Abstract: A printing system includes a print module with printheads covering a printing width in x-direction, and a substrate holder for supporting a substrate. The substrate and print module are movable relative to each other in y-direction. Each printhead is positioned spaced at a first distance from the substrate holder in z-direction. A detection mechanism is provided for detecting obstructions on the substrate holder. A control unit is provided for stopping further relative movement in the y-direction between the substrate and the print module when an obstruction has been detected. The detection mechanism includes individually movable sub-detection elements that together cover the printing width, where those elements are designed to have a detection signal send out to the control unit when one of the elements gets moved out of a starting position by an obstruction trying to pass it.

Abstract: A printing system comprises a sub-frame (5), a print module (8) with printheads (27), a first support unit (30) that is connected to the sub-frame (5), in particular movable in a displacement direction (z) relative to the sub-frame, a substrate holder (2) for supporting a substrate (3), and a positioning mechanism for moving the print module relative to the first support unit to and from a print position. A set of positioning parts (34-36) and positioning references (14-16) is provided that form part of or are connected to the print module (8) respectively the sub-frame (5). The positioning parts (34-36) are engageable with corresponding ones of the positioning references (14-16) for aligning the print module (8) relative to the sub-frame (5) when moved into its print position. The positioning mechanism comprises one or more four-bar linkage mechanisms (32) acting between the print module (8) and the first support unit (30).

Abstract: A printing system comprises a sub-frame (5), a print module (8) with printheads (27), a first support unit (30) that is connected to the sub-frame (5), in particular movable in a displacement direction (z) relative to the sub-frame, a substrate holder (2) for supporting a substrate (3), and a positioning mechanism for moving the print module relative to the first support unit to and from a print position. A set of positioning parts (34-36) and positioning references (14-16) is provided that form part of or are connected to the print module (8) respectively the sub-frame (5). The positioning parts (34-36) are engageable with corresponding ones of the positioning references (14-16) for aligning the print module (8) relative to the sub-frame (5) when moved into its print position. The positioning mechanism comprises one or more four-bar linkage mechanisms (32) acting between the print module (8) and the first support unit (30).

Abstract: A printing system includes a print module with printheads covering a printing width in x-direction, and a substrate holder for supporting a substrate. The substrate and print module are movable relative to each other in y-direction. Each printhead is positioned spaced at a first distance from the substrate holder in z-direction. A detection mechanism is provided for detecting obstructions on the substrate holder. A control unit is provided for stopping further relative movement in the y-direction between the substrate and the print module when an obstruction has been detected. The detection mechanism includes individually movable sub-detection elements that together cover the printing width, where those elements are designed to have a detection signal send out to the control unit when one of the elements gets moved out of a starting position by an obstruction trying to pass it.

Abstract: The invention resides in an assembly for rotationally supporting a wind turbine blade (110) relative to a wind turbine hub (120). The assembly comprises an intermediate ring (130) having an inner annular portion and an outer annular portion provided with means for attaching the turbine blade. The intermediate ring is rotatably mounted to the hub via a first bearing arrangement. According to the invention, the first bearing arrangement comprises a radial bearing (140) and a thrust bearing, whereby the inner annular portion is mounted to the hub via the radial bearing and the outer annular portion is mounted to the hub via the thrust bearing. The thrust bearing is a plain bearing comprising first and second sliding surfaces (151, 152) which are clamped to the hub between first and second clamping members (161, 162).

Abstract: A bearing assembly comprising a generator for harvesting electrical energy from rotational kinetic energy. The electromagnetic induction generator includes a magnetic rotor (including a plurality of magnets arranged with alternating polarities along a rotor periphery) and a stator having a coil. The generator is mounted to a first part of the assembly, which is rotatable about the bearing axis of rotation. The magnetic rotor is rotationally supported relative to the stator and is rotatable about an axis of rotation, which is different from the bearing axis of rotation. The assembly further comprises a target surface made of an electrically conductive material provided on a second part of the bearing assembly. During operation, relative rotation takes place between the first and second parts. The rotor is arranged whereby magnetic field lines from the plurality of magnets intersect the target surface during at least part of one revolution about the bearing axis.

Abstract: A rotary mechanism comprising a first component (a wind turbine hub base), and a second component (a wind turbine blade base); configured for coaxial rotation relative to one another around a first axis. A mechanical linkage couples the first and second components together, allowing relative rotation and maintaining a constant spacing therebetween. The linkage is a modified embodiment of the Roberts' linkage comprising: a first rod, a second rod, a swiveling member (having a swiveling axis), and a swiveling shaft (comprising top and bottom parts); configured for constraining a relative movement of the first and second components to the coaxial rotation around the first axis. The bottom part is mounted to the swiveling shaft for swiveling around the swiveling axis. The swiveling axis and the first axis span a specific plane that is stationary with respect to a specific one of the first component and the second component.

Abstract: The invention resides in an assembly for rotationally supporting a wind turbine blade (110) relative to a wind turbine hub (120). The assembly comprises an intermediate ring (130) having an inner annular portion and an outer annular portion provided with means for attaching the turbine blade. The intermediate ring is rotatably mounted to the hub via a first bearing arrangement. According to the invention, the first bearing arrangement comprises a radial bearing (140) and a thrust bearing, whereby the inner annular portion is mounted to the hub via the radial bearing and the outer annular portion is mounted to the hub via the thrust bearing. The thrust bearing is a plain bearing comprising first and second sliding surfaces (151, 152) which are clamped to the hub between first and second clamping members (161, 162).

Abstract: In an inkjet print head an actuation chamber substantially extends in a first direction and the actuation chamber is associated with a piezo actuator arranged to generate a pressure wave in the actuation chamber. The pressure wave propagates in said first direction. A nozzle is associated with the actuation chamber such that a droplet may be expelled through the nozzle upon generation of the pressure wave in the actuation chamber. A reservoir is in fluid communication with the actuation chamber via an inlet and an outlet of the actuation chamber. A pump means is provided for pumping ink from the reservoir, via the inlet, through the actuation chamber, via the outlet back into said reservoir. The print head is provided with a means for reflecting the pressure wave at the outlet of the actuation chamber for enabling to generate a sufficient pressure at the nozzle for expelling the droplet.

Abstract: An ink jet device with an ink reservoir and a jetting assembly, with an ink supply line being arranged to allow liquid ink to flow through the valve into the ink reservoir in accordance with and supported by gravity acting on the flowing ink, and a purging device adapted to apply a purging pressure to an inner space of the ink reservoir, wherein a passive one-way valve is arranged below a nominal minimal fill level (L) of the ink reservoir for blocking a connection of the ink supply line to the ink reservoir when a pressure within the ink reservoir is high enough but not required to be higher than the purging pressure.

Abstract: An improved printing device is provided with a rotatable, cylindrical image-receiving support having a number of image-forming stations disposed along the rotational path of the image-receiving support. In each image-forming station a separation image of a required image is generated and transferred in correct registration to the image-receiving support at an image-transfer zone. Preferably, each image-forming station has a rotatable, cylindrical image-registration element and an imaging means for forming the separation image on the image-registration element. When measured along the circumference of the image-registration element in the direction of movement thereof, there is an equal distance in each image-forming station between the place where the separation image is formed on the image-registration element and the center of the image-transfer zone where the separation image is transferred to the image-receiving support.