巴西专利BR102012021869B1 method for manufacturing a fiber reinforced part

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专利摘要:
apparatus, method and material mixture for direct digital manufacture of fiber-reinforced parts. The present invention relates to the part which is manufactured by introducing magnetic particles into a matrix material, and orienting the particles by coupling them with an electromagnetic field. The matrix material is solidified into shaped layers while the particles remain field oriented.
公开号:BR102012021869B1
申请号:R102012021869
申请日:2012-08-30
公开日:2018-09-11
发明作者:Ian Lyons Brett；William Fonda James；Blake Vance Jonathan；Robert Johnston Scott
申请人:Boeing Co；
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专利说明:

(54) Title: METHOD FOR MANUFACTURING A REINFORCED PIECE WITH FIBER (51) Int.CI .: B22F 1/00; B22F 3/00; B29C 67/00; B29C 70/00 (30) Unionist Priority: 01/09/2011 US 13 / 223,924 (73) Holder (s): THE BOEING COMPANY (72) Inventor (s): SCOTT ROBERT JOHNSTON; JONATHAN BLAKE VANCE; JAMES WILLIAM FONDA; BRETT IAN LYONS (85) National Phase Start Date: 08/30/2012
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Invention Patent Descriptive Report for
METHOD FOR MANUFACTURING A PIECE REINFORCED WITH FIBER.
GENERAL INFORMATION
1. Technical Field:
[001] This description relates in general to direct digital fabrication techniques, in particular additive methods, and deals, more particularly, with a method and apparatus for the manufacture of fiber-reinforced polymeric resin parts, and the a mixture of material that can be used to build the parts.
2. Background:
[002] Direct digital fabrication (DDM), now referred to as Additive Fabrication (AM), is a process that creates physical parts directly from a 3D CAD file (Computer Assisted Design), using computer controlled additive manufacturing techniques. Common additive manufacturing techniques include stereolithography (SLA), fusion and deposition modeling (FDM), selective laser sintering (SLS) and three-dimensional printing (3DP), to name a few. Each of these processes builds a solid three-dimensional part, layer by layer, by melting locally or curing construction materials that can be in the form of powder or liquid. For example, the SLA process builds part of one layer at a time, using a UV laser and a UV curable liquid photopolymeric resin tank. For each layer, the laser traces a cross-section pattern of the part on the surface of the liquid resin based on a 3D CAD data model of the part. Exposure to UV laser light cures and solidifies the pattern drawn on the resin and adheres it to the layer below. After a pattern has been drawn, an elevator platform descends through a single layer thickness, and a blade filled with resin sweeps through the section of the part, covering it with material
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2/22 fresh. The process continues layer by layer until the part is complete.
[003] SLS uses a high-powered laser to melt small particles of plastic or metal, ceramic or glass powders into a mass that has a desired shape in three dimensions. The laser selectively melts the building material into powder by scanning the cross sections generated from a 3D digital description (CAD model) of the part on the surface of a powder bed. After each cross section is swept, the powder bed is lowered into a thick layer, a new layer of material is applied on top, and the process is repeated until the part is complete.
[004] The 3DP process uses a cutting algorithm to extract detailed information from each layer of a CAD model of the part. Each layer begins with a fine distribution of dust spread over the surface of a dust bed. Using technology similar to inkjet printing, a binder material selectively binds the particles where the object is being formed. A piston that supports the dust bed and the moving part lowers so that the next layer of dust can be spread and selectively joined. After heat treatment, the loose powder is removed, leaving the fabricated part. [005] In order to reinforce the pieces produced by additive production techniques, reinforcement particles, usually short ground or chopped fibers, have been introduced in powders or liquid resins used to build the pieces. However, the fibers are randomly distributed throughout the powder or resin matrix and have individual random orientations. Therefore, these fiber reinforcements produce a highly anisotropic reinforcement in relation to the axis of the machine on which they are built.
[006] Therefore, there is a need for a method and apparatus for direct digital fabrication of fiber-reinforced parts
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3/22 where the reinforcement fibers can be selectively oriented to provide isotropic reinforcement and directional resistance on the part. There is also a need for a method and apparatus that positions and / or aligns short reinforcing fibers or other particles in the construction materials used in various additive manufacturing processes.
Summary [007] According to the described modalities, a method and apparatus are provided for direct digital fabrication of fiber-reinforced parts that control the orientation and / or position of the fibrous reinforcement materials used in the construction materials. The position and / or orientation of short reinforcing fibers is influenced by the coupling of the fibers with controlled magnetic fields while an energy source selectively solidifies the surrounding matrix material. The orientation of the fibers is controlled by considering the dimension of time during the construction process, along with three Cartesian spatial coordinates and a vector for each volume (also known as voxel = 3D volume dimension that is parallel to a pixel) for orientation of the fibers. Digital control of the position and / or orientation of the reinforcement fibers results in improved mechanical and / or electrical performance and / or in the characteristics of the parts. [008] According to a presented modality, a method is provided for the manufacture of a part, comprising the supply of magnetic particles and introducing the magnetic particles into a matrix material. The method further includes orienting the particles in the matrix material by coupling the particles within an electromagnetic field, and solidifying the matrix material, while the particles are oriented. The coupling of the particles with an electromagnetic field includes the positioning of at least one pair of electromagnets adjacent to the matrix material, aligning the electromagnets 870180045826, of 29/05/2018, p. 9/36
4/22 hands, and using electromagnets to generate the electromagnetic field. The orientation of the particles can include aligning the particles in the desired direction and / or moving the particles to form a characteristic of the part within the matrix material. Curing of the matrix material can be carried out using an energy beam. The delivery of the particles includes coating elongated synthetic fibers with a magnetic metal and / or forming bundles of synthetic fibers and wrapping or coating each bundle with magnetic metal. The matrix material can comprise a powder and the matrix material can be solidified by sintering the powder.
[009] According to another modality, a method of manufacturing a piece of fiber-reinforced compound is provided. The method comprises providing a layer of liquid polymer resin and magnetic reinforcement fibers suspended in the liquid resin. The method also includes the generation of an electromagnetic field using the electromagnetic field to orient the fibers within the liquid resin, and using an energy beam to cure the liquid resin. The method further comprises moving the energy beam and the electromagnetic field over the liquid resin layer to orient the fibers and cure the resin in a desired pattern within the liquid resin layer. The use of an energy beam to cure the liquid resin can be accomplished using a computer-controlled ultraviolet laser to scan the layer to selectively cure parts of the layer.
[0010] According to yet another modality, a direct digital manufacturing method is provided to produce a part. The method comprises providing a mixture of a matrix material and elongating reinforcement fibers that exhibit magnetic properties and using a digitally controlled energy beam to selectively cure parts of the polymer resin, layer by layer, based
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5/22 in a digital definition of the part. The method further comprises the use of an energy field to align the magnetic fibers, at least, in the parts to be cured by the energy beam. The use of the energy field to align the fibers can be performed using electromagnets. The matrix material can be a powder and solidification of the matrix material can be carried out by sintering the powder. The matrix material can be a liquid resin and the fibers can be suspended in the liquid resin. The fibers can be cut or ground fibers, which include at least one of glass, aramid and carbon. The resin can be a polyamide powder.
[0011] According to an additional modality, a mixture of material is provided for use in an additive production process to manufacture a part. The mixture comprises a matrix material that can be selectively solidified, and magnetic particles. The magnetic particles can include at least one of aramid, glass and carbon fibers with a magnetic coating, and the matrix material can be a polymeric powder, a photopolymeric liquid, a powdered metal, and glassy microspheres. The matrix material is a polymeric powder present in the mixture in an amount between approximately 50% and 90% by weight, and the magnetic particles may include one of cut fibers having an approximate length between 3 and 6 mm, and ground fibers having a length approximate length between 50 and 500 microns. The magnetic particles can include bundles of non-magnetic reinforcement fibers, and a layer of magnetic material around each of the bundles.
[0012] According to another modality, an apparatus is provided for the direct digital manufacture of a part. The apparatus comprises a supply of a matrix material containing the magnetic particles, an energy beam to selectively solidify the matrix material layer by layer, to form the part, electromagnets for orientation 870180045826, from 29/05/2018, p. 11/36
6/22 enters the magnetic particles in the three-dimensional space inside the matrix, and a controller to control the energy beam and the electromagnets based on a digital definition of the piece. The electromagnets are arranged in aligned pairs, generating an electromagnetic field coupled with the magnetic particles in the matrix, and the controller synchronizes the operation of the energy beam with the orientation of the particles by the electromagnets.
[0013] In summary, according to one aspect of the invention, a method of manufacturing a part is provided, including: supply of magnetic particles; introduction of magnetic particles in a matrix material; orientation of the particles in the matrix material by coupling the particles with an electromagnetic field; and curing the matrix material while the particles are oriented.
[0014] Advantageously, the method in which the coupling of the particles with an electromagnetic field includes positioning at least one pair of electromagnets adjacent to the matrix material, including aligning the electromagnets in relation to each other, and using the electromagnets to generate the electromagnetic field.
[0015] Advantageously, the method in which the orientation of the particles comprises the repositioning of the particles within the matrix material.
[0016] Advantageously, the method in which the orientation of the particles comprises aligning the particles in a desired direction.
[0017] Advantageously, the method also includes the use of the electromagnetic field to form a characteristic of the piece through the repositioning of the magnetic particles.
[0018] Advantageously, the method in which the supply of the particles comprises the coating of elongated synthetic fibers with
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7/22 a magnetic metal.
[0019] Advantageously, the method in which the supply of the particles comprises the formation of bundles of synthetic fibers and the wrapping of each bundle with a magnetic metal.
[0020] Advantageously, the method in which the matrix material is a powder and the curing is carried out by sintering the powder.
[0021] According to another aspect of the invention there is provided a method of manufacturing a fiber-reinforced composite part, including providing a layer of liquid polymeric resin; suspending magnetic reinforcement fibers in the liquid resin; generation of an electromagnetic field using the electromagnetic field to orient the fibers within the liquid resin, and using an energy beam to cure the liquid resin.
[0022] Advantageously, the method further comprises moving the energy beam and the electromagnetic field over the liquid resin layer to orient the fibers and cure the resin in a pattern within the liquid resin layer.
[0023] Advantageously, the method in which the generation of the magnetic field is performed using at least two electromagnets aligned.
[0024] Advantageously, the method in which the fibers include a substantially non-magnetic material surrounded by a magnetic material.
[0025] Advantageously, the method in which an energy beam is used to cure the liquid resin is carried out using a computer-controlled ultraviolet laser to scan the layer and to selectively cure parts of the layer.
[0026] In accordance with an additional aspect of the present invention, a direct digital manufacturing method is provided for the production of a part, including providing a mixture of a maPetition 870180045826, 05/29/2018, pg. 13/36
8/22 matrix material and elongate reinforcement fibers that exhibit magnetic properties; using a digitally controlled energy beam to selectively solidify parts of the matrix material, layer by layer, based on a digital definition of the part; and using an energy field to align the magnetic fibers in the three-dimensional space.
[0027] Advantageously, the method in which an energy field is used to align the fibers is carried out using electromagnets.
[0028] Advantageously, the method in which the matrix material is a powder and the solidification of the matrix material is carried out by sintering the powder.
[0029] Advantageously, the method in which the matrix material is a liquid polymer resin and the fibers are suspended in the liquid resin.
[0030] In accordance with yet another aspect of the present invention, a mixture of material is provided for use in an additive manufacturing process to manufacture a part, including a matrix material that can be selectively solidified, and magnetic particles.
[0031] Advantageously, the mixture in which the magnetic particles include at least one of aramid, glass and carbon fibers having a magnetic coating.
[0032] Advantageously, the mixture, in which the matrix material is one of a polymeric powder, a photo-polymeric liquid, a powdered metal, and glassy microspheres.
[0033] Advantageously, the mixture, in which the matrix material is a polymeric powder present in the mixture in an amount between approximately 50% and 90% by weight.
[0034] Advantageously, the mixture in which the magnetic particles include one of chopped fibers having an approximate lengthPetition 870180045826, of 29/05/2018, p. 14/36
9/22 between 3 and 6 mm, and of ground fibers having a length of approximately between 50 and 500 microns.
[0035] Advantageously, the mixture in which the magnetic particles include bundles of non-magnetic reinforcement fibers, and a layer of magnetic material around each of the bundles.
[0036] In accordance with another aspect of the present invention, an apparatus is provided for the direct digital fabrication of a part, including: a supply of a matrix material containing the magnetic particles; a beam of energy to selectively solidify the matrix material layer by layer; to form the piece; electromagnets to guide the magnetic particles in the three-dimensional space inside the matrix; and a controller to control the energy beam and electromagnets based on a digital definition of the part.
[0037] Advantageously, the device in which the electromagnets are arranged in aligned pairs generating an electromagnetic field coupling the field with the magnetic particles in the matrix, and the controller synchronizes the operation of the energy beam with the orientation of the particles by the electromagnets.
[0038] The characteristics, functions and advantages can be achieved independently in various modalities of the present disclosure or can be combined, however in other modalities in which additional details which can be seen with reference to the following description and drawings.
BRIEF DESCRIPTION OF THE DRAWINGS [0039] The new attributes considered characteristic of the advantageous modalities are established in the attached claims. Advantageous embodiments, however, as well as a preferred mode of use, additional objectives and advantages thereof, will be better understood by reference to the following detailed description of an advantageous embodiment of the present description, when read in
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10/22 together with the attached drawings, in which:
[0040] Figure 1 is an illustration of a combined block and schematic view of an apparatus for direct digital production of a fiber-reinforced part using a photo-polymer.
[0041] Figure 1A is an illustration of the area designated as figure 1A in figure 1, showing the intersection of the aligned magnetic fields produced by the apparatus in figure 1.
[0042] Figure 2 is an illustration of a perspective view of a reinforcing magnetic fiber.
[0043] Figure 3 is an illustration of a perspective view of a bundle of reinforcement fibers surrounded by an external magnetic cover.
[0044] Figure 4 is an illustration of a layer comprising a mixture of a dry powder matrix and randomly oriented magnetic reinforcement fibers.
[0045] Figure 5 is an illustration similar to that of figure 4, but it shows that the fibers have been oriented within the powder matrix in unidirectional alignment by electromagnetic fields.
[0046] Figure 6 is an illustration similar to that of figure 5, but it shows that the fibers have been melted and cured, or fused with the remaining oriented fibers.
[0047] Figure 7 is an illustration of a flow diagram of a method of direct digital fabrication of fiber-reinforced parts. [0048] Figure 8 is an illustration of a side view of an apparatus modality in relation to a piece layer being formed from a mixture of magnetic fibers and dry powder.
[0049] Figure 9 is an illustration of a combined block and seen in cross section of another modality of the device showing that a piece reinforced with fiber has been fully formed. [0050] Figure 10 is an illustration of a plan view of a
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11/22 arrangement of electromagnets that can be used to generate electromagnetic magnetic fields in embodiments shown in figures 1.8 and 9.
[0051] Figure 11 is an illustration of a schematic top view of a gantry system to orient the electromagnets in relation to a machine axis.
[0052] Figure 12 is an illustration of a layer of liquid resin in which the reinforcing magnetic fibers are suspended before being subjected to an electromagnetic field.
[0053] Figure 13 is an illustration similar to Figure 12, but after an electromagnetic field is applied, showing the reinforcing magnetic fibers having migrated to the outer limits of the part to form a continuous, electrically conductive outer surface over a layer healed.
[0054] Figure 14 is an illustration similar to figure 13, but it shows the fibers having been positioned by an electromagnetic field to form an internal electrical conductor.
[0055] Figure 15 is an illustration of the area designated as figure 15 in figure 14, showing the fibers aligned end to end to form the conductor.
[0056] figure Figure 16 is an illustration of an aircraft production flow diagram and maintenance methodology.
[0057] Figure 17 is an illustration of an aircraft block diagram.
DETAILED DESCRIPTION [0058] Referring first to figure 1, the apparatus 20 for manufacturing a part 22 using a direct digital manufacturing technique in general comprises a head 34 that moves on a table 26 within a tank 32 containing a suitable building material 24, which in the illustrated example, is a
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12/22 liquid polymer resin. Construction material 24, which will hereinafter be referred to as a matrix or matrix material, can comprise any of a variety of curable, bondable or meltable materials, depending on the application and the additive process to be used, including, but not limited to thermosetting plastics such as epoxy or polyester resins, metals such as Al, Ti, Fe, and Ni, ceramics such as Si, Al2So3, SiC, and thermoplastics, such as polyamide, Poly (aryl-ether ketone), polyphenylene sulfide, polyphthalamide and glassy microspheres, to name just a few.
[0059] The table 26 can be raised or lowered 30, inside the tank 32 by a piston 28 or other appropriate mechanism, along a central axis of the machine 35. In one embodiment, the matrix material 24 can comprise a resin of photo-polymer having a viscosity between approximately 100 and 2000 cps, which is selectively solidified in sequential layers 42 using a UV (ultraviolet) laser 33 on the head 34, which directs a beam of UV laser 38 on the liquid resin. Depending on the particular matrix material 24 and additive process being used, other energy beams can be used to cure or melt the matrix material 24, such as, without limitation, an infrared (IR) light beam or an electron beam . Magnetic particles, such as, without limitation, chopped or ground reinforcement fibers 25 are mixed and suspended within the matrix material 24, forming a mixture that may or may not be substantially homogeneous. Different magnetic particles, or in addition to the fibers 25, can be mixed within the matrix material 24 to obtain the desired characteristics of the part. As used in this document, magnetic particles, magnetic fibers and magnetic materials refer to particles, fibers or other materials that produce a magnetic field in response to an applied magnetic field, and in particular, materials that are ferromagnetic
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13/22 or ferrimagnetic.
[0060] The fibers 25 may comprise a magnetic metal or a combination of one or more magnetic metals or alloys of metals and non-magnetic materials, such as, without limitation, a polymer, glass or a mineral. Suitable metals include, without limitation, Fe, Ni, Co, and their alloys, to name but a few. The fibers 25 may themselves comprise permanent magnets, and the resulting part 22 may comprise a permanent magnetic compound. The aspect ratio (length-to-diameter ratio) of the fibers 25 can be selected according to the particular application, the matrix material 24, the strength of the electromagnetic field and the additive process being used, as well as other variables, such as viscosity of the matrix material. Generally, however, it may be desirable to select fibers having a relatively high aspect ratio, in order to minimize the magnetic resistance of the magnetic circuit formed by the fibers 25 and the electromagnetic fields 40. The content of fiber 25 in the mixture can be in a fraction volume in the range of approximately 20% to 50%. In one example, the fibers 25 may comprise cut synthetic fibers having a length of approximately between 3 mm and 6 mm which are coated with a magnetic metal. In another example, the fibers 25 can be milled fibers having a length between 50 and 500 microns which are also coated with a magnetic metal. In another practical embodiment, the matrix material comprises a polymeric powder present in the mixture in an amount between approximately 20% and 99% by weight, but preferably between 50% and 90% by weight.
[0061] The head 34 further includes one or more pairs of electromagnets 36, which are aligned with each other in relation to a machine axis 35 to generate electromagnetic fields 40, which, as shown in figure 1A, cooperate to guide the reinforcement fibers
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14/22 in a desired direction, in order to harden part 20 along a desired direction, such as, for example, generally parallel to machine axis 35 (figure 1). The magnetic fibers 25 align themselves in such a way that their longitudinal axes 54 are aligned with the lines of force 37 of the fields 40, in order to minimize their magnetic resistance. Electromagnetic fields 40 can also be used to position fibers 25 by moving them to a desired region (not shown) within matrix 24, as will be discussed in more detail later. The electromagnets 36 control the orientation and / or the position of the fibers 24 in three-dimensional space and in time with respect to the application of the energy used to solidify the matrix material. The laser 33, the head 34 and the electromagnets 36 are coupled to a suitable power supply 44 and are controlled by a controller 45. The shape and / or orientation of the fields 40 may depend on the position and / or orientation of the electromagnets 36, as well as the type, size and / or density of the magnetic fibers 25. [0062] Controller 45 can comprise a programmed computer that accesses a 3D digital definition of part 22, as a CAD file, from the electronic file storage 48. The controller 45 uses the 3D CAD file to control the movement of the head 34, synchronized with the operation of the laser 33 and the electromagnets 36 to orient and / or position the magnetic fibers 25, and to selectively solidify, bond or fuse parts of each layers 42 of resin 24 to produce part 22. As each layer 42 of part 22 is completed, table 26 is lowered, and head 34 proceeds to form the next layer 42 of part 22. While laser 33 and electromagnets 36 are mobile, together with the head 34 in the example shown in figure 1, in other embodiments discussed below, they can instead be mounted stationary. [0063] As mentioned above, fibers 25 may comprise
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15/22 a combination of magnetic and non-magnetic metallic materials. For example, referring to figure 2, the fibers 25 may comprise a core 50 of high-strength synthetic fiber such as, without limitation, a carbon fiber, surrounded by a magnetic metal covering or the coating 52, which may contain, without limitation, Ni or Ni alloy. Other magnetic coatings are possible. Figure 3 illustrates an alternative form of magnetic fiber 25a comprising a plurality of individual polymeric fibers 50 arranged in a bundle 56, which is surrounded by an outer magnetic layer 52 of a suitable magnetic metal or metal alloy. As shown in figure 1A, when coupled with the aligned magnetic fields 40 produced by the electromagnets 36 (figure 1), the fields 40 orient the fibers 25, 25a as their longitudinal axes 54 are aligned substantially parallel to each other and parallel to the lines force 37 of fields 40.
[0064] The method and apparatus described can be used to manufacture fiber-reinforced parts in which matrix material 24 is supplied in powder form, rather than as a liquid resin, as shown in figure 1. For example, figure 4 illustrates a part of a layer 42 comprising a matrix 24 of dry powder particles or granules 60 in which the magnetic fibers 25 (or other magnetic particles) are mixed homogeneously or inhomogeneously. The fibers 25 have generally random orientations.
[0065] Referring to figure 5, when electromagnetic fields 40 (figure 1) are applied to the matrix 24, the fibers 25 orient themselves in unidirectional alignment inside the dry powder particles 60. Then, as shown in figure 6, the dry powder particles 60 are transformed into a solid matrix 24 around the aligned fibers 25. Depending on the particular additive process to be used, this transformation can be achieved by curing,
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16/22 melting or bonding the matrix material 24. Where the dust particles 60 are a polymer, they can be melted into a liquid using heat, and then cured by an energy beam such as a laser beam 38 ( figure 1). Where the powder particles 60 are glass, ceramic or a metal or metal alloy, they can be melted together as a solid by sintering, using an energy beam, such as laser beam 38 to melt together at least the outer layers (not shown) of particles 60. Alternatively, powder particles 60 can be transformed into a solid using a 3D printing process in which the powder particles are selectively joined together by printing a binder ( (not shown) in selected areas of a layer 42 of matrix material 24, which links particles 60 together.
[0066] Here it should be noted that, while the fibers 25 can be oriented using the magnetic fields 40 before the powder particles 60 are transformed into a solid or liquid as described above in connection with figures 4 and 5 can be possible to guide them during the transformation process. For example, and without limitation, where the powder particles 60 are of a polymeric resin, the fibers 25 can be oriented after the powder particles 60 are melted into a liquid, however, before the liquid polymer is cured to a solid.
[0067] Referring now to figure 7, a method of direct manufacture of a piece 22 according to the described modalities begins at step 62 in which the magnetic particles are supplied, such as the reinforcement magnetic fibers 25. As discussed earlier, reinforcement fibers 25 can be manufactured by coating or by wrapping one or more non-magnetic fibers with a magnetic material. In step 64, the magnetic particles 25 are introduced into the matrix material by mixing reinforcement fibers
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Magnetic 17/22 25. In step 66, the magnetic particles in the matrix material can be oriented by coupling one or more electromagnetic fields 40 with the magnetic particles 25. The elevation of a support table of part 22 is adjusted in step 68 to present a layer 42 of matrix material 24 and fibers 25, after which, in step 70, features of part 22 are formed using a beam of energy, to solidify the selected areas of layer 42, while the magnetic particles remain oriented. Steps 68 and 70 are repeated until all layers 42 of part 22 have been formed. As noted earlier, step 66 in which the particles 25 are oriented can be carried out substantially simultaneously with step 70.
[0068] Figure 8 illustrates an alternative embodiment of the apparatus 20a in which a fiber laser 33, together with a matrix of four electromagnets 36 are mounted on a movable head 34. The electromagnets 36 are arranged in matched arrays aligned axially in such a way. so that each pair of electromagnets 36 produces a magnetic field 40 which is coupled with an area 76 of layer 42 that is being solidified by a beam of energy 38 produced by the fiber laser 33. In this example, a layer 58 consisting of dry powder 60 and the magnetic particles 25 are being selectively fused. The area shown in 76 is in the process of being melted and fused by a laser beam 38 produced by the fiber laser 33, and the magnetic particles 25 are oriented in unidirectional alignment by the electromagnets 36 as the powder 60 is being melted and melted. Head 34 is moved over layer 58, controlled by controller 45 (figure
1) based on a 3D digital part definition, such that the patterns (not shown) on the successive layers 76 of layer 58 are fused and solidified. The melting of the powder 24, and thus the displacement rate of the head 34 must be synchronized with the
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18/22 time required to orient or reposition the magnetic particles 25. This timing depends on a number of variables, including the strength of the magnetic field and the viscosity of the powder 24 as it is being melted.
[0069] Figure 9 illustrates another embodiment 20b of the apparatus that avoids the need for the moving head 34 used in the embodiment shown in figures 1 and 8. A laser 33 generates a laser beam 38 which is controlled by a scanner 78 and reflector 80 for digitizing successive patterns (not shown) on layers 42 of a matrix material which may include magnetic particles 25. In this embodiment, the electromagnets 36 are mounted stationary around the table 26, and are controlled by the controller 45 (figure 1) to produce electromagnetic fields 40, which guide the magnetic particles, shown here as reinforcement fibers 25, as desired. In this example, part 22 has a generally cylindrical body 82a, and a reduced diameter, generally cylindrical top 82b connected by a conical neck 82cs. As discussed earlier, part 82 is formed layer by layer, 42 by additive fabrication using a 3D digital definition of part 22. The solidified matrix material 24 forming layers 42 of body 22 has magnetic reinforcement fibers 25 that are aligned in generally normal to the machine shaft 35, while the reinforcing magnetic fibers 25 in the layers 42 of the top 22b are aligned substantially in parallel with the machine shaft 35. In the conical neck 22c of part 82, at least some of the reinforcement fibers 25 can be aligned to adapt to the conical neck contour 82c. Thus, it can be appreciated that the strength and / or the location of the electromagnetic fields 40 produced by electromagnets 36 can be changed in order to change the orientation and / or the position of the reinforcing magnetic fibers 25 as part 82 is manufactured layer by layer 42.
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19/22 [0070] The number, alignment and layout of the 36 electromagnets may vary according to the application. For example, and without limitation, figure 10 illustrates a circular set of two levels of electromagnets 36 around machine 35. The matrix shown in figure 10 can provide additional flexibility in forming and changing the location and / or geometry of electromagnetic fields 40 which can allow the magnetic fibers 25 to be oriented at different angles as each layer of the part is formed.
[0071] Figure 11 illustrates another arrangement that can provide flexibility in forming and changing the location and / or geometry of electromagnetic fields 40. One or more pairs of electromagnets 36 can be mounted on a gantry or other structure 55, which allows the electromagnets 36 are rotated 34 around the axis of the machine 35 and / or to be transferred along both x, y axes mutually orthogonal 82. Changing the position and / or orientation of the electromagnets 36 in this way can be used to direct the fields electromagnetic 40 and thereby control the orientation and / or position of the magnetic fibers 25 within the matrix 24. The alignment and / or positioning of the fibers 25 can also be controlled by controlling the strength of the fields 40 produced by the electromagnets 36.
[0072] The electromagnetic fields 40 used to orient magnetic particles, such as magnetic fibers 25, can also be used to form the characteristics of a piece 22, changing the position of the 25 fibers in piece 22. For example, figure 12 illustrates a layer 42 of matrix material containing 24 electrically conductive magnetic fibers 25. The electromagnetic force fields 40 (Figure 1) can be applied to the mixture of matrix material 24 and fibers 25 in a way that does so much that the fibers 25 line up unidirectionally, as you move 88 to the outer edges 86 of layer 42. As shown in figure 13, the repositioning 870180045826, of 29/05/2018, p. 25/36
20/22 of the fibers 25 to the outer edges 86 results in an accumulation of fibers 25 to form a continuous outer metallic layer 90 over the solidified layer 42 which is electrically conductive. Such electrically conductive layers 90 can be useful for a wide range of applications, such as, without limitation, protection against lightning impact on aircraft surfaces (not shown).
[0073] Attention is now drawn to figure 14 which illustrates an additional example in which electromagnetic fields 40 can be used in additive manufacturing processes to form the characteristics of the part. In this example, a continuous electrical conductor 90 is formed internally within of a layer 42 of matrix material 24, using electromagnetic fields 40 to move 88 magnetic particles 25, which may be metal fibers 25, within matrix material 24. As the fibers 25 are repositioned and move together under the influence of fields 40, they are also oriented in a unidirectional alignment. Figure 15 is an enlarged view of part of the conductor shown in Figure 14. The electromagnetic fields 40 align the fibers 25 end to end and position them side by side. A slight spacing is shown between the fibers 25 in figure 15 to show their relationship with respect to the other, however they are, in reality, in electrical contact from end to end and side to side when fully oriented and positioned.
[0074] Modalities of the description can find use in a variety of potential applications, especially in the transport industry, including, for example, aerospace, marine, automotive applications and other applications where automatic molding equipment can be used. In this way, now referring to figures 16 and 17, the description modalities can be used in the context of aircraft manufacturing and maintenance method 870180045826, of 29/05/2018, p. 26/36
21/22 maintenance 94 as shown in figure 16 and an aircraft 96 as shown in figure 17. Applications in aircraft of the described modalities may include, for example, without limitation, hatches, covers, reinforcements, linings and other parts. During pre-production, example method 94 may include aircraft specification and design 98 and material acquisition 100. During production, component and subset 102 manufacturing and system integration 104 of the aircraft takes place. Subsequently, aircraft 96 may undergo certification and delivery 106 in order to be placed in service 108. While in service by a customer, aircraft 96 is scheduled for routine maintenance and overhaul 110 which may also include modification, reconfiguration, remodeling, and so on.
[0075] Each of the method 94 processes can be performed or performed by a system builder, a third party, and / or an operator (for example, a customer). For the purposes of this description, a system builder may include, without limitation, any number of aircraft manufacturers and subcontractors of the main systems; a third party may include without limitation any number of vendors, subcontractors and suppliers; and an operator can be an airline, leasing company, military entity, service organization, etc.
[0076] As shown in figure 17, aircraft 96 produced by method 94 can comprise a structure 112 with a plurality of systems 114 and an interior 116. Examples of high level systems 114 include one or more of a propulsion system 118 , an electrical system 120, a hydraulic system 122, and an environmental system 124. Any number of other systems can be included. Although an aerospace example is shown, the principles of the description can be applied to other industries such as industries. Petition 870180045826, 29/05/2018, p. 27/36
22/22 naval and automobile routes.
[0077] Systems and methods incorporated in this document can be used in any one or more stages of the production and maintenance method 94. For example, the components or subassemblies corresponding to the production process 102 can be manufactured or manufactured in a similar way to those components or sub-assemblies produced while aircraft 96 is in service. Also, one or more modes of the apparatus, method modalities, or a combination of them can be used during production phases 102 and 104, for example, by substantially speeding up assembly or reducing the cost of an aircraft 96. Likewise , one or more apparatus modalities, method modalities, or a combination thereof may be used while aircraft 96 is in service, for example, and without limitation, for maintenance and overhaul 110.
[0078] The description of the different advantageous modalities has been presented for purposes of illustration and description, and is not intended to be complete or limited to the modalities in the revealed form. Many modifications and variations will be evident to those skilled in the art. In addition, different beneficial embodiments can provide several advantages compared to other advantageous embodiments. The selected modality or modalities are chosen and described in order to better explain the principles of the modalities, their practical application, and to enable other experts in the art to understand the description for various modalities with various modifications as they are appropriate for the particular intended use.
Petition 870180045826, of 05/29/2018, p. 28/36
1/3

权利要求:
Claims (13)
[1]
1. Method of manufacturing a part (22), comprising:
supply (62) of magnetic particles (25); introducing (64) the magnetic particles (25) into a layer (42) of a matrix material (24);
orientation (66) of the particles (25) in the matrix material (24) by coupling the particles (25) with an electromagnetic field (40); and curing (70) of the matrix material (24) while the particles (25) are oriented, characterized by the fact that the orientation of the particles (25) includes the repositioning (88) of the particles (25) inside the matrix material (24), and that the electromagnetic field (40) is applied to the mixture of the matrix material (24) and the particles (25) so that it causes the particles (25) to unidirectionally align and move to outer limits (86 ) of the layer (42).
[2]
2. Method according to claim 1, characterized in that the coupling of the particles (25) with an electromagnetic field (40) includes:
positioning at least a pair of electromagnets (36) adjacent to the matrix material (24), including aligning the electromagnets (36) in relation to each other, and using electromagnets (36) to generate the electromagnetic field (40).
[3]
Method according to claim 1 or 2, characterized in that the orientation (66) of the particles (25) includes aligning the particles (25) in a desired direction.
[4]
Method according to any one of claims 1 to 3, characterized in that it additionally comprises:
Petition 870180045826, of 05/29/2018, p. 29/36
2/3 use of the electromagnetic field (40) to form a characteristic of the part (22) through the repositioning (88) of the magnetic particles (25).
[5]
Method according to any one of claims 1 to 4, characterized in that the supply (62) of the particles (25) comprises the coating of elongated synthetic fibers (50) with a magnetic metal (52).
[6]
Method according to any one of claims 1 to 5, characterized in that the supply (62) of the particles (25) includes:
formation of bundles (56) of synthetic fibers (50), and wrapping each of the bundles (56) in a magnetic metal (52).
[7]
7. Method according to any one of claims 1 to 6, characterized by the fact that:
the matrix material (24) is a powder, and curing (70) is carried out by sintering the powder.
[8]
8. Method according to claim 1, characterized by the fact that the matrix material (24) is selectively solidified.
[9]
Method according to claim 8, characterized in that the magnetic particles (25) include at least one of the following elements: aramid, glass fiber and carbon fiber having magnetic coating (52).
[10]
10. Method according to claim 8 or 9, characterized by the fact that the matrix material (24) is one of the following:
a polymeric powder, a photopolymeric liquid, a metallic powder, e.g. glassy microspheres.
[11]
11. Method according to any of the claimsPetition 870180045826, of 29/05/2018, p. 30/36
3/3 sections 8 to 10, characterized by the fact that the matrix material (24) is a polymeric powder present in the mixture in an amount approximately between 50% and 90% by weight.
[12]
Method according to any one of claims 8 to 11, characterized in that the magnetic particles (25) include one of the following:
cut fibers having a length of approximately between 3 and 6 mm, and ground fibers having a length of approximately between 50 and 500 microns.
[13]
13. Method according to any of claims 8 to 12, characterized in that the magnetic particles (25) include:
bundles (56) of non-magnetic reinforcement fibers (50), and a layer of magnetic material (52) around each of the bundles (56).
Petition 870180045826, of 05/29/2018, p. 31/36
1/10
44 45 48
35 ^

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同族专利:

公开号 | 公开日

JP2013063641A|2013-04-11|

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CA2782430C|2016-01-12|

EP2565022A1|2013-03-06|

CN102963002A|2013-03-13|

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US9457521B2|2016-10-04|

CA2782430A1|2013-03-01|

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法律状态:
2014-02-25| B03A| Publication of an application: publication of a patent application or of a certificate of addition of invention|

2018-04-03| B07A| Technical examination (opinion): publication of technical examination (opinion)|

2018-08-14| B09A| Decision: intention to grant|

2018-09-11| B16A| Patent or certificate of addition of invention granted|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 30/08/2012, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

申请号 | 申请日 | 专利标题

US13/223,924|US9457521B2|2011-09-01|2011-09-01|Method, apparatus and material mixture for direct digital manufacturing of fiber reinforced parts|

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