• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a waveguide and its manufacturing method by additive technology in which the section of the waveguide is defined by the intersection of a plane (P ") and several surfaces (S, S ', S ", S1, S2) constituting the functional surfaces and the self-supporting surfaces of the waveguide.
    公开号:FR3087954A1
    申请号:FR1801151
    申请日:2018-10-31
    公开日:2020-05-01
    发明作者:Mathieu Francois;Simon Turpault;Jean Pierre Aurez;Frederic Segonds;Patrice PEYRE;Mickael RIVETTE
    申请人:Centre National de la Recherche Scientifique CNRS;Thales SA;CNAM Conservatoire National des Arts et Metiers;Ecole National Superieure dArts et Metiers ENSAM;
    IPC主号:
    专利说明:

    [0001] The invention relates to a waveguide obtained by the additive manufacturing technique.
    [0002] The waveguide is a physical system used to guide electromagnetic waves, in order to keep them confined in a particular medium for a certain distance.
    Most of the research carried out on the production of microwave components - with so-called conventional or innovative geometries - in additive manufacturing have shown frequency shifts and a general increase in terms of losses.
    During the manufacture of waveguides using additive technology, a degraded surface condition can disrupt the trajectory of an electromagnetic wave.
    One of the objectives of the present invention is to minimize the roughness of the surfaces on which the electric field propagates, called "functional surfaces".
    According to the characteristics of additive manufacturing, an optimal functional surface finish is obtained when the functional surface forms an angle of 90 ° with the build plate and degrades cosinely down to 0, for example.
    The microwave components being related to hollow tubes, with an inlet and an outlet at each end, once the manufacture of the part is completed any supports used during the additive manufacturing process are trapped inside and remain impossible to remove. to withdraw.
    One solution to overcome this problem consists in designing self-supporting structures.
    The self-supporting capacity of a structure is dependent on the orientation in the manufacturing chamber.
    It may require the presence of support for some angles and be self-supporting for others.
    In general, for the laser beam melting process known by the term Laser Beam Melting (LBM), it is usual to place supports for surfaces whose angle formed with the build plate is. less than a = 45 ° for Aluminum.
    At the end of the manufacturing process, these supports must be removed.
    Patent FR3048556 describes an additive manufacturing process 5 in which openings are arranged along the propagation channel in order to lighten the structure of the waveguide without disturbing the signal.
    The object of the invention aims to provide a waveguide having minimal roughness on the surfaces on which the electric field moves, and a self-supporting structure, the guide being obtained by additive manufacturing without requiring the use of supports. must be disposed of at the end of production.
    The object of the invention relates to a waveguide obtained by additive manufacturing characterized in that the geometry of a section of said waveguide SG is defined as a surface formed by the intersection of a plane P "and of the union of several surfaces (S), (S '), (S "), (51), (S2) and (S3) defined as follows: Let three planes (P), (P') perpendicular at (P) and (P ") perpendicular to the planes (P ') and (P"), Two sides of the waveguide corresponding to two surfaces on which the electric current flows: A first surface (Si) of the guide is parallel and distinct to a plane (P) and a second surface (S ') is constructed symmetrical to the first with respect to the plane (P), For the other sides of the waveguide: A third surface (S') passing through the plane (P) and the surface (S) and defined in such a way that the tangent at each point of the surface (S ') forms an angle al with the plane (P') between [-89.9; 89.9 ° 11 {0} degrees and a fourth surface (S2) symmetrical to the surface (S ') with respect to the plane (P) with the same angle, the surface (S') and the surface (S) meet on a junction line, just as the surface (S2) with the surface (Si) on a junction line, the surface (S2) and the surface (S ') meet in a line, 3 A fifth surface (S ") passes through the surface (S) and the plane (P) and a sixth surface (S3) is symmetrical, or coincides with (S"), said surface joins the surface (S) by a junction line and the surface ( SI) by a connecting line.
    The fifth surface (S ") and the sixth surface (53) can be confused.
    According to one embodiment, the fifth surface (S ") of the guide is formed by a sixth surface (S4) passing through the plane (P) and the surface (S) and it is defined such that the tangent at each point of the surface (S4) forms an angle al with the plane (P ') between [-89.9; 89.911 {0} degrees and a seventh surface (S5) symmetrical of the surface (S') with respect to the plane (P) with the same angle, the two surfaces (S4), (S5) meet on a junction line (50).
    According to another embodiment, the waveguide has a first surface (RI) which passes through the plane (P) and the surface (S) and which is defined such that the tangent at each point of the surface (RI) forms an angle 13 with the plane (P ') between [-89.9; 89.911 {0} degrees and a fourth surface (R2) symmetrical to the surface (RI) with respect to the plane (P) with the same angle, the two surfaces (S ') and (RI) meeting along a junction line and the two surfaces (S) and (RI) along a junction line.
    The two surfaces (RI, R2) and the two surfaces (R3, R4) are each symmetrical of a surface (RI, R2) with respect to the plane (P ').
    The surface (S ') passing through the plane (P) and the surface (S) have the shape of an arc or ogive.
    According to one embodiment, the waveguide has a semi-circular surface and an arc-shaped surface.
    The value of the angle α1 is chosen depending on the material forming the waveguide and on the manufacturing technique.
    The material used to manufacture the waveguide is chosen from among metal alloys based on Aluminum, Titanium, Steel, Nickel, Chromium.
    4 The invention also relates to a method of manufacturing a waveguide according to the invention using the additive manufacturing technique, characterized in that a section of the waveguide is defined as follows: three planes (P), (P ') perpendicular to (P) and (P ") perpendicular to the planes (P') and (P"), We construct two sides of the waveguide corresponding to the two functional surfaces in the same way following: A first surface (S1) of the guide is parallel and distinct to a plane (P) and 10 a second surface (S ') is constructed symmetrical to the first with respect to the plane (P), and For the other sides of the guide wave corresponding to non-functional surfaces, A third surface (S ') of the guide passes through the plane (P) and the surface (S) and it is defined in such a way that the tangent at each point of the surface ( S ') forms an angle al with the plane (P') between [-89.9; 89.91 {0} degrees and a fourth surface (S2) is constructed symmetrical to the surface (S ') with respect to the plane (P) with the same angle, A fifth surface (S ") passes through the surface (S ) and the plane (P) and a sixth surface (S3) is symmetrical, or coincides with (S ").
    Other characteristics and advantages of the present invention will emerge better on reading the description of exemplary embodiments given by way of illustration and in no way limiting, appended to the figures which represent: FIG. 1, an example of a guide of wave according to the prior art, - Figure 2, a representation of a waveguide according to the prior art, - Figure 3, an illustration of the definition of the geometric parameters which will be used for the manufacture of a waveguide. wave according to the invention, 30 - Figure 4, a sectional view of a first geometry for the section of a waveguide according to the invention, 5 - Figure 5, a sectional view of a variant of the section of Figure 3, - Figure 6 and Figure 7, two other examples of waveguide section obtained by the invention, and - Figure 8, another variant of waveguide having a section 5 partly circular.
    An example of a waveguide according to the prior art is illustrated in FIG. 1.
    It consists of a hollow device 1, the shape and proportions of which determine the propagation characteristics for a given wavelength of the electromagnetic signal.
    Conventional waveguides 10 used in the radiofrequency field generally have internal openings of rectangular or circular section.
    They allow the propagation of electromagnetic modes corresponding to different distributions of electromagnetic field along their section.
    The waveguide in Figure 1 has a height b, a width a, and a length L.
    Figure 2 illustrates a waveguide with a rectangular section fabricated parallel to the build plate with "functional" surfaces on which the electric current flows, 20, 21, at 90 degrees.
    This structure has the drawback of not being self-supporting 20 because of the cantilevered surfaces 22, 23, which make up the parallelepiped forming the waveguide.
    The idea of the present invention is to offer an improved structure fulfilling at least the following three conditions: - Obtain a self-supported structure, without the use of a support for the manufacture of the guide, Have minimal roughness on the functional surfaces on which it runs. electric current, and Minimal manufacturing time.
    In order to make the waveguide G obtained by implementing the invention clearly understood, FIG. 3 illustrates the geometric parameters 6 which make it possible to define generically a waveguide according to the invention.
    Examples will then be given for section waveguides having different geometries.
    Using additive manufacturing technique, for example LBM technology, a user will program different shapes, geometries to obtain a waveguide section with a desired geometry.
    The machine on the basis of this information contained in a file will produce the "design" (geometry and dimensions) requested.
    The 10 steps of LBM technology will not be detailed because they are known to those skilled in the art.
    The parameters and the computer data stored on a computer medium defining a model according to the invention will be transmitted to the machine.
    To define the geometry of the section of the waveguide, method 15 uses mathematical notions which then make it possible to define a waveguide: - Either a plane (P), - Or a plane (P ') perpendicular to the plane (P), - Let a plane (P ") be perpendicular to the planes (P) and (P ').
    The waveguide according to the invention is constructed as follows: Two sides of the waveguide corresponding to the two surfaces on which the electric field moves, in normal operating mode, are constructed as follows: A first surface (Si) of the guide is parallel and distinct to the plane (P) and a second surface (S ') is constructed symmetrical to the first with respect to the plane (P), For the other sides of the waveguide: A third surface (S ') of the guide passes through the plane (P) and the surface (S) and is defined in such a way that the tangent at each point of the surface (S') forms an angle a1 with the plane (P ') between [-89.9; 89.911 {0} degrees and a fourth surface (S2) is constructed symmetrical to the surface (S ') with respect to the plane (P) with the same angle, A fifth surface (S ") passes through the surface (S) and the plane (P) and a sixth surface (S3) is symmetrical, or coincides with (S ").
    This latter surface may correspond with the manufacturing plane of the waveguide.
    The geometry of the section of the waveguide finally obtained is the closed surface SG formed by the intersection of the plane (P ") and the union of the surfaces (S), (S '), (S"), ( S1), (S2) and (S3).
    The geometry of the waveguide section corresponds to a digital model (eg .stl file) which will be transmitted to slicing software.
    After slicing, the file is sent to an additive manufacturing machine and the machine parameters (for example laser power, laser path, laser speed) are selected according to the characteristics of the manufacturing machine used according to steps known to those skilled in the art.
    Finally, the machine will be able to manufacture the waveguide by proceeding by adding material in successive layers.
    FIG. 4 illustrates a first example of a waveguide having a quasi-rectangular section constructed according to the principle given in FIG. 3.
    The section SG of the waveguide SG is formed by the intersection of the plane (P ") and the union of the surfaces (S), (S '), (S"), (51), (S2) and (S3): - a first surface (S) parallel and distinct to the plane (P) and a second surface (51) symmetrical to the first with respect to the plane (P), 25 - a third surface (S ') passing through the plane (P) and the surface (S) and defined in such a way that the tangent at each point of the surface (S ') forms an angle a1 with the plane (P') between [-89.9; 89.911 {0} degrees and a fourth surface (S2) symmetrical to the surface (S ') with respect to the plane (P) with the same angle, the surface 30 (S') and the surface (S) meet on a line of junction 41a, as the surface (52) with the surface (S1) on a line of 8 junction 41b, the surface (S2) and the surface (S ') meet in a line 40, - a fifth surface ( S ") passing through the surface (S) and the plane (P), this surface joins the surface (S) by a junction line 42a and the surface (S1) by a junction line 42b.
    The waveguide section thus obtained has a shape similar to that of a house.
    Angle α is defined more generally as the angle between the inclined surface of a cantilevered surface and the build plate.
    The value of the angle α is chosen, in particular, as a function of several parameters: - The material used to manufacture the waveguide, aluminum, titanium, etc. - The technology used by the machine, the laser power, etc.
    The idea is to choose an angle value and a suitable technology so that the structure of the waveguide is self-supporting and that it presents an optimal roughness on the functional surfaces.
    The angle value can vary between 1 and 89 °.
    FIG. 5 illustrates an alternative embodiment of a waveguide of FIG. 4, in which the fifth surface corresponding to the surface (S3) of FIG. 4 is formed by: - a sixth surface (S4) passing through the plane (P) and the surface (S), and in such a way that the tangent at each point of the surface (S4) forms an angle a1 with the plane (P ') comprised between E-89.9; 89.9 ° 11 {0} degrees, and - a seventh surface (S5) symmetrical to the surface (S ') with respect to the plane (P) with the same angle, the two surfaces (S4), (S5) meet on a junction line 50.
    In this variant, the waveguide 30 has symmetry.
    FIG. 6 represents an alternative embodiment of the wave section shown schematically in FIG. 4.
    In order to widen the frequency band, it is known to use “ridges”.
    A ridge is made using a rectangular waveguide by adding conductive "ridges" along the center of the top surfaces of the waveguide.
    These peaks have the particular function of lowering the cut-off frequency of the dominant mode and of increasing the cut-off frequency of the following higher-order modes.
    This results in a higher bandwidth.
    In the example of FIG. 6, there is shown in solid lines a first variant embodiment of a waveguide having two surfaces called ridges (R1, R2) and in dotted lines two additional surfaces or ridges (R3, R4 ) positioned in the lower part of the waveguide and symmetrical with the first two ridges with respect to the plane (P ').
    Starting from the waveguide of FIG. 4, the waveguide 15 comprises a first surface (R1) which passes through the plane (P) and the surface (S) and defined in such a way that the tangent at each point of the surface (R1) forms an angle R with the plane (P ') between [-89.9; 89.9'1 {0} degrees and a fourth surface (R2) symmetrical to the surface (R1) with respect to the plane (P) with the same angle.
    The two surfaces (S ') and (R1) meet along a junction line 60 and the two surfaces (S) and (R1) along a junction line 61.
    Without departing from the scope of the invention, one possibility shown in dotted lines in the figure consists in adding the ridges symmetrically.
    The section of the waveguide then being formed by the intersection of the plane (P ") and 25 of the union of the surfaces (S), (S '), (S"), (S1), (S2) and (S3) and the four surfaces (R1), (R2), (R3), (R4), corresponding to the four ridges.
    The surfaces (R1) and (R2) are symmetrical to the surfaces (R3) and (R4) with respect to the plane (P ').
    FIG. 7 illustrates an alternative embodiment where the two surfaces 30 (S ') passing through the plane (P) and the surface (S) have the shape of an arc or an ogive, the two half-arcs 70, 71 meet at a junction line 72.
    FIG. 8 illustrates a waveguide obtained by the method according to the invention, which has a circular waveguide section on part 5 of the section and a pointed part as shown in FIG. 7.
    The arc-shaped section comprises two half-arcs 70, 71 which join the circular part 80 at a junction line 83, 84 respectively.
    The materials for the manufacture of waveguides by additive manufacturing technology will be chosen from metal alloys based on Aluminum, Titanium, Steel, Nickel, Chromium etc.
    The “additive” manufacturing process used for manufacturing the waveguide according to the invention can be chosen from the various metal additive manufacturing processes known to those skilled in the art.
    For example, the expression “additive manufacturing” describes any process for manufacturing parts by adding material, according to computer data stored on a computer medium and defining a model of the part.
    The manufacturing methods can be, stereolithography, manufacturing methods by hardening or coagulation of liquid, powder in particular, methods based on ink jets, by aerosols, etc.
    The waveguide according to the invention can be used in the microwave domain, for example in the [3GHz-300GHz] range.
    The method and the waveguide sections obtained by implementing the method according to the invention in particular have the advantage of minimizing at least the following three parameters: absence of support,
    权利要求:
    Claims (10)
    [0001]
    CLAIMS 1 - Waveguide obtained by additive manufacturing characterized in that the geometry of a section of said waveguide Sc is defined as a surface formed by the intersection of a plane P "and the union of several surfaces (S), (S '), (S "), (S1), (S2) and (S3) defined as follows: Let three planes (P), (P') perpendicular to (P) and (P ") perpendicular to the planes (P ') and (P"), Two sides of the waveguide corresponding to two surfaces on which the current flows: A first surface (S1) of the guide is parallel and distinct to a plane (P) and a second surface (S ') is constructed symmetrical to the first with respect to the plane (P), For the other sides of the waveguide: A third surface (S') passing through the plane (P) and the surface ( S) and defined in such a way that the tangent at each point of the surface (S ') forms an angle al with the plane (P') between [-89.9; 89.911 (0) degrees and a fourth surface (S2) symmetrical to the surface (S ') with respect to the plane (P) with the same angle, the surface (S') and the surface (S) meet on a line of junction (41a), as the surface (S2) with the surface (S1) on a junction line (41b), the surface (S2) and the surface (S ') meet in a line (40), A fifth surface (S ") passes through surface (S) and plane (P) and a sixth surface (S3) is symmetrical, or coincides with (S"), said surface joins surface (S) by a junction line (42a) and the surface (S1) by a junction line (42b).
    [0002]
    2 - Waveguide according to claim 1 characterized in that the fifth surface (S ") and the sixth surface (S3) are merged.
    [0003]
    3 - Waveguide according to claim 1 characterized in that the fifth surface (S ") is formed by a sixth surface (S4) passing through the plane (P) and the surface (S) and defined such that the tangent at each point of the surface (S4) forms an angle al with the plane (P ') between [-89.9; 5 89.911 {0} degrees and a seventh surface (S5) symmetrical to the surface (S') with respect to the plane (P) with the same angle, the two surfaces (S4), (S5) meet on a junction line (50).
    [0004]
    4 - Waveguide according to claim 1 characterized in that it comprises at least a first surface (R1) which passes through the plane (P) and the surface (S) and which is defined such that the tangent at each point of the surface (R1) forms an angle is with the plane (P ') between [-89.9; 89.91 {0} degrees and a fourth surface (R2) symmetrical to the surface (R1) with respect to the plane (P) with the same angle, the two surfaces (S ') and (R1) meeting along a junction line (60) and the two surfaces (S) and (R1) along a junction line (61).
    [0005]
    5 - Waveguide according to claim 4 characterized in that it comprises two surfaces (R1, R2) and two surfaces (R3, R4) each being symmetrical with a surface (R1, R2) relative to the plane ( P ').
    [0006]
    6 - Waveguide according to one of claims 1 to 3 characterized in that the surface (S ') passing through the plane (P) and the surface (S) have an arc shape (70, 71) or warhead. 25
    [0007]
    7 - Waveguide according to one of claims 1 to 3 characterized in that it comprises a semi-circular surface (80) and an arcuate surface.
    [0008]
    8 - Waveguide according to one of claims 1 to 7 characterized in that the value of the angle a1 is chosen as a function of the material forming the waveguide and of the manufacturing technique. 13
    [0009]
    9 - Waveguide according to one of claims 1 to 8 characterized in that the material constituting it is chosen from metal alloys based on aluminum, titanium, steel, nickel, chromium. 5
    [0010]
    10 - A method of manufacturing a waveguide according to one of claims 1 to 9 using the additive manufacturing technique, characterized in that one defines a section of the waveguide as follows: Either three planes (P), (P ') perpendicular to (P) and (P ") perpendicular to planes (P') and (P"), 10 We construct two sides of the waveguide corresponding to the two functional surfaces in the same way following: A first surface (S1) of the guide is parallel and distinct to a plane (P) and a second surface (S ') is constructed symmetrical to the first with respect to the plane (P), and 15 For the other sides of the guide wave corresponding to non-functional surfaces, A third surface (S ') of the guide passes through the plane (P) and the surface (S) and it is defined in such a way that the tangent at each point of the surface (S ') forms an angle al with the plane (P') between [-89.9; 20 89.9 °] {0} degrees and a fourth surface (S2) is constructed symmetrical to the surface (S ') with respect to the plane (P) with the same angle, A fifth surface (S ") passes through the surface (S) and the plane (P) and a sixth surface (S3) is symmetrical, or coincides with (S "). 25
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    同族专利:
    公开号 | 公开日
    FR3087954B1|2021-12-17|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US2409913A|1944-02-14|1946-10-22|Gen Electric|Wave guide structure|
    US3299374A|1964-04-04|1967-01-17|Telefunken Patent|Asymmetrical waveguide|
    US3546635A|1968-08-13|1970-12-08|Us Air Force|Waveguide mode selective absorber|
    US20160056860A1|2013-04-03|2016-02-25|Sony Corporation|Waveguide, waveguide manufacturing method, and wireless transmission system|
    FR3048556A1|2016-03-04|2017-09-08|Swissto 12 Sa|METHOD FOR THE ADDITIVE MANUFACTURE OF A WAVEGUIDE AND WAVEGUIDE DEVICES MADE THEREBY|
    WO2017203568A1|2016-05-23|2017-11-30|三菱電機株式会社|Waveguide device|US11128034B2|2018-03-02|2021-09-21|Optisys, LLC|Mass customization of antenna assemblies using metal additive manufacturing|
    US11211680B2|2018-11-14|2021-12-28|Optisys, LLC|Hollow metal waveguides having irregular hexagonal cross-sections formed by additive manufacturing|
    US11233304B2|2018-11-19|2022-01-25|Optisys, LLC|Irregular hexagon cross-sectioned hollow metal waveguide filters|
    法律状态:
    2019-09-27| PLFP| Fee payment|Year of fee payment: 2 |
    2020-05-01| PLSC| Publication of the preliminary search report|Effective date: 20200501 |
    2020-10-13| PLFP| Fee payment|Year of fee payment: 3 |
    2021-09-30| PLFP| Fee payment|Year of fee payment: 4 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1801151A|FR3087954B1|2018-10-31|2018-10-31|WAVE GUIDE OBTAINED BY ADDITIVE MANUFACTURING|FR1801151A| FR3087954B1|2018-10-31|2018-10-31|WAVE GUIDE OBTAINED BY ADDITIVE MANUFACTURING|
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