WO2016084348A1 - Appareil de modelage en trois dimensions, procédé de modelage en trois dimensions et procédé de fabrication d'articles - Google Patents

Appareil de modelage en trois dimensions, procédé de modelage en trois dimensions et procédé de fabrication d'articles Download PDF

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Publication number
WO2016084348A1
WO2016084348A1 PCT/JP2015/005765 JP2015005765W WO2016084348A1 WO 2016084348 A1 WO2016084348 A1 WO 2016084348A1 JP 2015005765 W JP2015005765 W JP 2015005765W WO 2016084348 A1 WO2016084348 A1 WO 2016084348A1
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WO
WIPO (PCT)
Prior art keywords
layer
conveying member
dimensional modeling
roller
modeling apparatus
Prior art date
Application number
PCT/JP2015/005765
Other languages
English (en)
Inventor
Hirokazu Usami
Tatsuya Tada
Kenji Karashima
Takashi Kase
Satoru Yamanaka
Yuji Wakabayashi
Original Assignee
Canon Kabushiki Kaisha
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Priority claimed from JP2015203192A external-priority patent/JP2016107626A/ja
Application filed by Canon Kabushiki Kaisha filed Critical Canon Kabushiki Kaisha
Publication of WO2016084348A1 publication Critical patent/WO2016084348A1/fr

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    • GPHYSICS
    • G03PHOTOGRAPHY; CINEMATOGRAPHY; ANALOGOUS TECHNIQUES USING WAVES OTHER THAN OPTICAL WAVES; ELECTROGRAPHY; HOLOGRAPHY
    • G03GELECTROGRAPHY; ELECTROPHOTOGRAPHY; MAGNETOGRAPHY
    • G03G15/00Apparatus for electrographic processes using a charge pattern
    • G03G15/22Apparatus for electrographic processes using a charge pattern involving the combination of more than one step according to groups G03G13/02 - G03G13/20
    • G03G15/221Machines other than electrographic copiers, e.g. electrophotographic cameras, electrostatic typewriters
    • G03G15/224Machines for forming tactile or three dimensional images by electrographic means, e.g. braille, 3d printing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/10Processes of additive manufacturing
    • B29C64/141Processes of additive manufacturing using only solid materials
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B29WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
    • B29CSHAPING OR JOINING OF PLASTICS; SHAPING OF MATERIAL IN A PLASTIC STATE, NOT OTHERWISE PROVIDED FOR; AFTER-TREATMENT OF THE SHAPED PRODUCTS, e.g. REPAIRING
    • B29C64/00Additive manufacturing, i.e. manufacturing of three-dimensional [3D] objects by additive deposition, additive agglomeration or additive layering, e.g. by 3D printing, stereolithography or selective laser sintering
    • B29C64/10Processes of additive manufacturing
    • B29C64/141Processes of additive manufacturing using only solid materials
    • B29C64/147Processes of additive manufacturing using only solid materials using sheet material, e.g. laminated object manufacturing [LOM] or laminating sheet material precut to local cross sections of the 3D object
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y10/00Processes of additive manufacturing
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B33ADDITIVE MANUFACTURING TECHNOLOGY
    • B33YADDITIVE MANUFACTURING, i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION, ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING, e.g. BY 3-D PRINTING, STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING
    • B33Y30/00Apparatus for additive manufacturing; Details thereof or accessories therefor

Definitions

  • the present invention relates to a three-dimensional modeling apparatus, a three-dimensional modeling method, and an article manufacturing method.
  • the AM technique is a technique of modeling a three-dimensional object through the steps of slicing 3D shape data of a three-dimensional object to generate plural sets of slice shape data, forming each layer with a modeling material in accordance with each set of slide shape data, successively laminating layers of the modeling material, and fixating the laminated layers.
  • the AM technique has simplicity in not requiring molds or dies, and convenience in a capability of molding a complicated shape. Therefore, the AM technique is used in fabricating a trial product (prototype) to check whether the operation or the shape of a part is good or not, welfare equipment, such as a hearing aid, which is a single item or a small lot item, dental modeled objects for personal uses (such as parts for orthodontic therapy, artificial teeth, and crowns), finally modeled objects of airplane parts, etc.
  • the AM technique makes it possible to fabricate not only parts having complicated shapes, which cannot be fabricated using molds, but also parts being sophisticated in design, which take a lot of time and labor, the AM technique is further used in fabricating parts and modeled objects, which are difficult to fabricate by the related-art processing methods, and finally modeled products of clothing ornaments having high aesthetics, etc.
  • the AM technique is a method of additively laminating the material layer by layer, it is known that, from the viewpoint of productivity, the AM technique takes a longer time to fabricate one three-dimensional object than the prior art technique that produces objects having the same shape in a large amount.
  • a support portion for supporting a layer needs to be formed in addition to a modeling material portion at the same time in such a manner that an overlying layer will not come into a partly floating state.
  • the support portion has to be removed after the end of modeling steps.
  • a working time necessary to remove the support portion is also added to a total time to manufacture the finally modeled object.
  • productivity is further reduced in comparison with other types of AM techniques.
  • structural material implies a material of the finally modeled object.
  • a material of the support portion is called a support material, and the structural material and the support material are called together a modeling material.
  • Patent Literatures (PTL) 1 to 3 Three-dimensional modeling apparatuses of sheet lamination type are also proposed (Patent Literatures (PTL) 1 to 3).
  • a conveying member transfer belt
  • a stage are brought into an indirectly contacted state with a layer interposed between them. Thereafter, the layer is laminated on the stage by moving the conveying member and the stage away from each other.
  • the layer may be firmly stuck to the conveying member and the layer may be disordered in some cases. The disorder of the layer may lead to a possibility that accuracy or strength of a three-dimensional object is reduced.
  • the present invention provides a three-dimensional modeling apparatus that can suppress the layer from being disordered when the conveying member and the stage are moved away from each other.
  • PTLs 4 to 6 disclose three-dimensional modeling apparatuses in which the layer is separated from the conveying member with the aid of the curvature of the conveying member.
  • a three-dimensional modeling apparatus used to model a three-dimensional object, the apparatus including a layer forming unit configured to form a layer on a conveying member, and a laminating unit configured to laminate, at a lamination position, the layer having been conveyed to the lamination position by the conveying member, wherein the laminating unit includes a changing device configured to change an inclination or a shape of a surface of the conveying member at the lamination position.
  • Fig. 1 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a first embodiment.
  • Fig. 2 is a schematic view of a layer forming unit.
  • Fig. 3A illustrates a configuration of a particle image forming section.
  • Fig. 3B illustrates a configuration of a developing apparatus.
  • Fig. 4A is an illustration referenced to explain the reason why particle layers are to be formed such that the particle images will not overlap with each other.
  • Fig. 4B is an illustration referenced to explain the reason why particle layers are to be formed such that the particle images will not overlap with each other.
  • Fig. 5 is a flowchart representing an operation sequence of the three-dimensional modeling apparatus according to the first embodiment.
  • Fig. 5 is a flowchart representing an operation sequence of the three-dimensional modeling apparatus according to the first embodiment.
  • FIG. 6 is an enlarged perspective view of the surroundings of a lamination position in the three-dimensional modeling apparatus according to the first embodiment.
  • Fig. 7 is an enlarged perspective view of the surroundings of a lamination position in a three-dimensional modeling apparatus according to a second embodiment.
  • Fig. 8 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a third embodiment.
  • Fig. 9 is an enlarged perspective view of the surroundings of a lamination position in the three-dimensional modeling apparatus according to the third embodiment.
  • Fig. 10 is an enlarged perspective view of the surroundings of a lamination position in a three-dimensional modeling apparatus according to a fourth embodiment.
  • Fig. 11 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a fifth embodiment.
  • Fig. 11 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a fifth embodiment.
  • Fig. 12 is an enlarged perspective view of the surroundings of a sheet forming position in the three-dimensional modeling apparatus according to the fifth embodiment.
  • Fig. 13 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a sixth embodiment.
  • Fig. 14 is an enlarged perspective view of the surroundings of a lamination position in the three-dimensional modeling apparatus according to the sixth embodiment.
  • FIG. 1 is a schematic diagram illustrating the overall configuration of a three-dimensional modeling apparatus according to a first embodiment.
  • the three-dimensional modeling apparatus of this embodiment is constituted as an AM (Additive Manufacturing) system of the type of modeling a three-dimensional object by laminating (additive-forming) layers in each of which a particulate material is two-dimensionally arrayed.
  • the three-dimensional modeling apparatus is also called, e.g., a 3D printer, an RP (Rapid Prototyping) system.
  • the three-dimensional modeling apparatus mainly includes a control unit U1, a layer forming unit (also called an image forming unit) U2, and a laminating unit U3.
  • the control unit U1 is configured to execute, e.g., not only a process of generating slice data (section data) of plural layers from 3D shape data of a modeling object, but also control of individual sections of the three-dimensional modeling apparatus.
  • the layer forming unit U2 is configured to form a particle layer made of a particulate material by utilizing an electrophotographic process.
  • the laminating unit U3 is configured to model a three-dimensional object by successively laminating the plurality of particle layers each of which has been formed in the layer forming unit U2, and by fixating the laminated particle layers.
  • the above-mentioned units U1 to U3 may have different housings, or they may be disposed in a single housing.
  • the configuration of the units U1 to U3 being separately disposed in different housings is advantageous in that the units can be easily combined or replaced depending on, for example, the use of the three-dimensional modeling apparatus, the performance demanded, materials to be used, an installation space, and the occurrence of a failure, and that a degree of freedom and convenience in configuration of the apparatus are increased.
  • the configuration of all the units being disposed in a single housing is advantageous in reducing the size of the entire apparatus and realizing reduction of the cost.
  • the unit configuration of Fig. 1 is merely illustrative, and other configurations may be optionally adopted.
  • control unit U1 includes, e.g., a 3D shape data input section U10, a slice data calculation section U11, a layer forming unit control section U12, and a laminating unit control section U13 in terms of functions.
  • the 3D shape data input section U10 has the function of receiving 3D shape data of the modeling object from an external device (e.g., a personal computer).
  • the 3D shape data can be given as data that is generated and output by 3D CAD, a 3D modeler, or a 3D scanner, for example.
  • the file format of the 3D shape data is freely selected, but, for example, the STL (StereoLithography) file format can be preferably used.
  • the slice data calculation section U11 has the function of slicing the modeling object, which is expressed by the 3D shape data, at a predetermined pitch, calculating a section shape of each layer, and generating image data (also called slice data) that is used in the layer forming unit U2 to form an image on the basis of the calculated section shape.
  • the slice data calculation section U11 further has the function of analyzing the 3D shape data or the slice data of upper and lower layers, determining whether an overhang portion (or a floating portion) is present, and adding an image for a support material to the slice data if required.
  • the layer forming unit U2 in this embodiment is able to perform image formation using plural types of materials.
  • the slice data is generated as data corresponding to an image to be formed of each material.
  • positions and shapes of images expressed by different sets of slice data are preferably adjusted such that the images to be formed of different materials will not overlap with each other. The reason is that, if the images are overlapped with each other, a variation would occur in thickness of the particle layer, and dimensional accuracy of the modeled three-dimensional object would degrade.
  • the file format of the slice data may be, for example, a multi-value image data (each value representing the type of material) or multi-plane image data (each plane representing the type of material).
  • the layer forming unit control section U12 has the function of controlling a layer forming process in the layer forming unit U2 in accordance with the slice data generated in the slice data calculation section U11.
  • the laminating unit control section U13 further has the function of controlling a lamination process in the laminating unit U13. Details of practical control in the individual units are described later.
  • control unit U1 further includes an operating section, a display section, and a storage section.
  • the operating section has the function of receiving an instruction from a user. For example, instructions regarding power on/off and various settings and operations in the apparatus can be entered through the operating section.
  • the display section has the function of presenting information to the user. For example, various setting screens, error messages, operation statuses, etc. can be presented through the display section.
  • the storage section has the function of storing the 3D shape data, the slice data, various setting values, etc.
  • the control unit U1 can be constituted, in terms of hardware, by a computer including a CPU (central processing unit), a memory, auxiliary storages (e.g., a hard disk and a flash memory), an input device, a display device, and various I/F's.
  • the above-described functions U10 to U13 are realized by the CPU that reads programs stored in, e.g., the auxiliary storages, executes the programs, and controls the associated devices as required. It is to be noted that a part or the whole of the above-described functions may be constituted by one or more circuits, such as ASIC and FPGA, or may be executed by another computer with the use of cloud computing, grid computing, or other adapted techniques.
  • the layer forming unit U2 is configured to form the particle layer made of the particulate material by utilizing an electrophotographic process.
  • electrophotographic process implies a series of processes of uniformly charging a photosensitive member (image bearing member), exposing the charged photosensitive member (image bearing member) in accordance with image information, and forming an electrostatic latent image corresponding to the image information on the photosensitive member.
  • the electrophotographic process further includes a continued series of processes of attaching developer particles to the electrostatic latent image, and forming a developer image on the photosensitive member, thereby forming a desired image on the photosensitive member.
  • the principle of the electrophotographic process is in common to that used in a 2D printer, such as a copying machine.
  • a particulate material modeling material
  • process control and component structures in the 2D printer cannot be used as they are in some cases.
  • the particle diameter of the modeling material can be optionally selected.
  • the layer forming unit U2 includes a first particle image forming section 10a, a second particle image forming section 10b, an intermediate bearing and conveying belt 11, a belt cleaning apparatus 12, and an image sensor 13.
  • the first particle image forming section 10a is configured to form a particle image by employing a first particulate material (modeling material) Ma.
  • the first particle image forming section 10a includes an image bearing member (photosensitive member) 100a, a charging apparatus 101a that charges the image bearing member 100a, an exposure apparatus 102a that exposes the image bearing member 100a, and a developing apparatus 103a that develops an electrostatic latent image with the particulate material Ma and forms a particle image.
  • the first particle image forming section 10a further includes a transfer apparatus 104a that transfers the particle image onto the intermediate bearing and conveying belt 11, and a cleaning apparatus 105a that cleans the image bearing member 100a.
  • the second particle image forming section 10b is configured to form a particle image by employing a second particulate material Mb.
  • the second particle image forming section 10b includes an image bearing member 100b, a charging apparatus 101b, an exposure apparatus 102b, a developing apparatus 103b, a transfer apparatus 104b, and a cleaning apparatus 105b, which execute respectively similar functions to those of the above-described corresponding components in the first particle image forming section 10a.
  • a structural material made of, e.g., a thermoplastic resin is used as the first particulate material Ma, and a support material (modeling material) having thermal plasticity and water solubility is used as the second particulate material Mb.
  • a section does not include the overhang portion and hence does not require the support portion, an image is not formed in the second particle image forming section 10b.
  • the particle layer is formed using only the particle image of the structural material.
  • the structural material may be, for example, PE (polyethylene), PP (polypropylene), ABS, and PS (polystyrene).
  • the support material may be, for example, carbohydrate, polylactate (PLA), PVA (polyvinyl alcohol), and PEG (polyethylene glycol).
  • Particles of the structural material and the support material preferably have diameters of 5 ⁇ m or more and 50 ⁇ m or less. In this embodiment, particles having diameters of about 20 ⁇ m are used.
  • the particle image forming sections 10a and 10b are arranged along the surface of the intermediate bearing and conveying belt 11. While, in Fig. 1, the particle image forming section 10a for the structural material is arranged on the upstream side in a conveying direction, the order in arrangement of the particle image forming sections can be optionally determined. The number of the particle image forming sections may be more than two and can be increased, as required, depending on the types of modeling materials used. As another example, Fig. 2 illustrates the case where four particle image forming sections 10a to 10d are arranged. In that case, it is possible to adopt a configuration of performing image formation with four types of structural materials, or a configuration of performing image formation with three types of structural materials and one type of support material. The variety of three-dimensional objects to be formed can be increased by combining plural types of materials that are different in material properties, color, hardness, physical properties, etc. Such superiority in extensibility is also one advantage of the three-dimensional modeling apparatus utilizing the electrophotographic process.
  • Fig. 3A illustrates a configuration of the particle image forming section 10
  • Fig. 3B illustrates a detailed configuration of the developing apparatus 103.
  • the image bearing member 100 is configured to bear the electrostatic latent image.
  • a photosensitive drum including a photoconductor layer having a photoconductivity and formed on an outer circumferential surface of a metal cylinder made of aluminum, for example, is used as the image bearing member 100.
  • the photoconductor layer may be made of an organic photoconductor (OPC), an amorphous silicon photoconductor, or a selenium photoconductor.
  • OPC organic photoconductor
  • the type of photoconductor may be optionally selected depending on the use of the three-dimensional modeling apparatus and the performance demanded.
  • the image bearing member 100 is rotatably supported by a frame body (not illustrated) and is rotated clockwise in the drawing by a motor (not illustrated) at a constant speed during the image formation.
  • the charging apparatus 101 is configured to uniformly charge the surface of the image bearing member 100. While a non-contact charging technique utilizing corona discharge is employed in this embodiment, another type of charging, such as a roller charging technique of contacting a charged roller with the surface of the image bearing member 100, may also be used.
  • the exposure apparatus 102 is configured to expose the image bearing member 100 in accordance with image information (slice data) and to form the electrostatic latent image on the surface of the image bearing member 100.
  • the exposure apparatus 102 includes, for example, a light source such as a semiconductor laser or a light-emitting diode, a scanning unit including a polygon mirror that is rotated at a high speed, and an optical member such as a focusing lens.
  • the developing apparatus 103 is configured to supply a developer (in the form of particles of the structural material or the support material herein) to the image bearing member 100, thereby visualizing the electrostatic latent image (in this Description, an image visualized with the developer is called a particle image).
  • Fig. 3B illustrates a detailed configuration of the developing apparatus 103.
  • the developing apparatus 103 includes a container 1030 that contains the developer, a supply roller 1031 disposed inside the container 1030, a developing roller 1032 that bears the developer and supplies the developer to the image bearing member 100, and a restricting member 1033 that restricts a thickness of the developer.
  • the supply roller 1031 and the developing roller 1032 are rotatably supported by the container 1030 and are each rotated counterclockwise in the drawing by a motor (not illustrated) at a constant speed during the image formation.
  • the developer particles agitated and charged by the supply roller 1031 are supplied to the developing roller 1032, and a layer thickness of the developer particles is restricted by the restricting member 1033 to a value substantially corresponding to one particle.
  • the electrostatic latent image is developed in a zone where the developing roller 1032 and the image bearing member 100 are opposed to each other.
  • developing techniques there are a reversal developing technique of attaching the developer to a region where charges have been removed by exposure, and a normal developing technique of attaching the developer to a region that has not been exposed. One of those techniques may be optionally used.
  • the developing apparatus 103 has a structure of the so-called developing cartridge and is removably mounted to the layer forming unit U2.
  • the reason is that replenishment and change of the developer (including the structural material and the support material) can be easily made through replacement of a cartridge.
  • the image bearing member 100, the developing apparatus 103, the cleaning apparatus 105, and so on may be constituted into an integral cartridge (so-called process cartridge) such that the image bearing member 100 may be replaced in itself.
  • process cartridge integral cartridge
  • the transfer apparatus 104 is configured to transfer the particle image, which has been formed on the circumferential surface of the image bearing member 100, onto the surface of the intermediate bearing and conveying belt 11.
  • the transfer apparatus 104 is arranged on the side opposite to the image bearing member 100 with the intermediate bearing and conveying belt 11 interposed between them.
  • the particle image is electrostatically transferred to the intermediate bearing and conveying belt 11 by applying a voltage having a polarity reversed to that of the particle image on the image bearing member 100.
  • the transfer from the image bearing member 100 to the intermediate bearing and conveying belt 11 is also called primary transfer. While a transfer technique utilizing corona discharge is used in this embodiment, a different transfer technique other than the electrostatic transfer technique, such as a roller transfer technique, may also be used.
  • the cleaning apparatus 105 is configured to recover the developer particles that remain on the image bearing member 100 without being transferred, and to clean the surface of the image bearing member 100.
  • the cleaning apparatus 105 used in this embodiment is of the blade type scraping off the developer particles by a cleaning blade that is held in contact with the image bearing member 100 from a counter direction.
  • a cleaning apparatus of the brush type or the electrostatic absorption type may also be used.
  • the intermediate bearing and conveying belt (first intermediate bearing and conveying belt) 11 is a conveying member (intermediate conveying member) to which the particle image having been formed by each particle image forming section 10 is transferred.
  • the particle image of the structural material is transferred from the particle image forming section 10a on the upstream side, and thereafter the particle image of the support material is transferred from the particle image forming section 10b on the downstream side in alignment with the particle image of the structural material.
  • one particle layer is formed on the surface of the intermediate bearing and conveying belt 11.
  • Fig. 4A if the particle images are overlapped with each other on the intermediate bearing and conveying belt 11, a variation would occur in thickness of the particle layer.
  • the variation in thickness of the particle layer is suppressed, as illustrated in Fig. 4B, by adjusting positions and sizes of respective particle images of individual materials (the adjustment being made when the slice data for each material is generated) such that the particle images will not overlap with each other.
  • the three-dimensional modeling apparatus cannot be practiced by directly employing an electrophotographic method of expressing a full-color image with a subtractive mixture technique of superimposing toner images in four colors of C, M, Y and K, which is used in many full-color 2D printers.
  • the intermediate bearing and conveying belt 11 is an endless belt made of resin or polyimide. As illustrated in Fig. 1, the intermediate bearing and conveying belt 11 is arranged to extend over a plurality of rollers 110 and 111. A tension roller may be disposed in addition to the rollers 110 and 111 for adjustment of tension of the intermediate bearing and conveying belt 11. At least one of the rollers 110 and 111 is a driving roller that rotates the intermediate bearing and conveying belt 11 counterclockwise in the drawing with a driving force from a motor (not illustrated) during the image formation.
  • the roller 110 serves also as a roller constituting a secondary transfer section in cooperation with a secondary transfer roller 31 in the laminating unit U3.
  • the belt cleaning apparatus 12 is configured to clean the material adhering to the surface of the intermediate bearing and conveying belt 11.
  • the belt cleaning apparatus 12 used in this embodiment is of the blade type scraping off the material by a cleaning blade that is held in contact with the intermediate bearing and conveying belt 11 from a counter direction.
  • a cleaning apparatus of the brush type or the electrostatic absorption type may also be used.
  • the image sensor 13 is configured to read the particle layer borne on the surface of the intermediate bearing and conveying belt 11.
  • a detection result of the image sensor 13 is utilized in, e.g., alignment of the particle layer, timing control with respect to the laminating unit U3 in a subsequent stage, and detection of abnormality of the particle layer (detection of an abnormal state that the desired image is not formed, that there is no image, that the variation in thickness is large, or that a deviation of an image position is large).
  • the laminating unit U3 will be described below.
  • the laminating unit U3 is configured to form a three-dimensional object by receiving the particle layers, which have been formed in the layer forming unit U2, from the intermediate bearing and conveying belt 11, successively laminating the received particle layers, and fixating the laminated particle layers.
  • the laminating unit U3 includes a second intermediate bearing and conveying belt 30, a secondary transfer roller 31, an image sensor 32, a heater 33, and a stage 34. Detailed configurations of the individual components of the laminating unit U3 will be described below.
  • the second intermediate bearing and conveying belt 30 is a second conveying member that receives each of the particle layers, which have been formed in the layer forming unit U2, from the first intermediate bearing and conveying belt 11, and that bears and conveys the received particle layer to a lamination position.
  • the lamination position is a position at which the particle layers are laminated (namely, they are successively overlaid onto the three-dimensional object under additive manufacturing). In the configuration of Fig. 1, the lamination position corresponds to a region where the second intermediate bearing and conveying belt 30 is sandwiched between the heater 33 and the stage 34.
  • the second intermediate bearing and conveying belt 30 is an endless belt made of resin or polyimide. As illustrated in Fig. 1, the second intermediate bearing and conveying belt 30 is arranged to extend over the secondary transfer roller 31 and a plurality of rollers 301, 302, 303 and 304. At least one of the rollers 31, 301 and 302 is a driving roller that rotates the second intermediate bearing and conveying belt 30 clockwise in the drawing with a driving force from a motor (not illustrated).
  • the rollers 303 and 304 are a roller pair that serves to adjust tension of the second intermediate bearing and conveying belt 30, and to keep flat the second intermediate bearing and conveying belt 30 passing the lamination position (i.e., the particle layer while it is being laminated).
  • the secondary transfer roller 31 is configured to transfer the particle layer from the first intermediate bearing and conveying belt 11 in the layer forming unit U2 to the second intermediate bearing and conveying belt 30 in the laminating unit U3.
  • the secondary transfer roller 31 sandwiches the first intermediate bearing and conveying belt 11 and the second intermediate bearing and conveying belt 30 between itself and the opposing roller 110 in the layer forming unit U2, thereby forming a secondary transfer nip between both the belts.
  • the particle layer is transferred to the second intermediate bearing and conveying belt 30 by applying a bias, which has a polarity reversed to that of the particle layer, to the secondary transfer roller 31 from a power supply (not illustrated).
  • the image sensor 32 is configured to read the particle layer borne on the surface of the second intermediate bearing and conveying belt 30. A detection result of the image sensor 32 is utilized in, e.g., alignment of the particle layer and timing control in conveyance to the lamination position.
  • the heater 33 is a temperature control unit that controls a temperature of the particle layer conveyed to the lamination position.
  • a ceramic heater or a halogen heater can be used as the heater 33.
  • a unit of positively lowering the temperature of the particle layer through heat dissipation or cooling may be further disposed in addition to a heating unit.
  • a lower surface (i.e., a surface facing the belt) of the heater 33 is flat and serves as not only a guide for the second intermediate bearing and conveying belt 30 passing the lamination position, but also a pressing member that applies uniform pressure to the particle layer.
  • the stage 34 is a flat bench on which the three-dimensional object is formed by the additive manufacturing.
  • the stage 34 is movable by an actuator (not illustrated) in a vertical direction (i.e., a direction perpendicular to a belt surface in the lamination position).
  • the particle layer borne on and conveyed by the second intermediate bearing and conveying belt 30 to the lamination position is sandwiched between the stage 34 and the heater 33.
  • the stage 34 applies heat and pressure (including heat dissipation or cooling as required) to the particle layer, whereby the particle layer is transferred from the second intermediate bearing and conveying belt 30 to the stage 34.
  • the particle layer for the first layer is transferred directly onto the stage 34, and the particle layers for the second and subsequent layers are successively laminated on the three-dimensional object (under the additive manufacturing) on the stage 34.
  • the heater 33 and the stage 34 constitute a laminating apparatus that laminates the particle layers.
  • Driving devices 313 and 314 are actuators and move a roller 303 (first roller) and a roller 304 (second roller), respectively, from a state where the rollers 303 and 304 cooperatively form the surface of the second intermediate bearing and conveying belt 30 as a flat surface that is parallel to the surface of the stage 34. More specifically, as illustrated in Fig. 6, the driving device 313 changes an inclination of a rotation axis of the roller 303 to incline (as denoted by a dotted line), relative to the surface of the stage 34, the rotation axis of the roller 303 that has been set parallel (as denoted by a one-dot-chain line) to the surface of the stage 34.
  • the driving device 314 changes an inclination of a rotation axis of the roller 304 to incline (as denoted by a dotted line), relative to the surface of the stage 34, the rotation axis of the roller 304 that has been set parallel (as denoted by a one-dot-chain line) to the surface of the stage 34.
  • Fig. 6 is an enlarged perspective view of the surroundings of the lamination position in the three-dimensional modeling apparatus.
  • the rollers 303 and 304 are each positioned (as denoted by the one-dot-chain line) perpendicularly to an advancing direction of the second intermediate bearing and conveying belt 30.
  • the rollers 303 and 304 are each inclined (as denoted by the dotted line) from an ordinary set position (denoted by the one-dot-chain line).
  • the rollers 303 and 304 are each returned to the ordinary set position (denoted by the one-dot-chain line).
  • the driving devices 313 and 314 constitute a unit that changes the shape or the inclination of the surface of the second intermediate bearing and conveying belt 30 at the lamination position.
  • the lamination position is defined as a position at which the conveying member and the stage are in an indirectly contacted state with the particle layer (or the three-dimensional object) interposed between them.
  • the lamination position corresponds to a region of the second intermediate bearing and conveying belt 30 between the rollers 303 and 304 (specifically, in that region, the second intermediate bearing and conveying belt 30 is not contacted with the rollers 303 and 304).
  • the plural rollers are moved in this embodiment, only one roller (i.e., the roller 303 or 304) may be moved. While the plural rollers are inclined in different directions in this embodiment, the plural rollers may be inclined in the same direction. However, a deviation of the second intermediate bearing and conveying belt 30 can be reduced with a simple configuration in the case of inclining the rollers 303 and 304 in reversed directions as in this embodiment. When the rollers 303 and 304 are inclined in the same direction through the same angle, the inclination of the surface of the second intermediate bearing and conveying belt 30 is changed. Such a configuration may also be adopted.
  • rollers 303 and 304 are each inclined in a plane perpendicular to the advancing direction of the second intermediate bearing and conveying belt 30, the present invention is not limited to that configuration.
  • the roller 303 may be inclined in a plane including the second intermediate bearing and conveying belt 30 similarly to the configuration of a fourth embodiment described later.
  • Fig. 5 is a flowchart representing an operation sequence of the three-dimensional modeling apparatus according to this embodiment.
  • control unit U1 controls driving sources, e.g., motors, such that the image bearing member 100, the first intermediate bearing and conveying belts 11, and the second intermediate bearing and conveying belts 30 of the individual particle image forming sections 10 are rotated at the same peripheral speed (process speed) in synchronism.
  • driving sources e.g., motors
  • the image formation in the particle image forming section 10a at the most upstream side is started (S501). More specifically, the control unit U1 controls the charging apparatus 101a to uniformly charge the entire surface of the image bearing member 100a in a predetermined polarity and at a predetermined charging potential. Then, the control unit U1 controls the exposure apparatus 102a to expose the surface of the charged image bearing member 100a in accordance with information that represents an image to be formed. Here, a potential difference between an exposed region and a not-exposed region is formed by removing charges through the exposure. An image corresponding to the potential difference is an electrostatic latent image.
  • control unit U1 drives the developing apparatus 103a to form a particle image of the structural material by attaching particles of the structural material to the latent image on the image bearing member 100a.
  • the formed particle image is primary-transferred onto the intermediate bearing and conveying belt 11 by the transfer apparatus 104a.
  • the control unit U1 starts the image formation in the particle image forming section 10b on the downstream side (S502).
  • the image formation in the particle image forming section 10b is performed through similar procedures to those in the image formation in the particle image forming section 10a.
  • the time lag in the start of the image formation is set to a value resulting from dividing the distance from a primary transfer nip in the particle image forming section 10a on the upstream side to a primary transfer nip in the particle image forming section 10b on the downstream side by the process speed.
  • the second intermediate bearing and conveying belt 30 in the laminating unit U3 is rotated in a state contacting the first intermediate bearing and conveying belt 11 at the same outer circumferential speed (process speed) as that of the first intermediate bearing and conveying belt 11 in a synchronous relation.
  • the control unit U1 applies a predetermined transfer bias to the secondary transfer roller 31, whereby the particle layer is transferred to the second intermediate bearing and conveying belt 30 (S506).
  • the second intermediate bearing and conveying belt 30 continues to rotate at the same process speed and conveys the particle layer in a direction denoted by an arrow in Fig. 1.
  • the image sensor 32 detects a position of the particle layer on the belt 30, and the control unit U1 conveys the particle layer to a predetermined lamination position in accordance with the detection result (S508).
  • the control unit U1 stops the second intermediate bearing and conveying belt 30 and exactly positions the particle layer to the lamination position (S509).
  • control unit U1 ascends the stage 34 (to come closer to the belt surface) to such an extent that a stage surface (in the case forming a first layer) or an upper surface of a three-dimensional object formed on the stage surface (in the case forming a second or subsequent layer) is brought into contact with the particle layer on the belt 30 (S510).
  • the control unit U1 controls a temperature of the heater 33 in accordance with a predetermined temperature control sequence. More specifically, the control unit U1 first executes a first mode of heating the heater 33 up to a first target temperature for a predetermined time, thereby thermally melting the particle material of the particle layer (S511). With the first mode, the particle layer is softened and the particle layer in the form of a sheet is closely contacted with the stage surface or the upper surface of the three-dimensional object. Then, the control unit U1 executes a second mode of controlling the heater 33 to a second target temperature lower than the first target temperature for a predetermined time, thereby solidifying the softened particle layer (S512).
  • the temperature control sequence, the target temperatures, the heating times, and so on are set depending on respective characteristics of the structural material and the support material, which are used in forming the particle layer.
  • the first target temperature in the first mode is set to a value higher than the highest temperature between the meting points or the glass transition points of the materials, which are used in forming the particle layer.
  • the second target temperature in the second mode is set to a value lower than the lowest temperature between the crystallization temperatures or the glass transition points (in the case of amorphous materials) of the materials, which are used in forming the particle layer.
  • the temperature control As described above, it is possible to thermally plasticize (soften) the entire particle layer, which contains plural types of particle materials having thermal fusion characteristics different from each other, in a common fusion temperature range, and then to solidify the entire material layer in a common solidification temperature range. Accordingly, the fusion and the solidification of the particle layer containing plural types of particle materials can be performed in a stable manner.
  • a control range of the first target temperature is preferably set such that the highest temperature between the meting points or the glass transition points of the materials, which are used in forming the particle layer, is set as a lower limit temperature, and that an upper limit temperature is set to a value of the lower limit value + about 50°C.
  • a control range of the second target temperature is preferably set such that the lowest temperature between the crystallization temperatures or the glass transition points (in the case of amorphous materials) of the materials, which are used in forming the particle layer, is set as an upper limit temperature, and that a lower limit temperature is set to a value of the upper limit value - about 50°C.
  • the control ranges are preferably set as follows.
  • the control range of the first target temperature is set with the lower limit being 156°C or higher and the upper limit being 206°C or lower
  • the control range of the second target temperature is set with the lower limit being 80°C or higher and the upper limit being 130°C or lower.
  • the control unit U1 descends the stage 34 (S513). Then, the control unit U1 drives the rollers 303 and 304 through the respective driving devices to deform the surface of the second intermediate bearing and conveying belt 30 (S514).
  • the surface shape of the stage 34 and the surface shape of the second intermediate bearing and conveying belt 30 can be made different from each other such that the particle layer is easier to peel off from the surface of the second intermediate bearing and conveying belt 30. Hence damage of the particle layer can be suppressed. While, in the flowchart of Fig.
  • the surface of the second intermediate bearing and conveying belt 30 is started to deform after starting the descent of the stage 34, the deformation of the belt surface and the descent of the stage 34 may be started at the same time by controlling the stage and the driving devices in synchronism with each other. Alternatively, the surface of the second intermediate bearing and conveying belt 30 may be started to deform before starting the descent of the stage 34.
  • control unit U1 drives the rollers 303 and 304 through the respective driving devices to return the surface shape of the second intermediate bearing and conveying belt 30 to the original flat state (S515).
  • a desired three-dimensional object is formed on the stage 34 by repeating the above-described layer forming process and lamination process in the required number of times.
  • a finally modeled object (article) can be obtained by, in the last step, removing the three-dimensional object from the stage 34 and removing the support material, which is water soluble, with hot water, for example.
  • the finally modeled object (article) may be finished by further executing additional predetermined processes (such as cleaning and assembly) on the three-dimensional object.
  • the apparatus executes an operation of making the surface shape of the stage different from the surface shape of the conveying member (or making the surface of the stage nonparallel to the surface of the conveying member).
  • the particle layer (three-dimensional object) is easier to peel off from the surface of the conveying member, and damage of the particle layer (three-dimensional object) can be suppressed.
  • Fig. 7 is an enlarged perspective view of the surroundings of a lamination position in a three-dimensional modeling apparatus according to a second embodiment of the present invention.
  • the particle layer is laminated on the stage 34 by vertically moving the stage 34 in a state where the second intermediate bearing and conveying belt 30 is stopped.
  • the particle layer is laminated on a stage 340 in a state where the second intermediate bearing and conveying belt 30 and the stage 340 are moved in synchronism with each other. Only the features specific to the second embodiment will be described below while description of components in common to those in the first embodiment is omitted.
  • the stage 340 is held in contact with the second intermediate bearing and conveying belt 30 in a state where the stage 340 is moved in the same direction and at the same speed as those of the second intermediate bearing and conveying belt 30.
  • the stage 340 is movable by an actuator (not illustrated) not only in a vertical direction (i.e., a direction perpendicular to a belt surface at the lamination position), but also in a horizontal direction (i.e., a direction parallel to the belt surface at the lamination position).
  • the stage 340 is moved in an up-and-down direction and a right-and-left direction as denoted by a dotted line in Fig. 7.
  • the above-described second embodiment can also provide similar advantageous effects to those in the first embodiment.
  • the throughput of the three-dimensional modeling apparatus can be increased.
  • the particle layer is laminated on the stage 340 in a state where the second intermediate bearing and conveying belt 30 is moved, a zigzag motion of the second intermediate bearing and conveying belt 30 can be suppressed by inclining the rollers 303 and 304 through the same angle in opposite directions.
  • Fig. 8 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a third embodiment of the present invention.
  • Fig. 9 is an enlarged perspective view of the surroundings of a lamination position in the three-dimensional modeling apparatus according to the third embodiment.
  • the rollers are inclined to change the shape or the inclination of the surface of the second intermediate bearing and conveying belt 30.
  • one of the rollers is translated (namely, moved parallel). Only the features specific to the third embodiment will be described below while description of components in common to those in the first embodiment is omitted.
  • a laminating unit in this embodiment includes a pair of rollers 3030 and 3040.
  • the pair of rollers 3030 and 3040 act to keep flat the surface of the second intermediate bearing and conveying belt 30 at the lamination position.
  • the roller 3040 is constituted to be movable in a direction perpendicular to a rotation axis of the roller 3040.
  • the laminating unit in this embodiment further includes a driving device 3140.
  • the driving device 3140 is an actuator, and it moves the roller 3040 in the direction perpendicular to the rotation axis of the roller 3040 in accordance with an instruction from the laminating unit control section U13.
  • the driving device 3140 constitutes a unit that changes the inclination of the surface of the second intermediate bearing and conveying belt 30 at the lamination position.
  • the rollers 3030 and 3040 are each held at an ordinary set position (denoted by a one-dot-chain line in Fig. 9) where the surface of the second intermediate bearing and conveying belt 30 at the lamination position is parallel to the surface of the stage 34.
  • the roller 3040 is translated from the ordinary set position (as denoted by a dotted line in Fig. 9) such that the surface of the second intermediate bearing and conveying belt 30 at the lamination position and the surface of the stage 34 are nonparallel to each other.
  • the roller 3040 is returned to the ordinary set position (denoted by the one-dot-chain line in Fig. 9).
  • the roller 3040 is preferably moved in synchronism with the descent of the stage 34.
  • the surface of the second intermediate bearing and conveying belt 30 at the lamination position and the surface of the stage 34 may be made nonparallel to each other by moving a plurality of rollers (e.g., the rollers 3030 and 3040).
  • the apparatus executes an operation of making the surface of the stage nonparallel to the surface of the conveying member.
  • the particle layer (three-dimensional object) is easier to peel off from the surface of the conveying member, and damage of the particle layer (three-dimensional object) can be suppressed.
  • Fig. 10 is an enlarged perspective view of the surroundings of a lamination position in a three-dimensional modeling apparatus according to a fourth embodiment of the present invention.
  • the rollers are driven by the driving devices.
  • the rollers are fixedly positioned without being driven (although the rollers are allowed to rotate about their own axes corresponding to the movement of the second intermediate bearing and conveying belt 30). Only the features specific to the fourth embodiment will be described below while description of components in common to those in the second embodiment is omitted.
  • a laminating unit in this embodiment includes rollers 3031, 3032, 3010, and 3041.
  • the rollers 3032 and 3041 act to keep flat the surface of the second intermediate bearing and conveying belt 30 at the lamination position.
  • the roller 3041 (first roller) positioned upstream of the lamination position is arranged such that a rotation axis of the roller 3041 is parallel to the surface of the second intermediate bearing and conveying belt 30 and further parallel to a direction (denoted by a one-dot-chain line) perpendicular the advancing direction of the belt 30.
  • the roller 3032 (second roller) positioned downstream of the lamination position is arranged such that a rotation axis of the roller 3032 is parallel to the surface of the second intermediate bearing and conveying belt 30, but not parallel to the direction (denoted by the one-dot-chain line) perpendicular the advancing direction of the belt 30.
  • the rotation axis of the roller 3032 is inclined relative to the rotation axis of the roller 3041.
  • the roller 3031 (third roller) positioned downstream of the roller 3032 and the roller 3010 (fourth roller) positioned downstream of the roller 3031 are arranged such that respective rotation axes of the rollers 3031 and 3010 are parallel to the rotation axis of the roller 3032 (as denoted by dotted lines).
  • the roller 3032 Since the roller 3032 is located at the end (exit) of a region defining the lamination position and the rotation axis of the roller 3032 is not perpendicular to the advancing direction of the second intermediate bearing and conveying belt 30, the particle layer starts to peel off at its portion (one corner when the particle layer is rectangular) from the second intermediate bearing and conveying belt 30 with the advance of the belt 30. Therefore, the particle layer is easier to peel off from the surface of the second intermediate bearing and conveying belt 30, and damage of the particle layer (three-dimensional object) can be suppressed.
  • the rollers positioned downstream of the lamination position are inclined relative to the direction perpendicular to the advancing direction of the conveying member.
  • the region defining the lamination position has the exit that is inclined relative to a leading side of the particle layer.
  • the particle layer (three-dimensional object) is easier to peel off from the surface of the conveying member, and damage of the particle layer (three-dimensional object) can be suppressed.
  • the three-dimensional modeling apparatus can be provided in which control is facilitated.
  • Fig. 11 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a fifth embodiment of the present invention.
  • Fig. 12 is an enlarged perspective view of the surroundings of a sheet forming position in the three-dimensional modeling apparatus according to the fifth embodiment.
  • the present invention is applied to a sheet forming apparatus instead of the laminating unit.
  • a laminating unit in the fifth embodiment includes the sheet forming apparatus that forms the particle layer into a sheet.
  • the sheet forming apparatus includes a pressing member 410 and a heater 420.
  • the pressing member 410 is a component similar to the stage 34
  • the heater 420 is a component similar to the heater 33.
  • the particle layer having been transferred to the second intermediate bearing and conveying belt 30 is borne on and conveyed by the belt 30 to the lamination position via the sheet forming position.
  • the particle layer is heated and melted to be formed into a sheet-like thin film.
  • the sheet-like thin film is heated and melted again to be laminated on the stage 34.
  • Rollers 3051 and 3052 are tension rollers that act to keep flat the surface of the second intermediate bearing and conveying belt 30 at the sheet forming position.
  • the rollers 3051 and 3052 are components similar to the rollers 303 and 304.
  • Driving devices 315 and 316 are components that drive the rollers 3051 and 3052, respectively.
  • the driving devices 315 and 316 are components similar to the driving devices 313 and 314.
  • the driving devices 315 and 316 constitute a unit that changes the shape or the inclination of the surface of the second intermediate bearing and conveying belt 30 at the sheet forming position.
  • the sheet forming position is defined as a position at which the conveying member and the pressing member are in an indirectly contacted state with the particle layer interposed between them.
  • the sheet forming position corresponds to a region of the second intermediate bearing and conveying belt 30 between the rollers 3051 and 3052 (specifically, in that region, the second intermediate bearing and conveying belt 30 is not contacted with the rollers 3051 and 3052).
  • the apparatus executes an operation of making the surface shape of the pressing member different from the surface shape of the conveying member (or making the surface of the pressing member nonparallel to the surface of the conveying member). With the execution of such an operation, the particle layer is easier to peel off from the surface of the conveying member, and damage of the particle layer can be suppressed.
  • the technique of the laminating unit in at least one of the second to fourth embodiments may be applied to the sheet forming apparatus in the fifth embodiment. Such a modification is also involved in the present invention.
  • Fig. 13 is a schematic diagram illustrating an overall configuration of a three-dimensional modeling apparatus according to a sixth embodiment of the present invention.
  • Fig. 14 is an enlarged perspective view of the surroundings of a lamination position in the three-dimensional modeling apparatus according to the sixth embodiment of the present invention.
  • the roller 3040 over which the second intermediate bearing and conveying belt 30 is arranged to extend is translated in order to change the shape or the inclination of the surface of the second intermediate bearing and conveying belt 30.
  • a member other than the roller over which the second intermediate bearing and conveying belt 30 is arranged to extend is pressed against the belt 30. Only the features specific to the sixth embodiment will be described below while description of components in common to those in the third embodiment is omitted.
  • a laminating unit in this embodiment includes a member (pressing member) 3060 that is pressed against the second intermediate bearing and conveying belt 30.
  • the pressing member 3060 is movable in the direction perpendicular to the surface of the second intermediate bearing and conveying belt 30.
  • a width of the pressing member 3060 is smaller than that of the second intermediate bearing and conveying belt 30.
  • the laminating unit in this embodiment further includes a driving device 3160.
  • the driving device 3160 is an actuator and moves the pressing member 3060 in the direction perpendicular to the surface of the second intermediate bearing and conveying belt 30 in accordance with an instruction from the laminating unit control section U13.
  • the driving device 3160 corresponds to the unit that changes the inclination of the surface of the second intermediate bearing and conveying belt 30 at the lamination position.
  • the roller 3060 While the particle layer is being conveyed and when the lamination of the particle layer is started, the roller 3060 is held at an ordinary set position (denoted by a one-dot-chain line in Fig. 14) where the pressing member 3060 is not contacted with the second intermediate bearing and conveying belt 30.
  • the roller 3060 is translated from the ordinary set position (as denoted by a dotted line in Fig. 14). In other words, the pressing member 3060 is pressed against the second intermediate bearing and conveying belt 30 to make the surface of the second intermediate bearing and conveying belt 30 at the lamination position and the surface of the stage 34 nonparallel to each other. After the particle layer has completely departed away from the second intermediate bearing and conveying belt 30, the pressing member 3060 is returned to the ordinary set position.
  • the surface of the second intermediate bearing and conveying belt 30 at the lamination position and the surface of the stage 34 may be made nonparallel to each other by moving a plurality of pressing members. While the width of the pressing member 3060 is preferably smaller than that of the second intermediate bearing and conveying belt 30, the former may be larger than the latter.
  • the apparatus executes an operation of making the surface of the stage nonparallel to the surface of the conveying member.
  • the particle layer (three-dimensional object) is easier to peel off from the surface of the conveying member, and damage of the particle layer (three-dimensional object) can be suppressed.
  • the layer forming unit may be constituted to form a layer directly on the second conveying member with omission of the first conveying member.
  • the inclination or the shape of the belt surface is changed by driving at least one roller.
  • the inclination or the shape of the belt surface may be changed by additionally providing a member separate from the roller and pressing the member against the belt, as in the sixth embodiment.
  • the inclination or the shape of the belt surface may be changed by combining the first embodiment and the third embodiment with each other.
  • the layer is formed on the conveying member by employing the electrophotographic process
  • the layer may be formed on the conveying member by employing suitable one of other processes instead of the electrophotographic process.
  • the other processes include, e.g., an ink jet process.
  • the present invention can be further applied to a system disclosed in WO2014/092205, for example.

Abstract

L'invention porte sur un appareil de modelage en trois dimensions utilisé pour produire un objet tridimensionnel, comprenant une unité de formation de couche (U2) conçue pour former une couche sur un élément de transport (11, 30) et une unité de stratification (U3) conçue pour stratifier, au niveau d'une position de stratification, la couche ayant été transportée par l'élément de transport (11, 30) vers la position de stratification. L'unité de stratification (U3) comprend un dispositif de changement (313, 314) conçu pour changer une inclinaison ou une forme d'une surface de l'élément de transport (30) au niveau de la position de stratification.
PCT/JP2015/005765 2014-11-28 2015-11-18 Appareil de modelage en trois dimensions, procédé de modelage en trois dimensions et procédé de fabrication d'articles WO2016084348A1 (fr)

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JP2014242512 2014-11-28
JP2014-242512 2014-11-28
JP2015203192A JP2016107626A (ja) 2014-11-28 2015-10-14 立体造形装置、立体造形方法、及び、物品の製造方法
JP2015-203192 2015-10-14

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2019133846A3 (fr) * 2017-12-29 2019-08-15 Evolve Additive Solutions, Inc. Construction de couches à parties non supportées par fabrication additive à base de dépôt sélectif
US10675858B2 (en) 2015-12-18 2020-06-09 Evolve Additive Solutons, Inc. Electrophotography-based additive manufacturing with support structure and boundary
US20200247049A1 (en) * 2017-11-08 2020-08-06 Robert Bosch Gmbh Device and method for generative manufacturing of an object made up of a plurality of cross sections and three-dimensional object

Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5088047A (en) 1989-10-16 1992-02-11 Bynum David K Automated manufacturing system using thin sections
JPH07227909A (ja) * 1994-02-21 1995-08-29 Japan Synthetic Rubber Co Ltd 光造形装置
JPH08511217A (ja) 1994-03-31 1996-11-26 グレンダ,エドワード・ピー 電子写真、イオノグラフィ法又は同様の方法により三次元対象物を構築する装置及び方法
JPH10207194A (ja) 1997-01-24 1998-08-07 Fuji Xerox Co Ltd 積層造形方法及び積層造形装置
US20130075013A1 (en) * 2011-09-23 2013-03-28 Stratasys, Inc. Layer Transfusion with Rotatable Belt for Additive Manufacturing
JP2013140214A (ja) 2011-12-28 2013-07-18 Ricoh Co Ltd 画像形成装置
WO2014092205A1 (fr) 2012-12-13 2014-06-19 Canon Kabushiki Kaisha Procédé de fabrication de corps structural et appareil de fabrication associé
JP2014162009A (ja) 2013-02-21 2014-09-08 Toray Ind Inc 両面構造フィルムの製造方法および製造装置

Patent Citations (9)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US5088047A (en) 1989-10-16 1992-02-11 Bynum David K Automated manufacturing system using thin sections
JPH07227909A (ja) * 1994-02-21 1995-08-29 Japan Synthetic Rubber Co Ltd 光造形装置
JPH08511217A (ja) 1994-03-31 1996-11-26 グレンダ,エドワード・ピー 電子写真、イオノグラフィ法又は同様の方法により三次元対象物を構築する装置及び方法
JPH10207194A (ja) 1997-01-24 1998-08-07 Fuji Xerox Co Ltd 積層造形方法及び積層造形装置
US20130075013A1 (en) * 2011-09-23 2013-03-28 Stratasys, Inc. Layer Transfusion with Rotatable Belt for Additive Manufacturing
JP2014533210A (ja) 2011-09-23 2014-12-11 ストラタシス,インコーポレイテッド アディティブマニュファクチュアリングのための層溶融転写
JP2013140214A (ja) 2011-12-28 2013-07-18 Ricoh Co Ltd 画像形成装置
WO2014092205A1 (fr) 2012-12-13 2014-06-19 Canon Kabushiki Kaisha Procédé de fabrication de corps structural et appareil de fabrication associé
JP2014162009A (ja) 2013-02-21 2014-09-08 Toray Ind Inc 両面構造フィルムの製造方法および製造装置

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US10675858B2 (en) 2015-12-18 2020-06-09 Evolve Additive Solutons, Inc. Electrophotography-based additive manufacturing with support structure and boundary
US20200247049A1 (en) * 2017-11-08 2020-08-06 Robert Bosch Gmbh Device and method for generative manufacturing of an object made up of a plurality of cross sections and three-dimensional object
US11858203B2 (en) * 2017-11-08 2024-01-02 Robert Bosch Gmbh Device and method for generative manufacturing of an object made up of a plurality of cross sections and three-dimensional object
WO2019133846A3 (fr) * 2017-12-29 2019-08-15 Evolve Additive Solutions, Inc. Construction de couches à parties non supportées par fabrication additive à base de dépôt sélectif
US11654624B2 (en) 2017-12-29 2023-05-23 Evolve Additive Solutions, Inc. Building layers with unsupported portions through selective deposition-based additive manufacturing

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