The invention relates to a method for joining together parts made of a composite material. Parts of this type consist of one or more layers of fibers embedded in a matrix made of plastics materials. The plastics material matrix may be a thermoplastic or a thermoset; the choice of the plastics material matrix is usually determined by the properties which the finished product is required to have.
In a conventional manner of joining together two parts made of composite material, the parts are placed flat against one another. Subsequently, the thermoplastic matrix is melted under the influence of heat, after which the parts are fastened to one another under pressure by local fusion. In such a manner of fastening, a flange is usually formed on one or both parts, at the location of which flange or flanges the connection is then produced. Examples include the joining of a web plate provided with flanges to two accompanying purlins so as to form an I-shaped beam.
However, producing a connection between two composite parts in this way is not without its drawbacks. Firstly, the presence of one or more flanges on one of the composite parts, intended to produce the connection, can be problematic. Although a flange shaped in this way is readily possible in the case of a composite part which is otherwise flat, in the case of non-flat composite parts, such as an undulatory web for an I-shaped beam, shaping a flange is awkward, since this would also impart a non-flat shape to the bend line. The attachment of a flange by bending with respect to a non-straight bend line is, however, rendered difficult as a result of the fact that the deformation associated therewith causes high stresses in the plane of the flange and the web. A further drawback is that the flanges in the finished construction do not always contribute efficiently to the overall strength and rigidity properties. Although they do ensure the necessary connection between the web and purlins, this does not always lead to an effective contribution in the aforementioned properties.
In certain cases, the additional weight associated with flange connections of this type can be a drawback. This is relevant, in particular, in applications in aviation and space travel. Often the flanges are formed by extending the layers of fiber material continuously into the flange or flanges. If there is a specific prescribed minimum thickness of the flanges, the remainder of the respective composite part must then also have a specific layer thickness, and this is not always necessary for reasons of rigidity and strength.
The object of the invention is therefore to provide a method for joining together composite parts that does not have these drawbacks. That object is achieved by means of a method for joining together constructional parts which are made of a composite material and extend transversely to one another, such as a flange and a web of a profile, including the steps of:
According to the invention, the use of connecting flanges is dispensed with when producing a connection between two composite parts. Instead, a thermoplastic material, which after melting under the influence of heat and pressure forms the complete connection, is allowed to flow out between the abutting edge of one of the composite parts and the directly opposing face of the other composite part. This is possible because the properties of the connection are dictated by the thermoplastic without the layers of fibers proving to be the decisive factor in this regard. This finding therefore allows the production, using less material, namely without the hitherto conventional flanges, of a connection which meets the requirements placed on strength and rigidity.
The thermoplastic material which is allowed to flow out can, for example, derive from the parts to be joined together themselves. Under the influence of heat, the thermoplastic material of the parts becomes fluid in such a way that said thermoplastic material flows out under pressure into the connecting region. Since the amount obtained in this way of thermoplastic material in the connecting region is limited, this variation of the method is particularly suitable for constructions which are subject to relatively light loads. In addition, or alternatively thereto, additional thermoplastic material can be added to the connecting region. The connection is then produced using a relatively large amount of thermoplastic material, so connections produced in this way using additional thermoplastic material are suitable for constructions which are subject to heavier loads.
The connections obtained in this way must be able to meet various requirements. A distinction must be drawn in this regard between the requirement of strength and the requirement of rigidity. The first requirement is critical if the connection must be able to withstand maximum loads. In the case of a conventional connection, the shearing force from the web plate is transferred over a broad width, as determined by the width of the flange or flanges, onto the surface of the purlin (in the case of an I-shaped beam or T-shaped beam). In the case of a product produced using the present method, this width is considerably lower and is limited to the width of the bead made of thermoplastic material.
The method according to the invention may, in particular, include the steps of:
A method of this type is particularly suitable for stiffeners which are attached to floor joists and for annular stiffeners on web plates.
For constructional parts which are subject to relatively high loads, the leading edge of one constructional part can also be widened. This increases the boundary surface area between the web plate and the purlin. The advantage of this is that, for otherwise equal shearing forces, the shear stress in the boundary surface can remain lower.
In particular, this can involve carrying out the steps of:
The thermoplastic material in the longitudinal cavity is preferably filled with fibers, for example to an amount of 60%. This improves the stability of the filling material in the longitudinal cavity, yielding a stabler construction.
The stability can further be improved by the step of:
Another possible embodiment of the method according to the invention includes the steps of:
In this method, there is therefore no need to remove the leading edge of the respective constructional part. The original leading edge is placed directly against or almost against the other constructional part. The beads of thermoplastic material on either side of the leading edge ensure effective transmission of force in this embodiment.
The thermoplastic material used in the connecting region is preferably PEI, PEKK or PEEK.
A fiber-reinforced composite material can be used in the method according to the invention. Various materials can be used as the fiber reinforcement; examples include metal-reinforced composite material, or composite material impregnated with PEI, PEKK or PEEK.
The method according to the invention can be carried out in various ways. According to a preferable option, the method according to the invention includes the steps of:
As stated hereinbefore, in the case of specific constructions which are subject to relatively heavy loads, the connection between the constructional parts can be obtained by adding thermoplastic material. This can be achieved, in particular, by introducing that thermoplastic material in the form of a filling element. The filling element can be preproduced, for example by means of extrusion or pressing, and be positioned at the desired location in the connecting region. This can involve, for example, applying two filling elements on either side of an abutting constructional part. According to still another option, one or more filling elements can be applied on either side of the abutting constructional part and between that abutting constructional part and the other constructional part. The filling element can consist of a thermoplastic material which is filled with relatively short reinforcing fibers.
To ensure a good connection, use is made in the connecting region of a thermoplastic material which is similar to the thermoplastic material of the composite material of the constructional parts. The method according to the invention also includes the fusing under the influence of heat and pressure of the constructional parts in their entirety.
The mould which is used in this case follows closely the contours of the products to be produced. The overall assembly consisting of the mould and the workpiece, which is enclosed therein and comprises constructional parts consisting of composite and, if appropriate, filling elements, is placed into an autoclave. In the autoclave the assembly as a whole is exposed to heat and excess pressure. The thermoplastic material of the composite parts and of any filling elements melts in this case completely, thus totally fusing said components.
The invention further relates to a construction produced using the method as described hereinbefore. This construction comprises at least two constructional parts which are directed transversely to one another in such a way that the leading edge of one of the constructional parts abuts against or in proximity to a surface of the other constructional part so as to form a connecting region, and also a connection which is made of thermoplastic material which is located in that connecting region. This may be a T-shaped profile, an I-shaped profile and the like.
The invention will be described hereinafter in greater detail with reference to a few exemplary embodiments illustrated in the figures, in which:
The I-shaped beam shown in
This also applies to the variation from
The variation from
The variation from
The variation from
The overall assembly consisting of the mould 25, the purlins 2, 3, the web plate 1 and the filling elements 20 is placed into an autoclave and subjected to heat and pressure. This causes the thermoplastic material of the purlins 2, 3, the web plate 1 and of the filling elements 20 to melt. The thermoplastic material of said components blends in such a way that after cooling the finished I-shaped beam according to
The above-described connections can be used in all types of constructions and in particular in girders for use in aviation and in space travel. Examples of applications of this type include the supporting beams as used in the floor of a cockpit.
Number | Date | Country | Kind |
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2000570 | Apr 2007 | NL | national |
Number | Date | Country | |
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Parent | PCT/NL2008/050186 | Apr 2008 | US |
Child | 12572697 | US |