法国专利FR3046370A1 METHOD AND SYSTEM FOR ADJUSTING AN ADDITIVE MANUFACTURING DEVICE

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专利摘要:
The invention relates to a system for adjusting and measuring an additive manufacturing device (201), in particular by the CLAD method, comprising a powder projection nozzle (100) and a laser beam passing through the center of said nozzle, characterized in that it comprises: a. a light source comprising: ai. means (210) for positioning said light source relative to a material surface; aii. lighting means (220) capable of delivering a luminous flux (221) substantially perpendicular to a plane, called a lighting plane; b. a camera (240), said profile camera, installed so that its optical axis (241) is substantially parallel to the lighting plane; vs. an optical tracking device (250) adapted to project vision through the center of the nozzle (100); d. a second camera (260), said centering camera, whose optical axis is placed on the optical path (250); e. a target capable of being perforated by a low power laser firing; f. a set (290) of acquisition and processing capable of collecting the images from the cameras (240, 260) shooting.
公开号:FR3046370A1
申请号:FR1502754
申请日:2015-12-31
公开日:2017-07-07
发明作者:Jean-Yves Hascoet；Gilles Carabin
申请人:Ecole Centrale de Nantes；
IPC主号:

专利说明:

The invention relates to a method and a system for adjusting an additive manufacturing device. The invention is more particularly adapted to an additive manufacturing process called CLAD®, acronym for "Direct Additive Laser Construction", consisting in constructing an object by depositing a powder material melted by a laser.
FIG. 1, relating to the prior art, shows schematically an embodiment of this method. According to this embodiment, the deposition of material is carried out by means of a nozzle (100) of projection / melting of the powder comprising 3 concentric cones delimiting between their walls conical annular spaces also concentric. A laser (150) transverses the inner cone (130) by a bore centered on the axis of said cone. The laser is focused on the point (191) where the deposition (192) of material is performed on the object (190) during manufacture. Powder (160) is projected into the conical annular space between the inner surface of the outer cone (110) and the outer surface of an intermediate cone (120) while a gas is blown into the annular space conical portion between the inner surface of said intermediate cone (120) and the outer surface of the inner cone (130). Centering the cones (110, 120, 130) relative to one another and adjusting the parameters causes the powder to be projected in a hollow conical jet whose peak is, ideally, coincident with the laser's point of focus (191). (150). The distance (193) between the point (191) of deposition of the material and the front end of the cone (110) outside is commonly of the order of 5 mm, without this value can be considered as limiting or exhaustive.
The implementation of such a method requires to know precisely the shape of the projected material cone and ensure the perfect centering of said cone relative to the laser beam. More particularly in the context of the manufacture of an object requiring the implementation of complex trajectories comprising, for example, continuous variations of the orientation of the powder jet in space, require a perfect knowledge of the length of said cone , the position of its center or the shape of this cone. These parameters are notably managed in a numerically controlled machine by means of so-called correctors or tool gauges, which make it possible to control the axes in an appropriate manner, so as to respect a program which defines the movements by the displacement of the point. deposition and the orientation of the projection opposite the surface produced. For this purpose it is necessary to know the relative position of this point of deposition and focusing of the laser in the reference of the machine. These programming and control techniques, identical to those used in the context of manufacturing by material removal, are known from the prior art and are not detailed further. In the area of material removal, the tool gauge parameters are derived directly from the measurement of the physical tool, either off-machine or on the machine.
In the case of additive manufacturing, more particularly in the context of the CLAD process, the dimensions of the projection cone are given by the parameters of implementation of the process, such as the flow of gas and the nature of the projected powder, or again, by setting the cones of the nozzle. Also, it is not possible to measure a tool gauge parameter, such as the position of the axis of the projection cone in the machine coordinate system and the length of the projection cone, or to adjust the shape of said projection cone without putting the projection process.
According to a method of the prior art, the position of the laser axis is obtained by performing a low energy shot on an adhesive tape glued to the end of the nozzle. The end of the nozzle leaves a trace on the sticky part and the laser shot makes a hole in the tape. This procedure allows you to adjust the concentricity of the two marks: the hole and the trace of the nozzle, by acting on the appropriate settings of the cones of the nozzle. In all cases, this is an indirect measurement that must be repeated several times to make the adjustment. The quality of the adjustment is random, and even an experienced operator can not expect a repeatability error of less than 0.5 mm. In all cases, this technique of the prior art does not allow to determine the tool gauge, that is to say the length and, if necessary, the shape of the projection cone. The invention aims to solve the disadvantages of the prior art and concerns for this purpose a system for the adjustment and measurement of an additive manufacturing device, in particular by the CLAD method, comprising a powder projection nozzle and a beam laser passing through the center of said nozzle, which device comprises: a. a light source comprising: ai. means for positioning said light source relative to a material surface; aii. lighting means adapted to deliver a luminous flux substantially perpendicular to a plane, said lighting plane b. a camera, said profile camera, installed so that its optical axis is substantially parallel to the lighting plane; vs. an optical tracking device capable of projecting vision through this center of the projection nozzle; d. a second camera, said centering camera, whose optical axis is on the optical path; e. a target capable of being marked by a low power laser shot; f. a set of acquisition and processing able to collect the images from the cameras.
Thus, the object of the invention is to obtain images of the powder jet and the laser beam and to materialize the position of the powder projection orifice by the luminous flux passing through the nozzle and the centering of the laser by the marking. of the target. The device allows centering the nozzle and the laser in real time without having to re-fire or re-install the device. The invention is advantageously implemented according to the embodiments and variants described below, which are to be considered individually or in any technically operative combination.
Advantageously, the light source comprises a plurality of light-emitting diodes in an annular disposition in the lighting plane. This embodiment makes it possible to obtain shade-free illumination and the annular arrangement makes it possible to center the nozzle with respect to this illumination so that the image of the projection orifice on the centering camera is uniformly illuminated, whereas the point of focus of the laser beam remains dark enough to be visualized.
According to an improved embodiment, the system which is the subject of the invention comprises: g. a third camera, whose optical axis is parallel to the lighting plane and perpendicular to that of the profile camera.
This embodiment makes it possible to measure the shape of the powder jet and the alignment of its profile with the laser in two planes. The adjustment of the shape of the powder jet is achieved by adjusting the powder and gas flow rates. Thus the system object of the invention allows a measurement and a three-dimensional adjustment of the geometry of the projection / fusion. The invention also relates to a method for adjusting and measuring a material projection / melting device, in particular by the CLAD method, by means of a system according to the invention, which method comprises the following steps: . positioning the projection nozzle above the lighting plane in a substantially normal orientation to said plane; ii. placing the target between the exit of the nozzle and the lighting plane so that said target intercepts a laser shot; iii. perform a low energy laser shot; iv. illuminate the end of the nozzle by means of the light source; v. get the image through the end of the nozzle by the centering camera, the mark left by the laser shot on the target, while the end of the nozzle is illuminated.
This method makes it possible to obtain an image of the position of the powder projection orifice, which appears as a luminous crown, with respect to the axis of the laser beam, materialized by the mark left by the laser on the target, without removing said target, as well as to visualize the modifications of this position during each adjustment, by the displacement of the luminous crown, thus facilitating the adjustment of the nozzle.
According to a variant of the method which is the subject of the invention, the target is glued on the end of the nozzle.
According to another variant of the method which is the subject of the invention, the target is maintained on the lighting plane.
The possibility of vision through the nozzle conferred by the centering camera and the optical path of the device that is the subject of the invention makes it possible to implement the method that is the subject of the invention with the target placed between these two extremes, or any position between them.
Advantageously, the method which is the subject of the invention comprises the steps of: vi. measuring the centering error between the contour of the illuminated space and the image of the mark left by the laser on the target, on the image obtained in step v); vii. calculate the setting to correct the centering error.
These steps, implemented by the acquisition and processing means, allow, as a function of the adjustment device of the machine, to automatically determine the corrections to be made.
Advantageously, the method which is the subject of the invention comprises the steps of: viii. make a powder projection; ix. get the image of the powder projected by the profile camera.
Thus, the method that is the subject of the invention makes it possible to visualize the shape of the powder jet. Also, the method which is the subject of the invention advantageously comprises the steps consisting in: x. determining the shape of the image of the powder jet from a predetermined profile on the image obtained in step ix); xi. deduce from step x) the tool gauges corresponding to the jet.
Thus, the method which is the subject of the invention makes it possible to obtain precise tool gauges for improving the quality of manufacture of the objects.
Advantageously, the method which is the subject of the invention further comprises the steps of: xii. generate a laser beam during step viii) xiii. measuring on the image obtained in step ix) the orientation deviation of the image of the powder jet with respect to the image of the laser beam; xiv. derive from the results of step xii) the adjustments to be made to correct the orientation error.
In addition to obtaining a perfect orientation of the powder jet relative to the laser, the measurements made during step xii) make it possible to check the correct operation of the additive manufacturing device, in particular after a collision.
According to an improved embodiment, the method of the invention implements a system comprising three cameras and comprises the steps of: xv. obtain an image of the projected powder by means of the third camera; xvi. repeat steps xiii) and xiv) with the image obtained in step xv) in place of the image obtained in step ix).
According to this same mode of implementation, the method which is the subject of the invention comprises a step consisting of: xvi. repeat steps x) and xi) with the image obtained in step xiv) instead of the image obtained in step ix).
This improved embodiment of the method that is the subject of the invention makes it possible to carry out a control and a three-dimensional adjustment of the powder jet and the laser beam. Thus, according to this embodiment, the method which is the subject of the invention advantageously comprises a step consisting in: xvii. repeat steps x) and xi) with the image obtained in step xv) instead of the image obtained in step ix). The invention is described below according to its preferred embodiments, which are in no way limitative, and with reference to FIGS. 1 to 5, in which: FIG. 1, relating to the prior art, shows according to a principle view in perspective and in section, an exemplary embodiment of a projection / melting nozzle used in the CLAD® process; - Figure 2 shows in a schematic front view and in section AA defined in Figure 3 an example of installation of the system object of the invention in an additive manufacturing machine; - Figure 3 shows in a top view of an embodiment of the system object of the invention; FIG. 4 illustrates the adjustment of the concentricity of the laser beam and the nozzle by the image obtained by the centering camera; and FIG. 5 shows an example of the screen displayed on the acquisition and processing means for carrying out the adjustments or means of the profile cameras.
Figure 2, according to an exemplary embodiment, the system object of the invention is installed in a machine tool capable of performing additive manufacturing. By way of example, said system is installed on the table (201) of said machine, on which it is fixed by means of a magnetic support (210). According to alternative embodiments (not shown), said support is not magnetic and is clamped or bolted on the table, or fixedly fixed thereon at a location that does not interfere with the manufacturing operations. The system includes a light source (220). Said light source (220) emits a luminous flux (221) mainly directed perpendicularly to a lighting plane, a lighting plane which, according to this exemplary embodiment, is substantially parallel to the table (201) of the machine. According to alternative embodiments, the support is a V e support, for example to install the system on a cylindrical surface, or comprises means for adjusting its orientation, and consequently the orientation of the light source, with respect to the surface on which it is placed.
For the implementation of the system that is the subject of the invention, the additive manufacturing head (202) of the machine is positioned above the light source (220), so that the direction (203) of the laser beam is substantially perpendicular to the illumination plane, said laser beam preferably being centered with respect to the light source so as to obtain uniform illumination of the nozzle (100).
According to this exemplary embodiment, a support arm (230), attached to the support (210) of the light source, makes it possible to place a video camera (240), preferably a digital camera, said profile camera, so that the axis (241) the camera lens is substantially perpendicular to the presumed direction (203) of the laser beam, thus substantially parallel to the lighting plane, and that said camera provides an image of the end of the projection nozzle (100) and powder jet exiting said nozzle. Alternatively, the profile camera is fixed in the machine independently of the support (210) of the light source, while respecting the orientation of its optical axis relative to the presumed direction of the laser beam.
An optical path (250) is formed in the additive machining head, allowing a second (260) camera, said centering camera, to obtain an image through the powder projection orifice of the nozzle (100). . On a number of machines implementing the CLAD method, this optical path (250) and the location for the installation of this second camera are pre-installed so that no modification of the additive manufacturing head is necessary. The representation of the optical path 2 is a representation of principle. In practice, said path is made so that it does not interfere with the laser beam. Thus, the centering camera (260) produces an image as viewed through the nozzle (100). The camera setting, including the sharpness point and depth of field, the optical path and the position of the additive machining head (202) relative to the light source (220), is such that the camera of centering can visualize in the same image, with a sharpness adapted to the measurements made, the perimeter of the powder projection orifice and a materialization of the position of the laser beam. This materialization is obtained by the perforation of a target placed between the end of the nozzle (100) and the lighting plane. The perforation of said target is performed by a laser fire at reduced power.
The two cameras (240,260) are connected to a system (290) for acquisition and processing, for example a laptop, for collecting the images provided by said cameras and to perform various treatments on these images.
FIG. 3, according to an exemplary embodiment, the light source comprises a plurality of light sources (320), for example light-emitting diodes arranged on the lighting plane in an annular configuration, the additive manufacturing head being placed substantially in the center of this ring. Such a light source makes it possible to obtain shade-free illumination of the nozzle with a darker central zone making it possible to better visualize the target (303) in the center of the device. According to this exemplary implementation, the target (303) is placed on the lighting plane. Said target is for example made of paper or adhesive tape to achieve a mark made on the target by a low-power laser shot, less than 10 watts preferably less than 5 watts.
Said target (303) is placed on the path of the laser beam between the lighting plane and the outlet of the nozzle of the additive manufacturing head. The easiest positions of implementation are obtained when said target is placed on the lighting plane or on the outlet end of the nozzle. The target is glued or held by a clamp (not shown). The low-power laser firing produces on the target a darker burn zone (393) or a substantially circular perforation.
According to a particular embodiment, the device according to the invention comprises a second camera (340) in profile, aimed at the nozzle of the additive manufacturing head, whose optical axis is perpendicular to the presumed axis of the laser beam and substantially perpendicular to the axis of the first camera (240) profile.
4, the image observed by the centering camera comprises a luminous crown (420) whose perimeter corresponds to the expulsion orifice of the powder and a dark spot (493) corresponding to the mark left by the laser on the target. From the acquisition and processing means, the contours of these two spots, the light spot (420) and the dark spot (493), are for example similar to circles whose relative eccentricity is easy to measure. This measurement operation is performed by the operator by visualizing on the screen means of acquisition and processing the image delivered by the centering camera. The identification of the two circles is done by the operator, for example by means of a graphical tool for superimposing the drawing of said contours on the image obtained by the centering camera. In order to carry out the measurement precisely, the acquisition and processing means advantageously receive from the centering camera like other cameras information such as the focal length of the lens used, the adjustment of the focus, the diaphragm and the resolution, without this list being neither exhaustive nor limiting, this information making it possible to calculate precisely the reproduction ratio of the displayed image and thus to carry out the appropriate measurements.
When the target is placed on the lighting plane, the adjustment is made by acting on the mechanical centering of the cones of the nozzle, and provided not to move the additive manufacturing head relative to the device object of the invention any change in the centering of the expulsion orifice of the powder is immediately visible without performing a new laser shot, which allows the nozzle to be adjusted with a real-time image. When the additive manufacturing device comprises an optical adjustment of the laser, for example by means of a lens, then the initial setting is calculated by means of image acquisition. Once the adjustment is made, a new shot is made. According to this last embodiment, the ease of production is identical whether the target is placed on the end of the nozzle or on the lighting plane.
FIG. 5, according to an exemplary implementation, the display screen (500) on the acquisition and processing means corresponding to one or the other of the profile cameras, comprises a first frame (501) representing the image seen by the profile camera. This image shows the end of the nozzle (100) of the additive manufacturing head, and when a jet of powder is propelled by this nozzle, the profile camera makes it possible to visualize the image (560) of this jet of powder . If a laser beam is generated during the powder jet, the illumination of the powder particles allows a visualization of the direction (593) of said laser beam. According to alternative embodiments, the image of the nozzle and the powder projection in this first screen is an animated image showing in real time the powder projection and the shape of the jet as a function of the regulation of the powder and gas flows. , or a photographic image taken from a powder projection test carried out previously.
The system which is the subject of the invention advantageously comprises memory means for recording and possibly time-stamping the images or films acquired by the various cameras as well as the adjustments made.
A second frame (502) of the screen allows the operator to access a set of tools including, for example, graphical tools for drawing on the image represented in the first screen (501). With the aid of these tools, the operator, according to an example embodiment, determines the profile of the image (560) of the powder jet, according to a predetermined pattern (565), for example a trapezium. According to this exemplary embodiment, a label (566) displayed in the first frame (501) gives the operator a first level of information on the characteristics of the trapezium (565) thus identified. A display (513) in the second frame, informs the operator on the tool gauges deduced from the profile (565) identified. These tool gauges are then entered manually by the operator into the correction tables of the machine, or, more advantageously, the acquisition and processing means comprise a data exchange interface with the director of the machine. machine control and the machine's correction tables are immediately updated by transfer of identified numerical values once the operator has validated the measurement. These gauges consist for example in the length of the trapezium, the width of its large base, similar to the large diameter of the powder jet and the width of its truncated apex, comparable to the small diameter of the frustoconical jet. The image in the first frame (501) also makes it possible to detect the case of a laser beam (594) that is misaligned with respect to the powder jet, and if necessary to calculate the necessary adjustments to restore this orientation.
When the system object of the invention comprises two profile cameras these different settings and controls are made from the images provided by each of said profile cameras.
The above description and the exemplary embodiments show that the invention achieves the intended purpose, ie it makes it possible to greatly facilitate the different positioning adjustments of the laser with respect to the nozzle. The invention is here presented in the context of an additive manufacturing machine, but it is also adaptable to the adjustment of the concentricity and the orientation of a laser cutting nozzle with respect to said cutting laser. The images and the settings are advantageously stored in memory means to ensure the traceability of manufactured products.

权利要求:
Claims (12)
[1" id="c-fr-0001]
A system for adjusting and measuring an additive manufacturing device (201), in particular by the CLAD method, comprising a powder spraying nozzle (100) and a laser beam passing through the center of said nozzle, characterized in that that it comprises: a. a light source comprising: ai. means (210) for positioning said light source relative to a material surface; aii. lighting means (220) capable of delivering a luminous flux (221) substantially perpendicular to a plane, called a lighting plane; b. a camera (240, 340) for shooting, said profile camera, installed so that its optical axis (241) is substantially parallel to the lighting plane; vs. an optical tracking device (250) adapted to project vision through the center of the nozzle (100); d. a second camera (260), said centering camera, whose optical axis is placed on the optical path (250); e. a target (303) adapted to be marked by a low power laser firing; f. an acquisition and processing unit (290) capable of collecting the images from the cameras (240, 260, 340) for shooting.
[2" id="c-fr-0002]
The system of claim 1, wherein the light source comprises a plurality of light emitting diodes (320) in an annular disposition in the illumination plane.
[3" id="c-fr-0003]
The system of claim 1 comprising: g. a third camera (340) whose optical axis is parallel to the lighting plane and perpendicular to that of the first (240) profile camera.
[4" id="c-fr-0004]
4. A method for setting up and measuring a material projection / melting device, in particular by the CLAD method, by means of a system according to claim 1, characterized in that it comprises the steps of: . positioning the projection nozzle (100) above the illumination plane in an orientation substantially normal to said plane; ii. placing the target (303) between the nozzle outlet and the lighting plane so that said target intercepts a laser shot; iii. perform a low energy laser shot; iv. illuminate the end of the nozzle by means of the light source; v. obtaining the image (493) through the end of the nozzle by the centering camera, the mark (393) left by the laser shot on the target, while the end of the nozzle is illuminated.
[5" id="c-fr-0005]
5. The method of claim 4, wherein the target is adhered to the end of the nozzle.
[6" id="c-fr-0006]
The method of claim 4 wherein the target (303) is maintained on the illumination plane.
[7" id="c-fr-0007]
The method of claim 4, comprising the steps of: vi. measuring the centering error between the contour of the image (420) of the illuminated space and the image (493) the mark (393) left by the laser on the target, on the image obtained in step v); vii. calculate the setting to correct the centering error.
[8" id="c-fr-0008]
The method of claim 4, comprising the steps of: viii. make a powder projection; ix. obtaining the image (560) of the powder projected by the camera (240, 340) in profile.
[9" id="c-fr-0009]
The method of claim 8, comprising the steps of: x. determining the shape (565) of the powder jet from a predetermined profile on the image obtained in step ix); xi. deduce from step x) the tool gauges corresponding to the jet.
[10" id="c-fr-0010]
The method of claim 8, comprising the steps of: xii. generate a laser beam during step viii) xiii. measuring on the image obtained in step ix) the orientation deviation of the image (560) of the powder jet relative to the image (593) of the laser; xiv. derive from the results of step xii) the adjustments to be made to correct the orientation error of the laser beam with respect to the powder jet.
[11" id="c-fr-0011]
11. The method of claim 10, implementing a system according to claim 3 and including the steps of: xv. obtaining an image (560) of the projected powder by means of the third camera (340); xvi. repeat steps xiii) and xiv) with the image obtained in step xv) in place of the image obtained in step ix).
[12" id="c-fr-0012]
The method of claim 11, comprising the steps of: xvii. repeat steps x) and xi) with the image obtained in step xv) instead of the image obtained in step ix).

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引用文献:

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

US5396333A|1992-05-21|1995-03-07|General Electric Company|Device and method for observing and analyzing a stream of material|

DE102005058172A1|2005-12-05|2007-06-06|Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.|Laser treatment unit comprises a head with a zoom optical unit and a nozzle head section|

DE102007032190A1|2007-07-11|2009-01-15|Daimler Ag|Method for treating the surface of a workpiece using heat comprises analyzing image signals in pixels and identifying an object based on shade gradients from which a geometric property can be determined|

US4564736A|1984-05-07|1986-01-14|General Electric Company|Industrial hand held laser tool and laser system|

US5593531A|1994-11-09|1997-01-14|Texas Instruments Incorporated|System, method and process for fabrication of 3-dimensional objects by a static electrostatic imaging and lamination device|

JP2003225787A|2002-01-30|2003-08-12|Amada Eng Center Co Ltd|Method and device for centering nozzle in laser beam machine|

EP1396556A1|2002-09-06|2004-03-10|ALSTOM Ltd|Method for controlling the microstructure of a laser metal formed hard layer|

US6940037B1|2003-08-25|2005-09-06|Southern Methodist University|System and method for controlling welding parameters in welding-based deposition processes|

CN201654406U|2010-03-25|2010-11-24|深圳大学|Novel multi-spark type hypervelocity digital imaging device|

CN101870039B|2010-06-12|2014-01-22|中国电子科技集团公司第四十五研究所|Double-workbench drive laser processing machine and processing method thereof|

JP5240301B2|2011-01-25|2013-07-17|三星ダイヤモンド工業株式会社|Workpiece placement fixing table and work piece placement fixing glass chuck|

CN102608126A|2012-02-23|2012-07-25|中冶连铸技术工程股份有限公司|On-line detection method and device for surface defects of high-temperature continuously cast bloom|

US10821508B2|2013-08-15|2020-11-03|General Electric Company|System and methods for enhancing the build parameters of a component|

US9724876B2|2013-12-13|2017-08-08|General Electric Company|Operational performance assessment of additive manufacturing|

DE102014202020B4|2014-02-05|2016-06-09|MTU Aero Engines AG|Method and device for determining residual stresses of a component|

JP6359316B2|2014-03-31|2018-07-18|三菱重工業株式会社|Three-dimensional laminating apparatus and three-dimensional laminating method|

US10112262B2|2014-10-28|2018-10-30|General Electric Company|System and methods for real-time enhancement of build parameters of a component|

US10048661B2|2014-12-17|2018-08-14|General Electric Company|Visualization of additive manufacturing process data|

WO2016131022A1|2015-02-12|2016-08-18|Glowforge Inc.|Cloud controlled laser fabrication|WO2019151911A1|2018-02-01|2019-08-08|Stjernberg Automation Ab|Method and device for controlling position of a tool|

DE102018202203A1|2018-02-13|2019-08-14|Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.|Arrangement for adjusting a powder flow in relation to the central longitudinal axis of an energy beam|

CN108422673A|2018-03-05|2018-08-21|郑州精图三维科技有限公司|A kind of 3D printing monitoring detecting system|

KR102078814B1|2019-07-29|2020-04-07|주식회사 에스에프에스|Hybrid 3D printer|

法律状态:
2016-12-29| PLFP| Fee payment|Year of fee payment: 2 |

2017-07-07| PLSC| Publication of the preliminary search report|Effective date: 20170707 |

2017-12-29| PLFP| Fee payment|Year of fee payment: 3 |

2019-12-30| PLFP| Fee payment|Year of fee payment: 5 |

2020-12-28| PLFP| Fee payment|Year of fee payment: 6 |

2021-12-30| PLFP| Fee payment|Year of fee payment: 7 |

优先权:

申请号 | 申请日 | 专利标题

FR1502754|2015-12-31|

FR1502754A|FR3046370B1|2015-12-31|2015-12-31|METHOD AND SYSTEM FOR ADJUSTING AN ADDITIVE MANUFACTURING DEVICE|FR1502754A| FR3046370B1|2015-12-31|2015-12-31|METHOD AND SYSTEM FOR ADJUSTING AN ADDITIVE MANUFACTURING DEVICE|

JP2018534779A| JP6861711B2|2015-12-31|2016-12-31|System and method for adjusting laminated modelingequipment|

US16/064,446| US10766200B2|2015-12-31|2016-12-31|Method and system for adjusting an additive manufacturing device|

CN201680082616.5A| CN108698061B|2015-12-31|2016-12-31|Method and system for adjusting an additive manufacturing device|

KR1020187022011A| KR20180099838A|2015-12-31|2016-12-31|Adjustment system of laminated working apparatus and adjustment method thereof|

EP16822488.9A| EP3397393B1|2015-12-31|2016-12-31|Method and system for adjusting an apparatus for additive manufacturing|

PCT/EP2016/082951| WO2017114965A1|2015-12-31|2016-12-31|Method and system for adjusting an additive manufacturing device|

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