阅读说明：本技术 一种复合材料格栅制品及其制备方法 (Composite material grid product and preparation method thereof ) 是由 张薇 宋寒 刘建叶 陈阳 陈娜 邢宽 于 2021-11-15 设计创作，主要内容包括：本发明提供一种复合材料格栅制品及其制备方法,制备方法包括如下步骤：S1、将高强纤维与耐烧蚀纤维制成短切纤维并混合,然后与树脂材料进行混合,得到预混料；S2.将高强纤维与耐烧蚀纤维混合,并浸渍树脂材料,然后裁剪成需要长度的纤维,得到预浸料；S3.安装模具,根据铺料设计在模具中装填步骤S1的预混料和步骤S2的预浸料；S4.对步骤S3中的材料进行固化成型,得到复合材料格栅制品。本发明的复合材料格栅制品及其制备方法可以解决现有技术中的复合材料格栅制品成型方法得到的制品承载强度、均匀性较差、耐热性能不佳的技术问题。(The invention provides a composite material grid product and a preparation method thereof, wherein the preparation method comprises the following steps: s1, preparing chopped fibers from the high-strength fibers and the ablation-resistant fibers, mixing the chopped fibers and the ablation-resistant fibers, and mixing the chopped fibers and the resin material to obtain a premix; s2, mixing high-strength fibers and ablation-resistant fibers, impregnating the mixture with a resin material, and cutting the mixture into fibers with required lengths to obtain a prepreg; s3, installing a mold, and filling the premix of the step S1 and the prepreg of the step S2 in the mold according to the paving design; s4, curing and molding the material in the step S3 to obtain the composite material grid product. The composite material grid product and the preparation method thereof can solve the technical problems of poor bearing strength, poor uniformity and poor heat resistance of the product obtained by the composite material grid product forming method in the prior art.)

1. A method of making a composite grid article comprising the steps of:

s1, preparing chopped fibers from the high-strength fibers and the ablation-resistant fibers, mixing the chopped fibers and the ablation-resistant fibers, and mixing the chopped fibers and the resin material to obtain a premix;

s2, mixing the high-strength fibers with the ablation-resistant fibers, impregnating the mixture with a resin material, and cutting the mixture into fibers with required length to obtain prepreg;

s3, installing a mould, and filling the premix material in the step S1 and the prepreg material in the step S2 in the mould according to the paving design;

s4, curing and molding the material in the step S3 to obtain the composite material grid product.

2. A method of making a composite grid article according to claim 1, wherein:

the length of the chopped fibers in the step S1 is 15-30 mm; the mass ratio of the high-strength fibers to the ablation-resistant fibers is 1: (0.5-2); in the premix, the mass content of the resin material is 36-44%.

3. A method of making a composite grid article according to claim 1, wherein:

the length of the fiber cut in the step S2 is more than or equal to 400 mm; the mass ratio of the high-strength fibers to the ablation-resistant fibers is 3: (1-3); in the premix, the mass content of the resin material is 36-44%.

4. A method of making a composite grid article according to claim 1, wherein:

in step S3, prepreg is filled in the middle force bearing position of the grid product in the mold, and premix is filled in the whole grid product.

5. A method of making a composite grid article according to claim 1, wherein:

in step S4, the curing molding system is: the pressure is 30-40 MPa; the heating rate is 5-15 ℃/30 min; the temperature is 150 ℃ and 170 ℃; the heat preservation time t = a × d, a is 5-10min/mm, and d is the thickness of the composite material grid product.

6. A method of making a composite grid article according to claim 1, wherein:

in the step S3, preheating a mold, the premix in the step S1 and the prepreg in the step S2 before filling the premix and the prepreg, wherein the preheating time is not more than 30min, and the preheating temperature of the mold is 100-110 ℃; the preheating temperature of the premix and the prepreg is 90-100 ℃.

7. A method of making a composite grid article according to claim 1, further comprising:

s5, after the solidification and the molding are carried out in the step S4, the temperature of the mold is reduced to be below 60 ℃, and the demolding is carried out to obtain the composite material grid product.

8. A method of making a composite grid article according to claim 1, wherein:

in step S3, after the premix and the prepreg are filled, the premix and the prepreg are pre-compacted by using an auxiliary tool, and then the premix is added to a position where the amount of the premix is small.

9. A method for manufacturing a composite grid article according to claim 8, wherein a release agent is further applied to a lower mold of said mold before filling said pre-mixed material and said pre-impregnated material in step S3, and a release agent is applied to an upper mold of said mold after said pre-compacting and before completion of mold closing.

10. A composite grid article produced by the method of producing a composite grid article according to any one of claims 1 to 9.

Technical Field

The invention belongs to the technical field of composite material molding, and particularly relates to a composite material grid product and a preparation method thereof.

Background

In the prior art, the product obtained by the composite material grid product forming method has poor heat resistance, low strength, low density and poor uniformity. For example, chinese patent document CN10508255A discloses a method for manufacturing a grid, in which a fiber prepreg is first laid in a mold, a resin is injected into a closed space formed by the mold, the mold is cured, and finally the mold is released. In the processes of resin injection and resin curing, the distribution of the resin in the mold is not uniform due to the self gravity factor, gaps even exist between some positions and the mold, and the density of the obtained product is low due to the resin injection. Therefore, when a grid product with higher requirements on load-bearing strength and uniformity needs to be formed, the requirements are often not met.

Firstly, for the strength performance of a composite material grid product, the premix is mainly prepared by mixing chopped fibers, resin and a solvent, and as the chopped fibers are in a non-end state, the fibers exist in all aspects, the strength is relatively uniform, but the fiber length is short, the reinforcing effect per se is limited, the bearing requirement cannot be met by only reinforcing the severely stressed part by the chopped fibers in the using process, the hollow structure is simply made by reinforcing the chopped fibers, the bearing strength is low, and the product is easy to damage; the prepreg is prepared by mixing long fibers, resin and a solvent, the long fibers ensure the continuity of the fiber strength and the high strength, but due to the shape limitation of a grid-shaped product, the prepreg is completely adopted, the formability is poor, the phenomenon of material shortage is easy to occur, the local strength is low, in addition, the fiber has high strength only in the continuous direction, the layers are connected only by the resin, the strength is low, and the requirements are difficult to meet by using the prepreg only.

Secondly, the type of fiber also has an important influence on the strength and heat resistance of the product. Compared with the ablation-resistant fiber, the high-strength fiber has the silicon dioxide content of about 75 percent, the ablation-resistant fiber has the silicon dioxide content of more than 96 percent, the heat resistance of the ablation-resistant fiber is superior to that of the high-strength fiber, but the strength performance is poor, and the strength of the high-strength fiber is higher than that of the ablation-resistant fiber, but the ablation resistance performance is poor.

In view of the above, a method for preparing a composite material grid product is needed to obtain a composite material grid product with high bearing strength, high uniformity and good heat resistance.

Disclosure of Invention

The invention aims to provide a composite material grid product and a preparation method thereof, and aims to solve the technical problems of poor bearing strength, poor uniformity and poor heat resistance of the product obtained by the composite material grid product forming method in the prior art.

In order to solve the above problems, an aspect of the present invention provides a method of manufacturing a composite grid article, comprising the steps of:

s1, preparing chopped fibers from the high-strength fibers and the ablation-resistant fibers, mixing the chopped fibers and the ablation-resistant fibers, and mixing the chopped fibers and the resin material to obtain a premix;

s2, mixing the high-strength fibers with the ablation-resistant fibers, impregnating the mixture with a resin material, and cutting the mixture into fibers with required length to obtain prepreg;

s3, installing a mould, and filling the premix material in the step S1 and the prepreg material in the step S2 in the mould according to the paving design;

s4, curing and molding the material in the step S3 to obtain the composite material grid product.

Because the grid product has a special structure and a hollow structure, the conventional method of firstly paving the reinforcing material and then injecting the resin is adopted, and the resin is unevenly distributed in the mould due to the self gravity factor, so that the density of the product is low and the strength performance is poor. The method for preparing the composite material grid product adopts a compression molding method combining the chopped fiber premix and the long fiber prepreg, the premix is prepared by mixing the chopped fibers, the resin and the solvent, and because the chopped fibers are in a non-end state and have fibers in all aspects, the strength is relatively uniform, the strength of the whole product can be ensured to be uniform, and the phenomenon of material shortage of the product is prevented; the prepreg is prepared by mixing long fibers, resin and a solvent, the long fibers can ensure the continuity of the fiber strength, the strength is high, and the parts of the product with serious stress can further meet the bearing requirements. In addition, the invention adopts the mixture of the high-strength fiber and the ablation-resistant fiber as the reinforcing material, the ablation-resistant fiber provides good ablation-resistant performance for the product, and the high-strength fiber provides good strength performance for the product, so that the prepared product can meet the double requirements of heat resistance and strength.

Wherein, the high-strength fiber can be high-strength carbon fiber, high-strength aramid fiber and high-strength glass fiber; the ablation-resistant fibers may be ablation-resistant carbon fibers, ablation-resistant quartz fibers, ablation-resistant high silica fibers. The high-strength fiber is preferably high-strength glass fiber; the ablation resistant fibers are preferably ablation resistant high silica fibers.

Among them, the resin material is preferably a phenol resin.

Preferably, the length of the chopped fibers in the step S1 is 15-30 mm; the mass ratio of the high-strength fibers to the ablation-resistant fibers is 1: (0.5-2); more preferably, the mass ratio of the high-strength fibers to the ablation-resistant fibers is 1: 1; in the premix, the mass content of the resin material is 36-44%.

Preferably, the length of the fiber cut in the step S2 is more than or equal to 400 mm; the mass ratio of the high-strength fibers to the ablation-resistant fibers is 3: (1-3); more preferably, the mass ratio of the high strength fibers to the ablation resistant fibers is 3: 2; in the premix, the mass content of the resin material is 36-44%.

Because the content of silicon dioxide in the high-strength fiber is about 75 percent, and the content of silicon dioxide in the ablation-resistant fiber is more than 96 percent, the heat resistance of the ablation-resistant fiber is better than that of the high-strength fiber but the strength is poor, and the strength of the high-strength fiber is higher than that of the ablation-resistant fiber but the heat resistance is poor. Through repeated experiments, the invention discovers that the product has high strength and high heat resistance and the best comprehensive performance when the proportion of the high-strength fiber and the ablation-resistant fiber is adopted.

Preferably, in step S3, the prepreg is filled in the middle load-bearing position of the grid product in the mold, and the whole grid product is filled with the premix.

Preferably, in step S4, the curing molding system is: the pressure is 30-40 MPa; the heating rate is 5-15 ℃/30 min; the temperature is 150 ℃ and 170 ℃; the heat preservation time t = a × d, a is 5-10min/mm, and d is the thickness of the composite material grid product.

Preferably, in step S3, the mold, the premix in step S1 and the prepreg in step S2 are preheated before the premix and the prepreg are filled, the preheating time is not more than 30min, and the preheating temperature of the mold is 100-; the preheating temperature of the premix and the prepreg is 90-100 ℃. The process performance can be improved by preheating the premix and the prepreg before the die filling.

Preferably, the method further comprises the following steps:

s5, after the solidification and the molding are carried out in the step S4, the temperature of the mold is reduced to be below 60 ℃, and the demolding is carried out to obtain the composite material grid product.

Further, the cooling can be forced cooling or natural cooling.

Preferably, in step S3, after the premix and the prepreg are filled, the premix and the prepreg are pre-compacted by using an auxiliary tool, and then the premix is added to a position where the amount of the premix is small. The product is pre-compacted after mold filling and before mold closing, so that the uniformity of the whole product in charging can be ensured, the premix is supplemented at the position with less premix, the phenomenon of material shortage of the product can be prevented, and the local part of the product is prevented from bearing too weak.

Preferably, before the premix and the prepreg are loaded in step S3, a release agent is applied to a lower mold of the mold, and after the pre-compaction, a release agent is applied to an upper mold of the mold before the mold clamping is completed. The release agent is an interface coating applied to the surfaces of two objects which are easy to adhere to each other, and the release agent is applied to enable the mold to be easily separated from the product, so that the surface of the product is smooth. After the mold is filled and before the mold is closed, the product is pre-pressed for one time, after the pre-pressing, the mold is opened, the pre-pressing mode is used for ensuring the charging uniformity of the whole surface product, if the mold releasing agent is coated in the upper mold cavity in advance for pre-pressing, the mold releasing agent is brought in, so that the product has defects, therefore, after the pre-pressing, the mold releasing agent is coated on the upper mold before the mold filling and closing are finished.

Another aspect of the present invention provides a composite material grid product manufactured by the method of manufacturing a composite material grid product as described above.

Compared with the prior art, the invention has the following beneficial effects:

1. the method for preparing the composite material grid product adopts a compression molding method combining the chopped fiber premix and the long fiber prepreg, the premix is prepared by mixing the chopped fibers, the resin and the solvent, and because the chopped fibers are in a non-end state and have fibers in all aspects, the strength is relatively uniform, the strength of the whole product can be ensured to be uniform, and the phenomenon of material shortage of the product is prevented; the prepreg is prepared by mixing long fibers, resin and a solvent, the long fibers can ensure the continuity of the fiber strength, the strength is high, and the parts of the product with serious stress can further meet the bearing requirements. In addition, the invention adopts the mixture of the high-strength fiber and the ablation-resistant fiber as the reinforcing material, the ablation-resistant fiber provides good ablation-resistant performance for the product, and the high-strength fiber provides good strength performance for the product, so that the prepared product can meet the double requirements of heat resistance and strength.

2. According to the method for preparing the composite material grid product, disclosed by the invention, a large number of experiments repeatedly try to find the optimal proportion range of the high-strength fibers and the ablation-resistant fibers, so that the product has high strength, high heat resistance and optimal comprehensive performance.

Drawings

FIG. 1 is a schematic view of a composite grid article making mold installation of example 1 of the present invention.

In the figure: 1-upper template; 2-a composite grid article; 3-die sleeve; 4-lower template.

Detailed Description

Those not indicated in the examples of the present invention were carried out under the conventional conditions or conditions recommended by the manufacturer. The reagents or instruments used are not indicated by the manufacturer, and are all conventional products commercially available. The raw materials used in the examples are all commercially available.

Example 1

The method of making a composite grid article of this embodiment comprises the steps of:

s0a, paving the material according to the bearing requirements of the product and the stress condition, wherein in the embodiment, the product is paved according to a grid with a supporting structure at the edge as shown in the figure 1;

s0b, designing a mold according to the structural form of the product, wherein the size and the material of the mold, the structural form of the product, the shearing edge during pressing, a guide column, a temperature field, a demolding mode and the like are considered during the mold design; the die material is ensured to bear high temperature and high pressure for a long time without deformation, and has good wear resistance and higher surface finish; the length of the shearing edge is about 1mm generally, and the shearing edge is easy to tear when being matched with overlong; in general, a guide column is designed on a die, and a certain fit clearance is reserved between the guide column and a guide sleeve; the demoulding has enough demoulding inclination, generally 2 degrees;

s1, cutting the high-strength glass fiber and the ablation-resistant high-silica fiber into chopped fibers of 15-30mm, uniformly mixing the chopped fibers according to the mass ratio of 1:1, mixing phenolic resin and solvent ethanol according to the mass ratio of 5:1 to prepare phenolic solution, and mixing the mixed chopped fibers with the phenolic solution, wherein the mass ratio of the chopped fibers to the phenolic solution is 3:2, kneading, tearing, airing and drying to obtain a premix;

s2, mixing high-strength glass fibers and ablation-resistant high-silica fibers according to the mass ratio of 3:2, mixing phenolic resin and solvent ethanol according to the mass ratio of 5:1 to prepare phenolic solution, soaking the mixed reinforcing fibers in the phenolic solution through a glue dipping machine within a certain time to prepare prepreg, airing and drying the prepreg, and then cutting the prepreg into fibers with required length according to the paving design to obtain the prepreg;

s3, installing the die on a hydraulic press with pressure and table height meeting the requirements, installing the upper die plate 1 of the die on the upper table of the press, assembling the lower die plate 4 of the die and the die sleeve 3 on the lower table of the press, fastening the nail by a special nail, opening the die, cleaning the product area of the die, coating a release agent on the product area of the lower die of the die, and closing the upper die and the lower die of the die without coating the upper die temporarily; preheating the die, the premix in the step S1 and the prepreg in the step S2, wherein the preheating time is not more than 30min, and the preheating temperature of the die is 100-110 ℃; preheating the premix and the prepreg at 90-100 ℃; the press is confirmed to have enough stroke before the die is installed, so that the product is convenient to take out; when the die is installed, the die is ensured to be in the center of the table board of the hydraulic machine, and the pressure is ensured to be uniform; opening and closing the die after the die is installed so as to ensure that the die is aligned up and down; coating a mold release agent in a mold product area, wherein all product areas need to be coated in place and cannot be coated in a missing way, and coating is carried out in a non-product area if the product areas are matched with a female mold and a male mold;

filling the premix of the step S1 and the prepreg of the step S2 in a mold according to a paving design, as shown in FIG. 1, filling the product in a subarea manner, dividing the product into 9 areas (2-1 to 2-9 areas), filling the prepreg and the premix in a matching manner, putting the prepreg in a Chinese character 'jing' shape according to the shape of the product, and manually pre-compacting the prepreg by a copper plate after filling; due to the support of 8 areas (2-1-2-8 areas) on the edge, premix is directly filled in the areas, and an auxiliary tool is used for pre-compaction when necessary; after die assembly and prepressing, putting the rest materials into the position with less premix and putting the rest premix into the position; then coating a release agent on an upper die of the die, paying attention to the fact that no release agent can be gathered, shielding the position of a material cavity of a lower die when the release agent is coated, preventing the release agent from falling into the material cavity, and closing the upper die and the lower die of the die;

s4, carrying out curing molding on the material in the step S3, wherein the curing molding system is as follows: the pressure is 35 MPa; the heating rate is 10 ℃/30 min; the temperature is 150 ℃; the heat preservation time t = a × d, a is 5-10min/mm, and d is the thickness of the composite material grid product.

S5, after the solidification and the molding are carried out in the step S4, the mold is naturally cooled to below 60 ℃, and the demolding is carried out, so that the composite material grid product 2 is obtained.

Example 2

The method for manufacturing a composite grid product according to this example is the same as example 1 except that in step S5, the mold is forcibly cooled to a temperature below 60 ℃ and demolded.

Example 3

The method for manufacturing a composite material grid product in this example is the same as in example 1 except that in step S4, the temperature is directly raised to 160 ℃ without controlling the temperature raising rate, and the holding time is not changed.

Example 4

The remaining steps of the method for manufacturing a composite grid article described in this example are the same as those of example 1, except that the mass ratio of the high-strength glass fibers to the ablation-resistant high-silica fibers in step S1 is 2: 1; in step S2, the mass ratio of the high-strength glass fiber to the ablation-resistant high-silica fiber is 3: 1.

Example 5

The remaining steps of the method for manufacturing a composite grid article described in this example are the same as those of example 1, except that the mass ratio of the high-strength glass fibers to the ablation-resistant high-silica fibers in step S1 is 1: 2; in step S2, the mass ratio of the high-strength glass fiber to the ablation-resistant high-silica fiber is 1: 1.

Example 6

The remaining steps of the method for manufacturing a composite grid article described in this example are the same as those of example 1, except that the mass ratio of the high-strength glass fibers to the ablation-resistant high-silica fibers in step S1 is 1: 3; in step S2, the mass ratio of the high-strength glass fiber to the ablation-resistant high-silica fiber is 3: 4.

Examples of Effect test

GB/T1445 is adopted to detect the tensile strength and the heat resistance of the composite material grid product prepared in each embodiment (the maximum heat flow is 700 kw/m)²Time ≧ 200 s), and the results are reported as in Table 1 below. As can be seen from the results in the following table, in example 2, by using forced cooling, the product is likely to form internal stress due to uneven cooling, but due to the structural form and thickness of the product, the temperature is relatively uniformly cooled in the forced cooling process, and the internal stress has little influence on the product performance; in example 3, the temperature rise rate was not set to directly reach the molding temperature, since the material was a poor conductor of heat, the temperature rise rate was too fast, the surface temperature of the material was high and the internal temperature was low, resulting in a large difference between the internal temperature and the external temperature of the product, the external temperature was high, the curing degree was high at the first curing, the internal temperature was low, the internal stress was generated due to the uneven curing degree, and the subsequent curing process was followedThe method has the advantages that small molecules and water in the product are discharged, defects such as bubbles and cracks can be generated on the product, and the relative strength is greatly reduced.

TABLE 1

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.