RU2723856C1 - Method of making composite bumper for ground vehicle - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: invention relates to machine building, in particular, to motor industry, and can be used in making structural components of ground vehicles, including trucks and buses, such as vehicles bumpers, having protective function, decorative design function. Method of making bumper consists in forming a model, coating the model with a separating agent, applying a number of layers of prepreg from basalt fabric onto the model, applying a perforated film and then absorbing layer. Then model is placed with layers of prepreg in vacuum bag and pump is connected. Model is placed in the furnace under influence of temperature and pressure. First, it is heated in furnace to 75 °C at article heating rate of 1.5–2 °C/minute and held at this temperature for 30 minutes. Then it is further heated to 120 °C at heating rate of 1.5 °C/minute, with holding at temperature of 120 °C for 30 minutes. After that, it is cooled at a rate of not more than 3 °C/minute to ambient temperature. Further, model with made bumper is cooled down. All operations provide creation of vacuum from 0.8 to 0.99 atm. Finished bumper is subjected to machining.EFFECT: obtaining an article having improved strength characteristics with considerable (up to 40 %) weight reduction.1 cl

Description

The invention relates to the field of engineering, in particular the automotive industry, and can be used in the manufacture of structural elements of land vehicles, including trucks and buses, such as bumpers of vehicles that perform a protective function, a decorative design function.

From the prior art, new generations of composite materials used in the automotive industry made of fibers are known, which are fiberglass, carbon fiber, basalt fiber, organic fiber, polyester fiber, para-aramid fiber, meta-aramide fiber, polyacrylonitrile fiber, and binders, as which use an epoxy binder, a polyester binder, a vinyl ester binder, a polyurethane-based binder, thermoplastics-based binder, elastomer-based binder, and an organosilicon binder. Such materials begin to be widely used in the manufacture of various vehicle components, since they have several advantages over traditional materials (metals), such as tensile strength, low weight, corrosion resistance, heat-insulating properties, and service life.

Panels or more complex functional elements, for example, in the automotive and aerospace industries can be produced using any of the manufacturing techniques known in the art, such as plastic transfer molding (RTM), compression molding, vacuum bag molding, autoclave molding, molding winding fibers, etc.

Known composite bumper of a land vehicle made of chopped fiber and a binder by the method of long fiber injection, while the strength of the local sections is set by the density of the composite material. The density of the composite material can be set by varying the length and fiber content. So, the density may be in the range of 0.5-2.0 g / cm ³ . In addition, the fiber length can be from 5 to 50 mm, and the fiber content can be from 5 to 50%. At the same time, fiberglass and / or carbon and / or basalt and / or organic and / or polyester and / or para-aramid and / or meta-aramid and / or polyacrylonitrile fibers can be used as fiber.

In addition, a binder based on polyurethane, and / or a binder based on thermoplastics, and / or a binder based on elastomers, and / or an organosilicon binder, and / or an epoxy binder, and / or a polyester binder, and / or a vinyl ester binder (for an analogue, see RF patent No. 168680, IPC B60R 19/03 (2006.01), from 2017).

The disadvantage is: expensive and complex forms, the complexity of the process, the need to have injection equipment.

A wide range of products for industrial purposes, made from polymer composite materials (PCM), suggests the presence of many technological methods and methods of their production, taking into account the size and purpose of the products, production volumes and operating conditions, product configuration, qualifications and equipment of the manufacturer, etc. ., etc. One of the main technological methods for processing the considered group of composite materials into finished industrial products is molding from prepregs and premixes.

Over the years, prepreg technology has been the basis for the production of many materials, products and structures.

A prepreg is a semi-finished composite material consisting of a fibrous reinforcing filler and a binder applied on both sides. First of all, reinforcing filler of glass and carbon fibers is used. The binder can have an epoxy base (or another thermoset, for example, a phenolic binder), can be made on the basis of thermoplastics - polyethylene or PET. Depending on the binder, the prepreg can be soft and sticky (epoxy base) or hard and slippery (PET).

There are several methods for making a prepreg. The most advanced and convenient is the impregnation of the fibrous material with a binder melt or a melt method. Thus, at the moment, most of the prepregs are made. Another method is impregnation with a binder solution and further drying. Despite the outdated and low-environmental technology, a significant portion of the prepregs are still manufactured in this way. There are other techniques for making prepregs.

The most widespread are prepregs based on high viscosity epoxy resins made by melt impregnation. Such material has the appearance of double-sided adhesive tape with protective films on one or two sides. Various other types of prepregs are commonly used in specialized fields.

The process of manufacturing a part from prepreg is reduced to cutting out a layer of a given configuration of the prepreg according to the template or on a cutting plotter with further laying out of the prepreg on a snap layer by layer. After the necessary thickness has been set, the part is either directly molded in the press, or the vacuum bag is assembled and further molded in a heating cabinet or autoclave.

KM products for these purposes are made either in one stage (after the fillers impregnate the fillers with binders, they immediately form the product and cure under the influence of high temperatures), or in two stages (through the prepreg stage, when the product is formed from prepregs and then exposed to curing) high temperatures). Usually for the manufacture of complex products it is more convenient to use prepregs with great viability, due to which such materials retain stickiness and processability for a long time.

Recently, a basalt composite has become widespread, its advantage is that it works perfectly with conventional resins used in the manufacture of products, but it is much better impregnated than carbon.

https://basalt.today/ru/2017/04/10491/

Basalt is a dark gray or black, dense, medium-grained volcanic rock. Basalt fiber is a 100% inorganic mineral continuous fiber that was released for civilian use only in 1995. A diameter of 11.0 microns guarantees the best compromise between stability, durability and cost. In addition, the fiber has a natural golden brown color, which can be used for decorative purposes.

A known method of manufacture and design of a sandwich panel. This design of the sandwich panel includes an inner core material having first and second opposite surfaces, first and second cladding films respectively associated with first and second opposite surfaces of the core, the panel including an open-structured film inserted between the first the surface of the core and its corresponding cladding film, and the panel includes less than 200 g / sq. m of glue. One design option involves the use of a prepreg as facing layers (see patent for the invention of the Russian Federation No. 2545370, IPC B32B 3/12 (2006.01), 2015).

The disadvantages of this method are:

- the strength properties of the sandwich panel are limited by the low mechanical characteristics of the core;

- high flammability of core materials.

From sources available on the Internet, molding of products from prepregs is known, which occurs as follows:

- the shape or model of the future part is made from various materials (gypsum, wood, etc.);

- on this form impose the required number of layers of the prepreg;

- put it all in an autoclave, and under the influence of high pressure and temperature, the prepreg is cured;

- the cured product is subjected to finishing and stripping.

Often, a vacuum bag is also used in addition, it is less safe, but has several advantages.

A vacuum bag can be used without an autoclave, if everything is placed in a vacuum bag and external pressure is created, the bag will evenly press the prepreg against the mold. It's like putting a part in a bag and pumping air out of it. This molding is called vacuum bag molding.

The whole process can be divided into 6 stages:

• Coating the mold with a release agent (wax, primer, etc.).

• Unfolding absolutely evenly carbon fabric in the form without wrinkles, bubbles and other defects.

• Each layer is impregnated with resin. Layers can be alternated with fiberglass, basalt fabric and other composite materials.

• Laying a perforated film for squeezing resin and air.

• The absorbent layer is laid.

• Placing in a vacuum bag and connecting the pump.

(see publication - http://vys-tech.ru/2017/08/24/detali-iz-karbona/). This decision was made as a prototype.

The disadvantage of this method is that when the general stages of obtaining composite products for the automotive industry are known, the manufacture of each product has its own specific modes not specified in the description, and therefore the possibility of its implementation using the above information without additional invention is not confirmed.

The technical problem solved by the invention is to obtain a molded composite bumper with local sections of a given strength, while the density should be in the range of 0.5-2.0 g / cm.

The specified technical result is achieved in that in the known method of manufacturing a composite bumper for a land vehicle, which consists in forming a model, covering the model with a release agent, applying the required number of prepreg layers to the model, applying a perforated film and then an absorbent layer, placing it in a vacuum bag and connecting pump, followed by placement of the product in the furnace under the influence of temperature and pressure, and further cooling and machining of the product,

according to the invention

use a prepreg made of basalt fabric, first they heat it in an oven to 75 ° C at a heating rate of 1.5-2 ° C / minute and maintain it at this temperature for 30 minutes, then produce subsequent heating to 120 ° C with a heating rate of 1, 5 ° C / minute, with exposure at a temperature of 120 ° C for 30 minutes, after which it is cooled at a speed of no more than 3 ° C / minute to ambient temperature, and they ensure the creation of vacuum during the entire cycle of heating, curing and cooling from 0.8 to 0.99 atm.

Use a basaltic prepreg with a weaving density of 240g / m2 with an epoxy content of prepreg in the amount of 42%.

The technical result from the use of all the essential features of the invention is to obtain a product having increased strength characteristics with a significant (up to 40%) weight reduction.

The use of a prepreg of basalt fabric in the manufacture of a bumper, heating the product in an oven to 75 ° C at a heating rate of 1.5-2 ° C / min, followed by exposure at this temperature for 30 minutes, further heating to 120 ° C at a speed of 1 , 5 ° C / minute and holding at a temperature of 120 ° C for 30 minutes, then cooling the product at a speed of no more than 3 ° C / minute to ambient temperature, while creating a vacuum during the entire cycle of heating, curing and cooling the mold from 0.8 to 0.99 atm, allows you to get a product that has increased strength characteristics with a significant (up to 40%) weight reduction.

The use of a prepreg made of basalt fabric with improved absorbent properties (https://basalt.today/ru/2017/04/10491/) allows you to obtain a product with the necessary physical and technical characteristics - increased strength and reduced temperature at a reduced temperature and reduced heat exposure time. weight.

Heating the product from basaltic prepreg in the furnace at a speed of 1.5-2 ° C / min, to a temperature of 75 ° C and a further 30 minutes holding at this temperature when exposed to a vacuum product from 0.8 to 0.99 ATM. promotes the distribution of the binder (resin) over the entire surface and its penetration into the layers of the basaltic prepreg to ensure reliable communication between them.

Subsequent heating of the product from basaltic prepreg when exposed to vacuum from 0.8 to 0.99 atm. up to 120 ° C with a heating rate of 1.5 ° C / min, with exposure at a temperature of 120 ° C for 30 minutes, it contributes to the curing of all layers of basalt prepreg with a binder and the formation of a strong connection of layers of basalt prepreg with the formation of a monolith.

Further cooling when the product is exposed to vacuum from 0.8 to 0.99 atm., Not faster than 3 ° C / min, to the ambient temperature allows gradual cooling of the part in the mold, preventing deformation of the geometry of both the mold itself and the part in her.

Vacuum pressure during the entire cycle of heating, curing and cooling of the product is 0.8 to 0.99 atm. helps to remove air (volatile) particles from the prepreg structure and from the cavity of the vacuum bag as a whole, which ensures high quality of the connection of all layers of the prepreg with each other, without the formation of air bubbles.

When heated at a rate of less than 1.5 ° C / minute, for example, even at a speed of 1.3 ° C / minute, the resin impregnated with the prepreg does not harden in time, thereby going beyond the fabric and the part will turn out to be of poor quality, with low physical and mechanical properties.

When heated at a speed of more than 2 ° C / minute, for example, 3 degrees per minute, the resin impregnated with the prepreg will not have time to spread over the entire surface before curing, thereby the part will turn out to be of poor quality, with low physical and mechanical properties.

A method of manufacturing a composite bumper from basalt prepreg (basalt fabric with a weaving density of 240g / m2 with an epoxy content of 42%) consists of the following main steps:

1) Preparation of the model (form). A special high-temperature release agent is applied to the model.

2) Cut the prepreg. Cutting can be done either manually or automated using a cutting machine.

3) The required number of prepreg layers is applied to the model, aligning each layer to prevent wrinkles and creases.

4) An unperforated release film is placed on top of the last layer of the prepreg.

5) Next, an absorbent (drainage) layer is laid. The drainage layer must be connected to the outlets of the vacuum pump, where two or three additional layers of drainage material must be laid locally.

6) Next, the model with the prepreg layers laid is sealed with a vacuum bag. Around the perimeter, the model is pasted over with a high-temperature sealing tape and covered with a high-temperature vacuum film. A tube connected to a vacuum pump on which a vacuum gauge is to be installed is inserted into the vacuum bag, or a second tube is additionally inserted into the bag and brought to the vacuum gauge.

7) Next, create a vacuum to check the tightness of the bag and, if the tightness is achieved, place the model in the oven. It is recommended that a vacuum be maintained during the entire curing cycle, even during mold cooling. It is advisable to use the highest vacuum - 0.99 atm.

8) Start heating. The heating rate is maintained in the range of 1.5-2 ° C / minute. At this speed, they are heated to 75 ° C. Consistently made several batches of products. The implementation of the method in part of this operation is described below for each batch.

8.1. The first batch of 10 pcs. made by primary heating to 75 ° C at a rate of 1.5 ° C / min.

8.2. The second batch of 10 pcs. produced by primary heating to 75 ° C at a rate of 1.8 ° C / min.

8.3. The third batch in the amount of 10 pcs. made by primary heating to 75 ° C at a rate of 2 ° C / min.

Subsequent operations were performed for all parties in the same sequence and with the same modes.

9) After heating to 75 ° C, was kept at this temperature for 30 minutes.

10) Next, heating was carried out to 120 ° C, with a heating rate of 1.5 ° C / minute.

11) At a temperature of 120 ° C, exposure was carried out in an oven for 30 minutes.

12) Then cooled the form, not faster than 3 ° C / minute.

13) After the model with the manufactured bumper has cooled, the bumper is removed from the model.

14) Next, the manufactured bumper is machined. Namely, technological holes are milled in it and technological brackets and fasteners are glued.

Prepregs are semi-finished composite materials. They are obtained by impregnating a reinforcing fiber base with uniformly distributed polymer binders. Impregnation is carried out in such a way as to maximize the physicochemical properties of the reinforcing material. Prepreg technology allows you to get monolithic products of complex shape with minimal tooling.

The resulting composite bumper from basalt prepreg has local sections with a given strength. So local sections with increased strength are stiffeners and slopes that specify the overall strength of the structure, and are used to attach lighting fixtures to them, as well as to attach to the vehicle body using fasteners.

Local areas with reduced strength are the bumper planes, which provide energy absorption due to the deflection of the less durable contact zone during contact of the vehicle with an obstacle, including the head and trunk of a pedestrian. Moreover, the increased strength of the stiffeners and slopes and the reduced strength of the bumper planes are set by a high density of the composite material equal to 1.6 g / cm ³ in the first case and a low density of the composite material equal to 0.8 g / cm ³ in the second. This is achieved due to the difference in the number of stacked prepreg layers on the tool during molding parts. (from 1 layer (0.2 mm) to the required amount to set the desired thickness of the product, taking into account the fact that 1 layer of the prepreg is 0.2 mm in the finished product.

Tests were made on the bumpers made by the present method in comparison with bumpers made by methods known from the prior art, from other composite materials. The test results showed that the bumpers made according to the claimed method, in comparison with bumpers made from fiberglass and other composite materials, have increased strength characteristics with a significant (up to 40%) weight reduction.

The claimed method can be implemented using known equipment (for example, a Nabertherm KTR 22500 / S furnace and an applied vacuum bag assembled on the basis of a vacuum film, for example, Airtech Wrightlon® 7400) and the described material - basalt prepreg (basalt fabric with a density of weaving 240g / m2 with an epoxy content of 42%).

The claimed invention can be used in the field of engineering, in particular the automotive industry, in the manufacture of structural elements of land vehicles, such as bumpers of vehicles.

Claims (1)

A method of manufacturing a composite bumper for a land vehicle, which consists in forming a model, coating the model with a release agent, applying the required number of prepreg layers to the model, applying a perforated film and then an absorbent layer, placing it in a vacuum bag and connecting the pump, followed by placing the product in an oven under the influence of temperature and pressure, and further cooling and machining of the product, characterized in that they use a prepreg of basalt fabric, first heated in an oven to 75 ° C at a heating rate of 1.5-2 ° C / minute and kept at this temperature for 30 minutes, then produce subsequent heating to 120 ° C with a heating rate of 1.5 ° C / minute, with exposure at a temperature of 120 ° C for 30 minutes, after which it is cooled at a speed of no more than 3 ° C / minute to ambient temperature environment, and ensure the creation of vacuum during the entire heating cycle, exposure at temperature and cooling o t 0.8 to 0.99 atm.