DE102014224740A1 - Method for adjusting the degree of coverage of a woven structure of braided fiber strands and braiding device therefor - Google Patents

Abstract

The present invention relates to methods for adjusting the degree of coverage of a braided fiber strand braid structure (12), comprising the steps of: braiding a plurality of fiber strands (12), each consisting of a plurality of fibers, to a braided structure (10) on a mandrel (14) , wherein on at least one surface portion (A, B) of the braided structure (10), a pressure is applied, through which the cross section of the respective fiber strands (12) in this surface portion (A, B) changes. Furthermore, the invention relates to a braiding device (100) for carrying out the method. By the present invention, it is possible to increase the degree of coverage of braided fiber strands after the braiding process.

Description

The present invention relates to a method for adjusting the degree of coverage of a braided fiber strand braid structure, comprising a step of braiding a plurality of fiber strands each consisting of a plurality of fibers into a braided structure on a mandrel. The present invention further relates to a braiding apparatus for adjusting the degree of coverage of a braided fiber strand braid structure, comprising at least a first coil support for receiving at least a first coil having a wound fiber strand; at least one second bobbin for receiving at least one second bobbin having another wound fiber strand; a drive device, by means of which the at least two coil carriers with the coils mounted thereon can be moved about a mold core in such a way that a braiding structure can be created from the fiber strands of the coils in a braiding process, which can be applied to the mold core.

Fiber-reinforced plastics, in particular carbon-reinforced plastics (CFK, colloquially often referred to as carbon) are known from the general state of the art, which are outstandingly suitable as lightweight materials due to their high weight-specific strength and rigidity. CFRP components basically consist of a combination of two materials: the fiber and the plastic matrix. Unless preimpregnated materials are used, the production chain of a fiber reinforced plastic component is as follows. The first step is to process the dry fiber into a preform, also called preform. For this first process step often derived from textile technology processes are used, such as the braiding process. In the subsequent infiltration, the plastic matrix is introduced under pressure into the preform and cured. Since the matrix is usually thermosetting plastics, the component can not be reshaped after curing.

From this, the requirement for a near-net shape fiber deposition in preform production is derived. That is, it is preferred that the fibers already have their final course in the preform. In the braiding process, this is done by braiding a so-called mandrel. Infiltration is a largely independent step from preforming.

In a conventional braiding apparatus, a braided hose or a braided structure which has a plurality of fiber strands which in turn comprise a plurality of fibers is produced. This braiding structure is deposited on a mold core guided through the center of the plant of a braiding device. The braided structure is clamped for this purpose, for example, in a robot and widened by the mandrel to a corresponding diameter. Due to the tension of the fiber strands, the braiding structure attaches to the surface of the mandrel and thus reflects its geometry. Consequently, the geometry of the mandrel is selected so that it corresponds to the shape of the later component.

After the infiltration of the mandrel is no longer needed because the composite itself now has a high rigidity. The mold core is therefore usually subsequently removed again.

By means of the braiding technique, components with complex geometries can be produced. However, the adaptability of the mesh limits this complexity. If, for example, components with changes in circumference are to be produced, this change must only take place to a certain extent. In the case of large changes in circumference, the initially thin braiding structure can indeed adapt to a very large mandrel, although gaps or lanes may form in the braided structure. The reason for these lanes is the limited storage width of the fiber strands. It adapts only to a certain extent to the extent to be fused.

With a certain braiding structure, given by braiding size and fiber material, only cores in a defined peripheral area can be littered. Otherwise, the fibers are too narrow on a smaller cross-section or they can, as in 1 represented, the core at a larger cross-section, no longer completely cover because of resulting gaps.

Both the increased ripple at the small and the gap formation caused by a narrow deposition of the fibers lead to losses in the mechanical material characteristics, such as a lower rigidity and a lower strength.

The design of braided components is therefore either a narrow framework prescribed for the maximum permissible changes in circumference or it is to be expected with lower strengths and stiffnesses. Both approaches limit the exploitation of the lightweight potential of braided structures.

If the course of the fiber predetermined by the load paths is not to be changed, the fibers are to be matched to the core circumference in terms of their storage width. Too narrow pushed together fibers, it is difficult to change them later, since they are already tightly packed and thus hardly allow change. This braiding structure, with its mechanical disadvantages, is therefore avoided, for example, by specifying a minimum amount.

In the DE 10 115 953 A1 a guide of the braiding threads is provided via two mutually moving braided rings. The objective is to avoid the reduction / avoidance of fiber damage on the braiding ring and the associated deterioration of the material quality. This is done by reducing the friction between the fibers.

In the US 6 032 342 A and the US 3 795 944 A the spreading of individual fibers is described. The use of these fibers in a braiding process, however, leads to difficulties because they have to be processed in their spread form.

It is therefore the object of the present invention to avoid the disadvantages described above in a method for adjusting the degree of coverage of a braiding structure made of braided fiber strands and a braiding device for this at least partially. In particular, it is the object of the present invention to provide a method for adjusting the degree of coverage of a braided fiber strand braid structure and a braiding device therefor by means of which in a simple manner even with large changes in circumference in the mandrel a homogeneous braid structure on the same without gaps or lanes between the individual fiber strands is feasible.

The above object is achieved by a method for adjusting the degree of coverage of a braiding structure made of braided fiber strands and a braiding device therefor having the features of claims 1 and 8.

Further features of the invention will become apparent from the dependent claims, the description and the drawings. In this case, features and details that are described in connection with the method for adjusting the degree of coverage, of course, also in connection with the braiding device according to the invention and in each case vice versa, so that with respect to the disclosure of the individual aspects of the invention always reciprocal reference is or can be.

According to one aspect of the present invention, there is provided a method of coverage level matching a braided fiber strand braid structure, comprising a step of braiding a plurality of fiber strands each consisting of a plurality of fibers into a braid structure on a mandrel, wherein on at least one surface portion Flechtstruktur a pressure or a compressive force is applied, through which the cross section of the respective fiber strands changed in this surface portion. Pressure is in the sense of the present invention, in particular for one force per area, d. h., The pressing force acting on a certain surface portion of the braided structure.

By such a method it is possible to adjust or increase the degree of coverage of braided fiber strands after the braiding process. Due to the pressurization of the fiber strands according to the invention after the braiding process, it is also possible to apply fiber strands in the form of a dense or gapless braided structure on mandrels with large cross-sectional changes.

The degree of coverage corresponds to a surface density of the braided structure. A high degree of coverage thus corresponds to a braided structure with a small gap or lane size between the individual fiber strands and a low degree of coverage corresponds to a braided structure with many and / or large gaps or gaps between the individual fiber strands. In the present case, braiding is to be understood as a regular interlacing of several fiber strands. The merging of the fiber strands, however, is not limited to braiding, but may, for example, also be carried out by means of a weaving process or another process known, for example, from the textile industry.

The surface portion to which the pressure is applied is not limited to any specific portion of the braided structure. It may comprise part of the braiding structure or the entire braiding structure.

The pressure applied to the braided structure is preferably applied perpendicularly or substantially perpendicular to the surface of the braided structure or of the mandrel, but may also be applied at a different angle. The pressure is also preferably applied before, in particular shortly before the application of the braided structure on the mandrel. Particularly preferably, the pressure is applied to the braid structure after the braiding structure has been applied to the mandrel, while the braided structure is still located on the mandrel.

The change in the cross section of the respective fiber strands of the braided structure is to be understood as meaning a substantial change in the cross section. Not meant are (often only minor) changes in the cross-section of the fiber strands, which occur due to a stronger or weaker bias of the fiber strands in the fiber direction in a braiding device during the application or braiding of the fiber strands. By fiber direction is meant the direction in fiber length. The cross section of the respective fiber strands can for example be changed such that it is reduced from its original maximum height by about 10 to 90%, preferably by about 30 to 70%, thereby correspondingly increasing in its maximum width. This can also be spoken of a spreading or flattening of the fiber strands. The cross section of the respective fiber strands can be changed by the applied pressure but also stronger or weaker.

According to a further aspect of the present invention, such a pressure can be applied to the braided structure that gaps or, preferably, all the gaps between the fiber strands close or substantially close. By such pressurization, it is possible to provide a gapless braiding structure which, after infiltrating a plastic matrix, has excellent mechanical material characteristics such as high rigidity and high strength. The lanes or gaps between the fiber strands are to be understood as meaning holes through which the surface of the mold core or the surface located beneath the one fiber structure becomes visible. After the braided structure has been pressurized and the streets between the fiber strands have been at least substantially closed, the braided structure is so dense that an underlying mandrel or the underlying surface is no longer visible. The design of the pressurization depends on the fiber strands used and the shape of the mandrel. For example, if there is a mandrel with a large circumferential change, it is advantageous in the sections of the mandrel having the largest cross-section to apply a relatively high pressure on the braiding structure resting thereon in order to close the relatively large streets or gaps. In a mold core with small changes in the circumference, however, a low pressure is sufficient.

Furthermore, for the degree of coverage adaptation according to the invention of a braided structure of braided fiber strands, the pressure on the braiding structure can be applied selectively in a surface section in which the braided structure has a lower surface density than in another surface section. By applying pressure only in certain surface sections on the braided structure, the method can be carried out particularly time and energy efficient. An unnecessary pressurization of already closed surface sections, d. That is, area sections having a sufficiently high degree of coverage or a sufficiently high areal density can be avoided. Which of the surface portions are to be pressurized can be determined, for example, by means of an optoelectronic sensor, the present invention not being limited thereto. Other sensors or detection devices known to those skilled in the art are also conceivable. Thus, for example, it is also conceivable that the geometry of the mandrel is stored in a corresponding memory of a braiding device and the pressurization is performed via a control device depending on the geometry of the mandrel. The control unit then knows in advance in which surface sections on the mandrel an excessively low degree of coverage is likely to occur and can pressurize these surface sections in a targeted manner.

According to another aspect of the present invention, compressed air can be applied to the braid structure by means of a compressed air device for adjusting the degree of coverage of a braided fiber strand braid structure. By the compressed air device and the loading of the braided structure with compressed air, it is particularly easy to pressurize the braided structure before applying the same to the mandrel and thus to spread the individual fiber strands. By means of the compressed air device, the braided structure can of course also be applied correspondingly on the mold core befindlichem with pressure. The magnitude of the pressure of the air depends on the fiber strands used and the shape of the mandrel, i. h., The degree of coverage of the fiber strands resting on it. The air may for example have a pressure between 2 and 10 bar, preferably between 3 and 8 bar, more preferably between 4 and 6 bar. However, lower or higher pressures are also conceivable.

Moreover, it is also possible according to the invention that the pressure is applied to the braided structure by means of mechanical force transmission. By mechanical power transmission, the surface structure can be particularly targeted pressurized. Furthermore, by means of mechanical force transmission, in particular using a sufficiently large force transmission surface, a relatively high pressure can be applied to the braided structure, without running the risk of damaging the individual fiber strands.

According to one aspect of the present invention, the mechanical power transmission to the braided structure may be performed by means of a rolling device. In this way, a particularly uniform and continuous pressurization of the braided structure can be ensured. It is preferred that the rolling device only is placed on surface portions of the braided structure in which the degree of coverage is too low. However, the method is not limited to this. For example, the rolling device can always be pressed onto the braided structure and apply a uniform pressure on the same. In this case, a device for detecting different degrees of coverage could be dispensed with. In the presence of a device for detecting different degrees of coverage, it is also conceivable that the rolling device moves on the braided structure with its own weight fitting over the entire braiding and only in area sections with a degree of coverage or to be thickened braiding a higher pressure between braid and Rolling device is applied.

Moreover, it is conceivable according to the invention to carry out the mechanical power transmission to the braided structure by means of a stamping device. The force transmission to or the pressurization of the braided structure by means of the stamp device can be carried out before or during or after the application of the braided structure to the mandrel. The stamping device may comprise one or more stamps. The stamp surfaces of the individual stamps can in turn be formed from individual, for example rod-shaped elements, by means of which the stamp surface can be adapted to an uneven surface. The pressurization by means of the stamp device is preferably carried out after the application of the braided structure to the mandrel, in particular after the mandrel no longer moves relative to the braiding device. In this case, it is conceivable for the stamp device to move up to a point with a degree of coverage which is too low relative to the mold core with the braiding structure applied thereon and to apply pressure to it selectively. Here, too, it is conceivable that, for example, an optoelectronic sensor is used to identify the different degrees of coverage of the braiding structure.

In particular, it is preferable if the stamping device by a vibrating device of the braiding device with a vibration, for. B. by means of ultrasound, is excited. This improves the spreading result and reduces fiber damage even further.

Another aspect of the present invention relates to a braiding apparatus for adjusting the degree of coverage of a braided fiber strand braid structure, comprising at least a first coil support for receiving at least a first coil having a coiled fiber strand; at least one second bobbin for receiving at least one second bobbin having another wound fiber strand; and a drive device, by means of which the at least two coil carriers with the coils mounted thereon can be moved about a mold core in such a way that a braiding structure can be created from the fiber strands of the coils in a braiding process, which can be applied to the mold core. The braiding device furthermore has a pressure device, by means of which at least one surface section of the braided structure can be acted upon by a pressure through which the cross section of the respective fiber strands in this surface section changes.

As a result of the braiding device according to the invention, the same advantages result as from the method for adjusting the degree of coverage of a braiding structure made of braided fiber strands according to claim 1, which can be carried out by means of the present braiding device.

The printing device is preferably arranged in such a way that pressure can be applied by the printing device perpendicularly or substantially perpendicular to the surface of the braided structure or of the mold core.

If the printing device is designed so that it can be applied to the braiding structure such that gaps between the fiber strands can be closed or substantially closed, a braided structure with excellent mechanical material characteristics, such as a high rigidity and a high strength, can be created become. In this case, it is of further advantage if the pressure by the printing device can be selectively applied to the braiding structure in a surface section in which the braided structure has a lower surface density than in another surface section. For this purpose, the braiding device can have, for example, a detection device such as an optoelectronic sensor, by means of which the surface sections with the different surface densities can be identified. This sensor can then send the corresponding signals to a control device, which in turn causes the corresponding pressurization of the respective surface sections. For this purpose, devices and methods known in the prior art may be used, to which reference will not be made in the present case.

It is a further advantage if the pressure device has a compressed air device, by means of which compressed air can be applied to the braided structure. As a result, it is particularly easy to apply pressure to the braided structure before the application of the same and to spread the respective fiber strands. However, the compressed air device may also be arranged such that it pressurizes the braided structure when it is already applied to the mandrel. The compressed air device has, for example, at least one nozzle, through which the compressed air can be applied to the braided structure. For example, a single nozzle may be provided which extends around the braid structure or core, ie, is movable relative to it in the braiding device. But it can also be provided a plurality of nozzles which are fixedly mounted in the braiding or movable or movable. That is, the one or more nozzles may be movably arranged in the braiding apparatus so as to be able to change their position or at a substantially fixed position in which they are deflectably arranged. The compressed air device with the at least one compressed air device can also be movable relative to the mandrel - linear or radial.

In addition, the printing device according to the invention can have a device for the mechanical transmission of force to the braided structure. Provided that the printing device is designed with a sufficiently large force transmission surface, in this case a relatively high pressure can be applied to the braided structure, without running the risk of damaging the individual fiber strands. Furthermore, the pressure can be applied very specifically targeted to the braid structure.

According to a preferred development, the printing device may comprise a rolling device. This allows the pressure to be applied evenly to the braiding structure. The geometric configuration of the rolling device is arbitrary. The rolling surface may have a straight, concave, convex or non-uniform structure. Preferably, the rolling surface is configured such that it can be positively or substantially positively applied to the periphery of the mold core or the braiding applied thereto or pressed. The rolling apparatus is not limited to any specific material. For a power transmission which is as direct as possible, for example, it can consist at least partially, preferably on its surface, of a dimensionally stable material such as metal, a thermoplastic and / or a duroplastic. In order to provide a rolling device which is adaptable to the contour of the braiding structure located on the mandrel, it may consist of an elastic material, whereby the geometric shape of the rolling device is deformable when pressed against the braided structure. As already mentioned with regard to the compressed air device, the rolling device is not limited to a single roller body. According to the invention, the braiding device can also have a plurality of rollers which can be deflectably fastened or movably mounted around the braiding structure.

Furthermore, the device according to the invention for mechanical power transmission can have a stamp device. With regard to the choice of material and the number of stamp elements, the principle applies to the compressed air device and rolling device.

In accordance with another aspect of the present invention, the printing device may be annular or substantially ring-shaped and disposed about the mandrel during the braiding process. The annular pressure device is not limited to a circular cross-section but may also be configured elliptical or angular. In the case of a circular configuration of the printing device, it is possible, for example, for the compressed air device, the rolling device or the stamp device to be arranged circumferentially therein. The annular printing device may be either statically suspended or movably mounted. If it is arranged to be movable, it can favor spreading or flattening, for example by means of a pulsating movement.

Under the printing device according to the invention is not to be understood as a single printing device. Rather, it is also conceivable, for example, to switch the compressed air device and the rolling device and / or the stamp device together to form a printing device. As a result, it would be possible, for example, to spread or loosen individual fiber strands of the braiding structure initially by means of the compressed air device, in order then to further spread or flatten them with a mechanical pressure device. By such a combination, the risk of damage to the braided structure by the pressurization can be further reduced.

Further, measures improving the invention will become apparent from the following description of some embodiments of the invention, which are shown schematically in the figures. All of the claims, description or drawings resulting features and / or advantages, including constructive details and spatial arrangements may be essential to the invention both in itself and in the various combinations.

Show it:

1 a schematic view of a known in the prior art braided structure on a mandrel;

2 a schematic side view of a braiding device according to the present invention;

3 a schematic front view of a part of the braiding device according to a first embodiment;

4 a schematic front view of a part of the braiding device according to a second embodiment; and

5 a schematic front view of a part of the braiding device according to a third embodiment;

Elements with the same function and mode of action are in the 1 to 5 each provided with the same reference numerals.

1 shows a schematic view of a known in the prior art braided structure 10 on a mold core, which at least in a surface portion A an unsatisfactory degree of coverage of braided fiber strands 12 having. While the degree of coverage in another surface section B, in which the mandrel has a significantly smaller cross-section than in the surface section A, is still sufficiently high, clear gaps or streets appear in the surface section A. 22 between the individual fiber strands 12 , This is to be avoided in a finished and subsequently to be infiltrated or impregnated braiding structure.

Therefore, according to the invention in 2 illustrated braiding device 100 provided. This essentially has an annular body 140 on, at which a first coil carrier 120 for receiving at least a first coil 122 which a wound fiber strand 12 and at least one second coil carrier 130 for receiving at least a second coil 132 which is another wound fiber strand 12 has, are arranged. The braiding device further comprises a drive device, not shown, through which the at least two coil carrier 120 . 130 with the coils attached to it 122 . 132 on the annular body 140 are movable. The spools 122 . 132 can be so around a through the annular body 140 moving mandrel move that out of the fiber strands 12 the coils 122 . 132 in a braiding process a braided structure 10 It is possible to create something on the mold core 14 , preferably a braided ring 150 running, can be applied. This is done by a known in the prior art braiding usually with a variety of bobbins and coils, which will not be discussed in detail in the present case.

The present braiding device 100 however, further includes a printing device 50 by means of which at least one surface section of the braided structure 10 can be acted upon by a pressure through which the cross section of the respective fiber strands 12 changed in this area section. Here is the printing device 50 in the 2 shown example by means of a fastening device 60 with the annular body 140 connected. The fastening device 60 But not directly on the ring-shaped body 140 be attached. It is also conceivable that the fastening device 60 not shown intermediate elements on the annular body 140 , or at another element of the braiding device 100 is arranged. The printing device 50 does not have to be at a fixed distance to the annular body 140 can be arranged, but can relative to this movable in the braiding device 100 be arranged. The arrangement of the printing device 50 is not limited to the direction of braiding (arrow in 2 ) after the braiding ring 150 to be arranged. For example, it can also be concentric with the braiding ring 150 or in Flechtrichtung at least partially in front of the braiding ring, so right of him in 2 be arranged.

As in 2 represented, it is by means of the printing device according to the invention 50 it is possible to increase the insufficient degree of coverage in the surface portion A while the mandrel 14 with the braid structure applied thereon 10 (in the direction of arrow) through the braiding device 100 emotional. The respective fiber strands 12 usually consist of a plurality of individual filaments or fibers, for example 12000-50000 pieces per strand, each with a diameter of about 5 to 71 microns. Since these deposit not only next to each other, but also one above the other in the deposition on the mandrel, can be by a flattening of the fiber strand 12 through the printing device 50 a wider filing of the fiber can be achieved. The printing device 50 in this case moves relative to the surface of the mandrel 14 ,

3 schematically shows an embodiment of the present invention, in which the printing device 50 a compressed air device 20 having. The compressed air device 20 again has at least one nozzle 21 on. In 2 an embodiment is shown in which the compressed air device 20 a plurality of nozzles 21 comprising, from the annular printing device 50 to the braided structure 10 stick out. The compressed air device 20 but is not limited to this. The nozzles 21 can also into the printing device 50 be arranged offset in it. The nozzles 21 are not limited to any particular embodiment. They each form a substantially tubular device, which over its entire Length may have the same surface area, expand and / or rejuvenate. For example, they may also be holes in the compressed air pressure device 50 be formed on the braid structure 10 demonstrate. Furthermore, it is conceivable that the printing device 50 no plurality of nozzles 21 but only a single nozzle 21 having on the inner periphery of the printing device 50 is arranged movable, pivotable and / or rotatable.

4 shows a further embodiment of the present invention, in which the printing device 50 a rolling device 16 having. With regard to arrangement and number of structural elements applies to the rolling device 16 basically the compressed air device 20 executed. That is, the rolling device 16 can a roller 17 or more rolls 17 having, fixed or movable on the printing device 50 can be arranged. In the 4 illustrated rollers 17 have a concave cross-section which is at least substantially positive fit on the curved surface of the mandrel 14 or the braiding structure resting thereon 10 fits. The geometric design of a roller 17 but is not limited to this. The rolling surface may have a straight, concave, convex or non-uniform structure. A roller 17 is not limited to any specific material. For the most direct possible transmission of force, for example, it can consist at least partially, preferably on its surface, of a dimensionally stable material such as metal, a thermoplastic and / or a duroplastic. To a roller 17 to create the contour of the mold core 14 braided structure 10 is adaptable, it may consist of an elastomer, whereby the geometric shape of the rolling surface when pressed against the braid structure 10 is deformable.

5 shows a further embodiment of the present invention, in which the printing device 50 a stamp device 18 having. With respect to arrangement and number of structural elements applies to the stamping device 18 basically the rolling device 16 and to the compressed air device 20 executed. In the 5 schematically and exemplified punch device 18 again has a plurality of punches 19 on that at the printing device 50 are arranged radially inwardly projecting. The stamp area of the respective stamp 19 is designed curved so that they are at least substantially positive fit on the curved surface of the mandrel 14 or the braiding structure resting thereon 10 can be applied. To a stamp 19 to create the contour of the mold core 14 braided structure 10 is adaptable, it may at least partially consist of an elastomer, whereby the geometric shape of the stamp surface when pressed against the braid structure 10 is deformable. The stamp surfaces of each stamp 19 may in turn be formed of individual, for example, rod-shaped elements, by which the stamp surface of an uneven surface can be adjusted.

In addition to the embodiments illustrated in the figures, according to a preferred embodiment, a plurality of printing devices according to the invention 50 be combined with each other. That is, it is also possible to provide a braiding device which is a compressed air device 20 , a rolling device 16 and / or a stamp device 18 which, in braiding direction (arrow in 2 ) one after the other, ie, from right to left in 2 , are arranged. This can be a braided structure 10 by a first printing device 50 with a compressed air device 20 pneumatically treated and then through another printing device 50 be treated mechanically with a rolling and / or stamping device. The combination of the individual printing device is arbitrary and can be adapted to the respective requirements.

LIST OF REFERENCE NUMBERS

10

braided

12

tow

14

mold core

16

rolling device

17

roller

18

stamping device

19

stamp

20

Pneumatic device

21

jet

22

streets

50

printing device

60

fastener

100

braider

120

first coil carrier

122

first coil

130

second coil carrier

132

second coil

140

annular body

150

braiding

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 10115953 A1 [0011]
• US 6032342 A [0012]
• US 3795944A [0012]

Claims (15)

Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ), comprising a step of braiding a plurality of fiber strands ( 12 ), each consisting of a plurality of fibers, to a braided structure ( 10 ) on a mandrel ( 14 ), characterized in that on at least one surface portion (A, B) of the braided structure ( 10 ) a pressure is applied, through which the cross section of the respective fiber strands ( 12 ) in this area section (A, B) changed. Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ) according to claim 1, characterized in that such a pressure on the braided structure ( 10 ) is applied that lanes ( 22 ) between the fiber strands ( 12 ) or substantially close. Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ) according to claim 1 or 2, characterized in that the pressure on the braided structure ( 10 ) specifically in a surface section (A), in which the braided structure ( 10 ) has a lower surface density than in another surface portion (B) is applied. Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ) according to one of claims 1 to 3, characterized in that by means of a compressed air device ( 20 ) Compressed air on the braided structure ( 10 ) is applied. Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ) according to one of claims 1 to 4, characterized in that the pressure by means of mechanical power transmission to the braid structure ( 10 ) is applied. Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ) according to claim 5, characterized in that the mechanical power transmission to the braided structure ( 10 ) by means of a rolling device ( 16 ) is carried out. Method for adjusting the degree of coverage of a braided structure ( 10 ) of braided fiber strands ( 12 ) according to claim 5 or 6, characterized in that the mechanical power transmission to the braided structure ( 10 ) by means of a stamping device ( 18 ) is carried out. Braiding device ( 100 ) for the degree of coverage of a braided fiber strand braid structure ( 12 ), comprising: at least one first coil carrier ( 120 ) for receiving at least a first coil ( 122 ) comprising a wound fiber strand ( 12 ) having; at least one second coil carrier ( 130 ) for receiving at least one second coil ( 132 ), which another wound fiber strand ( 12 ) having; a drive device, by which the at least two coil carriers ( 120 . 130 ) with the coils attached thereto ( 122 . 132 ) in such a way around a mold core ( 14 ) are movable, that from the fiber strands ( 12 ) of the coils ( 122 . 132 ) in a braiding process a braided structure ( 10 ) which can be built on the mandrel ( 14 ), characterized in that the braiding device ( 100 ) further a printing device ( 50 ), by means of which at least one surface section (A, B) of the braided structure ( 10 ) can be acted upon by a pressure through which the cross section of the respective fiber strands ( 12 ) in this area section (A, B) changed. Braiding device ( 100 ) according to claim 8, characterized in that by the printing device ( 50 ) such a pressure on the braided structure ( 10 ) can be applied that lanes ( 22 ) between the fiber strands ( 12 ) are closable or substantially closable. Braiding device ( 100 ) according to claim 8 or 9, characterized in that the pressure by the printing device ( 50 ) on the braided structure ( 10 ) in a surface section (A), in which the braided structure ( 10 ) has a lower surface density than in another surface section (B), can be selectively applied. Braiding device ( 100 ) according to one of claims 8 to 10, characterized in that the printing device ( 50 ) a compressed air device ( 20 ), by which compressed air to the braid structure ( 10 ) can be applied. Braiding device ( 100 ) according to one of claims 8 to 11, characterized in that the printing device ( 50 ) a device for mechanical power transmission to the braided structure ( 10 ) having. Braiding device ( 100 ) according to claim 12, characterized in that the mechanical power transmission device comprises a rolling device ( 16 ) having. Braiding device ( 100 ) according to claim 12 or 13, characterized in that the device for mechanical power transmission a stamp device ( 18 ) having. Braiding device ( 100 ) according to one of claims 8 to 14, characterized in that the printing device ( 50 ) is annular or substantially ring-shaped and during the braiding process around the mandrel ( 14 ) is arranged around.

Images