RU2264295C1 - Prepreg - Google Patents

Abstract

FIELD: layered products.

SUBSTANCE: prepreg comprises polymeric binder and filler. The filler may be made of cords, belts, or textile.

EFFECT: enhanced strength.

2 cl, 3 tbl, 12 ex

Description

The invention relates to the field of high-strength composite materials based on fibrous fillers and polymer binders that can be used in the aviation industry, in machine-building, shipbuilding and other technical fields.

Known composite materials based on prepregs obtained by impregnating fibers from rigid chain aromatic polymers with an epoxy binder followed by curing (Dhingra AA, Pigliacampi JJ, Tanner D. Aramid fibers for general engineering. J. Metals. 1986, v. 38, No. 3, p. 21-25).

These materials are characterized by increased specific strength and rigidity and are used for the manufacture of structural products in various fields of technology.

The disadvantage of these materials is the reduced interlayer strength, the tendency to delamination under the influence of shock loads, as well as the low viability of the prepreg, making it difficult to obtain a material with stable properties.

Known composite materials made by forming layers of a prepreg based on aromatic polyamide fiber CBM and an epoxy binder (Kudryavtsev G.I., Varshavsky V.Ya., Schetinin A.M., Kazakov M.E. "Reinforcing chemical fibers for composite materials" . - M .: "Chemistry", 1992, p. 88-111).

Organoplastics based on CBM fiber are high-strength, heat-resistant materials with low density. However, high water absorption and reduced properties in a thermo-humid environment limits the use of these materials in a number of cases when increased requirements are placed on maintaining weight and strength characteristics of products during operation.

The closest of the analogues adopted for the prototype is a prepreg containing a fibrous filler and an epoxy binder with a ratio of components, wt.%:

Fiberfill 58.0-70.0 Epoxy binder 30.0-42.0

which contains glass, carbon or organic tows, ribbons, fabrics or threads as a fibrous filler, and triglycidyl derivative of paraaminophenol EAF grade, polyglycidyl derivative of low molecular weight phenoformaldehyde novolak brand UP-643, a product of the interaction of diphenylastropane 4 with ephenylapropane 4, epiline diphenylpropane 4 4'-diaminodiphenylsulfone and a mixture of isopropyl or ethyl alcohol and acetone as a solvent, as well as a product obtained by molding this pre prega (RF patent No. 2184128).

The disadvantage of the prepreg prototype is the lack of viability, which does not allow for its long-term storage and transportation to consumers in a centralized specialized production.

The disadvantages of the composite material obtained from the prepreg prototype, and products from it are reduced resistance to the influence of the thermo-humid environment, high water absorption, reduced strength properties after exposure to high humidity, the tendency to delamination upon impact.

An object of the invention is the creation of a high-tech long-lived prepreg based on aramid filler made of aramid neutral yarns Rusar, which has the ability to long-term storage and suitable for transportation to consumers in a centralized production environment. Composite materials based on the inventive prepreg and products made from it have a high level of strength retention after exposure to a thermo-humid environment, reduced water absorption, increased impact resistance, and the absence of corrosion activity in contact with aluminum alloys and other metals.

To solve the technical problem, a prepreg is proposed, including a polymeric binder and an aramid filler, which as a filler contains an aramid filler of neutral aramid yarns Rusar with a nominal linear density of 14.3 tex, 29.4 tex and 58.8 tex; specific breaking load of at least 210 cN / tex; elongation at break of at least 2.6%, with the following ratio of components, wt.%:

filler 45-65 binder 35-55

Aramid filler is made in the form of bundles, ribbons, fabrics.

A product obtained by molding said prepreg is also provided.

The use of a filler based on neutral aramid yarns Rusar as part of the prepreg provides the products with increased operational characteristics: reduced water absorption, increased strength retention after exposure to moisture, and the absence of corrosion activity in contact with metals and alloys.

As a polymeric binder, binders of various chemical nature can be used, but it is most preferable to use binders based on epoxy and phenolic resins.

Examples of implementation

Example 1

Making flat plates.

An epoxy binder solution containing ETF and ED-20 epoxy resins, TF-82 polyester resin, UP-605/3 epoxy resin hardener, acetone and isopropyl alcohol (TU 1-595-25-494-96) are applied to Rusar fabric art. 11954N (TU 8378-008-18059169-02), made of Rusar yarns with a nominal linear density of 14.3 tex, a specific breaking load of 244 cN / tex and an elongation at break of 3.2%, and dried at room temperature. The binder content in the prepreg is 52%. The prepared prepreg is pressed in a stepwise mode with a maximum heating temperature of 160 ° C at a specific pressure of P _beats = 5 atm.

Example 2

The manufacture of winding products.

The binder (without solvent) in Example 1 is impregnated with a Rusar H 29.4 tex thread (TU 2272-023-51605609-2002) with a specific breaking load of 238 cN / tex and an elongation at break of 3.3%. The binder content in the prepreg is 40%. The formed tape is wound on a mandrel for subsequent installation on the machine.

Winding products is carried out on a winding machine.

The formation of the winding product is carried out according to the temperature-time regime specified in example 1.

Example 3

The manufacture of multilayer parts of complex configuration.

A solution of an epoxy binder including ED-22 and ETF epoxy smokes, UP-631 epoxy bromine-containing resin, hardener No. 9 (TU 1-595-12-672-2002) is applied to the fabric of Example 1, dried at room temperature. The binder content in the prepreg is 55%. Layers of the prepreg are laid on a pre-prepared surface of the mold and molded in an autoclave in a stepwise mode with a maximum heating temperature of 140 ° C at a specific pressure of R _beats = 5 atm.

Example 4

The manufacture of winding products.

Impregnation and winding is carried out analogously to example 2. Filler - thread Rusar N 58.8 tex (TU 2272-023-51605609-2002) with a specific breaking load of 233 cN / tex and an elongation at break of 3.2%. The binder content in the prepreg is 35%.

The formation of the winding product is carried out according to the mode specified in example 3.

Example 5

Making flat plates.

A solution of a mixture of epoxynovolac and 3-functional epoxy resin with aromatic diamine as a hardener (TU 1-595-12-542-98) is applied to the fabric of example 1, dried. The binder content in the prepreg is 50%. The prepared prepreg is pressed in a stepwise mode with a maximum heating temperature of 175 ° C at a specific pressure of P _beats = 5 atm.

Example 6

The manufacture of winding products.

Impregnation and winding is carried out analogously to example 2. Filler - according to example 4. The content of the binder in the prepreg - 42%. The formation of the winding product is carried out according to the mode specified in example 5.

Example 7

The manufacture of winding products.

Impregnation and winding is carried out analogously to example 2. Filler - Rusar harness obtained by tearing Rusar 58.8 tex yarn according to example 4. The binder content in the prepreg is 38%.

The formation of the winding product is carried out according to the mode specified in example 5.

Example 8

Making flat plates.

A solution of phenol-formaldehyde binder (TU 1-5955-25-276-95) is applied to the fabric of example 1. Dry at room temperature. The binder content in the prepreg is 45%. The prepared prepreg is pressed in a stepwise mode with a maximum heating temperature of 170 ° C at a specific pressure of P _beats = 5 atm.

Example 9

The manufacture of winding products.

Impregnation and winding is carried out analogously to example 2. Filler - according to example 4. The binder content in the prepreg is 40%.

The formation of the winding product is carried out according to the mode specified in example 8.

Example 10 (prototype).

The manufacture of multilayer parts of complex configuration.

The binder solution of Example 5 is applied to the CBM tissue art. 56313 (TU 17 VNIIIPKhV 350-88), made of CBM thread with a breaking load of 208 cN / tex and elongation at break of 4.3%, and dried at room temperature. The binder content in the prepreg is -30%. The first layers of the prepreg are laid on the previously prepared surface of the mold, heated at a temperature of 110-130 ° C for 30 minutes, cooled, then the remaining layers are laid out sequentially.

The part is molded in an autoclave according to the mode of example 5.

Example 11 (prototype).

The manufacture of winding products. Binder - as in example 5. Filler - CBM thread in example 10.

The binder content in the prepreg is 42%.

The formation of the winding product is carried out according to the mode specified in example 5.

Example 12 (prototype).

The manufacture of winding products.

Impregnation and winding is carried out analogously to example 2. Filler - CBM harness. The binder content in the prepreg is 42%.

The formation of the winding product is carried out according to the mode specified in example 5.

Table 1 shows the compositions of the inventive prepreg according to examples 1-9 and the prepreg prototype of examples 10-12.

Table 2 presents the technological properties of the prepregs according to the compositions of examples 1-9 in comparison with the prototype of examples 10-12.

Table 3 presents the properties of composite materials obtained on the basis of the prepregs according to examples 1-9 in comparison with the prototype of examples 10-12.

The invention is not limited to the examples given.

From the above data it follows that the claimed prepregs have improved technological properties compared with the prepregs of the prototype. The declared prepregs have a longer viability (1.5-4 times), which allows for their long-term storage and transportation to consumers in a centralized specialized production. The curing temperature of the prepregs is lower or at the level of the prototype, which makes it possible to reduce energy costs for the production of products from composite material.

Table 3 Name of properties KM Examples of the invention Prototype 1 2 3 4 5 6 7 8 nine 10 eleven 12 Breaking stress in bending (in the initial state), MPa 490 810 480 750 530 840 790 400 510 800 760 Breaking stress after bending after exposure to thermal and humid conditions (relative humidity 98%, temperature 70 ° C), MPa:
- 750 h
- 1500 h 490 810 480 750 530 840 790 400 480 760 720 470 760 440 420 520 820 770 350 - 380 630 590 The degree of preservation of strength after exposure to thermal and humid conditions is 750 hours. 100 100 100 100 100 100 100 100 95 95 95 -1500 h 94 95 92 93 97 98 98 87 - 75 79 78 Water absorption,%: 1 day 0.19 0.22 0.20 0.22 0.18 0.18 0.19 0.24 0.25 0.41 0.50 0.66 30 days 1.20 1.20 0.70 0.75 0.60 0.63 0.67 0.90 0.94 2.60 2.95 3.05 90 days 2.00 2.20 2.40 2,50 1.90 1.90 2.10 2.60 2.80 4.20 4.60 5.10 The area of destruction upon impact (with kinetic energy of 12 J / mm), mm ² 210 280 240 320 120 300 360 320 420 360 650 800

Composite materials based on the inventive prepregs have high stability of properties when exposed to a thermo-humid environment. The bending strength of the product after exposure for two months at a humidity of φ = 98% and a temperature of 70 ° C is 10-20% higher than that of the prototype.

The water absorption of the inventive composite material is about 2 times lower compared to the prototype. At the same time, the pH of the aqueous extract of the material is 6-7, which ensures the absence of corrosion activity in relation to metal alloys and allows its use in contact with anodized aluminum alloys, structural steels with cadmium and phosphate coatings with protection of paintwork, titanium alloys and corrosion-resistant steels.

The inventive products have high resistance to low speed impact. When impact with a kinetic energy of 12 J / mm, the damage area of the inventive product is 1.3-2.0 times less than that of the prototype product.

EFFECT: invention makes it possible to obtain a prepreg with stable technological properties, long viability, and also to obtain multilayer and winding products from it with increased operational reliability, increased strength properties after exposure to a thermo-humid environment, with reduced water absorption, and increased resistance to low-speed impact, ensuring the absence of corrosion activity in contact with metal.

Claims (3)

1. A prepreg comprising a polymeric binder and an aramid filler, characterized in that as the filler it contains an aramid filler of neutral aramid yarns Rusar with a nominal linear density of 14.3; 29.4; 58.8 tex, specific breaking load of at least 210 cN / tex and elongation at break of at least 2.6% in the following ratio of components, wt.%: Filler 45-65 Binder 35-55 2. The prepreg according to claim 1, characterized in that the aramid filler is made in the form of bundles, tapes, fabrics. 3. The product, characterized in that it is made by molding the prepreg according to claim 1.