The present application is a National Phase entry of PCT Application No. PCT/FR2014/000109, filed May 20, 2014, which claims priority from FR Patent Application No. 1301170, filed May 22, 2013, which applications are hereby incorporated by reference in their entireties.
The present invention relates to the manufacture of parts made of composite material by automatic fiber layup machines, and more particularly to a method of defining fiber trajectories on a layup surface for automatic layup machines.
There are known composite material parts produced by methods called fiber placement, by superposing several plies of fiber in different directions. In this document, the term “fiber placement” refers to the placement of tows, in which each ply is made by laying up in contact on a mold of bands side by side, each band being formed of several independent tows arranged side by side, and the placement of bands in which each ply is formed by laying up in contact on a mold of bands side by side, each band being formed of a single tow, of a greater width than in the case of the placement of tows. The tows typically used are unidirectional and include a multitude of filaments. The laid fibers can be pre-impregnated with resin or not. The technology for the placement of tows, using tows of a smaller width, enables laying up on layup surfaces of complex shapes. Parts are manufactured by automatic placement machines, to which are given the trajectories of fibers to produce the plies. In the case of the placement of tows, these machines are typically called fiber placement machines or AFP machines (Automated Fiber Placement) and tape placement machines or ATP machines (Automated Tape Placement) in the case of the placement of bands.
The fiber trajectories are typically defined by software by means of a rosette, consisting of a system of axes associated to a transfer method which enables the definition of a fiber direction on all points of a surface. Today there are different rosettes, based on different transfer methods, which are recognized and used in the aerospace sector according to the layup surface, such as for example Cartesian rosette or the translation rosette.
Each trajectory is generated by defining the direction of the trajectory at different analysis points of the layup surface, also called propagation points, by transfer of the axes system to said analysis point according to the associated transfer method. These transfers of the axis system for the propagation points require calculation time which can prove to be relatively long, particularly in the case of complex surfaces.
The trajectories obtained are then typically subjected to a curvature analysis, commonly called “steering” analysis, and/or an angular deviation analysis. The steering analysis at an analysis point of a trajectory consists of calculating the value of the mean radius of curvature in the plane tangent to the surface at the analysis point.
Following these analysis results, the trajectories must be redefined manually to adjust the trajectories to the acceptable or achievable minimum radii of curvature with a given fiber, and to the maximum angular deviation desired by the designer of the part. Therefore, the definition of the trajectories can prove to be long and tedious.
In the case of non-continuous layup surfaces comprising recesses and/or embossments, in particular for producing reinforcements, the positioning of prefabricated reinforcements, the positioning of honeycombs or others, the definition of satisfactory trajectories at the level of these discontinuities proves to be complicated, and requires lengthy manual operations.
The purpose of the present invention is to propose a solution aiming to overcome at least one of the aforementioned disadvantages.
To this end, embodiments of the present invention provide a method for defining the trajectories of the fibers on a layup surface for producing at least one ply having a given theoretical orientation, for producing of parts made of composite material by the laying up of fibers, wherein the method comprises the definition of constraint curves, and/or the definition of at least one constraint grid from the definition of the layup surface, with association of at least one constraint vector to each node of the constraint grid, the constraint curves and the constraint vectors being representative of geometric constraints, geodesic curvature radius constraints, angular deviation constraints and/or stress constraints, the direction of a fiber at an analysis point of the layup surface, for the definition of the trajectory of said fiber for at least one orientation of the plies, being obtained by calculation of the normalized weights of the constraint vectors of the constraint curves and/or by calculation of the normalized weights of the constraint vectors of the constraint grid, and by weighting by the normalized weights of the constraint vectors.
According to embodiments of the invention, the definition of the trajectories is made by taking into account manufacturing and/or design constraints, these constraints being modeled under the form of constraint curves or vectors associated to the nodes of a constraint grid, the direction to an analysis point being defined by applying a weighting law to the constraint vectors associated to the analysis point and issued from the constraint curves and/or constraint grid. The method according to embodiments of the invention enables the incorporation of design and/or manufacturing constraints during the definition of the trajectories, thereby reducing the time for defining the trajectories.
The method according to the invention can be implemented automatically under the form of software. The method according to the invention can be used for producing parts made of composite material by laying up fibers, whether by layup by contact, such as by placement of tows or by placement of bands, or by layup without contact such as by filament winding. The method according to embodiments of the invention is of particular interest in the case of the placement of tows on non-planar layup surfaces.
According to one embodiment, the trajectories are made directly from the constraint grid or the constraint curves, each trajectory of fibers is then obtained by defining the directions of the fiber at several analysis points of the layup surface.
According to another embodiment, a vector field is made from the constraint grid or the constraint curves, such as described in the patent application filed by the applicant, and entitled “Method for defining the trajectories from a vector field”. The trajectories are then made from said vector field.
According to one embodiment, in the case of a constraint grid, the method includes the definition of a constraint grid, each element of said constraint grid constraint preferably being defined by four nodes, and the association of at least one constraint vector to each node of the constraint grid, the direction of a fiber at an analysis point of the layup surface being obtained by:
According to one embodiment the constraint vectors of the constraint grid are representative of the geometric constraints of the layup surface.
According to one embodiment, in the case of constraint curves, the method includes the definition of at least two constraint curves, preferably on the mesh of the layup surface, the direction of a fiber at an analysis point of the layup surface being obtained by:
According to one embodiment, the constraint curves are representative of geometric constraints of the layup surface.
According to another embodiment, the constraint curves are representative of maximum angular deviation values, and are obtained from a so called angular deviation grid, and reference directions. These reference directions are for example obtained from a classic rosette, a constraint grid or constraint curves, the angular deviation grid serving to reorientate these reference directions within angular deviation limits in order to be closer to the geodesics thereby limiting the radius of curvature of the fibers. In this embodiment, the method comprises the definition of an angular deviation grid, each element of the angular deviation grid preferably being defined by four nodes, and the association of at least one maximum angular deviation value to each node of the angular deviation grid, the definition of a constraint curve comprising the definition of propagation directions at different analysis points of the layup surface, the definition of a propagation direction in an analysis point including:
According to one embodiment, the reorientation step of the reference direction includes:
According to one embodiment, the method includes the definition of a finite element transfer mesh of a transfer surface corresponding to a simplified surface, substantially continuous, of the layup surface, the direction of a fiber at an analysis point of the layup surface being obtained by:
The use of such a simplified transfer surface for the transfer of direction data proves itself to be particularly effective for the definition of acceptable trajectories in terms of the radius of curvature and of angular deviation in the case of non-continuous layup surfaces, having recesses and/or embossments generating ramps.
In the case of using of an angular deviation grid in combination with a constraint grid, the first reference direction at the analysis point is obtained from a constraint grid by:
In the case of using a transfer surface in combination with an angular deviation grid, the first reference direction at the analysis point is obtained from a transfer surface, by:
In the case of using a transfer surface in combination with a constraint grid and possibly an angular deviation grid, the second reference direction at said projected point is obtained from a constraint grid by:
In the case of using an angular deviation grid in combination with constraint curves, obtained for example from geometrical constraints, the first reference direction at the analysis point is obtained from a constraint grid by:
In the case of using a transfer surface in combination with constraint curves, obtained for example from geometric constraints, and possibly an angular deviation grid, the second reference direction at the projected point is obtained from a constraint grid by:
Following the lay-up surface, constraint curves and/or a constraint grid defined for an orientation of a ply can be used for the other orientations. In this case, once the directions of the fibers defined for a first orientation of the ply, for example 0°, the directions of the fibers for the other orientations of the plies, for example, 90°, +/−45°, are obtained by simple rotation of the vectors obtained for the first direction.
Embodiments of the present invention also concern a process for manufacturing parts made of composite materials by an automatic fiber layup machine, characterized in that the trajectories of the fibers for the layup of plies by the layup machine are defined by the method for defining the trajectory as described previously.
Embodiments of the present invention also concern a computer program comprising a set of instructions capable of implementing the method for defining the trajectory such as described previously, when the program is executed on a computer.
The invention will be better understood, and the other objectives, details, characteristics and advantages will appear more clearly during the detailed explanatory description which follows several specific embodiments currently preferred from the invention, with reference to the appended schematic drawings, in which:
According to embodiments of the invention, as shown in
The vector field is obtained using the Cartesian transfer of the vector X of the global rosette on each element 92 of the mesh, the Cartesian transfer of the vector X on the element consisting of a normal projection of the vector X on the plane of the relevant element, the projected vector of the so-called projected rosette constituting the direction vector 11 of the element.
Trajectories 81 of the fiber for a ply orientation at 0° can then be generated from this vector field 1, as shown in
A radius of curvature of analysis can then be performed on these thus obtained trajectories.
An analysis of the radius of curvature and/or angular deviation can be performed directly from the vector field, without generating trajectories, this analysis may for example be displayed on the vector field by assigning different colors to the vectors according to the values of the radius of curvature or the angular deviation.
Fiber trajectories for other ply orientations, such as 90°, +45° or −45°, can be generated from the same vector field 1, by performing a corresponding rotation of the direction vectors.
With reference to
A mesh 21 is defined from these geometric constraints, each element of the mesh being formed of at least four nodes, then a constraint vector T is assigned to each node N of the mesh to form the constraint grid 2.
To form the vector field, the direction vector of each mesh element is defined in the following manner.
As shown in
With reference to
D1=∥T1×w1+T2×w2+T3×w3+T4×w4∥
The direction vector of the element is then obtained by a transfer by normal projection of this vector D1 to the central point P1 of the element.
According to an alternative embodiment of the invention, as shown by the arrow in a discontinuous line in
With reference to
To form the vector field, the direction vector of each element of the mesh is defined in the following manner.
Considering the central point P2 of an element on
w5=1−(d5/(d5+d6))
w6=1−(d6/(d5+d6))
One then defines the vector D2, which corresponds to the direction vector of the element, by weighting the two tangent vectors T5, T6 by their respective normalized weights w5, w6:
D2=∥T5×w5+T6×w6∥
The vector D2 of the element corresponds to the direction vector D2 thus obtained. The vector field obtained from these constraint curves 3 is similar to that 101 previously obtained by means of the constraint grid.
According to an alternative embodiment of the invention, as shown by the arrow in a discontinuous line in
With reference to
Constraint curves are generated on the layup surface by defining for each constraint curve the propagation directions at different points of analysis also called propagation points. The propagation direction at a propagation point P3 is defined in the following manner.
With reference to
Next one performs a normal projection of the point P3 on the angular deviation grid, the projected point P′3 belonging for example to the element of the grid defined by the four nodes N′1, N′2, N′3, N′4 One performs a calculation of the normalized weights w7, w8, w9, w10, at the projected point P′3, of the four nodes. These normalized weights, also called barycentric coordinates of the projected point, are calculated according to a method known per se, depending on the distance between the projected point and the nodes. One performs a weighting of the four maximum angular deviation values Va, Vb, Vc, Vd by the normalized weights to obtain an authorized maximum angular deviation value α associated to the projected point:
α=w7×Va+w8×Vb+w9×Vc+w10×Vd
Next one determines a tolerance sector around the reference direction TR by defining direction limits L1 and L2 at an angle of +α and −α around the reference direction. Furthermore one determines a geodesic direction G corresponding to the propagation direction at the propagation point P3 of a geodesic curve.
This is followed by a reorientation of the reference direction within the limits of the authorized angular deviation value. If the geodesic direction G is included in the tolerance sector, then the propagation direction at the propagation point is defined as being the geodesic direction. If the geodesic direction is not included in the tolerance sector, then the propagation direction at the propagation point is defined as being the direction limit L1 or L2 the closest to the geodesic direction.
Obtaining a vector field is carried out according to the method described previously with constraint curves 3 of
D3=∥w11×T11+w12×T12∥
The direction vector of the element corresponds to the vector D3, preferably after a 90° rotation of the vector D3 to have a vector field concerning the plies at 0° by default.
The vector field 301 obtained from these constraint curves is shown in
According to an alternative embodiment of the invention, as shown by the arrow in a discontinuous line in
According to another embodiment of the invention, the vector field is obtained from a constraint vector grid and an angular deviation grid. In this case, for the generation of the constraint curves according to the method explained above with reference to
One defines a so-called continuous transfer surface which corresponds to a simplified surface of the lay-up surface. In this case, the transfer surface corresponds to the layup surface without its central recess. This transfer surface is defined by a so-called transfer mesh.
To form the vector field, the direction vector of each element of the mesh 191 of the layup surface is defined in the following manner, with reference to
According to another embodiment, the vector field is obtained from a constraint vector grid and a transfer surface. In this case, for the definition of the cutting plane A2 according to the method explained above with reference to
According to another embodiment illustrated in
The direction of the propagation at the point P6 is then obtained as described previously with reference to
According to another embodiment, the vector field is obtained from a constraint vector grid, an angular deviation grid and a transfer surface. In this case, for the definition of the cutting plane A4 above, the definition of the reference direction T″R is made, not from the Cartesian rosette, but from the constraint vector grid, by normal projection of the point P′6 on the constraint grid and definition of a vector D1 according to the weighting method explained previously with reference to
According to other embodiments, such as illustrated in
Furthermore, a vector field obtained according to the invention can be reintroduced as an input of the method according to the invention to obtain a new vector field.
Depending on the type of layup surface, different vector fields can be used for the definition of trajectories of the plies of different orientations. By way of example, with reference to
The use of a vector field enables shear analyses to be performed quickly, in order to verify that the angle between the trajectories of different orientations are well within an acceptable range of values. Advantageously, as previously, the direction vectors of the vector fields are all defined for an orientation at 0°. In the case of the vector field for the plies at 90°, a 90° rotation of the direction vectors is performed to generate trajectories at 90°. Similarly, in the case of the field vectors for the plies at +/−45°, a rotation of more or less 45° of the direction vectors is performed to generate the trajectories at +45° or −45°. These different vector fields with the direction vectors defined for an orientation at 0°, allows a quick and easy comparison of the direction vectors for the shear analysis.
Although the invention has been described in conjunction with several specific embodiments, it is obvious that it is in no way limited thereto and includes all technical equivalents of the described means as well as their combinations if they are within the scope of the invention.
Number | Date | Country | Kind |
---|---|---|---|
13 01170 | May 2013 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FR2014/000109 | 5/20/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2014/188085 | 11/27/2014 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4696707 | Lewis | Sep 1987 | A |
5041179 | Shinno et al. | Aug 1991 | A |
6191796 | Tarr | Feb 2001 | B1 |
6714901 | Cotin et al. | Mar 2004 | B1 |
7180523 | Macri et al. | Feb 2007 | B1 |
7190374 | Lake et al. | Mar 2007 | B2 |
9481135 | Munaux | Nov 2016 | B2 |
20050042410 | Sakonjo et al. | Feb 2005 | A1 |
20060103648 | Wu et al. | May 2006 | A1 |
20090048812 | Hanisch et al. | Feb 2009 | A1 |
20100095526 | Derrien et al. | Apr 2010 | A1 |
20100136293 | Kubryk et al. | Jun 2010 | A1 |
20120226482 | Wu et al. | Sep 2012 | A1 |
20130041635 | Zhu et al. | Feb 2013 | A1 |
20130231902 | Luby et al. | Sep 2013 | A1 |
20140288895 | Fricero et al. | Sep 2014 | A1 |
20150279029 | Jensen | Oct 2015 | A1 |
20160082672 | Munaux | Mar 2016 | A1 |
20160121558 | Munaux et al. | May 2016 | A1 |
20160136899 | Koranne | May 2016 | A1 |
Number | Date | Country |
---|---|---|
WO 2013112114 | Aug 2013 | WO |
Entry |
---|
PCT International Search Report for PCT/FR2014/000109, dated Oct. 16, 2014, 4 pgs. |
Search Report dated Oct. 21, 2014 for PCT Application No. PCT/FR2014/000108, 4 pages. |
Search Report dated Oct. 16, 2014 for PCT Application No. PCT/FR2014/000110, 4 pages. |
Application and File history for U.S. Appl. No. 14/893,402, filed Nov. 23, 2015. Inventors: Munaux et al. |
Application and File history for U.S. Appl. No. 14/893,310, filed Nov. 23, 2015. Inventors: Munaux. |
Number | Date | Country | |
---|---|---|---|
20160121557 A1 | May 2016 | US |