Abstract: A radiation source assembly for an apparatus for layer-by-layer formation of a three-dimensional object by the consolidation of particulate material, the radiation source assembly comprising a plurality of radiation sources, each radiation source being operable to emit a respective beam of radiation towards a build bed surface of the apparatus and one or more collimators arranged to collimate the beams of radiation to produce one or more collimated beams of radiation and to direct said collimated beams of radiation towards the particulate material on the build bed surface.

Abstract: A radiation source assembly (100) for an apparatus (110) for layer-by-layer formation of a three-dimensional object by the consolidation of particulate material, the radiation source assembly (100) comprising: a plurality of radiation sources (21), each radiation source (21) being operable to emit a respective beam of radiation (26) towards a build bed surface (12) of the apparatus (110); and one or more collimators (22) arranged to collimate the beams of radiation (26) to produce one or more collimated beams of radiation (27) and to direct said collimated beams (27) of radiation towards the particulate material on the build bed surface (12).

Abstract: A radiation source assembly for an apparatus for layer-by-layer formation of a three-dimensional object by the consolidation of particulate material, the radiation source assembly comprising a plurality of radiation sources, each radiation source being operable to emit a respective beam of radiation towards a build bed surface of the apparatus and one or more collimators arranged to collimate the beams of radiation to produce one or more collimated beams of radiation and to direct said collimated beams of radiation towards the particulate material on the build bed surface.

Abstract: A radiation source assembly (100) for an apparatus (110) for layer-by-layer formation of a three-dimensional object by the consolidation of particulate material, the radiation source assembly (100) comprising: a plurality of radiation sources (21), each radiation source (21) being operable to emit a respective beam of radiation (26) towards a build bed surface (12) of the apparatus (110); and one or more collimators (22) arranged to collimate the beams of radiation (26) to produce one or more collimated beams of radiation (27) and to direct said collimated beams (27) of radiation towards the particulate material on the build bed surface (12).

Abstract: Apparatus (1) for manufacturing a three-dimensional object from a powder, the apparatus comprising: a work surface (170); a build bed (201) having a build area (190), the build area (190) being comprised within the work surface (170), wherein successive layers of said three-dimensional object are formed in the build bed (201); a first powder supply module (2) fixedly arranged on a first side of the work surface (170), outward from a first side of the build bed (201); a second powder supply module (3) fixedly arranged on a second side of the work surface (170), outward from a second side of the build bed (201); a first powder distribution sled (300) operable to distribute powder dosed to the work surface (170) from the first powder supply module (2) while moving in a first direction from the first side of the work surface (170) towards the second side of the work surface (170), and from the second powder supply module (3) while moving in a second direction from the second side of the work surface (170) towards

Abstract: A method for the manufacture of three-dimensional objects is disclosed, utilising an independently operable printing sled (350) for sintering fusible powder and an independently operable powder distribution sled (300) for depositing a layer of fusible powder on the sintered layer. Since the printing sled and the powder distribution sled are independently operable, the time between sintering and deposition can be altered, dependent on the printing conditions and materials, resulting in an enhanced bond between the layers of the three-dimensional object.

Abstract: Improved apparatus and methods of sensing or monitoring body orientation and motion and measuring range of motion (ROM) for use in athletic training and physical rehabilitation and evaluation. The apparatus includes a 3-axis sensor, at least one memory, and at least one processor, and is attachable to an object to be monitored. The 3-axis sensor senses a magnitude of tilt along each of a first, second, and third axis, the memory stores data representing the sensed magnitudes of tilt, and the processor processes the data stored in the memory. In one embodiment, the processor determines an angle between each of the first, second, and third axes and a horizontal plane, and selects the two axes corresponding to the two smallest angles between the three axes and the horizontal plane. The processor then generates an indication of the orientation of the object based upon the sensed magnitudes of tilt along the two selected axes.

Abstract: A sign comprising at least one support member and a body portion attached to the support member. The sign includes at least one reflective layer secured to the body portion. The sign includes at least one optically transmissive layer secured to the reflective layer such that the reflective layer is positioned between the optically transmissive layer and the body portion. The optically transmissive layer defines an interior portion, a border encompassing the interior portion, and at least one message positioned at least partially within the interior portion. The interior portion and the border comprise contrasting colors. The reflective layer is structured to reflect light through the optically transmissive layer to augment the contrast between the interior portion and the border to thereby enhance the visibility of the message.

Abstract: A system and method of monitoring the position of a body part of a user. The system may be employed in athletic training, physical rehabilitation, or maintenance of proper body balance in daily activities. The system essentially creates a learning environment in which an athlete or physiotherapy patient is taught via immediate verbal feedback the proper body position to maintain for a particular sport or activity. The system includes one or more motion-detecting/signal-emitting units (“student units”) and one or more monitor/control units (“pro units”). Each student unit is mountable on the student user, and a position sensor within the unit senses a direction/magnitude of tilt/rotation relative to a predetermined reference position. The user of the pro unit can remotely monitor the positional information generated by the student unit via a wireless communications interface, as the user engages in the particular sport or activity.