A rotary dough molding machine (10). The machine has a frame (6), a die roller (4) rotatably mounted to the frame (6), a knife (3) for scraping dough from the die roller (4), the knife (3) extending along the die roller (4), and a driver for moving the knife (3) between a scraping position and an inactive position, with the driver having a first drive (1) acting on the first end (31) of the knife (3) and a second drive (2) acting on the second end (32) of the knife (3). The first drive (1) and the second drive (2) can be actuated independently of each other.

A manufacturing apparatus that includes a conveyance device that moves a stage, where an electronic device shaped by multiple layers is placed, in X-axis and Y-axis directions. A first shaping unit, a second shaping unit, and a component mounting unit are arranged within a range in which the stage can move. The manufacturing apparatus performs additive manufacturing of the electronic device on the stage by performing a sequential movement of the stage to respective working positions of different units. As a result, in this manufacturing apparatus, a workpiece on the stage does not have to be removed and repositioned during each work process such as shaping by a first shaping unit, shaping by a second shaping unit, and electronic component mounting by a component mounting unit.

A die assembly for forming a composite gap filler, including a first die having a first portion which extends along a first central axis of the first die and has a first curved surface which has a radius which changes as the first curved surface extends about the first central axis. A second die a second portion which extends along a second central axis of the second die and has a second curved surface which has a radius which changes as the second curved surface extends about the second central axis. A third die defines a third wall member which extends about the third die and which changes in width dimension wherein with the first die abutting the second die and with the third wall member abutting the first and second dies, a closed gap is formed.

A manufacturing apparatus that includes a conveyance device that moves a stage, where an electronic device shaped by multiple layers is placed, in X-axis and Y-axis directions. A first shaping unit, a second shaping unit, and a component mounting unit are arranged within a range in which the stage can move. The manufacturing apparatus performs additive manufacturing of the electronic device on the stage by performing a sequential movement of the stage to respective working positions of different units. As a result, in this manufacturing apparatus, a workpiece on the stage does not have to be removed and repositioned during each work process such as shaping by a first shaping unit, shaping by a second shaping unit, and electronic component mounting by a component mounting unit.

An apparatus (10) for producing reshaped plastic granules from a plurality of initial granules (12) with a predetermined shape is disclosed comprising: a feeding unit (20) for continuously receiving a plurality of said initial granules (12), a pressing unit (30) for mechanically reshaping the initial granules, said pressing unit comprising at least two opposite pressing surfaces (32) with a gap (34) therebetween, the width (W) of said gap ranging from 0 mm to 0.5 mm, a receiving chamber (40) for receiving the reshaped final granules (13) from the pressing unit, and a frame (50) for supporting the feeding unit, the pressing unit and the receiving chamber. A method is also provided to produce final granules by mechanically reshaping the initial granule, each final granule having a certain surface-to-volume ratio and a primary thickness of at most 0.7 mm within substantially the entire volume of the final granules.

The invention relates to a device for processing fibre-reinforced plastic, more particularly for producing structural components for aircraft (2) or preforms for same, said device comprising at least two functional units (4), the functional units (4) comprising at least one feed unit (5) for feeding a laid fibre scrim web (6) and a processing unit (8) for processing the laid fibre scrim web (6), with a primary drive (9) for driving the laid fibre scrim web (6), with a control arrangement (10) for open-loop or closed-loop control of the primary drive (9). According to the invention the device (3) has at least one secondary drive (11) for driving the laid fibre scrim web (6), the device (3) has a force-measuring device (12) associated with the secondary drive (11), with a force sensor (13) for measuring a web tension in the laid fibre scrim web (6) by means of the control arrangement (10), the control arrangement (10) controls the secondary drive (11) in a feedback control routine, the feedback control routine comprises a secondary feedback circuit (14) to control the secondary drive (11), the control arrangement (10) in the feedback control routine supplies the web tension measured by the force-measuring device (12) associated with the secondary drive (11) as an actual value (15) to the secondary feedback circuit (14) and determines and sets a controlled variable (16) for the secondary drive (11) on the basis of the web tension in the secondary feedback circuit (14).

An apparatus for fabricating a microneedle includes a first substrate having a plurality of first spaced viscous materials formed on one side thereof and including at least one first transmission area, a second substrate disposed opposite to the first substrate, having a plurality of second spaced viscous materials formed on one side thereof facing the first substrate and including at least one second transmission area corresponding to the first transmission area, a light emitting unit arranged to correspond to the first transmission area on the other side of the first substrate and emitting light, and a light receiving unit arranged to correspond to the second transmission area on the other side of the second substrate. The microneedle manufacturing apparatus checks whether the first substrate and the second substrate are aligned according to whether the light receiving unit receives light emitted from the light emitting unit.

A die assembly for forming a composite gap filler, including a first die having a first portion which extends along a first central axis of the first die and has a first curved surface which has a radius which changes as the first curved surface extends about the first central axis. A second die a second portion which extends along a second central axis of the second die and has a second curved surface which has a radius which changes as the second curved surface extends about the second central axis. A third die defines a third wall member which extends about the third die and which changes in width dimension wherein with the first die abutting the second die and with the third wall member abutting the first and second dies, a closed gap is formed.

A method is provided for applying a laser marking to a sheet of material forming a capsule from portions of the sheet of material using a pair of die rollers wherein the location of the laser marking is established such that it does not overlap at least one of a seal between the pair of sheets of material formed during the formation of the capsule.

A manufacturing apparatus that includes a conveyance device that moves a stage, where an electronic device shaped by multiple layers is placed, in X-axis and Y-axis directions. A first shaping unit, a second shaping unit, and a component mounting unit are arranged within a range in which the stage can move. The manufacturing apparatus performs additive manufacturing of the electronic device on the stage by performing a sequential movement of the stage to respective working positions of different units. As a result, in this manufacturing apparatus, a workpiece on the stage does not have to be removed and repositioned during each work process such as shaping by a first shaping unit, shaping by a second shaping unit, and electronic component mounting by a component mounting unit.