RU2622924C1 - Equipment for forming products of polymer composite materials and method of its manufacture - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: equipment for forming products of polymer composite materials contains a supporting structure and a mould made of polymer composite material placed on it. At least one stiffening rib is located on the surface of the mould on the side of the supporting structure, which is made in the form of an elongated foam glass element coated with a layer of polymer composite material onto the mould surface. In this case, the shape and the layer of the polymer composite material, covering the stiffening rib, are made of layers of carbon reinforcing fiber impregnated with a low viscosity epoxy binder with an amine hardener.

EFFECT: improved quality of products manufactured from polymer composite materials.

12 cl, 3 dwg

Description

The invention relates to the field of engineering, namely to the manufacture of tooling designed for molding products from polymer composite materials (PCM), and can find application in aerospace, automotive, shipbuilding and other industries.

Currently, for the manufacture of parts from PCM, tooling is used, made of various metal alloys or tooling of composite materials with a metal frame.

Equipment made of aluminum alloys is machined quite well, however, they have a high coefficient of linear thermal expansion (CTE), which imposes significant restrictions on the use of this material, especially when using high-quality composite materials for aviation purposes. In the process of molding a product from PCM, the technological package is heated to temperatures of 180-240 ° C, while due to the high CTE of the material of the tool, its geometry changes, which, in turn, leads to a change in the geometry of the mold made from PCM with respect to the initial , the manifestation of such an effect as warpage of the product (changing the geometry of the product after removing the product from technological equipment), the creation of residual stresses that adversely affect the mechanical characteristics of the PCM during prolonged use of the product i.

A modern approach to the manufacture of composite tooling has a number of common features. Separately, the mold is manufactured on a pre-fabricated master model, which is the prototype of the final product. The supporting structure on which the mold is placed is usually made of metal. The main drawback of this approach is, as mentioned above for some metal snap-ins, the difference in the CTE of the metal and the composite shape, which can lead to distortion of the snap shape, the development of warping processes and residual stresses in the products when manufacturing target products from PCM.

One of the main methods used today to compensate for changes that occur is the manufacture of tooling with a pre-calculated distortion, which is leveled by distorting the geometry of the product after molding, which makes it possible to produce products with the most accurate geometry. In addition, often the assessment of the correctness of the geometric parameters of the manufactured part is checked by the contact method by placing the molded part on the tool and checking the fit of the part surface to the tool surface.

The problem of changing the geometric dimensions of the resulting products becomes especially relevant in the manufacture of large-sized integrated structures. With a snap size of about ten meters, the change in linear dimensions due to the CTE can reach several centimeters, and in the case of a warping effect, several tens of centimeters.

The closest analogue of the proposed tooling for molding parts from polymer composite materials is a tooling containing a support structure and a mold placed on it from a polymer composite material (RU 2090364, В29С 33/40, 09/20/1997). In the same patent, the closest analogue of the manufacturing method of a tooling for molding products from polymer composite materials is disclosed, which includes manufacturing a mold from a polymer composite material and mounting said mold on a support structure.

The disadvantage of the snap-in described in the patent RU 2090364 and the method of its manufacture is that when molding products on a mold made from PCM, they are heated to temperatures of 180-240 ° C, and this changes the geometry of the shape, which, in turn, leads to a change in the geometry of the molded part from PCM with respect to the initial set and the appearance of residual stresses and a decrease in the quality of manufactured products.

The objective of the present invention is to improve the quality of products made from PCM, including large complex geometry, by eliminating the distortion of the shape of the tool at a low labor intensity and the cost of their manufacture.

The technical result is achieved by means of a tool for molding articles made of polymer composite materials containing a support structure and a mold made of a polymer composite material placed on it, on the surface of which from the side of the support structure there is at least one stiffener made in the form of an elongated foamglass element coated approaching the surface of the mold with a layer of polymer composite material, while the shape and layer of the polymer composite material, covering th stiffener are made of layers of carbon fiber reinforcement impregnated with low-viscosity epoxy binder with amine hardener.

The equipment may contain several stiffeners.

The technical result is also achieved by a method of manufacturing a tool for molding products from polymer composite materials, including: manufacturing a mold from a polymer composite material by placing several layers of carbon reinforcing fiber on the surface of the master model, impregnating the specified fiber with a low viscosity epoxy binder with an amine hardener by vacuum infusion and preliminary curing at room temperature; the manufacture of at least one stiffener blank in the form of an elongated foam glass member; fixing the specified workpiece stiffeners on the surface of the mold, the opposite of its working surface; coating the stiffener blank with a layer of polymer composite material by spreading stiffeners on the surface of the said blank with stiffening several layers of carbon reinforcing fibers onto the mold surface, impregnating the mentioned fibers with a low viscosity epoxy binder with an amine hardener by vacuum infusion and curing it at room temperature; post-curing of the form with a stiffener located on it in a stepwise mode with gradual slow heating; slow cooling of the mold with a stiffener located on it and its installation on the supporting structure with the placement of the stiffening rib on the side of the supporting structure.

The foam glass used for the manufacture of stiffening ribs has a unique set of properties: low CTE, low thermal conductivity, high heat resistance, sufficient strength and elastic modulus. These properties of foam glass provide optimal compensation for changes in the shape of the snap-fit that occur during temperature molding, i.e. allow the snap-in to be slightly distorted and at the end of molding during cooling to return to their previous state. Moreover, under normal conditions, technological composite tooling has the exact shape and geometry according to the specified requirements for conducting contact quality control of the part. In addition, due to changes in the number and size of stiffeners made of foam glass, it is possible, according to the results of preliminary calculations, to adjust the possible distortions of the equipment and products from it. At the same time, foam glass is well processed, has a low weight, low cost and high durability, does not require energy costs for multiple repairs throughout the entire service life. It does not burn, is non-hygroscopic, does not absorb liquids, and is resistant to aggressive substances. Due to the low thermal conductivity, foam glass does not require additional energy consumption for its heating during molding of parts at elevated temperatures. Thus, the implementation of stiffeners made of foam glass - a material with high heat resistance and the closest KLTR value to the form will minimize or eliminate its warpage due to the KLTR difference and significantly increase the accuracy of its shape and geometric parameters during manufacture.

Carbon reinforcing fibers can be used either in the form of fabric, or in the form of a non-woven fabric, or in the form of a coated tape, etc.

For large PCM products having complex geometry, it is preferable to impregnate the layers of carbon reinforcing fiber with a binder in the manufacture of a snap mold by vacuum infusion, since this method allows you to get the best ratio of filler and binder in the composite material, providing the lowest CTE values during curing in two stages, and the second stage is carried out without additional vacuum. In addition, this method is the least time-consuming, can reduce the time of manufacture of products, as well as reduce their cost.

In this case, preliminary curing of the mold is carried out at room temperature for two days to obtain an incompletely cured composite material, but which has passed the gelation stage, which makes it possible to use master models made of easily processed polymeric materials for molding molds, however, with low heat resistance.

The preliminary curing of the layer of polymer composite material covering the stiffener blank is carried out at room temperature for two days to obtain a partially cured composite material, but which has passed the gelation stage, which makes it possible to use master molds made of easily processed polymer materials for molding however, with low heat resistance.

In the first stage of post-curing, heating is carried out to 70 ° C at a rate of not more than 2 ° C / hour. A lower heating rate will lead to an unreasonably high duration of the curing process, on the contrary, heating at a speed of more than 2 ° C / hour will increase the likelihood of side processes and the occurrence of structural defects in the cured binder, which will reduce the quality of the final product.

In the second stage of post-curing, heating is carried out from 70 to 190-200 ° C at a rate of 5 ° C / h in order to ensure complete curing of the epoxy binder to obtain products with high strength characteristics and minimal thermal shrinkage. Carrying out heating at a speed of more than 5 ° C / hour will increase the likelihood of side processes and the occurrence of structural defects in the cured binder, which will reduce the quality of the final product.

In the third stage of post-curing, exposure is carried out at 200 ° C for one hour. Raising the curing temperature to 200 ° C with subsequent exposure is required to reduce the viscosity of the binder that has passed the gelation stage in order to increase the curing rate and reduce the duration of the manufacturing process. Post-cure at a temperature of less than 200 ° C can lead to incomplete curing of the product, characterized by low strength characteristics and greater shrinkage during cooling.

The mold with a stiffening rib is cooled to room temperature at a rate of not more than 5 ° C per minute. When cooling molds at a rate of more than 5 ° C / min, relaxation processes in the cured binder will not have time to pass, which will lead to the appearance of high stresses in the cooled product with subsequent possible distortion of its shape and the formation of microdefects that reduce its operational properties.

The above features and advantages of the invention will be apparent from the following description of a preferred example of its implementation with reference to the accompanying drawings, in which to represent the same elements using the same position.

In FIG. 1 shows a diagram of a tooling for molding PCM products made with stiffeners made of foam glass, in accordance with the present invention;

in FIG. 2 is a diagram of manufacturing a mold by vacuum infusion in accordance with the present invention;

in FIG. 3 is a diagram of manufacturing a mold stiffener by a vacuum infusion method in accordance with the present invention.

Equipment 1 for molding products from polymer composite materials contains a mold 2 placed on a supporting structure 3.

Form 2 has a working surface 4, which is the forming surface for laying out the workpiece manufactured on snap parts from PCM. Form 2 is made of PCM made of layers of carbon fiber reinforced with a binder. Carbon reinforcing fibers can be used in the form of fabric, either as a non-woven fabric, or in the form of a flat tape, etc. As a binder, a low viscosity epoxy binder with an amine hardener can be used.

At least one stiffening rib 6 is located on the surface 5 of the mold 2 opposite its working surface 4 from the side of the supporting structure 3.

Equipment 1 may contain several stiffening ribs 6.

The stiffener 6 is made in the form of an elongated element cut from foam glass - a material similar in terms of KLTR to material of form 2.

The elongated stiffener 6 can be made with a trapezoidal or rectangular, square, or any other cross-section, depending on the magnitude of the possible distortions of the part that need to be compensated.

On top of the elongated stiffener 6 is coated with a layer 7 of a polymer composite material approaching the surface of mold 2, the same as PCM of mold 2. Moreover, form 2 and layer 7 of the polymer composite material covering the elongated stiffener 6 are made of layers of carbon reinforcing fiber, impregnated with a low viscosity epoxy binder with an amine hardener. These carbon reinforcing fibers can be used in the form of fabric, or in the form of a non-woven fabric, or in the form of a flat tape or in some other form.

The above-described equipment for molding parts from polymer composite materials can be made in the following way.

First, form 2 is made from a polymer composite material. For this, several layers of carbon reinforcing fiber are placed on the surface of the master model 8. As carbon reinforcing fibers, fabrics, non-woven fabric, flat tape, and the like can be used. Then carry out the impregnation of carbon reinforcing fibers with a binder followed by its curing. As a binder for impregnation of a carbon reinforcing fiber, a low viscosity epoxy binder with an amine hardener is used, prepared immediately before impregnation. The impregnation of the specified fiber with a binder is carried out by the method of vacuum infusion.

Preliminary curing of Form 2 was carried out at room temperature for two days.

A blank of at least one stiffener 6 is made. For this, an elongated element of the desired shape is cut out of the foam glass by machining to the specified dimensions, for example, on a CNC milling machine.

The resulting preform of at least one stiffener 6 is placed and fixed on the surface 5 of mold 2, the opposite working surface 4, for example, is glued using epoxy glue.

Several layers of carbon reinforcing fibers in the form of a fabric, non-woven fiber, flat tape, etc. are laid on the surface of said preform stiffener 6 with approaching surface 5 of mold 2, and the fibers are impregnated with a bonding method of vacuum infusion. As a binder for impregnation of a carbon reinforcing fiber, a low viscosity epoxy binder with an amine hardener is used, prepared immediately before use.

After that, the binder is pre-cured within two days and a layer 7 of the polymer composite material is obtained, which is the same as the polymer composite material of form 2.

In this case, curing is carried out in two stages: the first stage is carried out at ambient temperature in order to obtain a composite material that has passed the gelation and incomplete curing stage, and in the second stage, slowly heating 2-5 degrees / hour to a temperature of 200 ° C, cure without deformations and deviations from linear dimensions in the product, which is characterized by high strength characteristics and does not have thermal shrinkage.

Then, to obtain a high-quality product with high strength characteristics and low shrinkage, post-curing of form 2 is carried out with stiffeners 6 located on it, covered with a PCM layer 7 in a stepwise mode with gradual slow heating. At the same time, at the first stage of post-curing, heating is carried out to 70 ° C at a speed of not more than 2 ° C / hour. In the second stage of post-curing, heating is carried out from 70 to 190-200 ° C at a rate of 5 ° C / h. And in the third stage of post-curing, exposure is carried out at 200 ° C for one hour.

Form 2 with stiffeners 6 is cooled to room temperature at a rate of not more than 5 ° C per minute.

At the same time, stiffeners 6 on the surface of mold 2, covered with a PCM layer 7, form a single structure with mold 2.

The resulting form 2 with stiffeners 6 is laid on a supporting structure 3, designed to maintain the form 2 of the snap 1, with the placement of stiffeners 6 on the side of the supporting structure 3. In this case, the supporting structure 3 can be made of metal, fiberglass, carbon fiber or other available materials .

An example embodiment of the invention

First, mold 2 of tool 1 is manufactured. For this, several sheets of carbon reinforcing fabric are placed on the surface of master model 8. On the master model 8, a sealing tourniquet 9 is glued in two rows along the edge of the laid sheets of carbon reinforcing fabric.

A layer 10 of sacrificial fabric is laid on top of the mold 2, on top of which a distribution grid 11 is placed, a binder supply line 12, which is a spiral polyethylene tube 13, is placed on top. A vacuum outlet line is placed along the edge of the master model.

Collect the first technological package. For this, the vacuum film 14 is placed on the surface of the layers of carbon reinforcing fiber and fixed with a sealing rope 9. The assembled bag is connected to a vacuum line and a vacuum is created.

The second technological package is assembled according to a scheme similar to the first.

A low viscosity epoxy binder with an amine hardener is prepared by mixing the starting components in a mixer.

The prepared binder is fed through a spiral tube 13 of the binder supply line 12 to the assembled technological package and the process of impregnating the layers of carbon reinforcing fiber with the prepared binder is carried out.

The end of the impregnation is controlled visually by the exit of the binder into the vacuum line.

At the end of the impregnation, the binder feed line 12 is closed.

Pre-curing of form 2 is carried out at room temperature 25 ± 3 ° C. The curing time is 2 days.

At the end of curing, the technological packages are disassembled and auxiliary materials are removed.

From foam glass on a CNC milling machine, blanks of stiffeners 6 are cut in the form of elongated elements of a given size. For the manufacture of the stiffeners neoprene foam glass 6 used grade D 130 (PECC Company, Vladimir) with the following characteristics: CTE 9,0⋅10 ^-6 C ^-1; density 0.12-0.14 g / cm ³ , high heat resistance up to 485 ° C, compressive strength 1.0 MPa.

The blanks of the stiffening ribs 6 are placed on the surface 5 of the mold 2 of the tool 1, opposite the working surface 4 of the mold 2, and fixed with glue.

Sheets of carbon fabric are cut in the required amount and spread on top of the entire surface of each of the stiffeners 6 with the approach to the surface of the mold 2 snap 1.

On top of form 2 with stiffening ribs 6 placed on it, a layer 15 of sacrificial tissue is laid.

Then, on top of each of the stiffening ribs 6, covered with a layer 15 of sacrificial tissue, a distribution grid 16 is placed connected to the binder supply line 17.

A binder supply line 17 connected to the distribution grid 16 is formed on top of the stiffeners 6, while in order to improve the supply of the binder and improve the quality of impregnation of the stiffeners 6, a spiral polyethylene pipe 18 is sewn into the distribution grid 16 along the entire length of the stiffener 6 . With this embodiment, the supply line 17 of the binder in the presence on the form of 2 protruding elements can be circumvented, breaking the line to an obstacle and continuing behind it, while the distribution grid 16 will be placed throughout Line line impregnation.

The resulting structure, consisting of a mold 2, on which stiffeners 6 are placed, covered with a layer 15 of sacrificial fabric and a distribution grid 16, is covered with two layers 19 of a vacuum film, fixed with a sealing rope 9 to form a double vacuum technological package, and in each of formed vacuum technology packages create a vacuum.

Via the supply line 17 of the binder, low viscosity epoxy binder with an amine hardener is fed into the distribution grid 16 and each of the stiffening ribs 6 is impregnated with the specified binder. The output of excess binder will be carried out along the perimeter of form 2, while since form 2 has already been prevented, it will not absorb excess binder, which along the distribution grid 16 will go into the vacuum outlet line. After this, the PCM layer 7 is cured, covering stiffeners 6, at room temperature 25 ± 3 ° C for two days.

Then, post-curing of form 2 is carried out with stiffening ribs 6 located on it, covered with a PCM layer 7, in a stepwise mode with gradual slow heating: at the first post-curing step, heating is carried out to 70 ° C at a speed of not more than 2 ° C / hour; at the second stage of post-curing, heating is carried out from 70 to 190-200 ° C at a rate of 5 ° C / h; in the third stage of post-curing, exposure is carried out at 200 ° C for one hour, and then cooling form 2 with stiffening ribs 6 to room temperature at a speed of not more than 5 ° C per minute.

Thus, in order to obtain a high-quality product with high strength characteristics and low shrinkage, curing is carried out in two stages: the first stage takes place at ambient temperature in order to obtain a composite material that has passed the gelation and incomplete curing stage, and in the second stage with slow heating 2- 5 deg / h to a temperature of 200 ° C, cure without deformation and deviation from linear dimensions in the product, which is characterized by high strength characteristics and does not have heat eskoy shrinkage.

Form 2 with stiffeners 6 is fixed on the supporting structure 3 with the placement of stiffeners 6 from the side of the supporting structure 3.

Thus, the resulting construction of a tooling, consisting of a mold reinforced on its working surface with stiffening ribs made of foam glass coated with a layer of polymer composite material made of layers of carbon fiber reinforced with a binder, which is used as a low-viscosity epoxy binder with an amine hardener, will increase the quality of products made from PCM, including large-sized complex geometries, by eliminating distortion in the shape of the tool at low labor intensity and the cost of their manufacture.

Claims (19)

1. Tooling for molding articles made of polymer composite materials, comprising a support structure and a mold made of a polymer composite material placed on it, on the surface of which at least one stiffener is located on the side of the support structure, made in the form of an elongated foam glass element coated with an approach on the surface of the mold with a layer of polymer composite material, wherein the shape and layer of the polymer composite material covering the stiffener are made of carbon layers Nogo reinforcing fiber impregnated with low-viscosity epoxy binder with amine hardener. 2. Equipment according to claim 1, which contains several stiffening ribs. 3. A method of manufacturing a tool for molding products from polymer composite materials, including: making a mold from a polymer composite material by placing several layers of carbon reinforcing fiber on the surface of the master model, impregnating the specified fiber with a low viscosity epoxy binder with an amine hardener by vacuum infusion and curing it at room temperature; the manufacture of at least one stiffener blank in the form of an elongated foam glass member; fixing the specified workpiece stiffeners on the surface of the mold, the opposite of its working surface; coating the stiffener blank with a layer of polymer composite material by spreading stiffeners on the surface of the said blank with stiffening several layers of carbon reinforcing fibers onto the mold surface, impregnating the mentioned fibers with a low viscosity epoxy binder with an amine hardener by vacuum infusion and curing it at room temperature; post-curing of the form with a stiffener located on it in a stepwise mode with gradual slow heating; slow mold cooling with a stiffener located on it; and its installation on the supporting structure with the placement of stiffeners on the side of the supporting structure. 4. The method of claim 3, wherein the carbon reinforcing fibers are used in the form of a fabric. 5. The method according to p. 3, wherein the carbon reinforcing fibers are used in the form of a non-woven fabric. 6. The method according to p. 3, in which the carbon reinforcing fibers are used in the form of a flat tape. 7. The method according to p. 3, in which the preliminary curing of the form is carried out at room temperature for two days. 8. The method according to p. 3, in which the preliminary curing of the layer of polymer composite material covering the workpiece stiffeners is carried out at room temperature for two days. 9. The method according to p. 3, in which the first stage of post-curing is heated to 70 ° C at a speed of not more than 2 ° C / hour. 10. The method according to p. 3, in which the second stage of post-curing is heated from 70 to 190-200 ° C at a speed of 5 ° C / hour. 11. The method according to p. 3, in which the third stage of post-curing is carried out exposure at 200 ° C for one hour. 12. The method according to p. 3, in which the cooling of the mold with a stiffener is carried out to room temperature at a speed of not more than 5 ° C per minute.

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