reaction under the protection of pure nitrogen gas, obtain mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1.5h;Then, then by after deaeration Mixtures II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with 330 DEG C With precompressed under the pressure of 8MPa 8 minutes, sintering minute at 450 DEG C, then was cooled to 125 DEG C subsequently, and with 8MPa's Pressure pressurize 45 minutes, i.e. obtains computer mouse resistance to compression tensile materials after the demoulding.
The computer mouse resistance to compression tensile materials that above-mentioned technique prepares, records its mechanical property parameters as follows: pressure resistance Degree 8MPa, tensile strength 10MPa, bending strength 2MPa.
Comparative example 2
A kind of computer mouse resistance to compression tensile materials, is made up of matrix, and described matrix includes ceramic powders and glass fibre, In terms of weight portion comes, ceramic powders 35 parts, glass fibre 18 parts;The mesh number of described ceramic powders is 1200 mesh;Described A diameter of 500-800nm of glass fibre, a length of 400-500 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) ceramic powders is melt into liquid, in being subsequently placed into chemical vapor deposition stove, is incubated 1.5h at 1300 DEG C, cold Pulverize after going and carry out crosslinking curing with glass fibre, obtaining mixture I;
(2) mixture I carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1.5h;Then, then by after deaeration Mixture I addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with 330 DEG C With precompressed under the pressure of 8MPa 8 minutes, sintering minute at 450 DEG C, then was cooled to 125 DEG C subsequently, and with 8MPa's Pressure pressurize 45 minutes, i.e. obtains computer mouse resistance to compression tensile materials after the demoulding.
The computer mouse resistance to compression tensile materials that above-mentioned technique prepares, records its mechanical property parameters as follows: pressure resistance Degree 1MPa, tensile strength 2MPa, bending strength 0.5MPa.
Comparative example 3
A kind of computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, and described matrix includes ceramic powders, tungsten Powdered steel and glass fibre, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tin plating Copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 35 parts, wolfram steel powder 23 parts, glass fibre 18 parts, 8 parts of vinyl chloride, acrylate 8 parts, magnesium oxide powder 5 parts, 5 parts of calcium chloride powder, Tinned copper wire 5 parts, iminodisuccinic acid 0.3 part, nano titanium dioxide powder 0.2 part;The mesh number of described ceramic powders Being 1200 mesh, described wolfram steel powder mesh number is 1400 mesh, and described magnesium oxide powder mesh number is 1200 mesh, described calcium chloride Powder mesh number is 800 mesh;A diameter of 500-800nm of described glass fibre, a length of 400-500 μm;Described tin-coated copper A diameter of 100-200 μm of silk, a length of 600-800 μm.
The preparation method of a kind of computer mouse resistance to compression tensile materials, concretely comprises the following steps:
(1) by ceramic powders, wolfram steel powder and magnesium oxide powder, calcium chloride powder, nano titanium dioxide powder and tin plating Copper wire is melt into liquid, is subsequently placed in chemical vapor deposition stove and is incubated 1.5h at 1300 DEG C, cold go after pulverize and add Iminodisuccinic acid, is thoroughly mixed till soilless sticking, then carries out crosslinking curing with glass fibre, is mixed Compound I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, carry out microwave heating treatment, To mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1.5h;Then, then by after deaeration Mixtures II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with 330 DEG C With precompressed under the pressure of 8MPa 8 minutes, sintering minute at 450 DEG C, then was cooled to 125 DEG C subsequently, and with 8MPa's Pressure pressurize 45 minutes, i.e. obtains computer mouse resistance to compression tensile materials after the demoulding.
The computer mouse resistance to compression tensile materials that above-mentioned technique prepares, records its mechanical property parameters as follows: pressure resistance Degree 12MPa, tensile strength 13MPa, bending strength 3MPa.
Above the better embodiment of this patent is explained in detail, but this patent is not limited to above-mentioned embodiment, In the ken that those of ordinary skill in the art is possessed, it is also possible to make each on the premise of without departing from this patent objective Plant change.

Claims (8)

1. a computer mouse resistance to compression tensile materials, is made up of matrix and reinforcement, it is characterised in that described matrix bag Including ceramic powders, wolfram steel powder and glass fibre, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, chlorine Change calcium powder, tinned copper wire, iminodisuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 25-45 Part, wolfram steel powder 15-30 part, glass fibre 15-20 part, vinyl chloride 5-10 part, acrylate 5-10 part, magnesium oxide Powder 2-8 part, calcium chloride powder 2-8 part, tinned copper wire 2-8 part, iminodisuccinic acid 0.1-0.5 part, nanometer two Titanium dioxide powder 0.1-0.3 part.
Computer mouse resistance to compression tensile materials the most according to claim 1, it is characterised in that Mus used by described computer Mark resistance to compression tensile materials, can be to you by matrix and reinforcement group volume, and described matrix includes ceramic powders, wolfram steel powder and glass Fiber, described reinforcement includes vinyl chloride, acrylate, magnesium oxide powder, calcium chloride powder, tinned copper wire, imino group Disuccinic acid, nano titanium dioxide powder, in terms of weight portion comes, ceramic powders 30-40 part, wolfram steel powder 18-27 part, Glass fibre 19-26 part, vinyl chloride 6-9 part, acrylate 6-9 part, magnesium oxide powder 4-6 part, calcium chloride powder 4-6 Part, tinned copper wire 4-6 part, iminodisuccinic acid 0.2-0.4 part, nano titanium dioxide powder 0.2-0.4 part.
Computer mouse resistance to compression tensile materials the most according to claim 1 and 2, it is characterised in that described ceramics The mesh number at end is 1200 mesh, and described wolfram steel powder mesh number is 1400 mesh, and described magnesium oxide powder mesh number is 1200 mesh, institute Stating calcium chloride powder mesh number is 800 mesh.
Computer mouse resistance to compression tensile materials the most according to claim 1 and 2, it is characterised in that described glass fibers A diameter of 500-800nm of dimension, a length of 400-500 μm.
Computer mouse resistance to compression tensile materials the most according to claim 3, it is characterised in that described tinned copper wire A diameter of 100-200 μm, a length of 600-800 μm.
6. a preparation method for the computer mouse resistance to compression tensile materials as described in claim 1-5 is arbitrary, its feature exists In, concretely comprise the following steps:
(1) by ceramic powders, wolfram steel powder and magnesium oxide powder, calcium chloride powder, nano titanium dioxide powder and tin plating Copper wire is melt into liquid, is subsequently placed in chemical vapor deposition stove and is incubated 1-2h at 1200-1400 DEG C, cold go after pulverize also Add iminodisuccinic acid, be thoroughly mixed till soilless sticking, then carry out crosslinking curing with glass fibre, To mixture I;
(2) mixture I step (1) obtained and vinyl chloride and crylic acid ester mixture, at catalysis and the height of organic platinum filament Carry out isobaric thermal gradient reaction under the protection of pure nitrogen gas, obtain mixtures II;
(3) mixtures II carrying out in vacuum defoamation machine deaeration, inclined heated plate is 1-2h;Then, then by after deaeration Mixtures II addition mould solidifies, puts in high-frequency induction heating hot-pressed sintering furnace, in argon gas atmosphere, with Precompressed 5-8 minute under the pressure of 320-340 DEG C and 5-10MPa, sinters 20-40 minute at 400-500 DEG C subsequently, then drops Temperature is to 125 DEG C, and with the pressure pressurize 45 minutes of 5-10MPa, i.e. obtains computer mouse resistance to compression tensile materials after the demoulding.
The preparation method of computer mouse resistance to compression tensile materials the most according to claim 6, it is characterised in that described It is incubated 1.5h at 1300 DEG C in concrete steps (1) are subsequently placed into chemical vapor deposition stove.
The preparation method of computer mouse resistance to compression tensile materials the most according to claim 6, it is characterised in that described With precompressed 8 minutes under the pressure of 330 DEG C and 8MPa in concrete steps (3), sinter 30 minutes at 450 DEG C subsequently, then It is cooled to 125 DEG C, and with the pressure pressurize 45 minutes of 8MPa.
CN201610375829.9A 2016-05-31 2016-05-31 Compression and tension resistant computer mouse material and preparation method thereof Pending CN106009370A (en)

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CN109270612A (en) * 2018-09-04 2019-01-25 安徽新恒辉反光材料有限公司 A kind of tension reflective strip and preparation method thereof

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EP0822062A1 (en) * 1996-07-29 1998-02-04 Asahi Fiber Glass Co., Ltd. Composite substrate for plastic reinforcement, and fiber-reinforced plastic using such composite substrate
CN1884438A (en) * 2006-07-06 2006-12-27 袁新周 Non-metal inorganic powdery composite flame-proof material and its production method, and sheet and its production method
CN105330879A (en) * 2015-10-23 2016-02-17 福建梭罗复合材料研究有限公司 Light-cured glass fiber composite material and preparation method thereof

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EP0822062A1 (en) * 1996-07-29 1998-02-04 Asahi Fiber Glass Co., Ltd. Composite substrate for plastic reinforcement, and fiber-reinforced plastic using such composite substrate
CN1884438A (en) * 2006-07-06 2006-12-27 袁新周 Non-metal inorganic powdery composite flame-proof material and its production method, and sheet and its production method
CN105330879A (en) * 2015-10-23 2016-02-17 福建梭罗复合材料研究有限公司 Light-cured glass fiber composite material and preparation method thereof

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* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109270612A (en) * 2018-09-04 2019-01-25 安徽新恒辉反光材料有限公司 A kind of tension reflective strip and preparation method thereof

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