Abstract: A work vehicle including: a transmission configured to receive motive power input from a motive power source, and shift and output the input motive power to a travel device; a transmission case housing the transmission; and a gear pair disposed in the transmission, in a bottom section of an internal space of the transmission case, and including (i) a first power transmission gear configured to rotate about a first rotation axis, and (ii) a second power transmission gear configured to mesh with the first power transmission gear and rotate about a second rotation axis that is parallel with the first rotation axis. The work vehicle further includes at least one gear cover covering the first power transmission gear and the second power transmission gear.

Abstract: A power transmission device for a work vehicle includes a transmission case, a gear transmission housed in the transmission case and configured to transmit power to a travel device, and a transmission gear provided in the gear transmission in a state of sitting in lubricating oil stored in an internal space of the transmission case, the transmission case being provided with a wall part supporting a support shaft of the transmission gear in a state of being adjacent to the transmission gear, and the wall part being provided with a cover part protruding toward the outer periphery of the transmission gear from the wall part and covering the transmission gear.

Abstract: An optical connector for connecting single mode optical fibers includes a ferrule that connects to and holds an optical fiber, and a resin optical element coupled to the ferrule and that includes a lens positioned relative to an end of the optical fiber held in the ferrule, and the lens is provided with an antireflection structure. When the optical connector is oppositely connected to another identical optical connector, the opposing optical elements are disposed such that a diverging light is emitted from the end of the optical fiber, transmitted through the lens, and emitted as a collimated beam of light, and the collimated beam of light is incident on an opposing lens of the opposing, identical optical connector and condensed onto an end of an opposing optical fiber of the opposing, identical optical connector.

Abstract: An optical element is coupled to a ferrule that holds an optical fiber for single mode. The optical element includes: a glass-made optical portion in which a plurality of lenses is disposed; and a resin-made holder that holds the optical portion. The lenses are disposed with respect to an end portion of the optical fiber, using at least a part of the holder.

Abstract: An optical connector for connecting single mode optical fibers includes a ferrule that connects to and holds an optical fiber, and a resin optical element coupled to the ferrule and that includes a lens positioned relative to an end of the optical fiber held in the ferrule, and the lens is provided with an antireflection structure. When the optical connector is oppositely connected to another identical optical connector, the opposing optical elements are disposed such that a diverging light is emitted from the end of the optical fiber, transmitted through the lens, and emitted as a collimated beam of light, and the collimated beam of light is incident on an opposing lens of the opposing, identical optical connector and condensed onto an end of an opposing optical fiber of the opposing, identical optical connector.

Abstract: An optical element is coupled to a ferrule that holds an optical fiber for single mode. The optical element includes: a glass-made optical portion in which a plurality of lenses is disposed; and a resin-made holder that holds the optical portion. The lenses are disposed with respect to an end portion of the optical fiber, using at least a part of the holder.

Abstract: An optical element connects to a ferrule that holds a plurality of optical fibers. The optical element includes: a plurality of lenses; and a cutout that engages with a projection part of the ferrule. The lenses are positioned relative to the optical fibers held in the ferrule by an engagement of the projection part and the cutout.

Abstract: An optical element is configured to transmit a light flux emitted from a light source having a single light source wavelength, and is formed from a material in which resin and glass fillers are mixed. A difference between respective refractive index change rates (dn/dT) of the resin and the glass fillers relative to a temperature change at least in a vicinity of the light source wavelength becomes 10.5×105 or less.

Abstract: Since the lens (10) includes the alignment portions (14), the lens (10) is positioned with high precision with respect to the second mold (61) during molding of the holder member (40), and the holder member (40) and the lens (10) are positioned with each other with high precision. Further, since the positioning of the lens (10) with respect to the second mold (61) may be performed using the alignment portions (14) provided outside the second optical surface (13e), influence of the heat and pressure produced by the second mold (61) and the resin during molding of the holder member (40) on the second optical surface (13e) of the lens (10) may be reduced. Therefore, occurrence of degradation, such as distortion, in the second optical surface (13e) of the lens (10) during molding of the holder member (40) may be prevented.

Abstract: Since the lens (10) includes the alignment portions (14), the lens (10) is positioned with high precision with respect to the second mold (61) during molding of the holder member (40), and the holder member (40) and the lens (10) are positioned with each other with high precision. Further, since the positioning of the lens (10) with respect to the second mold (61) may be performed using the alignment portions (14) provided outside the second optical surface (13e), influence of the heat and pressure produced by the second mold (61) and the resin during molding of the holder member (40) on the second optical surface (13e) of the lens (10) may be reduced. Therefore, occurrence of degradation, such as distortion, in the second optical surface (13e) of the lens (10) during molding of the holder member (40) may be prevented.

Abstract: A lens assembling method for assembling a first lens and a second lens where the first lens has a first mark on a first surface thereof and a second mark on a second surface opposite to the first surface, and the second lens has a third mark on a first surface thereof, the lens assembling method including: a first step of aligning a position of one of the first mark and second marks of the first lens with a position of the third mark of the second lens; and a second step of aligning a position of the other one of the first and second marks of the first lens with the position of the third mark of the second lens, while keeping the position alignment performed in the first step.

Abstract: According to one embodiment, there is provided a power generation facility information management system including a power generation variation information analysis unit configured to analyze information about the form of a stop of power generation, and information about the form of a variation in the power generation amount, thereby analyzing the possibility of reduction of an environmental impact caused by the power generation. The system includes a calculation unit configured to calculate the reduction amount of the environmental impact when the stop in an avoidable power generation stop period is assumed to be avoided and calculate the reduction amount of the environmental impact when the avoidable variation is assumed to be avoided, based on the analysis result.

Abstract: Provided is an optical component manufacturing method wherein various types of information, including information relating to each optical component, can be relatively easily printed on each optical component, even in the case where a plurality of optical components are manufactured in a batch. A lens, a lens unit and a camera module manufactured by using such method are also provided. Prior to dividing camera modules into individual camera modules, a pattern to be printed on each camera module, i.e., printing contents determined based on information on a first lens array or the like after formation, is printed on the surface of the first lens array at one time. Thus, information specific to each camera module can be printed even by the relatively simple method.

Abstract: A diaphragm position measuring method and a diaphragm position measuring apparatus are disclosed, which are capable of measuring a deviation quantity between a center of an optical diaphragm and an optical axis with high accuracy. A diaphragm positioning method and a diaphragm positioning apparatus are further disclosed, which are capable of disposing the optical diaphragm in a lens unit with the high accuracy. A light condensing spot is formed by getting a collimated beam of light incident upon lenses of the lens units supported on a glass sheet, and a position of the light condensing spot, if detected by a microscope, can be used as a reference point for positioning the optical diaphragm. A central processing unit can obtain a deviation quantity between the position of the light condensing spot and a central position of the optical diaphragm, which is acquired by the microscope, and the lens unit can be effectively inspected by use of a result thereof.

Abstract: A lens assembling method for assembling a first lens and a second lens where the first lens has a first mark on a first surface thereof and a second mark on a second surface opposite to the first surface, and the second lens has a third mark on a first surface thereof, the lens assembling method including: a first step of aligning a position of one of the first mark and second marks of the first lens with a position of the third mark of the second lens; and a second step of aligning a position of the other one of the first and second marks of the first lens with the position of the third mark of the second lens, while keeping the position alignment performed in the first step.

Abstract: Provided is an optical component manufacturing method wherein various types of information, including information relating to each optical component, can be relatively easily printed on each optical component, even in the case where a plurality of optical components are manufactured in a batch. A lens, a lens unit and a camera module manufactured by using such method are also provided. Prior to dividing camera modules into individual camera modules, a pattern to be printed on each camera module, i.e., printing contents determined based on information on a first lens array or the like after formation, is printed on the surface of the first lens array at one time. Thus, information specific to each camera module can be printed even by the relatively simple method.

Abstract: An objective lens unit for use in an optical pickup device, includes: a first lens section; a first flange section positioned peripheral of the first lens section; and a support section which supports a second objective lens having a second lens section provided in parallel to the first lens section with an optical axis different from that of the first lens section, wherein the first lens section, the first flange section and the support section are integrally formed.

Abstract: An optical element used in a bidirectional optical communication module used for bidirectional optical fiber communication by a wavelength multiplex system, comprising a diffraction grating of binary structure prepared by molding, wherein a taper is formed at a portion of the diffraction grating where light entering the diffraction grating is intercepted by a convex part of the binary structure of the diffraction grating.

Abstract: An object lens unit for an optical pickup device is disclosed. The object lens unit includes a first optical element facing an optical information recording medium; a second optical element positioned on a light source side of the first optical element; and a frame in which the first optical element and the second optical element are fixed. The frame includes a first fitting portion and a second fitting portion, and has a prescribed clearance in a perpendicular direction to the optical axis between at least one of the first fitting portion of the frame and the first optical element, and the second fitting portion of the frame and the second optical element to adjust a position of at least one of the first optical element and the second optical element in a perpendicular direction to the optical axis. An optical pickup device including such object lens unit is also disclosed.

Abstract: An object lens unit for an optical pickup device is disclosed. The object lens unit includes a first optical element positioned facing an optical information recording medium; a second optical element positioned on a light source side of the first optical element; and a frame in which the first optical element and the second optical element are fixed. The frame includes a first fitting portion and a second fitting portion, and has a prescribed clearance in a perpendicular direction to the optical axis between at least one of the first fitting portion of the frame and the first optical element, and the second fitting portion of the frame and the second optical element to adjust a position of at least one of the first optical element and the second optical element in a perpendicular direction to the optical axis. An optical pickup device including such object lens unit is also disclosed.