Abstract: An image projection device that includes an optical projection system including: a projection lens arranged with an optical axis thereof shifted with respect to a light modulation device to project the light beam obliquely onto the screen; a flat mirror that reflects the light beam from the projection lens, has a rotation center on a side thereof on which a light beam having a long path from the projection lens to the screen is reflected, rotates around the rotation center and adjusts an angle of the light beam; and a curved mirror that reflects and magnifies the light beam from the flat mirror, has a rotation center on a side thereof on which a light beam having a short path from the projection lens to the screen is reflected, rotates around the rotation center and adjusts the angle of the light beam.

Abstract: An object is to provide a light source unit that focuses a laser beam, having different divergence angles in longitudinal direction and lateral direction, so as not to allow longitudinally and laterally deviating from an incident end-face of an optical fiber.

Abstract: A reflection surface (1a) of a mirror (1) has a rotationally-symmetrical shape about an optical axis (110). The mirror (1) is rotatably supported by a pivot supporting portion (41) on the position of the optical axis (110) of the reflection surface (1a) or in the vicinity of the optical axis (110). Furthermore, the mirror (1) is slidably supported by slide supporting portions (42) at two positions on the upper part thereof. With such a configuration, the mirror (1) is supported at three points. Further, even when the mirror (1) expands and contracts due to the change in temperature or the like, the deformation of the reflection surface (1a) of the mirror (1) is prevented by the action of the slide supporting portions (42). As a result, it is possible to prevent the generation of distortion of an image projected on a screen (300).

Abstract: A light source unit includes a laser element that includes a plurality of light emitting points that are arranged along one direction on an end face thereof and irradiates laser beams having a spread in a spreading direction that is perpendicular to the one direction. A cylindrical lens held by a first body tube collimates the laser beams in block. Circular lenses held by a second body tube condense the collimated beams into an inlet of an optical fiber. The first body part and the second body part are positioned and directly coupled to each other so that an optical axis of the cylindrical lens accords with that of the circular lenses.

Abstract: An object is to provide a light source unit that focuses a laser beam having different divergence angles in longitudinal direction and lateral direction, without deviating longitudinally and laterally from an incident end-face of an optical fiber, and also that simplifies assembling lenses into a lens barrel. The light source unit herein provided includes a first lens barrel 1 that holds cylindrical lenses 10 and 11, and 12 for forming a parallel-ray laser beam by refracting the laser beam 9 having different divergence angles in longitudinal direction and lateral direction emitted from a laser element 7, a second lens barrel 2 that holds circular lenses 13 and 14 for focusing the parallel-ray laser beam onto the entrance of the optical fiber 3, and a lens holder 15 that holds at least one of the cylindrical lenses and is inserted into the first lens barrel 1 and fixed therein.

Abstract: A cabinet is provided in a projection apparatus including a rectangular screen (200), and an optical engine (300) that projects an image onto a back surface of the screen (200) from a lower side thereof. The cabinet includes a screen frame (100) that holds four sides of the screen (200) and has at least an upper-side frame (1) that supports an upper side of the screen (200), a bottom plate (9) that holds the optical engine (300) and has an end portion mounted to the screen frame (100), and a reinforcing stay (10b) that connects the upper-side frame (1) of the screen frame (100) and the other end portion of the bottom plate (9) along a contour of light ray (18a) projected onto the screen (200).

Abstract: In the case of a conventional screen holding structure, in the case where, due to external force, the case is deformed, the restoration of the case is insufficient due to the frictional force caused between each of the pressure members and the screen, even though the external force is removed. Accordingly, it has been a problem that relative positional misalignment between the optical engine and the screen is left, whereby image distortion is caused. A projection apparatus is configured in such a way that pressure members 201 and 203 that press in the direction which is perpendicular to the screen plane and hold the peripheral edges of a screen 20 are provided, and the pressing force that is applied by the pressure member 201 to the top edge of the screen 20 is smaller than the pressing force that is applied by the pressure member 203 to the bottom edge.

Abstract: A reflection surface (1a) of a mirror (1) has a rotationally-symmetrical shape about an optical axis (110). The mirror (1) is rotatably supported by a pivot supporting portion (41) on the position of the optical axis (110) of the reflection surface (1a) or in the vicinity of the optical axis (110). Furthermore, the mirror (1) is slidably supported by slide supporting portions (42) at two positions on the upper part thereof. With such a configuration, the mirror (1) is supported at three points. Further, even when the mirror (1) expands and contracts due to the change in temperature or the like, the deformation of the reflection surface (1a) of the mirror (1) is prevented by the action of the slide supporting portions (42). As a result, it is possible to prevent the generation of distortion of an image projected on a screen (300).

Abstract: A nozzle hole of a conductive nozzle plate exposes the liquid surface of conductive ink. Ultrasonic generation means vibrates the ink for forming fine surface waves on the liquid surface so that the ink is sprayed from the nozzle hole as an atomized liquid particle group. A back plate provided on the opposite side of the nozzle hole in relation to a printing paper is supplied with a potential different from that for the nozzle plate, so that an electric field is formed therebetween. The sprayed liquid particle group is charged and hence urged by this electric field to adhere to the printing paper.

Abstract: A nozzle ejects molten metal in an ejecting direction. The nozzle has a solder-philic surface in a first region and a solder-repellent surface in a second region. The second region is located forward of the first region in the ejecting direction. Before molten metal is ejected, the peripheral edge of the liquid surface of the molten metal is held at a position located further forward in the ejecting direction than the boundary between the solder-philic surface and the solder-repellent surface. The peripheral edge of the liquid surface is thus held before being ejected so that solder drops can be ejected steadily with a uniform diameter, constant direction, and constant speed.

Abstract: A noncontact transmitting apparatus includes first and second noncontact transmitting units mounted on a main device and an attachment device, respectively. The second noncontact transmitting unit is removably attachable to the first noncontact transmitting unit for enabling noncontact signal transfer between the main device and the attachment device. Each of the noncontact transmitting units includes a power coil and a signal coil. The power coil is wound on a first core to supply power from the main device to the attachment device by electromagnetic induction. The first cores of the first and second noncontact transmitting units face each other at a first position when the attachment device is loaded on the main device. The signal coil is wound on a second core for signal transfer between the main device and the attachment device by electromagnetic induction.

Abstract: A reflector has an inlet opening toward a piezoelectric element, an outlet opening toward a nozzle plate and a reflecting wall connecting the same with each other. The nozzle plate has a nozzle located in the vicinity of the outlet. The piezoelectric element is provided with a through hole on a position opposed to the outlet, and applies ultrasonic waves to a liquid supplied into the reflector from the through hole. The ultrasonic waves are reflected by the reflecting wall and converged in the vicinity of the outlet for improving acoustic energy on this position so that the nozzle ejects droplets. Thus, the dimension in a direction perpendicular to that for ejecting the droplets is suppressed for providing a droplet ejector having a compact structure.

Abstract: A nozzle (2) ejects molten metal (20) in an ejecting direction Z. The nozzle (2) has a solder-philic surface in a region P1 and a solder-repellent surface in a region P2. The region P2 is located forward of the region P1 in the ejecting direction Z. Before ejected, the peripheral edge of the liquid surface of the molten metal is held at a position A located further forward by a distance &dgr; (>0) in the ejecting direction Z than the boundary between the solder-philic surface and the solder-repellent surface. The peripheral edge of the liquid surface is thus held before ejected so that the solder drops can be ejected steadily with a steady diameter, steady direction, and steady speed.

Abstract: A liquid ejector including at least one acoustic conductor for propagating acoustic wave, the at least one acoustic conductor including a first surface which is provided with the acoustic wave from the outside and an outer surface configured to focus the acoustic wave at a focal point, and a supplying path for supplying liquid to be ejected from the outside of the acoustic conductor to the focal point.

Abstract: An acoustic conductor has an outer surface which presents a parabola in cross section and reflects acoustic wave given to a first surface by a vibration excitor and focuses it onto the vicinity of a second surface. A focal point of the parabola is set above the second surface. Ink is supplied onto the second surface through a supplying path and its liquid level is positioned separately from the second surface more than the focal point. The acoustic wave is focused onto the focal point existing in the ink, resulting in increase in the acoustic energy of the ink, and an ink droplet is ejected.

Abstract: Non-contact signal transmission apparatus provides signal transmission between a main unit and an auxiliary unit via electromagnetic induction. A set of power cores having hollow sections are provided as a pair at corresponding positions of the main unit and the auxiliary unit. A wire is wound around each of the power cores as power coils for feeding power from the main unit to the auxiliary unit. At least one set of signal cores are provided as a pair at corresponding positions of the main unit and the auxiliary unit. A wire is wound around each of signal cores as signal coils transmitting signals between the main unit and the auxiliary unit. The signal coils are arranged in hollow sections of the power cores.

Abstract: A reflector has an inlet opening toward a piezoelectric element, an outlet opening toward a nozzle plate and a reflecting wall connecting the same with each other. The nozzle plate has a nozzle located in the vicinity of the outlet. The piezoelectric element is provided with a through hole on a position opposed to the outlet, and applies ultrasonic waves to a liquid supplied into the reflector from the through hole. The ultrasonic waves are reflected by the reflecting wall and converged in the vicinity of the outlet for improving acoustic energy on this position so that the nozzle ejects droplets. Thus, the dimension in a direction perpendicular to that for ejecting the droplets is suppressed for providing a droplet ejector having a compact structure.

Abstract: A nozzle hole of a conductive nozzle plate exposes the liquid surface of conductive ink. Ultrasonic generation means vibrates the ink for forming fine surface waves on the liquid surface so that the ink is sprayed from the nozzle hole as an atomized liquid particle group. A back plate provided on the opposite side of the nozzle hole in relation to a printing paper is supplied with a potential different from that for the nozzle plate, so that an electric field is formed therebetween. The sprayed liquid particle group is charged and hence urged by this electric field to adhere to the printing paper.

Abstract: Non-contact signal transmission apparatus according to the invention is characterized in that the apparatus performs signal transmission between a main unit and an auxiliary unit via electromagnetic induction in a non-contact state, wherein a set of power cores having hollow sections are provided as a pair at corresponding positions of a main unit and an auxiliary unit, wherein a wire is wound around each of power cores (power coils) for feeding power from the main unit to the auxiliary unit and at least one set of signal cores are provided as a pair at corresponding positions of the main unit and the auxiliary unit, wherein a wire is wound around each of signal cores (signal coils) transmitting signals between the main unit and the auxiliary unit, the at least one set of signal coils arranged in the hollow section of the power core.

Abstract: A noncontact transmitting apparatus includes first and second noncontact transmitting units mounted on a main device and an attachment device, respectively. The second noncontact transmitting unit is removably attachable to the first noncontact transmitting unit for enabling noncontact signal transfer between the main device and the attachment device. Each of the noncontact transmitting units includes a power coil and a signal coil. The power coil is wound on a first core to supply power from the main device to the attachment device by electromagnetic induction. The first cores of the first and second noncontact transmitting units face each other at a first opposite position when the attachment device is loaded on the main device. The signal coil is wound on a second core to perform signal transfer between the main device and the attachment device by electromagnetic induction.