DE102018125243A1 - Core component for an aerodynamic component of a vehicle - Google Patents

Abstract

Core component (10) for an aerodynamic component (100) of a vehicle, comprising a base body (20) with an aerodynamically effective outer contour (22) and a support surface (24) for supporting stiffening tissue material (110), at least in the base body (20) a cavity (30) for reducing the weight of the base body (20) is arranged.

Description

The present invention relates to a core component for an aerodynamic component of a vehicle and a method for producing such an aerodynamic component.

It is known that vehicles are equipped with aerodynamic components in order to influence the flow around the vehicle. On the one hand, such aerodynamic components can have the task of lowering the driving resistance, that is to say the CW value of the vehicle. It is also known that aerodynamic components are used to locally increase the resistance to the airstream and in this way to stabilize the driving of the vehicle. Such stabilizing aerodynamic components are also referred to as spoiler components or spoiler devices.

In the known aerodynamic components, these are often composed of several components. These multiple components are usually based on a central core component around which reinforcing fabric fiber layers are placed. The flowable matrix material can then be introduced into the fabric layers and the aerodynamic component can be finished by subsequent curing of the matrix material.

A disadvantage of the known solutions is that, although the combination of a core component and one or more fabric layers with hardened matrix material makes it possible to provide a stable aerodynamic component, it is equipped with a relatively high weight. A high weight in vehicles usually means that a correspondingly higher fuel consumption has to be accepted. It is also necessary to remove the higher weight with correspondingly more stable fastening options and to incorporate it into the body of the vehicle. Last but not least, the higher weight is also associated with a higher material expenditure in the manufacture of the aerodynamic component or the core component.

It is an object of the present invention to remedy the disadvantages described above. In particular, it is an object of the present invention to reduce the weight of an aerodynamic component in a cost-effective and simple manner.

The above object is achieved by a core component with the features of claim 1 and a method with the features of claim 10. Further features and details of the invention emerge from the subclaims, the description and the drawings. Features and details that are described in connection with the core component according to the invention also apply, of course, in connection with the method according to the invention and vice versa, so that with respect to the disclosure of the individual aspects of the invention, reference can always be made to one another.

According to the invention, a core component is used to manufacture an aerodynamic component of a vehicle. For this purpose, the core component has a base body with an aerodynamically effective outer contour. This aerodynamically effective outer contour or the base body is equipped with a surface for supporting stiffening fabric material. In addition, at least one cavity for reducing the weight of the base body is arranged in the base body.

A core component according to the invention thus already has the aerodynamic outer contour for the aerodynamic component. The fabric material layers subsequently applied lead exclusively to a mechanical stabilization of this outer contour against the attacking airstream during operation of the vehicle. This support surface is essentially smooth, so that fabric material in the form of GRP and / or CFRP material can be easily and, above all, placed smoothly on the support surface. This smooth and essentially crack-free support surface also serves to be able to provide the aerodynamically effective outer contour already explained.

The support surface and thus also the aerodynamically effective outer contour preferably occupies the entire surface of the base body. In other words, the support surface is in particular designed around the base body and in a closed manner. This leads to the possibility that the entire support surface and thus also the entire aerodynamically effective outer contour and also the entire base body can be stiffened with the appropriate fabric material. The application of the fabric material and the introduction of flowable matrix material will be explained in more detail later with reference to a method according to the invention.

In the case of a core component according to the invention, the base body can be made of a plastic material, for example. It is also conceivable that a foam material can be used for the base body. Irrespective of the choice of material for the base body, the core idea according to the invention is the arrangement of at least one cavity within the base body. The cavity has minimal density compared to the material of the base body, so that the cavity in terms of its volume a reduction in weight of the base body. The larger the cavity, the lower the weight of the base body and thus the attainable weight of the aerodynamic component produced from it. The smaller the cavity, the greater the stability of the base body. Due to the fact that the base body is designed with the support surface for the support of stiffening fabric material, the cavity can be made relatively large, since the stability of the base body is basically or essentially exclusively for the manufacture of the aerodynamic component and thus for the stabilization when the support is placed on it Tissue material and when inserting the flowable matrix material is necessary. During normal operation of the vehicle, when the matrix material is hardened, the main force of attack of the airstream on the aerodynamic component is absorbed and removed via the tissue material stiffened by the hardened matrix material. The load absorption in the base body therefore relates essentially exclusively or at least largely to the manufacturing process of the aerodynamic component.

The weight of the base body and thus also of the aerodynamic component can now be significantly reduced by the configuration according to the invention. When designing the cavity, particular attention is paid to the fact that sufficient residual stability is still ensured by the remaining material of the base body for the production with the fabric material. This can be provided by several variants, as will be explained later. Basically, however, it is sufficient to make the cavity sufficiently small in order to be able to provide stability for the application and hardening of stiffening fabric material.

It can be advantageous if, in the case of a core component according to the invention, the base body has or consists of a polymer plastic, in particular in the form of a foam. A polymer plastic is an artificially produced material that forms long chains of molecules through a polymerization reaction. These long molecular chains can be formed in particular in foam form, so that the base body itself can be made available with a reduced density and thus with a reduced weight. The density of the polymeric plastic, particularly in the form of foam, can be, for example, in the range from 70 g / l to 110 g / l. Polymethacrylide, for example, can be used as plastic. In addition to the inexpensive and, above all, easy availability of the plastic as the base body, this leads to a significant simplification in the manufacture of the base body. For example, an injection molding process can be used to manufacture the base body. The flowable or liquid plastic can be introduced and cured within an injection molding cavity. Such a cavity can also be used to foam a plastic foam.

Further advantages can be achieved if, in the case of a core component according to the invention, the wall thickness of the base body around the cavity is made thicker at least in one reinforcement section. Such a reinforcement section relates to the wall thickness in the remaining or normal sections of the base body or the wall of the base body. In particular in zones subject to higher aerodynamic loads, for example the inflow areas or tear-off edges of the aerodynamic component, a reinforcement section with thicker walls can result in the basic body also taking on part of the mechanical stabilization work for the use situation of the aerodynamic component on the vehicle. In addition to the main load, which is dissipated via the fabric material reinforced by hardened matrix material, the base body can thus take on a partial load and provide mechanical stabilization, at least in local areas. The actual load on the component is used to adapt the reinforcement sections accordingly.

It can also be advantageous if, in a core component according to the invention, the cavity is at least partially, in particular completely or essentially completely, filled with a lightweight construction material with a lower density than the base body. Independently and separately from the base body, the lightweight material can also be designed as a lightweight body which is inserted into the cavity. The insertion can take place in particular in the manufacture of the base body. In this way, such a lightweight material can provide internal stabilization by collapsing. If the base body is produced in an injection molding process, in addition to the stabilizing manner, a manufacturing advantage can also be achieved in that the lightweight construction material forms the base core for the manufacture of the base body, so to speak. The lightweight material is also made of plastic, for example in a foam-like manner.

Further advantages can be achieved if, in the case of a core component according to the invention, at least one stabilization web supports two wall sections of the support surface of the base body against one another in the cavity. Such a stabilizing web or two or more such stabilizing webs extend in particular between oppositely aligned support surfaces. For example, the top and bottom of the Aerodynamic component, so that the pressure side and the tension side of the aerodynamic component are connected to one another via the stabilizing web and can exchange force. This leads to local stabilization in the cavity. Such stabilizing webs are preferably provided at several locations. The stabilizing web can preferably be made of the same material and in particular also integrally, monolithically or in one piece with the base body. It is thus possible to design and manufacture the stabilization bar in the same manufacturing step as the base body.

Further advantages can be achieved if, in the case of a core component according to the invention, at least one stabilizing rod arrangement is arranged in the cavity for supporting at least two wall sections of the support surface of the base body. Similarly, as has already been explained with regard to the stabilizing webs, a corresponding stabilizing rod can perform this additional stabilizing task even better. A stabilizing rod structure is understood to mean individual stabilizing rods which are connected to one another and which, for example in the form of a lattice structure, a cross structure, a honeycomb structure or other individual and combined structures, ensure the stabilizing function. The stabilizing rod structure can be part of the base body. However, it can be advantageous if the stabilizing rod structure itself is a separate component which is formed separately from the base body. Manufacturing can thus be made significantly easier since the stabilizing rod structure can be used in the manufacturing process of the base body.

It is also advantageous if, in the case of a core component according to the invention, the base body has at least two separate base body parts which are connected to one another via connecting sections and at least partially enclose the cavity. The separation of the base body into two separate base body parts brings with it a multitude of further advantages. In particular, this facilitates production, since the cavity is only made available by assembling the separate basic body parts. Undercuts or closed cavities, which would otherwise not be possible or could only be produced with great effort, can be avoided in this way. The corresponding size of an associated injection molding tool is also reduced, so that the production of the individual separate basic body parts can be made available more cheaply, more easily and more quickly. The type of connection between the connecting sections can be designed in a reversible as well as in an irreversible manner. Due to the fact that the fabric material encloses the base body in a completely final manner on the aerodynamic component, a reversible or even loose connection of the connecting sections can be sufficient only for the step of the manufacturing process of the aerodynamic component. The connection can also be arranged or the connection sections can also be arranged in the framework or in stabilization webs, so that these are also formed in several parts.

Further advantages can be achieved if, in the case of a core component according to the invention, the connecting sections are aligned in a common connecting plane which extends in particular horizontally and / or vertically through the cavity. Such a connection plane in a horizontal and / or vertical manner allows undercuts through the cavity to be reduced even further or even avoided entirely. The assembly of the individual basic body parts can be made available in this way like the assembly of two egg halves. In this way, the entire manufacturing process can be carried out more easily and quickly.

It can be a further advantage if, in the case of a core component according to the invention, the connecting sections are connected to one another by positive locking and / or by material locking. A form fit is to be understood in particular to mean pressing, fitting, latching or jamming. A material bond is to be understood in particular as an adhesive or welded connection. Of course, form-locking and material locking can also be combined with one another.

• - Auflegen von Gewebematerial auf einer Auflageoberfläche eines Kernbauteils gemäß der vorliegenden Erfindung,
• - Einsetzen des Kernbauteils mit dem Gewebematerial in eine Werkzeugform,
• - Einbringen von fließfähigem Matrixmaterial in das Gewebematerial,
• - Aushärten des eingebrachten Matrixmaterials.

The present invention further relates to a method for producing an aerodynamic component for a vehicle, comprising the following steps:

• Placing tissue material on a support surface of a core component according to the present invention,
• Inserting the core component with the fabric material into a tool mold,
• Introduction of flowable matrix material into the tissue material,
• - Hardening of the matrix material introduced.

By using a core component according to the invention, the same advantages are achieved in a method according to the invention as have been explained in detail with reference to a core component according to the invention.

• 1 eine Ausführungsform eines Aerodynamikbauteils,
• 2 eine Ausführungsform eines erfindungsgemäßen Kernbauteils,
• 3 eine weitere Ausführungsform eines Aerodynamikbauteils mit einem erfindungsgemäßen Kernbauteil,
• 4 eine weitere Ausführungsform eines Aerodynamikbauteils mit einem erfindungsgemäßen Kernbauteil,
• 5 eine Möglichkeit eines Verbindungsabschnitts,
• 6 eine weitere Möglichkeit eines Verbindungsabschnitts,
• 7 eine weitere Möglichkeit eines Verbindungsabschnitts,
• 8 eine Ausführungsform eines Aerodynamikbauteils mit einem erfindungsgemäßen Kernbauteil und
• 9 eine Ausführungsform eines Aerodynamikbauteils mit einem erfindungsgemäßen Kernbauteil.

Further advantages, features and details of the invention emerge from the following description, in which reference is made to FIG Drawings embodiments of the invention are described in detail. The features mentioned in the claims and in the description can each be essential to the invention individually or in any combination. They show schematically:

• 1 one embodiment of an aerodynamic component,
• 2nd one embodiment of a core component according to the invention,
• 3rd another embodiment of an aerodynamic component with a core component according to the invention,
• 4th another embodiment of an aerodynamic component with a core component according to the invention,
• 5 a possibility of a connecting section,
• 6 another possibility of a connecting section,
• 7 another possibility of a connecting section,
• 8th an embodiment of an aerodynamic component with a core component according to the invention and
• 9 an embodiment of an aerodynamic component with a core component according to the invention.

In 1 is schematically the simplest embodiment of a core component according to the invention 10th in an aerodynamic component 100 shown. With this aerodynamic component 100 in this case it is a spoiler device for a vehicle. On an upper side and a lower side, an air stream can be guided, which through the contour, which in 1 is shown in cross section, has an aerodynamic effect. This contour of the aerodynamic component 100 is due to the corresponding aerodynamically effective outer contour 22 of the basic body 20th of the core component 10th made available. This core component is used in the manufacturing process 10th now with a plurality of different layers of fabric material 110 , for example reinforced with GRP and CFRP fibers. Then the fabric material 110 impregnated with a flowable matrix material, which is then cured. The mechanical stiffening and stabilization of this hardened matrix material in combination with the fabric material 110 gives the mechanical stability for the use of the aerodynamic component 100 .

In 1 it can be clearly seen that the core component 30th under its surface 24th for the fabric material 110 a large cavity 30th having. This is free of any material of the basic body 20th , so that the total weight of the core component 10th and thus also the total weight of the aerodynamic component 100 could be significantly reduced. That too is 1 can be seen that in areas subject to higher mechanical stress, such as the inflow area at the left tip of the aerodynamic component 100 as well as at the tear-off edge at the right end of the aerodynamic component 100 the corresponding basic body 20th of the core component 10th with a reinforcement section 26 is provided with increased wall thickness. Thus, additional mechanical stabilization can be achieved in these local areas by the reinforcement in the wall thickness in the reinforcement section 26 to provide.

2nd shows a further embodiment of a core component according to the invention 10th . This is based on the solution that you already have for 1 has been explained. However, here is in the cavity 30th a stabilizing bar 34 with a large number of individual stabilizing bars. This stabilization bar 34 is designed here as a cross shape and serves the two opposite support surfaces 24th support each other and thus stabilize.

3rd shows another possibility of additional stabilization in the cavity 30th . Essentially the same design is shown here as the one 1 shows. However, were also in the cavity 30th three stabilizing bars 32 used, which is between the two support surfaces 24th extend to stabilize the same. In contrast to the stabilizing rod structure 34 according to 2nd , which is separate from the main body 20th is formed, the stabilizing webs 32 integral, monolithic and / or in one piece with the material of the base body 20th be trained like this 3rd shows.

In 4th is shown as the basic body 20th multi-part in two basic body parts 20a and 20b is divided. These are separated by a connection level V , which extends horizontally here. A vertical connection level is also exemplary V shown, which, however, not in this embodiment for separating the base body 20th serves. The connection via the connection sections 28 between the individual body parts 20a and 20b can, for example, according to one or more of the solutions of 5 , 6 and 7 be trained. So here can be a blunt bump 5 , according to a partial overlap 6 or an engaging form fit according to 7 provide the connection functionality individually or in combination with a material connection.

The 8th and 9 show one way the cavity 30th further develop and additionally stabilize. In addition to the solutions according to the 2nd and 3rd also by introducing a lightweight material 40 be made available. This lightweight material 40 can according to 8th fill the entire cavity or according to 9 only part of the cavity 30th to complete.

The above explanation of the embodiments describes the present invention exclusively in the context of examples. Of course, individual features of the embodiments, if technically meaningful, can be freely combined with one another without leaving the scope of the present invention.

Claims (10)

Core component (10) for an aerodynamic component (100) of a vehicle, comprising a base body (20) with an aerodynamically effective outer contour (22) and a support surface (24) for supporting stiffening tissue material (110), at least in the base body (20) a cavity (30) for reducing the weight of the base body (20) is arranged. Core component (10) after Claim 1 , characterized in that the base body (20) comprises or consists of a polymeric plastic, in particular in foam form. Core component (10) according to one of the preceding claims, characterized in that the wall thickness of the base body (20) around the cavity (30) is made thicker at least in one reinforcing section (26). Core component (10) according to one of the preceding claims, characterized in that the cavity (30) is at least partially, in particular completely or substantially completely, filled with a lightweight material (40) with a lower density than the base body (20). Core component (10) according to one of the preceding claims, characterized in that in the cavity (30) at least one stabilizing web (32) supports two wall sections of the support surface (24) of the base body (20) against each other. Core component (10) according to one of the preceding claims, characterized in that at least stabilizing rod structure (34) is arranged in the cavity (30) for supporting at least two wall sections of the support surface (24) of the base body (20). Core component (10) according to one of the preceding claims, characterized in that the base body (20) has at least two separate base body parts (20a, 20b) which are connected to one another via connecting sections (28) and at least partially enclose the cavity (30). Core component (10) after Claim 7 , characterized in that the connecting sections (28) are aligned in a common connecting plane (V) which extends in particular horizontally and / or vertically through the cavity (30). Core component (10) according to one of the Claims 7 or 8th , characterized in that the connecting sections (28) are connected to one another by positive locking and / or by material locking. A method for producing an aerodynamic component (100) for a vehicle, comprising the following steps: - Placing tissue material (110) on a support surface (24) of a core component (10) with the features of one of the Claims 1 to 9 , - inserting the core component (10) with the tissue material (110) into a tool mold, - introducing flowable matrix material into the tissue material (110), - curing the introduced matrix material.

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