DE102011015947A1 - Fiber composite multi-layer body component and its manufacturing process - Google Patents

Abstract

The present invention provides a method for making a Class A surface composite fiber composite multilayer body component and the composite fiber multilayer body component itself. The method comprises the steps of spraying an in-mold coating system with internal release agent directly on the inside of the mold and at least partially curing, thereby forming a first layer. Furthermore, the spray application of a polymer material is carried out and allowed to cure at least partially, thereby forming a second layer as a damper layer. Then follows the damper layer in the form of introducing a fiber material and a matrix-forming polymer material, thereby impregnating the fiber material with the matrix-forming polymer material, and at least partially curing of the matrix-forming polymer material and forming a fiber-reinforced composite layer, and finally the demolding of the finished body component.

Description

The invention relates to a method for producing a fiber composite multilayer body component with a Class A surface and a body component.

Fiber-reinforced plastics are increasingly used in automotive engineering for body parts, since they are easily malleable and have low weight with high stability. However, in the case of varnished fiber-reinforced plastic components in the field of vision, the effect of climatic changes such as heat, cold or atmospheric moisture results in clearly visible images of individual fibers on the paint surface. The resulting restless and matte surface does not meet the quality requirements of a Class A surface for the field of vision of a motor vehicle body.

A bodywork component with a high quality surface and a method for its production are in the DE 102 07 295 A1 described. First, an outside, thin, colored plastic film is provided here, on the inside of a protective layer is applied to form an intermediate product. The shaping can be done either on the plastic film or on the intermediate product of plastic film and inside protective layer by deep drawing. The intermediate product is then backfoamed on the inside with a plastic to form a fiber-reinforced layer, wherein at the same time the supply of the reinforcing fibers takes place. Because the plastic film is extremely smooth on the outside, it can form a Class A surface.

Similarly, the DE 103 08 582 A1 to provide a deep-drawn, film-like outer skin, on which a thin film of liquid plastic is applied, which prevents after curing with the subsequent foaming with a fiber-reinforced material, the outer appearance of the outer skin is impaired. In the DE 10 2006 049 913 A1 For example, a molded article having a decorative surface and a method of manufacturing the same are disclosed. Again, the decorative surface consists of a thermoplastic film, on the inside of an elastic intermediate layer is applied. The thermoplastic film is first deep-drawn before the elastic intermediate layer is applied by casting, spraying or co-extruding. Finally, a plastic carrier part is produced by injection molding, foam back, rear or back lamination.

A disadvantage with these procedures is that first of all a plastic film has to be produced, from which subsequently a self-supporting component shape is produced by a forming process such as deep-drawing. To ensure sufficient mechanical stability, the plastic film used for this purpose must have a sufficient thickness. In the DE 102 07 295 A1 For example, 1.3 mm are disclosed. The prior art manufacturing processes require a number of process steps to achieve class A surfaces and are feasible only with increased material cost.

Based on the above-mentioned prior art, the object of the present invention is to provide an improved method for producing a body component with Class A surface.

This object is achieved by a method having the features of claim 1. Further developments are set forth in the subclaims.

It is a further object of the present invention to provide a body component with Class A surface.

This object is achieved by a body component with the features of claim 7.

The inventive method for producing a fiber composite multilayer body component with a Class A surface first comprises the first step a) spray an in-mold coating system with internal release agent in a form whose inside images the surface of the body component. As a result, a first layer is formed, which is at least partially allowed to harden. In the next step b), a polymer material is also sprayed in and at least partially allowed to cure, this second layer being formed as a damper layer. Then, in a third step c), a fiber material and another matrix-forming polymer material are introduced into the mold on the damper layer, and the fiber material is impregnated with the matrix-forming polymer material. A further step d) follows with the at least partial curing of the matrix-forming polymer material, wherein a fiber-reinforced composite layer is formed, which contacts the damper layer, but not the IMC layer. Thus, advantageously, the fibers of the fiber material can not be imaged on the surface of the body component. In the last step e), the finished, multilayer fiber composite body component is removed from the mold.

The damper layer arranged between the first layer and the fiber-reinforced composite layer reliably prevents individual fibers from the fiber material from being imaged in the outer IMC layer and thus from the affect the external appearance of the body component.

Furthermore, the present method is efficient because it requires few process steps. The outer IMC layer, which directly forms the Class A surface, is produced directly in the mold for the body component and provided with the inner damper layer. Therefore, no separate film has to be produced and, for example, formed by deep-drawing. Thus, in addition to the number of process steps, the expenditure on equipment can be reduced. In addition, the amount of materials used can be reduced because less material can be used as the outer surface for the IMC layer than for a separate film.

The spray-in of the damper polymer material into the mold can take place separately in time, so that spraying is carried out on the in-mold coating layer. Alternatively, however, the first and the second layer can also be combined to form a combined IMC damper layer by carrying out the first two steps a), b) together by spraying a combined in-mold coating and damping polymer material.

The introduction of the fiber material in step three can be realized by the insertion of one or more fiber arrangement. Here, a fiber arrangement is understood to mean a fiber mat, a fiber braid, a fiber fabric, a nonwoven fabric, a fiber ribbon, a fiber bundle, etc. The insertion of the fiber arrangement (s) in the mold takes place before the matrix-forming polymer material is introduced into the mold, which can be done for example by spraying, spraying, brushing or pouring. Alternatively or in addition to the use of a fiber insert, cut short, long or continuous fibers may be used which are introduced into the mold in a mixture together with the matrix-forming polymer material, such as by spraying, spraying, brushing or pouring.

Thus, formation of the fiber-reinforced composite layer may be carried out in a known manner by a fiber spray method, a resin transfer molding (RTM) process, or a sheet molding compound (SMC) process.

The introduction of the fiber material, for example, by a fiber spray process, depending on the type of fiber material used allows a great flexibility in terms of thickness and density of the introduced fiber layer. The use of an RTM process allows for the body component according to the invention a lightweight mass production with large quantities. Alternatively, the SMC process makes it possible to premix the necessary components fiber material and polymer material and to feed directly to the further processing in the mold.

Advantageously, can be generated by the entry of the IMC layer, depending on the quality claim, a tool-dropping surface layer or a Lackiergrundlage. Thus, the IMC layer, for example, by means of a coloring IMC system as a finished paint surface without any post-processing steps or due to the generated Class-A surface as Lackiergrundlage be executed.

The use of the IMC layer as the surface of the body component has the advantage of a great freedom of design and, depending on the materials used, a very good resistance to light and aging. Since only a thin IMC layer is applied in the mold in the process according to the invention, solvent contents may be low, with which the emissions could be reduced. In addition, the IMC layer allows a very good adhesion to the simultaneously or subsequently applied inner damper layer.

The method according to the invention can use an IMC system with internal release agent, which essentially comprises a curable lacquer or a plastic. Two-component paint systems can be used.

The polymer materials for forming the damper layer and the matrix of the fiber-reinforced composite layer may substantially contain a synthetic resin or a polyurethane; a different or advantageously the same polymer material can be used for both layers, so that both layers bond well. The fibers of the fiber material may consist of a carbon, carbon or carbon, glass or plastic material or combinations thereof, also conceivable is the use of ceramic or metal fibers.

The use of a curable lacquer for the outer IMC layer provides the finished body surface in the body component according to the invention, without rework being necessary. Since the IMC layer contains color pigments and thus can already have a desired color, a subsequent coating can be omitted cost-saving.

Alternatively, a plastic may be used, which serves as a Lackiergrundlage. Depending on the material of the outer IMC layer, the material for the damper layer can be selected to allow optimum adhesion of the layers to each other. The same goes for the Polymer material of the fiber-reinforced composite layer, which, like the material of the damper layer, may contain various synthetic resins or polyurethanes.

Further, the present invention provides a body member having a Class A surface. This can be obtained in particular by the above-described method according to the invention for producing a body component. The body component comprises a first layer, which is an outer IMC layer, the surface of which is designed as a finished paint surface or as a paint base. A second layer is formed by an internal damper layer, which rests against a side of the in-mold coating layer facing away from the surface. Adjacent to the internal damper layer is a fiber-reinforced composite layer. The damper layer is designed such that the fibers of the fiber-reinforced composite layer do not come into contact with the outer IMC layer and thus do not form on the surface of the body component that is formed by the in-mold coating layer.

A major advantage of the body component according to the invention is in addition to the avoidance of the superficial Faserabbildung in its simple production, is created by the lower process costs and reduced use of materials, a body component with Class A surface.

For the production of the body component according to the invention, first of all a negative tool mold can be provided. The IMC system with internal release agent is "painted" into the mold to form the IMC layer, i. H. preferably applied by spraying, and finished in a subsequent curing process. Due to the quality of the negative tool shape and the advantageous properties of the IMC system, a reworking of the resulting surface is superfluous. For this purpose, a paint system with color pigments can already be used, which corresponds in color and surface structure of the paint of the rest of the body. An elaborate repainting of the body component according to the invention can thus be dispensed with.

As a result of the IMC layer separated from the fiber composite layer by means of the damper layer, the body component is resistant to aging even after long-term weathering effects due to light, moisture and temperature fluctuations, and exhibits no imaging of the fibers.

A fiber content in the fiber-reinforced composite layer may be about 15% by volume to about 60% by volume. By appropriate selection of the matrix-forming polymer material and the fiber material and the variation of the volume ratios shrinkage behavior and thermal expansion can be adjusted within certain limits.

For example, in a fiber spray process, a still liquid reaction mixture (for example polyurethane) with fibers (for example long fibers with a typical length of 5 to 25 mm) can be applied by spraying from a mobile mixing head to the damper layer. Here, the fibers can be cut directly on the mixing head and transported into the spray. The reaction mixture can cure under pressure and / or heat to the fiber reinforced layer.

Another method is the RTM process, which makes it possible to handle larger quantities in lightweight series production. First, a fiber arrangement or fiber insert is placed on the dishing layer in the negative mold, this is closed to introduce the matrix-forming polymer material in the mold cavity, for example, to inject. After complete filling of the cavity, the polymer material is cured at the predetermined processing temperature. Depending on the polymer material used, a predetermined closing force must be applied through the closed mold to keep it closed.

Further, an SMC process may be suitable for forming the fiber reinforced composite layer. The necessary components of fiber material and polymer material are already premixed and are ready for processing. The component mixture is processed into flexible films or plates and thus provided as SMC semifinished product. The SMC semi-finished product can be cut to a desired shape and placed in the negative tool mold. The SMC semi-finished product is further processed into the finished component by extrusion or other suitable processes.

After the final curing of the components and the bond between the layers, the finished body component is demolded and can be fed directly to the assembly without further surface treatment.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10207295 A1 [0003, 0005]
• DE 10308582 A1 [0004]
• DE 102006049913 A1 [0004]

Claims (7)

Method for producing a fiber composite multilayer body component with a Class A surface, comprising the steps: in a mold for the manufacture of fiber composite body parts, the inside of which depicts the surface of the body component, a) spray-coating at least one in-mold coating system with internal release agent directly on the inside of the mold and at least partially curing, thereby forming a first layer, b) allowing spray application of a polymer material and at least partially curing, thereby forming a second layer as a damper layer, c) to the damper layer in the form of introducing a fiber material and a matrix-forming polymer material, thereby impregnating the fiber material with the matrix-forming polymer material, d) at least partially curing the matrix-forming polymer material and forming a fiber-reinforced composite layer, and e) demolding the finished bodywork component. Method according to claim 1, characterized in that in step b) the spray-coating of the polymer material onto the in-mold coating layer takes place after step a) has been carried out, or together performing steps a) and b) by spray-coating a combined in-mold coating and damper polymeric material, wherein the first and second layers form a combined in-mold coating damper layer. Method according to claim 1 or 2, characterized in that in step c) the introduction of the fiber material By inserting at least one fiber arrangement, in particular a fiber mat, a fiber braid, a fiber fabric, a fiber fleece, a sliver, a fiber bundle, before introducing the matrix-forming polymer material by spraying, spraying, brushing or pouring, and or - Made by spraying, spraying, brushing or casting of short, long or continuous fibers together the matrix-forming polymer material. Method according to at least one of claims 1 to 3, characterized in that step c) is carried out by a fiber spraying process, a resin transfer molding process or a sheet molding compounding process. Method according to at least one of claims 1 to 4, characterized in that the in-mold coating layer is carried out as a finished paint surface or as Lackiergrundlage. Method according to at least one of claims 1 to 5, characterized in that the in-mold coating system contains a curable lacquer or a plastic and / or the polymer material of the damper layer is a synthetic resin or a polyurethane and / or the fiber material contains reinforcing fibers of carbon, glass, and / or plastic and / or the matrix-forming polymer material comprises a synthetic resin or a polyurethane. A composite fiber multilayer body member having a Class A surface producible by the method of any of claims 1 to 6, characterized in that the body part at least - As a first layer has an outer in-mold coating layer whose surface is formed as a finished paint surface or as Lackiergrundlage, and - As a second layer has a damper layer which abuts a side facing away from the surface side of the in-mold coating layer, and - Has a voltage applied to the damper layer fiber reinforced composite layer, wherein the damper layer is designed so that the fibers of the fiber reinforced composite layer do not image in the surface of the body component, which is formed by the in-mold coating layer.