A Docking Arrangement for an Additive Manufacturing Process An operating handle (50) for controlling the operational state of a valve arrangement (26) associated with a container (12) to control dispensing of material from the container (12) to a component of an additive manufacturing process. The operating handle (50) includes a rotatable shaft 56 which is coupled to the valve arrangement (26) and is rotatable between a plurality of angular positions corresponding one or more operational states of the valve arrangement (26). A lever (52) is operatively coupled to the shaft (56) and is configured to cause rotation of the shaft (56) between the plurality of angular positions upon rotation of the lever (52). The handle (50) is also rotatable under the operation of an actuator (40) provided as part of a docking arrangement (10) associated with the component.

A Docking Arrangement for an Additive Manufacturing Process An operating handle (50) for controlling the operational state of a valve arrangement (26) associated with a container (12) to control dispensing of material from the container (12) to a component of an additive manufacturing process. The operating handle (50) includes a rotatable shaft 56 which is coupled to the valve arrangement (26) and is rotatable between a plurality of angular positions corresponding one or more operational states of the valve arrangement (26). A lever (52) is operatively coupled to the shaft (56) and is configured to cause rotation of the shaft (56) between the plurality of angular positions upon rotation of the lever (52). The handle (50) is also rotatable under the operation of an actuator (40) provided as part of a docking arrangement (10) associated with the component.

A method of additively manufacturing an object includes steps of: (1) successively forming a plurality of powder layers by depositing powder; (2) selectively controlling a composition of the powder that forms each one of the plurality of powder layers; and (3) successively forming a plurality of object layers of the object by joining the powder of a portion of each one of the plurality of powder layers before forming each successive one of the plurality of powder layers.

A powder spreading apparatus includes a hopper having a first end, a second end opposite from the first end, a front wall, a rear wall opposite from the front wall, and a floor. The front wall, the rear wall, the first end, the second end, and the floor define an interior. An impeller is disposed within the interior of the hopper. The impeller includes a plurality of circumferentially spaced flutes and is configured to rotate about an impeller axis that extends from the first end of the hopper to the second end of the hopper to deposit powder onto a print area. A spreader rod is coupled to the hopper and extends along a spreader rod axis parallel to the impeller axis. The spreader rod is configured to rotate about the spreader rod axis to smooth the powder as it is deposited onto the print area.

The invention relates to a method and an apparatus for producing three-dimensional models by layering technology, and a recoater with a vacuum closure.

The invention relates to a method and an apparatus for producing three-dimensional models by layering technology, and a recoater with a vacuum closure.

An apparatus (100) for additive manufacturing of a part of an article from a first material comprising particles having a first composition is provided. The apparatus (100) comprises a layer providing means (110) for providing a first support layer from a second material comprising particles having a second composition, wherein the first composition and the second composition are different. The apparatus (100) comprises a concavity defining means (120) for defining a first concavity in an exposed surface of the first support layer. The apparatus (100) comprises a depositing means (130) for depositing a part of the first material in the first concavity defined in the first support layer. The apparatus (100) comprises a levelling means (140) for selectively levelling the deposited first material in the first concavity. The apparatus (100) comprises a first fusing means (150) for fusing some of the particles of the levelled first material in the first concavity by at least partially melting said particles, thereby forming a first part of the layer of the article. In this way, the second material may be thus used to provide a support structure during additive manufacturing of the part of the article.

An additive manufacturing machine (900) includes a build unit (904) that is supported by an overhead gantry (918). The build unit (904) includes a powder dispenser (906) including a vibration mechanism (922) and a scan unit (908) including a powder fusing device (910) for fusing or binding portions of a layer of additive powder. A vibration isolation device (932), such as a passive rubber damper (940) or an active vibration canceling mechanism (960), is positioned between the powder dispenser (906) and the scan unit (908) to prevent vibrations in the powder dispenser (906) from causing operational issues with the scan unit (908) and inaccuracies in the additive manufacturing process.

An additive manufacturing machine (900) includes a build unit (904) that is supported by an overhead gantry (918). The build unit (904) includes a powder dispenser (906) including a vibration mechanism (922) and a scan unit (908) including a powder fusing device (910) for fusing or binding portions of a layer of additive powder. A vibration isolation device (932), such as a passive rubber damper (940) or an active vibration canceling mechanism (960), is positioned between the powder dispenser (906) and the scan unit (908) to prevent vibrations in the powder dispenser (906) from causing operational issues with the scan unit (908) and inaccuracies in the additive manufacturing process.

A three-dimensional molding device includes a discharge unit that discharges a molding material towards a stage, a heating unit that heats the discharge unit, a temperature acquisition unit that acquires a temperature of the molding material placed on the stage, and a control unit. The control unit controls the heating unit such that a relationship of a temperature Tb of an existing layer, a path cross-sectional area Sb of the existing layer, a specific gravity ρb of a first thermoplastic resin contained in the existing layer, a specific heat Cb of the first thermoplastic resin, a temperature Tu of the heating unit, a path cross-sectional area Su of a subsequent layer, a specific gravity ρu of a second thermoplastic resin contained in the subsequent layer, a specific heat Cu of the second thermoplastic resin, a thermal decomposition temperature Td that is a lower temperature between a thermal decomposition temperature of the first thermoplastic resin and a thermal decomposition temperature of the second thermoplastic resin, and a glass transition point Tg that is a higher glass transition point between a glass transition point of the first thermoplastic resin and a glass transition point of the second thermoplastic resin satisfies the following expression (1).
Td>(Tu×Su×ρu×Cu+Tb×Sb×ρb×Cb)/(Su×ρu×Cu+Sb×ρb×Cb)>Tg  (1)