阅读说明：本技术 管道复合耐磨功能层、耐磨管道内壁及其制作方法 (Pipeline composite wear-resistant functional layer, wear-resistant pipeline inner wall and manufacturing method thereof ) 是由 张永华 黄其忠 胡中永 于 2020-07-03 设计创作，主要内容包括：本发明涉及管道复合耐磨功能层及耐磨管道内壁。管道复合耐磨功能层的特征：以管道内壁表面为内侧依次向复合有多向编织纤维布耐磨增强层和轴向编织纤维布耐磨增强层；所述多向编织纤维布耐磨增强层是由多向编织纤维布经树脂浸渍复合而成；所述轴向编织纤维布耐磨增强层是由轴向编织纤维布经树脂浸渍复合而成；耐磨管道内壁特征：由耐磨功能层、防渗层和纤维结构层组织构成的一体增强耐磨内壁。特点耐磨、抗渗、高强度、刚度、耐腐蚀,从而提高玻璃钢管道的使用寿命。(The invention relates to a composite wear-resistant functional layer of a pipeline and a wear-resistant pipeline inner wall. The composite wear-resistant functional layer of the pipeline is characterized in that: a multidirectional woven fiber cloth wear-resistant reinforcing layer and an axial woven fiber cloth wear-resistant reinforcing layer are sequentially compounded with the surface of the inner wall of the pipeline as the inner side; the multi-directional woven fiber cloth wear-resistant reinforcing layer is formed by impregnating and compounding multi-directional woven fiber cloth with resin; the axial woven fiber cloth wear-resistant reinforcing layer is formed by impregnating and compounding axial woven fiber cloth with resin; the characteristics of the inner wall of the wear-resistant pipeline are as follows: the integral reinforced wear-resistant inner wall is composed of a wear-resistant functional layer, an impermeable layer and a fiber structure layer. It features high antiwear, impervious, strength, rigidity and anticorrosion nature, so elongating service life of glass fibre reinforced plastic pipeline.)

1. The pipeline composite wear-resistant functional layer is characterized in that a multidirectional woven fiber cloth wear-resistant reinforcing layer and an axial woven fiber cloth wear-resistant reinforcing layer are sequentially compounded outwards through resin impregnation by taking the surface of the inner wall of the pipeline as the inner side;

the multi-directional woven fiber cloth wear-resistant reinforcing layer is formed by impregnating and compounding multi-directional woven fiber cloth with resin;

the axial woven fiber cloth wear-resistant reinforcing layer is formed by impregnating and compounding axial woven fiber cloth with resin;

the resin is pre-crosslinked cured mixed wear-resistant micro-powder resin formed by mixing hydrophobic gas silicon, silicon carbide micro-powder and bisphenol A vinyl resin;

silicon carbide micropowder is attached to the fiber gaps of the multi-directional woven fiber cloth and the axial woven fiber cloth which are impregnated with resin, and a silicon carbide micropowder layer is formed by attaching the upper surface and the lower surface of the multi-directional woven fiber cloth and the axial woven fiber cloth which are impregnated with resin.

2. The pipe composite wear resistant functional layer according to claim 1,

the multidirectional woven fiber cloth is glass fiber multidirectional woven cloth or carbon fiber multidirectional woven cloth, and the cloth layer is designed into 1-2 layers;

the axial woven fiber cloth is glass fiber axial cloth or carbon fiber axial cloth, the weaving form is uniaxial cloth or biaxial cloth, and the cloth layer is designed to be 2-10 layers.

3. The manufacturing method of the composite wear-resistant functional layer of the pipeline is characterized by comprising the following steps of:

the method comprises the following steps: preparation of resin mixed with hydrophobic gas-silicon

Adding hydrophobic gas-silicon into the bisphenol A vinyl resin, wherein the addition amount of the hydrophobic gas-silicon is 1.1-1.9% of the mass fraction of the bisphenol A vinyl resin, and fully and uniformly stirring;

step two: resin for preparing mixed wear-resistant silicon carbide micro powder

Adding silicon carbide micro powder into bisphenol A vinyl resin mixed with hydrophobic gas silicon, wherein the adding amount of the silicon carbide micro powder is 9-27% of the mass fraction of the bisphenol A vinyl resin, fully stirring, sequentially adding an accelerator inwards, uniformly stirring, adding a curing agent, and uniformly stirring to obtain pre-crosslinked cured mixed wear-resistant micro powder resin;

step three: impregnating and compounding

Fully soaking each layer of reinforced fiber cloth in 30-40 minutes to enable silicon carbide micro powder to be uniformly attached to the upper surface and the lower surface of the cloth, paving the cloth layer by layer, flattening the surface of each layer by using a grinding roller, removing bubbles between layers, and forming a composite wear-resistant functional layer of the fiber-reinforced, silicon carbide micro powder-reinforced and hydrophobic gas-silicon-reinforced multiphase reinforced double three-dimensional reticular crosslinked copolymer plastic after the resin is cured after the paving of each layer of cloth is finished;

the impregnation requirements of the reinforced fiber cloth and the mixed wear-resistant micro-powder resin are as follows: and (3) impregnating each layer of the reinforced fiber cloth with resin layer by layer according to a compounding sequence, wherein after the resin is fully impregnated, the silicon carbide micro powder with relatively small mesh number in the resin permeates gaps of the reinforced fiber cloth, so that the wear resistance between the fiber cloth is fully improved, and the silicon carbide micro powder with relatively large mesh number is attached to the upper surface layer and the lower surface layer of the reinforced fiber cloth to form a resin micro powder layer.

4. The method for manufacturing the composite wear-resistant functional layer of the pipeline according to claim 3, wherein the method comprises the following steps:

the particle size of the hydrophobic gas silicon is 12-16 nm;

the Mohs hardness of the silicon carbide micro powder is more than 9.2;

the silicon carbide micro powder comprises 100 meshes of silicon carbide micro powder, and the mass ratio of the silicon carbide micro powder is 60-70%, and the silicon carbide micro powder comprises 200 meshes of silicon carbide micro powder, and the mass ratio of the silicon carbide micro powder is 30-40%.

5. The method for manufacturing the composite wear-resistant functional layer of the pipeline according to claim 3, wherein the method comprises the following steps:

the content of the resin impregnated in the reinforced fiber cloth is 50% +/-2.5%;

the thickness of the composite wear-resistant functional layer is 1.8-8.8 mm.

6. The method for manufacturing the composite wear-resistant functional layer of the pipeline according to claim 3, wherein the method comprises the following steps:

the reinforced fiber cloth comprises 1-2 layers of multidirectional woven fiber cloth and 2-10 layers of axial woven fiber cloth;

the multidirectional woven fiber cloth is made of glass fibers or carbon fibers;

the axial woven fiber cloth is uniaxial cloth or biaxial cloth, and the material of the axial woven fiber cloth is glass fiber or carbon fiber.

7. The inner wall of the wear-resistant pipeline is characterized by comprising a wear-resistant functional layer, an impermeable layer and a fiber structure layer;

the wear-resistant functional layer is a multiphase reinforced double three-dimensional reticular cross-linked copolymer plastic formed by impregnating 1-2 layers of multidirectional woven fiber cloth and multiple layers of axial woven fiber cloth with bisphenol A vinyl resin premixed with hydrophobic gas silicon and silicon carbide;

the anti-seepage layer is formed on the wear-resistant functional layer, and the resin-rich reinforced plastic layer is prepared by crosslinking reaction of a stitch-bonded felt serving as a reinforcing material and hydrophobic gas silicon serving as a reinforcing material with resin;

the fiber structure layer is formed on the outer surface of the impermeable layer, and the reinforced plastic layer is prepared by reacting continuous glass fiber yarn bundles as a reinforced material, a hydrophobic gas-silicon reinforced material and resin.

8. A wear-resistant pipe inner wall as claimed in claim 7,

the impermeable layer is manufactured by fully soaking a stitch-bonded felt wound on the outer surface of the wear-resistant functional layer into silicon resin containing hydrophobic gas and curing, wherein the resin content is 70% +/-2.5%;

the content of the hydrophobic gas silicon in the resin is 0.8-1.1%;

the thickness of the impermeable layer is more than 1.2mm, and the composite stitch-bonded felt is controlled to be not less than 3 layers;

the stitch-bonded felt contains warp yarns and weft yarns in a certain proportion, so that the felt layer has certain strength in the warp and weft directions, and the strength requirement and the process manufacturing requirement during felt layer manufacturing are ensured.

9. A wear-resistant pipe inner wall as claimed in claim 7,

the continuous glass fiber yarn bundle of the fiber structure layer is fully impregnated with the silicon resin containing hydrophobic gas, then a layer of the continuous glass fiber yarn bundle is wound outside the anti-seepage layer in a ring winding mode, then the continuous glass fiber yarn bundle is wound for one circle in a spiral cross winding mode, and then the continuous glass fiber yarn bundle is wound for one circle in a ring winding mode, and the alternate winding is carried out until the designed layer number and thickness requirements are met;

the glass fiber yarn bundle is coiled continuous fiber, and the amount of the impregnated resin is basically constant, namely 40% +/-2.5%, so that the mechanical property of the wall layer of the pipeline is good, and the wall layer becomes a fiber structure layer;

the content of the hydrophobic gas silicon in the resin is 0.7-0.9%.

10. The manufacturing method of the wear-resistant pipeline inner wall is characterized by comprising the following specific steps:

the method comprises the following steps: making wear-resistant functional layers

Preparing resin mixed with hydrophobic gas-silicon, adding the hydrophobic gas-silicon into bisphenol A vinyl resin, wherein the addition amount of the hydrophobic gas-silicon is 1.1-1.9% of the mass fraction of the bisphenol A vinyl resin, and mechanically stirring for more than 10 minutes to fully and uniformly stir;

preparing resin mixed with wear-resistant silicon carbide micropowder, adding the silicon carbide micropowder into bisphenol A vinyl resin containing hydrophobic gas, wherein the addition amount of the silicon carbide micropowder is 9-27% of the mass fraction of the bisphenol A vinyl resin, fully stirring, sequentially adding an accelerator, uniformly stirring, adding a curing agent, and uniformly stirring to obtain the resin pre-crosslinked and cured mixed with the wear-resistant micropowder;

impregnating and compounding, namely fully impregnating each layer of reinforced fiber cloth within 30-40 minutes by using the pre-crosslinked cured mixed wear-resistant micro-powder resin prepared in the first step and the second step to enable the silicon carbide micro-powder to be uniformly attached to the upper surface and the lower surface of the cloth, paving the cloth layer by layer, rolling the surface of each layer by using a roller, removing bubbles between the layers, finishing paving each layer of cloth, and forming a wear-resistant functional layer of the fiber-reinforced, silicon carbide micro-powder-reinforced and hydrophobic gas-silicon-reinforced multiphase-reinforced double-three-dimensional reticular crosslinked copolymer plastic after the resin is cured;

the impregnation requirements of the reinforced fiber cloth and the mixed wear-resistant micro-powder resin are as follows: impregnating each layer of reinforced fiber cloth with resin layer by layer according to a compounding sequence, wherein after the resin is fully impregnated, silicon carbide micro powder with relatively small mesh number in the resin permeates gaps of the reinforced fiber cloth, so that the wear resistance between fiber layers is fully improved, and the silicon carbide micro powder with relatively large mesh number is attached to the upper surface layer and the lower surface layer of the reinforced fiber cloth to form a resin micro powder layer;

step two: making a barrier layer

The impermeable layer is prepared by fully soaking the stitch-bonded felt wound on the outer surface of the composite wear-resistant functional layer into the silicone resin containing hydrophobic gas and curing; 3 layers of stitch-bonded felts, wherein the resin content is 70% +/-2.5%;

the content of the hydrophobic gas silicon in the resin is 0.8-1.1%;

the thickness of the anti-seepage layer is more than 1.2mm, and the composite stitch-bonded felt is controlled to be not less than 3 layers, so that the anti-seepage effect is ensured;

step three: making a fibrous structure layer

The continuous glass fiber yarn bundle of the fiber structure layer is fully impregnated with the silicon resin containing hydrophobic gas, then a layer of the continuous glass fiber yarn bundle is wound outside the anti-seepage layer in a ring winding mode, then the continuous glass fiber yarn bundle is wound for one circle in a spiral cross winding mode, and then the continuous glass fiber yarn bundle is wound for one circle in a ring winding mode, and the alternate winding is carried out until the designed layer number and thickness requirements are met;

the content of the hydrophobic gas silicon in the resin is 0.7-0.9%.

Technical Field

The invention relates to a composite wear-resistant functional layer of a pipeline, a wear-resistant pipeline inner wall and a manufacturing method thereof, and belongs to the technical field of pipelines and manufacturing methods.

Background

The glass fiber reinforced plastic pipeline is characterized by designability, convenient molding, good corrosion resistance, low weight, long service life and the like, and is currently applied to the field of fluid transportation. But because of the lower wear resistance, the pipe is mostly applied to petrochemical pipelines with medium and small pipe diameters and used for conveying pure fluid, the design of the pipeline does not need to pay attention to the wear resistance of the pipe wall, the strength requirement of the pipeline is met, the material of the pipeline meets the anti-corrosion requirement, and the manufacture meets the anti-seepage requirement.

For conveying fluid containing solid matters, such as fluid containing sand, stone and other impurities, the solid particles can generate abrasion on the pipe wall under the driving of the fluid, damage the pipe wall and shorten the service life of the pipeline, so that the pipe wall with an abrasion-resistant function is required to be adopted to ensure the safe use of the pipeline.

The initial pipeline is subjected to the impact of hydraulic head generated by the pressurization of the liquid. The turbulent water flow at the inlet and the outlet of the pipeline has stronger impact force and vortex force, thus threatening the safety of the pipeline. When the pump runs at high speed, cavitation erosion phenomenon can be generated, and cavitation erosion can bring different damages to a pump shell, an impeller and a pipeline. The damage of a plurality of liquid pumps and vanes is seen as honeycomb, the pipe wall is worn as thin as paper, and the local wear of the pipe wall is also seen to reach 2-3 mm even in a stainless steel pipeline used for several years. Pumps used for a period of time may also cavitate due to wear, posing a threat to pipeline safety.

Hydraulic engineering pipelines and town flood discharge drainage pipelines are all centuries engineering, and water flow contains much silt, gravel and sundries and severely wears the pipelines, so that wear-resistant pipelines must be developed.

The composite wear-resistant functional layer is a multi-phase composite material, and not only has stronger wear-resistant performance, but also has enough strength and rigidity, so that the service life of the glass fiber reinforced plastic pipeline is prolonged.

In order to improve pipeline resistance to wear, shock resistance and bulk strength to make it have stronger toughness, prevent the fracture, this application provides a pipeline compound wear-resisting functional layer and wear-resisting pipeline inner wall.

Disclosure of Invention

The invention aims to provide a composite wear-resistant functional layer of a pipeline and a manufacturing method thereof, and aims to provide a wear-resistant pipeline inner wall and a manufacturing method thereof so as to solve the problem of wear resistance of large and medium pipelines, particularly pipelines for conveying fluid containing gravel and impurities.

In order to solve the problems, the technical scheme adopted by the invention is as follows:

the pipeline composite wear-resistant functional layer is characterized in that a multidirectional woven fiber cloth wear-resistant reinforcing layer and an axial woven fiber cloth wear-resistant reinforcing layer are sequentially compounded outwards through resin impregnation by taking the surface of the inner wall of the pipeline as the inner side;

the multidirectional woven fiber cloth wear-resistant reinforcing layer is formed by impregnating and compounding 1-2 layers of multidirectional woven fiber cloth with resin;

the axial woven fiber cloth wear-resistant reinforcing layer is formed by impregnating and compounding 2-10 layers of axial woven fiber cloth with resin;

the resin is pre-crosslinked cured mixed wear-resistant micro-powder resin formed by mixing hydrophobic gas silicon, silicon carbide micro-powder and bisphenol A vinyl resin. The bisphenol A vinyl resin forms an insoluble and infusible three-dimensional network crosslinking structure after free radical curing crosslinking reaction, has better mechanical property, chemical stability and toughness, and has corrosion resistance and hydrolysis resistance. Hydrophobic fumed silica (called hydrophobic fumed silica for short) has the functions of thickening, thixotropic property, reinforcing and wear resistance to resin. A three-dimensional network structure is formed by forming hydrogen bonds between hydroxyl on the surface of the hydrophobic silicon gas and resin, monomer silicon carbide, glass fiber and silicon gas. Besides surface hydroxyl, hydrophobic gas silicon mainly forms a three-dimensional network structure by winding modified alkyl groups on the surface of the gas silicon. Therefore, the composite wear-resistant functional layer is a fiber-reinforced, silicon carbide-reinforced, hydrophobic gas-silicon-reinforced double three-dimensional network cross-linked copolymerization structure plastic after being formed. The silicon carbide micro powder is used as a wear-resistant reinforcing material, and the Mohs hardness of the silicon carbide micro powder is more than 9.2.

In the resin impregnation process, the silicon carbide micro powder with relatively small particle size permeates and adheres to the fiber gaps of the multidirectional woven fiber cloth and the axial woven fiber cloth along with the impregnation of resin, and the silicon carbide micro powder with relatively large particle size adheres to the upper surface and the lower surface of the multidirectional woven fiber cloth and the axial woven fiber cloth after the resin impregnation, and forms a silicon carbide micro powder layer after the solidification.

The multi-directional woven fiber cloth is glass fiber multi-directional woven cloth or carbon fiber multi-directional woven cloth; the axial woven fiber cloth is glass fiber axial cloth or carbon fiber axial cloth, and the weaving mode is uniaxial cloth and biaxial cloth.

The thickness of the composite wear-resistant functional layer of the pipeline is determined by wear-resistant design requirements and the service life, and is generally designed to be 1.8-8.8 mm.

The multi-directional woven fiber cloth and the axial woven fiber cloth are all made of carbon fiber woven materials, and the formed composite wear-resistant layer is carbon + silicon carbide special multi-phase reinforced plastic and has the characteristics of high strength, high hardness, wear resistance and high temperature resistance. The strength, wear resistance and high temperature resistance of the pipeline can be greatly improved, and the service life of the pipeline is prolonged. The high-temperature-resistant pipeline is suitable for pipelines which have high conveying flow speed and large impact and are provided with more fluid such as gravel and stones, and is also suitable for high-temperature-resistant pipelines.

The composite wear-resistant functional layer of the pipeline is basically characterized in that: the multi-phase reinforced double-three-dimensional network crosslinked copolymer plastic is prepared by reacting 1-2 layers of multidirectional woven fiber cloth and 2-10 layers of axial woven fiber cloth containing hydrophobic gas silicon and silicon carbide resin with silicon carbide micro powder (fine particles) attached to the surfaces of the fibers.

The physical characteristics of the formed wear-resistant functional layer are insoluble and infusible double three-dimensional reticular fibers, silicon carbide and hydrophobic gas-silicon multiphase reinforced cross-linked copolymer structural plastics, and the wear-resistant functional layer has the characteristics of high hardness, high strength, wear resistance and temperature resistance.

The manufacturing method of the composite wear-resistant functional layer of the pipeline is characterized by comprising the following steps of:

the method comprises the following steps: preparation of resin mixed with hydrophobic gas-silicon

Adding hydrophobic gas-silicon into the bisphenol A vinyl resin, wherein the addition amount of the hydrophobic gas-silicon is 1.1-1.9% of the mass fraction of the bisphenol A vinyl resin, and fully and uniformly stirring.

The particle size of the hydrophobic gas silicon is 12-16 nm.

Step two: resin for preparing mixed wear-resistant silicon carbide micro powder

Adding silicon carbide micro powder into bisphenol A vinyl resin mixed with hydrophobic gas silicon, wherein the adding amount of the silicon carbide micro powder is 9-27% of the mass fraction of the bisphenol A vinyl resin, fully stirring, sequentially adding an accelerator inwards, uniformly stirring, adding a curing agent, and uniformly stirring to obtain pre-crosslinked cured mixed wear-resistant micro powder resin;

the Mohs hardness of the silicon carbide micro powder is more than 9.2;

the silicon carbide micro powder comprises 100 meshes of silicon carbide micro powder, and the mass ratio of the silicon carbide micro powder is 60-70%, and the silicon carbide micro powder comprises 200 meshes of silicon carbide micro powder, and the mass ratio of the silicon carbide micro powder is 30-40%.

Step three: impregnating and compounding

Fully soaking each layer of reinforced fiber cloth in 30-40 minutes to enable silicon carbide micro powder to be uniformly attached to the upper surface and the lower surface of the cloth, paving the cloth layer by layer, flattening the surface of each layer by using a grinding roller, removing bubbles between layers, and after the paving of each layer of cloth is finished, curing the resin to form the fiber-reinforced, silicon carbide micro powder-reinforced and hydrophobic gas-silicon reinforced multiphase reinforced double three-dimensional reticular crosslinked copolymer plastic composite wear-resistant functional layer.

The impregnation requirements of the reinforced fiber cloth and the mixed wear-resistant micro-powder resin are as follows: and (3) impregnating each layer of the reinforced fiber cloth with resin layer by layer according to a compounding sequence, wherein after the resin is fully impregnated, the silicon carbide micro powder with relatively small mesh number in the resin permeates gaps of the reinforced fiber cloth, so that the wear resistance between fiber layers is fully improved, and the silicon carbide micro powder with relatively large mesh number is attached to the upper surface layer and the lower surface layer of the reinforced fiber cloth to form a resin micro powder layer.

The content of the impregnated resin of the reinforced fiber cloth is 50% + -2.5%, wherein the resin content 50% is a mass ratio, and is a ratio of the mass of the resin after forming to the mass of an object.

The reinforced fiber cloth comprises 1-2 layers of multidirectional woven fiber cloth and 2-10 layers of axial woven fiber cloth; the multi-directional woven fiber cloth material can be glass fiber or carbon fiber; the axial woven fiber cloth adopts uniaxial cloth and biaxial cloth, and can be glass fiber axial cloth or carbon fiber axial cloth according to different material selections.

The thickness of the composite wear-resistant functional layer is designed according to the difference of the condition, the flow speed, the pipe diameter and the pressure of a fluid medium, and the general thickness is set to be 1.8-8.8 mm.

The inner wall of the wear-resistant pipeline is characterized by comprising a wear-resistant functional layer, an impermeable layer and a fiber structure layer;

the wear-resistant functional layer is formed by compounding resin with 1-2 layers of multidirectional woven fiber cloth layers and 2-10 layers of axial woven fiber cloth layers; hard silicon carbide micro powder is attached to the fiber gaps of each layer of the multidirectional woven fiber cloth along with resin impregnation, and hard silicon carbide micro powder film layers are attached to the upper surface and the lower surface of the cloth along with resin impregnation; hard silicon carbide powder is also attached to the fiber gaps of each layer of the axially woven fiber cloth along with resin impregnation, the hard silicon carbide powder is also attached to the upper surface and the lower surface of the cloth along with resin impregnation, and the cloth, the hydrophobic gas silicon and the resin are solidified to form an insoluble and infusible multiphase reinforced double three-dimensional network cross-linked structure plastic body which has high hardness, high strength, wear resistance and temperature resistance.

The anti-seepage layer is formed on the composite wear-resistant functional layer, and the resin-rich reinforced plastic layer is prepared by crosslinking reaction of a stitch-bonded felt serving as a reinforcing material and hydrophobic gas silicon serving as a reinforcing material with resin;

the impermeable layer is prepared by fully soaking the stitch-bonded felt wound on the outer surface of the wear-resistant functional layer in the silicon resin containing hydrophobic gas and curing. 3 layers of the stitch-bonded felt, wherein the resin content is 70% +/-2.5%, and the resin content is 70% of the mass percentage of a formed object and resin. The resin-rich quantity contained in the felt is used for preventing the leakage of the pipeline due to the pinholes and microgaps possibly existing on the inner wall and the outer wall of the pipeline.

The content of the hydrophobic gas silicon in the resin is 0.8-1.1%.

The thickness of the anti-seepage layer is larger than 1.2mm, the stitch-bonded felt is controlled to be not less than 3 layers, and the anti-seepage effect is ensured.

The stitch-bonded felt contains warp yarns and weft yarns in a certain proportion, so that the felt layer has certain strength in the warp and weft directions, and the strength requirement and the process manufacturing requirement during felt layer manufacturing are ensured.

The fiber structure layer is formed on the outer surface of the impermeable layer, and the reinforced plastic layer is prepared by reacting continuous glass fiber yarn bundles as a reinforced material, a hydrophobic gas-silicon reinforced material and resin.

The continuous glass fiber yarn bundle of the fiber structure layer is fully impregnated with the hydrophobic gas-containing silicon resin, then the continuous glass fiber yarn bundle is wound outside the anti-seepage layer in a ring winding mode, and then the continuous glass fiber yarn bundle is wound in a spiral cross winding mode for one circle, and then the continuous glass fiber yarn bundle is wound in a ring winding mode for one circle, and the alternate winding is carried out until the designed layer number and thickness requirements are met. The total number of winding layers of the yarn bundle layers and the spiral angle of the spirally and crossly wound yarn bundles are comprehensively determined according to design parameters such as pipeline pressure, diameter and working condition, so that the inner wall is ensured to have reasonable comprehensive performance, the complex, alternating and long-term fluid hydraulic impact action is resisted, and the fatigue resistance of the pipeline is improved.

Glass fiber yarn bundles are coiled continuous fibers, and can be up to about 300 meters long. Usually, dozens of rolls of fiber yarn bundles can complete winding of one layer of pipe wall at one time, and joints are few. The amount of the impregnated resin is basically constant about 40% +/-2%, so that the wall layer of the pipeline has good mechanical properties and becomes a fiber structure layer.

The content of the hydrophobic gas silicon in the resin is 0.7-0.9%.

The composite wear-resistant functional layer of the pipeline is a multi-phase composite material, has strong wear resistance and enough strength and rigidity, and thus the service life of the glass fiber reinforced plastic pipeline is prolonged. The resin is an insoluble and infusible three-dimensional network crosslinking structure resin which can be formed after free radical curing crosslinking reaction. Hydrophobic gas silicon is added into the resin, and a three-dimensional network structure can be formed by forming hydrogen bonds between hydroxyl on the surface of the gas silicon and the resin, the monomer and the gas silicon. Besides hydroxyl on the gas surface, hydrophobic gas silicon can also form a three-dimensional network structure by winding modified alkyl on the gas surface, so that a double three-dimensional network copolymerization structure is formed. The physical property of the formed wear-resistant layer is insoluble and infusible double three-dimensional reticular fiber, gas silicon and silicon carbide multiphase reinforced cross-linked copolymer structural plastic, and the formed wear-resistant layer has the characteristics of high hardness, high strength, wear resistance and temperature resistance. Compared with the common glass fiber reinforced plastic, the wear resistance of the inner wall of the pipeline with the composite material wear-resistant functional layer is improved by thousands of times. In the test, the wear-resistant pipe shell wall plate can grind reinforced cement, granite and steel. If the carbon fiber is selected as the fiber cloth, the wear resistance of the fiber cloth is improved by nearly ten thousand times compared with the common glass fiber reinforced plastic. The strength of the inner wall of the pipeline is about 3 times that of the common glass fiber reinforced plastic pipeline. The resin is bisphenol A vinyl resin. The resin forms insoluble and infusible three-dimensional network cross-linked structures after free radical curing cross-linking reaction. And the hydrophobic gas silicon added into the resin has the functions of thickening, thixotropic property, reinforcing and wear resistance to the resin. And hydrogen bonds are formed by hydroxyl on the surface of the gas silicon, resin, fiber and silicon carbide to form a three-dimensional network structure. The hydrophobic gas-silicon mainly depends on winding modified alkyl groups on the surface of the gas-silicon to form a three-dimensional network structure. The inner wall of the formed pipeline has good tissue layer integrity, better mechanical property, chemical stability and toughness, and corrosion resistance and hydrolysis resistance. Therefore, the service life of the pipeline is 5-7 times of that of common glass fiber reinforced plastic. The method is suitable for manufacturing large hydraulic engineering pipelines, large urban flood discharge water pipelines and gravel crushed stone conveying pipelines for dredging river and seabed. When the carbon fiber is selected as the fiber, the high-temperature resistant pipeline can also be manufactured.

Drawings

FIG. 1: the structural diagram of the composite wear-resistant functional layer of the first embodiment;

FIG. 2: the layered structure of the inner wall of the wear-resistant pipeline in the fourth embodiment is shown;

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings.