CN113831653B - Ethylene propylene diene monomer rubber material for wire drawing machine manipulator clamping jaw and preparation method thereof - Google Patents

Abstract

The invention discloses an ethylene propylene diene monomer rubber material for a manipulator clamping jaw of a wire drawing machine and a preparation method thereof, wherein the ethylene propylene diene monomer rubber material comprises the following components: ethylene propylene diene monomer, carbon black, modified talcum powder, fabric rubber powder, paraffin oil, epoxidized soybean oil, zinc oxide, an anti-aging agent, stearic acid, petroleum resin, phenolic tackifying resin, triallyl isocyanurate, dibenzoyl peroxide and sulfur. According to the invention, through the research and development of the ethylene propylene diene monomer rubber material, the surface viscosity of the material is reduced, the friction resistance and the surface scratch resistance are improved, the influence on the original rebound resilience is small, the process operability is obviously improved, the manufacturing process is simple, reliable and stable, and the material is suitable for the manipulator clamping jaw material of the automatic optical fiber wire drawing machine.

Description

Ethylene propylene diene monomer rubber material for wire drawing machine manipulator clamping jaw and preparation method thereof

Technical Field

The invention relates to the technical field of optical fiber manufacturing and processing, in particular to an ethylene propylene diene monomer material for a mechanical arm clamping jaw of a wire drawing machine and a preparation method thereof.

Background

The optical fiber image transmission element comprises an optical fiber panel, an optical fiber image inverter, an optical fiber light cone, an optical fiber image transmission bundle and the like, is a photoelectric imaging element with excellent performance, and has the characteristics of simple structure, small volume, light weight, high resolution, large numerical aperture, small interstage coupling loss, clear and real image transmission, high light transmission efficiency, optical zero thickness in image transmission, capability of improving edge image quality and the like. The optical fiber image transmission element is widely applied to various cathode ray tubes, image pickup tubes, charge-coupled Device (CCD) coupling, medical instrument display screens, high-definition television imaging and other instruments and equipment needing to transmit images in the fields of military affairs, criminal investigation, night vision, aerospace, medical treatment and the like, and is a high-tech top product in the industry of the present century.

The optical fiber image transmission element is characterized in that a high-refractive-index glass rod and a low-refractive-index glass tube are matched and combined, after high-temperature heating softening in a heating furnace, optical fiber yarns with unit fiber yarn diameters smaller than 6 mu m are manufactured through processes of single yarn drawing, primary multi-yarn drawing, secondary multi-yarn drawing and the like, then thousands of optical fibers with unit fiber yarn diameters smaller than 6 mu m are closely stacked and arranged, then hot melt forming is carried out, and then torsion forming or drawing forming is carried out to obtain the hard optical fiber image transmission element capable of transmitting images. Each optical fiber in the optical fiber image transmission element has good optical insulation, so that each optical fiber can independently transmit light and transmit images without being influenced by other adjacent optical fibers. The optical fiber image transmission element is mainly used in the instruments and equipment needing image transmission, such as a cathode ray tube, a camera tube, an image intensifier and the like, so that the requirements on the manufacturing process of products are extremely high, in particular to the drawing process of optical fiber yarns, which is a key process procedure in the preparation process of optical fiber products, and the optical fiber image transmission element heats and softens a matched optical fiber drawing prefabricated rod at high temperature in a drawing furnace, then depends on gravity to droop, clamps the softened and drooped optical fiber yarns by a drawing and pulling device of the optical fiber yarns, and then draws the optical fiber yarns downwards at a constant speed. The drawing mechanism of the optical fiber is a key device and device in the drawing process of the optical fiber, and the stability and the drawing precision of the device are directly related to the dimensional stability of the optical fiber diameter and the stability of the surface quality of the optical fiber diameter. Especially for preparing the optical fiber filament of the hard optical fiber image transmission element, the processes of single filament drawing, primary multifilament drawing and secondary multifilament drawing are needed. The surface of the secondary multifilament is a serrated surface formed by combining a plurality of arranged optical fibers, after the secondary multifilament is subjected to multiple composite arrangement and drawing, the number of teeth on the surface of the optical fibers is multiplied along with the arrangement times, the thickness of the cortex of the secondary multifilament is thinner and thinner, the thickness of the surface cortex glass is as thin as 0.2-0.3 mu m, and the damage of the cortex of the optical fibers can be caused by slight touch and friction, so that the light leakage of the optical fibers is caused, the spot defect or the grid defect is generated inside the prepared optical fiber image transmission element, and the production quality and the product yield of the optical fiber image transmission element are greatly reduced.

The mechanical arm wire drawing machine mode is different from the traditional wheel drawing mode and the traditional holding drawing mode, the wheel drawing mode and the holding drawing mode both depend on the extrusion of the surface of rubber to draw and draw optical fibers downwards, but the mechanical arm wire drawing mainly depends on the clamping force of the clamping jaw and the friction force of the material of the clamping jaw to draw the optical fibers. The clamping jaw material of the drawing mechanism of the optical fiber wire is a key material in the drawing process of the optical fiber wire, is directly contacted with the optical fiber wire, and the performance of the clamping jaw material is directly related to the stability of the wire diameter size of the optical fiber wire drawing, the quality of the wire diameter surface and the stability of the surface quality. The automatic wire drawing mode of the mechanical arm is adopted, and the drawing mode is a traction drawing mode which clamps the wire and then directly draws the wire, so that the clamping jaw material on the surface of the wire has to meet five conditions:

firstly, the clamping jaw material needs to be high temperature resistant, and the surface temperature of the optical fiber reaches 200-300 ℃ after the optical fiber passes through the wire drawing furnace and the diameter gauge and reaches the clamping jaw of the manipulator, so that the clamping jaw material needs to be capable of bearing the high temperature without surface deformation or fusion adhesion with the optical fiber;

the material of the two clamping jaws needs to be anti-skid, the material of the clamping jaws needs to be anti-skid after clamping the optical fiber, the hardness of the material of the clamping jaws cannot be too high, so that the material of the clamping jaws slips during wire drawing and cannot clamp the optical fiber, and the hardness of the material of the clamping jaws cannot be too low, otherwise, the optical fiber is adhered to the clamping jaws;

thirdly, the clamping jaw material needs certain wear resistance to prevent slipping or adhesion in the drawing process of the optical fiber, and after the optical fiber is drawn and drawn repeatedly, particles or powder cannot fall off from the surface, otherwise the surface of the optical fiber is polluted to generate spot defects;

fourthly, the material of the clamping jaw needs to have good rebound resilience, namely the elasticity is good, but if the elasticity is too large, the optical fiber yarn is easy to be adhered to the clamping jaw, and the elasticity is too small, so that the drawing process can slip;

fifthly, the clamping jaw material needs to have an antistatic effect, and impurities or dust particles cannot be adsorbed on the surface of the clamping jaw material so as to prevent the impurities from being adhered to the optical fiber.

The rubber is an elastic and insulating material prepared after processing, is a high-elasticity polymer material, is widely applied to various aspects of industry and life, and can cause the surface of the optical fiber to be damaged and scratched, and the wire diameter precision and the ovality of the optical fiber to be unstable after being used, thereby seriously restricting the performance improvement of the optical fiber image transmission element; the natural rubber has higher elasticity at normal temperature, but has poor high-temperature resistance, easy aging, poor wear resistance, easy generation of friction particles, short service life and serious scrap falling in the using process; the existing polyurethane material in the market has the advantages of abrasion resistance, chemical corrosion resistance and the like, but the heat resistance is poor, and the general use temperature is not more than 80 ℃; although the materials such as nitrile rubber and the like have better wear resistance and heat resistance, the materials are not suitable for the process of drawing and wire drawing due to poor aging resistance, serious abrasion and short service life; the silicon rubber material has excellent rebound performance, but has poor wear resistance, and the surface viscosity of the silicon rubber material is too large, so that dust is easily adsorbed, and the cleaning of the surface of the optical fiber filament and even the adhesion of the optical fiber filament can be influenced in the wire drawing process.

The clamping jaw material of the existing optical fiber filament can not meet the performance requirement of a high-performance optical fiber image transmission element.

Disclosure of Invention

In order to solve the defects in the prior art, the invention provides the ethylene propylene diene monomer rubber material for the clamping jaw of the mechanical arm of the wire drawing machine, which is an organic material with the surface tack removed, and has the characteristics of proper hardness, excellent rebound resilience, good high-temperature resistance, large frictional resistance, strong stability, wear resistance and excellent anti-skidding performance.

In order to achieve the purpose, the technical scheme adopted by the invention for solving the technical problem is to provide an ethylene propylene diene monomer material for a manipulator clamping jaw of a wire drawing machine, which comprises the following components in parts by weight:

the carbon black comprises:

the anti-aging agent is at least one selected from 2-dithiol methyl benzothiazole zinc salt, 2,4 dimethyl-1, 2-dihydroquinoline polymer and 9, 9-dimethylacridine;

wherein:

the invention provides another preferable technical scheme that the ethylene propylene diene monomer material for the manipulator clamping jaw of the wire drawing machine comprises the following components in parts by weight:

the invention provides a further preferable technical scheme, and the hydrogenated nitrile rubber material for the manipulator clamping jaw of the wire drawing machine comprises the following components in parts by weight:

the invention also provides a preparation method of the ethylene propylene diene monomer material for the manipulator clamping jaw of the wire drawing machine, which comprises the following steps:

(1) Sequentially adding the ethylene propylene diene monomer rubber, carbon black, modified talcum powder, fabric rubber powder, paraffin oil, epoxidized soybean oil, zinc oxide, an anti-aging agent, stearic acid, petroleum resin and phenolic tackifying resin into an internal mixer or an open mill for plastication and mixing to obtain rubber compound;

(2) Placing the mixed rubber placed for 36-48 hours into an internal mixer or an open mill, sequentially adding triallyl isocyanurate, dibenzoyl peroxide and sulfur, uniformly mixing to obtain vulcanized mixed rubber, standing for 12-36 hours at room temperature, and vulcanizing by a vulcanizing machine to obtain the ethylene propylene diene monomer rubber material.

The vulcanizing temperature is 160-200 ℃, the vulcanizing time is 15-30 min, and the vulcanizing pressure is 16-20 MPa.

The invention also provides an application of the ethylene propylene diene monomer material prepared by the preparation method in a mechanical arm clamping jaw of an automatic optical fiber wire drawing machine.

According to the invention, through the research and development of Ethylene Propylene Diene Monomer (EPDM) material, the surface viscosity of the material is reduced, the friction resistance and the surface scratch resistance are improved, the influence on the original resilience is small, the process operability is obviously improved, the manufacturing process is simple, reliable and stable, and the material is suitable for the manipulator clamping jaw material of the automatic optical fiber wire drawing machine.

In the invention, the ethylene propylene diene monomer adopts S512F of SK company, the low-Mooney series ethylene propylene diene monomer has better processing fluidity, the rubber gasket can have better flexibility, and the ethylene propylene diene monomer with higher ethylene content can achieve better elasticity and tensile strength;

the carbon black N774 has the effects of improving the tensile strength, elasticity and the like of rubber;

the carbon black N990 and the carbon black with large particle size can effectively increase the roughness of the surface of rubber, thereby improving the friction coefficient and ensuring that the rubber and a clamp are not easy to directly slide;

the modified talcum powder is a layered hydrous magnesium silicate, the surface of the talcum powder contains hydrophilic groups and has higher surface energy, the talcum powder and organic polymer molecules as inorganic filler have larger difference in chemical structure and physical form and lack affinity, so that the talcum powder and the polymer are not uniformly mixed and have weak adhesive force;

the fabric rubber powder FD-6 contains 30 percent of rubber powder of polyester fiber, and a mixture of rubber and the polyester fiber, and can increase the friction force of the rubber surface to a greater extent;

the paraffin oil 2280 can ensure that the rubber formula can reach lower hardness, is favorable for forming larger friction force, contains paraffin base which has the best compatibility with ethylene propylene diene monomer rubber and is favorable for processing and dispersion;

epoxidized soybean oil and industrial epoxidized soybean oil can further promote the compatibility of paraffin oil and rubber, so that the processing technology of the rubber is easier, and more uniform and stable rubber products can be obtained;

zinc oxide, znO, an active agent for chemical reactions;

an anti-aging agent 2-dithiol methyl benzothiazole zinc salt/ZMTI, which is a heterocyclic anti-aging agent for preventing rubber from aging;

antioxidant 2,4 dimethyl-1, 2-dihydroquinoline polymer/RD, amine antioxidant for preventing rubber aging;

anti-aging agent 9, 9-dimethylacridine/BLE, amine anti-aging agent for preventing rubber aging;

stearic acid Sa, chemical reaction activator;

the petroleum resin C9 provides self-adhesion for rubber processing and vulcanization into products, and increases the friction coefficient for the rubber gasket;

the phenolic tackifying resin 203 provides self-adhesiveness for rubber after processing and vulcanization into products, and increases the friction coefficient for the rubber gasket;

triallyl isocyanurate/TAIC, a vulcanization crosslinking coagent;

dibenzoyl peroxide/BPO, a vulcanizing agent enables rubber to have cross-linking reaction and have elasticity;

sulfur S, vulcanizing agent to make rubber produce cross-linking reaction and possess elasticity;

the Ethylene Propylene Diene Monomer (EPDM) material is a temperature-resistant material with excellent performance, has wide temperature-resistant range, can normally work within the temperature range of-20-200 ℃, and has outstanding environmental compatibility; traditional rubber materials mainly increase the friction performance of the materials by increasing the granularity of the raw materials, but can sacrifice the resilience of the materials, and influence the wear resistance of the materials to a certain extent, so that the single rubber materials hardly meet the requirements of production processes, cannot ensure the stability of production work, and therefore need to have better elasticity, reduce harmful substances in the materials and reduce the harm to the environment.

Compared with the prior art, the manipulator clamping jaw material for the full-automatic nondestructive vertical optical fiber wire drawing machine has the beneficial effects that:

(1) Can resist the high temperature of more than 200 ℃ without softening and deforming and is not adhered with the optical fiber;

(2) The Shore hardness is 68-72 HA, the rebound resilience is excellent, and the fiber is not adhered in the drawing process;

(3) Excellent wear resistance, large friction resistance, friction coefficient of 0.32 and abrasion volume of less than 0.03cm ³ ；

(4) The rebound resilience is good, the tensile strength is more than 10.0MPa, the tearing strength is more than 5.0KN.m, and the elongation at break is more than 60 percent;

(5) The invention realizes that the optical fiber is more stable in the wire drawing process by contacting the optical fiber with the mechanical clamping jaw material without damage to draw and draw stably at a constant speed, avoids the phenomena of wire twisting and slipping in the wire drawing process, reduces the surface contact and the cortex abrasion of the optical fiber in the drawing process, improves the surface quality of the optical fiber drawing and the stability of the wire diameter size of the optical fiber, and can draw and manufacture the optical fiber without damage and pollution, the wire diameter size precision of the drawn optical fiber can be controlled within +/-3 mu m, and the change difference of the ellipticity can be controlled within +/-2 mu m.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention are clearly and completely described below, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

The parameters and the method for measuring the ethylene propylene diene monomer material used for the mechanical arm clamping jaw of the automatic optical fiber drawing machine are as follows:

(1) Heat resistance, GB/T2941-1991 Standard temperature, humidity and time for environmental Regulation and experiments in rubber Style;

(2) Shore hardness, GB/T531-2008 "test method for indentation hardness of rubber pocket durometer";

(3) Coefficient of friction, HG/T2729-1995 determination of coefficient of friction between vulcanized rubber and a sheet;

(4) The abrasion volume, GB/T1689-1998 determination of the abrasion resistance of vulcanized rubber;

(5) Determination of tensile strength, tear strength, GB/T528-2009 tensile stress strain Properties of vulcanized rubber or thermoplastic rubber;

TABLE 1 parts by weight of the examples and their Properties

As can be seen from table 1:

(1) The heat resistance of the embodiment of the invention is 204 ℃ at least, which shows that the fiber can resist the high temperature of more than 200 ℃ without softening deformation and adhesion with the optical fiber;

(2) The Shore hardness is 68-72 HA, the rebound resilience is excellent, and the fiber is not adhered in the wire drawing process;

(3) Excellent wear resistance, large friction resistance, 0.32 friction coefficient and less than 0.03cm abrasion volume ³ ；

(4) The tensile strength is 12.2MPa at the lowest, the tearing strength is 5.6KN.m at the lowest, the elongation at break is 61% at the lowest, and the elastic resilience is good.

Example 1

A preparation method of an ethylene propylene diene monomer material for a manipulator clamping jaw of a wire drawing machine comprises the following steps:

(1) Putting 100kg of ethylene propylene diene monomer rubber, 52kg of carbon black N774, 5kg of carbon black N990, 15kg of modified talcum powder, 20kg of fabric rubber powder FD-6, 48kg of paraffin oil 2280, 5kg of epoxidized soybean oil, 6kg of zinc oxide ZnO, 1kg of anti-aging agent 2,4 dimethyl-1, 2-dihydroquinoline polymer/RD, 1kg of anti-aging agent 9, 9-dimethylacridine/BLE, 1kg of stearic acid, 3kg of petroleum resin and 4kg of phenolic tackifying resin into an internal mixer or an open mill for plastifying and mixing to obtain rubber compound;

(2) Placing the mixed rubber which is placed for 36-48 hours in an internal mixer or an open mill, sequentially adding 2kg of triallyl isocyanurate, 3.7kg of dibenzoyl peroxide and 0.1kg of sulfur, uniformly mixing to obtain the vulcanized mixed rubber, standing for 24 hours at room temperature, and vulcanizing by a vulcanizing machine, wherein the vulcanizing temperature is 180 ℃, the vulcanizing time is 20min, and the vulcanizing pressure is 18MPa to obtain the ethylene propylene diene monomer rubber material.

Example 2

The raw materials were dosed according to the compositions of the components given in table 1; the preparation is identical to example 1, except that: and adding the vulcanized rubber compound, standing for 12 hours at room temperature, wherein the vulcanization temperature is 160 ℃, the vulcanization time is 30min, and the vulcanization pressure is 16MPa.

Example 3

The raw materials were dosed according to the compositions of the components given in table 1; the preparation is identical to example 1, except that: and (3) adding the vulcanized rubber compound, standing for 30 hours at room temperature, wherein the vulcanization temperature is 200 ℃, the vulcanization time is 15min, and the vulcanization pressure is 20MPa.

Example 4

The raw materials were dosed according to the compositions of the components given in table 1; the preparation is identical to example 1, except that: and (3) adding the vulcanized rubber compound, standing for 26 hours at room temperature, wherein the vulcanization temperature is 170 ℃, the vulcanization time is 18min, and the vulcanization pressure is 17MPa.

Example 5

The raw materials were dosed according to the compositions of the components given in table 1; the preparation is identical to example 1, except that: and adding the vulcanized rubber compound, standing for 20 hours at room temperature, wherein the vulcanization temperature is 200 ℃, the vulcanization time is 25min, and the vulcanization pressure is 19MPa.

The invention contacts with the optical fiber wire in a non-destructive contact clamping mode of the mechanical clamping jaw material, and then carries out uniform traction drawing, so that the drawing process of the optical fiber wire is more stable, the phenomena of wire twisting and slipping in the drawing process can not occur, the surface contact and the cortex damage of the optical fiber wire in the drawing process are reduced, and the surface quality of the drawing of the optical fiber wire and the stability of the wire diameter size of the optical fiber wire are improved.

The above-described embodiment is only one of the preferred embodiments of the present invention, and general changes and substitutions by those skilled in the art within the technical scope of the present invention are included in the protection scope of the present invention.

Claims (5)

1. The mechanical arm clamping jaw of the wire drawing machine is characterized by comprising an ethylene propylene diene monomer material, wherein the ethylene propylene diene monomer material comprises the following components in parts by weight:

ethylene propylene diene monomer 100.0 parts

50-65.0 parts of carbon black

15.0-20.0 parts of modified talcum powder

20.0-25.0 parts of fabric rubber powder

35-48 parts of paraffin oil

5-10 parts of epoxidized soybean oil

5-10 parts of zinc oxide

1-5 parts of anti-aging agent

1-5 parts of stearic acid

1-5 parts of petroleum resin

1-5 parts of phenolic tackifying resin

1-5 parts of triallyl isocyanurate

1-5 parts of dibenzoyl peroxide

0.1-0.5 part of sulfur;

the carbon black comprises:

45-55.0 parts of carbon black N774

990.0-10.0 parts of carbon black N;

the anti-aging agent is at least one selected from 2-dithiol methyl benzothiazole zinc salt, 2,4 dimethyl-1, 2-dihydroquinoline polymer and 9, 9-dimethylacridine;

wherein:

0-2 parts of 2-dithiol methyl benzothiazole zinc salt

0-2 parts of 2, 4-dimethyl-1, 2-dihydroquinoline polymer

0-2 parts of 9, 9-dimethylacridine;

the modified talcum powder is obtained by modifying talcum powder by a surface modifier;

the fabric rubber powder is rubber powder containing 30% of polyester fiber.

2. The manipulator clamping jaw of the wire drawing machine as claimed in claim 1, characterized by comprising the following components in parts by weight:

ethylene propylene diene monomer 100 parts

Carbon black N774 52 parts

Carbon black N990 parts

15 parts of modified talcum powder

20 parts of fabric rubber powder

Paraffin oil 48 parts

5 parts of epoxidized soybean oil

6 portions of zinc oxide

Anti-aging agent 2-dithiol methyl benzothiazole zinc salt 2 parts

1 part of anti-aging agent 2,4 dimethyl-1, 2-dihydroquinoline polymer

Anti-aging agent 9, 9-dimethylacridine 1 part

Stearic acid 1 part

Petroleum resin 3 parts

4 parts of phenolic tackifying resin

5 parts of triallyl isocyanurate

3.7 parts of dibenzoyl peroxide

0.1 part of sulfur.

3. The manipulator clamping jaw of the wire drawing machine according to claim 1, comprising the following components in parts by weight:

ethylene propylene diene monomer 100 parts

Carbon black N774 52 parts

Carbon black N990 parts

15 parts of modified talcum powder

25 parts of fabric rubber powder

Paraffin oil 40 parts

5 parts of epoxidized soybean oil

5 portions of zinc oxide

1 part of anti-aging agent 2,4 dimethyl-1, 2-dihydroquinoline polymer

Anti-aging agent 9, 9-dimethylacridine 1 part

Stearic acid 1 part

Petroleum resin 4 parts

5 parts of phenolic tackifying resin

Triallyl isocyanurate 2 parts

3.9 portions of dibenzoyl peroxide

0.15 part of sulfur.

4. The preparation method of the ethylene propylene diene monomer material for the manipulator clamping jaw of the wire drawing machine as claimed in any one of claims 1 to 3 is characterized by comprising the following steps:

(1) Sequentially adding the ethylene propylene diene monomer rubber, carbon black, modified talcum powder, fabric rubber powder, paraffin oil, epoxidized soybean oil, zinc oxide, an anti-aging agent, stearic acid, petroleum resin and phenolic tackifying resin into an internal mixer or an open mill for plastication and mixing to obtain rubber compound;

(2) Placing the mixed rubber placed for 36-48 hours in an internal mixer or an open mill, sequentially adding triallyl isocyanurate, dibenzoyl peroxide and sulfur, uniformly mixing to obtain vulcanized mixed rubber, standing for 12-36 hours at room temperature, and vulcanizing by a vulcanizing machine to obtain an ethylene propylene diene monomer rubber material;

the vulcanizing temperature is 160-200 ℃, the vulcanizing time is 15-30 min, and the vulcanizing pressure is 16-20 MPa.

5. The application of the ethylene propylene diene monomer material prepared by the preparation method according to claim 4 in a mechanical arm clamping jaw of an automatic optical fiber wire drawing machine.