Abstract: An apparatus (1) for manufacturing a three-dimensional object from particulate material, the apparatus comprising: • a work space (100) bounded by a first side wall (100A) on a first side of the work space, and a second side wall (100B) on a second side of the work space, the first side wall opposing the second side wall; • a build bed (170) having a build bed surface (160), the build bed surface being comprised in the floor of the work space and having a first edge (160?) on the first side of the work space, towards the first side wall, and a second edge (160?) on the second side of the work space, towards the second side wall; • a first gas inlet (101A) at or near the first side wall; • a second gas inlet (101B) at or near the second side wall; • a first gas outlet (102A) above the floor (100C) of the work space, the position of the first gas outlet being coincident with the first edge of the build bed surface, or between the first edge of the build bed surface and the first gas inlet; and • a second gas ou

Abstract: A controller and method for layer-by-layer manufacturing of a three-dimensional object from a powder. The method includes, in a first direction across a build area: moving a droplet deposition unit and depositing a radiation absorber onto regions of a previously applied layer of powder; moving a first radiation source according to a first velocity profile whilst activating the first radiation source to fuse the regions of powder where the absorber has been deposited; moving a powder distributor according to a second velocity profile and distributing a fresh layer of powder; and moving a second radiation source whilst activating the second radiation source to preheat the fresh layer of powder. The method further includes adjusting the first and/or second velocity profiles to control a time interval between the passing of the first radiation source and the powder distributor.

Abstract: A method of operating an apparatus for the layerwise manufacture of 3D objects. The method includes two or more operational cycles of a warm up phase, starting from ambient, followed by a build phase and a cooling phase. The warm up phase and the build phase each include a layer cycle of: (a) dosing build material to the work surface; (b) distributing a portion of the dosed amount over a build area; (c) heating the dosed amount; and (d) monitoring a temperature of the build material to determine a thermal state. The build phase includes melting layer-specific regions. These steps are repeated until the warm up and build phases are completed. A property of the subsequent warm up phases is determined such that the duration of a subsequent warm up phase is shorter than the duration of a preceding warm up phase.

Abstract: A method of operating an apparatus for the layerwise manufacture of 3D objects. The method includes a warm up phase followed by a build phase. The phases each include a cycle of (a) dosing an amount of build material from a dosing device; (b) pushing a portion of the dosed amount across a build area into a receiving chamber; (c) heating the dosed amount at one or both of (a) and (b); repeating (a) to (c) until each phase is complete. During the build phase, at step (b) a layer is formed over the build area and, at step (c), build material within a layer-specific region is selectively melted. Over a given duration of time, an aggregate volume of build material pushed into the receiving chamber during the warm up phase is larger than an aggregate volume of build material pushed into the receiving chamber during the build phase.

Abstract: An apparatus for formation of three-dimensional objects and having an infrared radiation deflector. The radiation deflector includes opposing first and second elongate side walls; at least one end support connecting the side walls; an upper opening and a lower opening arranged to pass lamp radiation to an exterior of the radiation deflector; and a mounting point provided at the/each end support for mounting an infrared lamp. The side walls include first and second elongate mirrors extending parallel to a lamp axis and along a lower internal portion of the respective side walls. The lamp axis extends along and between the first and second mirrors, each of which has a concave surface with respect to the lamp axis. The first mirror is an upward deflecting mirror and is arranged for redirecting at least a portion of direct lamp radiation through the upper opening.

Abstract: An infrared radiation deflector (100) for an elongate infrared lamp (110), the radiation deflector (100) comprising opposing first and second elongate side walls (130_1, 130_2); at least one end support (170) connecting the ends of the side walls (130_1, 130_2); an upper opening (140) and a lower opening (150) arranged to pass lamp radiation to an exterior of the radiation deflector (100); and a mounting point (172) provided at the/each end support (170) for mounting the infrared lamp (110) and defining between them a lamp axis location (114); wherein the first and second elongate side walls (130_1, 130_2) comprise a first elongate mirror (130_1) and a second elongate mirror (130_2) extending parallel to the lamp axis location (114) and along at least a lower internal portion of the respective first and second side walls (130_1, 130_2); wherein the lamp axis location (114) extends along and between the first mirror (130_1) and the second mirror (130_2), the first and second mirror (130_1, 130_2) each having a

Abstract: A method for determining a set point for measurements from a temperature sensor of an apparatus for the layer-by-layer formation of a three-dimensional object from particulate material, and associated controllers. The method includes distributing a calibration layer of particulate material over a build bed surface; selectively applying absorption-modifying fluid to a reference area or a surrounding area thereof, on the build bed surface; (c) lowering the build bed surface to a calibration depth, (d) applying heat to the reference area using a moveable heat source while measuring the temperature increase of a sub-reference area over a duration of time and/or taking optical readings of an optical property of the sub-reference area over the duration of time; (e) determining the onset of fusion of the particulate material; and (f) applying the onset of fusion as the set point for subsequent temperature measurements.

Abstract: A method for calibrating heat source(s) in an apparatus for manufacturing 3D objects including layer cycle steps of: distributing a layer of particulate material over a build bed; heating the layer with a heat source at a first power profile; measuring a set of temperatures at multiple regions; depositing absorption modifier (absorber) over each region and/or depositing absorption modifier (inhibitor) over a surrounding area; heating each region with the heat source or a second heat source at a second input power profile; and measuring a second set of temperatures at each region; repeating the layer cycle using different input power profiles; and determining an adjusted first and/or second input power profile, wherein when applied during a subsequent layer cycle, causes a subsequent measured set of temperatures to be within a range of target temperatures, such that the ranges are reduced over those measured for each of the calibration layers.

Abstract: A method for calibrating a heat source, used in manufacturing 3D object(s) from particulate material, including layer cycle steps of: (a) distributing a layer of particulate material; (b) heating a region of the layer with a heat source at a power input over a period of time; (c) measuring the temperature of the region; (d) depositing a radiation absorber over the region and/or an absorption inhibitor over a surrounding area; (e) heating the region and a second region within the surrounding area at a second power input and period of time; and (f) measuring a second temperature of the region and a third temperature of the second region; repeating the layer cycle using different pairs of input powers from the preceding pairs; and determining for each layer an adjusted input power(s); and applying the adjusted input powers to the heat source in steps (b) and (e) for a subsequent cycle.

Abstract: A method of manufacturing 3D objects in an apparatus having a thermal sensor, a stationary heat source and one or more further heat sources. The method includes a warm up and a build process; each processing multiple layers by a layer cycle. The layer cycles include (a) providing build bed surface of particulate material; (b) heating the surface using the stationary or a first moving heat source; (b1) depositing absorption modifier (absorber) over one or more layer-specific regions and/or depositing absorption modifier (inhibitor) over a surrounding area; (c) heating the surface by the first or a second moving heat source; and (d) measuring the temperature of the surface after (a) and/or (b) and/or (c). During one or more of (a) to (c), heating the surface to a target temperature, such that (c) causes the layer-specific region of each layer to melt and form a portion of the 3D object.

Abstract: A method for determining a set point for a thermal sensor. The method includes: (a) distributing a layer of particulate material forming a build bed surface; (b) optionally, preheating the layer to a temperature below its melting temperature; (c) measuring a first temperature value with a primary or secondary thermal sensor; (d) depositing absorption modifier over the test region and/or surrounding area; (e) heating the test region; (f) measuring a second temperature value with the primary sensor; (g) distributing another layer of material over the preceding layer; repeating steps (b) to (g), such that the test region of each layer reaches a higher temperature than that of the preceding layer, at least until the test region starts to melt; determining a set point for the primary sensor from a characteristic in the evolution of the measured temperature values; and applying the set point to subsequent measurements of the primary sensor.

Abstract: A method for determining a set point for a thermal sensor. The method includes (a) distributing a layer of particulate material to provide a build bed surface; (b) depositing an amount of absorption modifier over a test region or a surrounding area; (c) heating the test region; (d) measuring a temperature value within the test region with the sensor; (e) distributing a new layer of material over the preceding layer; repeating (b) to (e) until the material of the test region starts to melt, wherein repeated step (b) deposits additional absorption modifier over the test region to absorb more energy from the heat source than the preceding layer; determining a set point for the thermal sensor from a characteristic in the evolution of the measured temperature value within the test region; and applying the set point to subsequent measurements of the thermal sensor.

Abstract: A method of manufacturing 3D objects with an apparatus having first and second heat sources and a thermal sensor. The method includes carrying out a build process after a thermal calibration process for a thermal control component(s). The calibration and build processes include a layer cycle including (i) providing a layer of particulate material defining a build bed surface; (ia) heating the surface; (ii) depositing absorption modifier over a layer-specific region and/or a surrounding area; (iii) heating the layer-specific region with the first heat source; and (iv) measuring a temperature of the surface after at least one of (i) to (iii). The layer cycle includes heating the surface of each layer with the second heat source and repeating until the calibration/build processes are complete. The outcome of each calibration routine being based on the measured temperature and being applied to the thermal control component for the subsequent layer cycle.

Abstract: A structure for delivering a flow of gas across a window or aperture of an imaging or measurement device within an apparatus for the manufacture of three-dimensional objects by layer-by-layer consolidation of particulate matter, the structure comprising: a hollow body having an upper aperture for mounting in correspondence with the window/aperture of said device, a gas flow intake region below the upper aperture, and a lower aperture; wherein the gas flow intake region is provided on opposing sides of the hollow body when viewed in cross-section along a longitudinal axis that runs from the upper aperture to the lower aperture, and comprises one or more channels configured to allow, in use, a flow of intake gas to enter the hollow body from the opposing sides of the hollow body with a flow component that predominantly lies in a plane parallel to the plane of the upper aperture, and to come into confluence within the hollow body; and wherein the hollow body is symmetrically shaped about the longitudinal axis so

Abstract: An infrared radiation deflector (100) for an elongate infrared lamp (110), the radiation deflector (100) comprising opposing first and second elongate side walls (130_1, 130_2); at least one end support (170) connecting the ends of the side walls (130_1, 130_2); an upper opening (140) and a lower opening (150) arranged to pass lamp radiation to an exterior of the radiation deflector (100); and a mounting point (172) provided at the/each end support (170) for mounting the infrared lamp (110) and defining between them a lamp axis location (114); wherein the first and second elongate side walls (130_1, 130_2) comprise a first elongate mirror (130_1) and a second elongate mirror (130_2) extending parallel to the lamp axis location (114) and along at least a lower internal portion of the respective first and second side walls (130_1, 130_2); wherein the lamp axis location (114) extends along and between the first mirror (130_1) and the second mirror (130_2), the first and second mirror (130_1, 130_2) each having a

Abstract: An apparatus (1) for manufacturing a three-dimensional object from particulate material, the apparatus comprising: a work space (100) bounded by a first side wall (100A) on a first side of the work space, and a second side wall (100B) on a second side of the work space, the first side wall opposing the second side wall; a build bed (170) having a build bed surface (160), the build bed surface being comprised in the floor of the work space and having a first edge (160?) on the first side of the work space, towards the first side wall, and a second edge (160?) on the second side of the work space, towards the second side wall; a first gas inlet (101A) at or near the first side wall; a second gas inlet (101B) at or near the second side wall; a first gas outlet (102A) above the floor (100C) of the work space, the position of the first gas outlet being coincident with the first edge of the build bed surface, or between the first edge of the build bed surface and the first gas inlet; and a second gas outlet (102B)

Abstract: A method for correcting thermal image distortion in a thermal camera in an apparatus for the layer-by-layer manufacture of three-dimensional objects, the thermal camera comprising a plurality of sensor pixels arranged along a first direction; the method comprising the steps of: (a) causing a temperature reference to be at a first steady state temperature; (b) moving the temperature reference at the first steady state temperature through a plurality of positions along the first direction through the field of view of the thermal camera; (c) recording a plurality of thermal images with the thermal camera while moving the temperature reference during step (b), each thermal image corresponding to one of the plurality of positions and comprising the detected temperature of the temperature reference as detected by at least one pixel of the plurality of sensor pixels; (d) identifying the at least one pixel that detected the temperature of the temperature reference within a respective thermal image at the correspondin

Abstract: An infrared lamp assembly for an apparatus for the formation of three-dimensional objects by consolidation of particulate material, the assembly comprising: an elongate infrared lamp extending along a lamp axis, an elongate shield extending parallel to and along one side of the axis of the lamp, and a support structure holding at least one of the ends of the lamp and of the shield, wherein the elongate shield at least partially bounds the space to one side of the lamp, and wherein the assembly provides a lower opening below the lamp and an upper opening above the lamp, such that, in use, radiation generated by the lamp is able to radiate through the openings and away from the lamp in directions not bounded by the shield.

Abstract: A heater arrangement (20?) for an apparatus (1) for layer-by-layer formation of a three-dimensional object (2) by the consolidation of particulate matter (16), the heater arrangement having a heater arrangement area, and comprising: one or more shrouded radiative heating elements (20?), arranged over the heater arrangement area, the shrouded radiative heating elements being operable to heat particulate matter at a build bed surface of said apparatus to a desired temperature profile; and one or more radiation-restricting shrouds (210), which are arranged in communication with the shrouded radiative heating elements, and each of which form one or more passages for restricting the solid angle over which radiation is emitted by the shrouded radiative elements, each passage having a first end which opens towards at least one of said shrouded radiative heating elements, and a second end which opens to the exterior.