Abstract: A lead pin rectifying apparatus is provided, including a first member which includes a tapered upper face and a cylindrically-shaped side face; a cylindrically-shaped second member which has an inner diameter corresponding to an outer diameter of the first member, wherein the second member covers over the first member therewith while an electronic component having the lead pin is housed inside the second member; and a pressing member which presses the electronic component to the first member from the top side of the second member while housing the electronic component having the lead pin inside the second member to abut the lead pin against an upper face of the first member, wherein the second member is pressed to the first member after pressing the electronic component to the first member with the pressing member to rectify the shape of the lead pin of the electronic component.

Abstract: A lead pin rectifying apparatus is provided, including a first member which includes a tapered upper face and a cylindrically-shaped side face; a cylindrically-shaped second member which has an inner diameter corresponding to an outer diameter of the first member, wherein the second member covers over the first member therewith while an electronic component having the lead pin is housed inside the second member; and a pressing member which presses the electronic component to the first member from the top side of the second member while housing the electronic component having the lead pin inside the second member to abut the lead pin against an upper face of the first member, wherein the second member is pressed to the first member after pressing the electronic component to the first member with the pressing member to rectify the shape of the lead pin of the electronic component.

Abstract: An optical scanning device configured to irradiate an object with light generating from a light source via at least one mirror with a first end portion and second end portion which are attached to a housing and to scan the object with the irradiating light is provided, wherein the first end portion of the at least one mirror is movably supported by the housing and the second end portion of the at least one mirror is bonded to the housing.

Abstract: A mirror includes a substrate, a reflection layer, and a protection layer. The substrate includes a surface having an attachment area and a reflection area. The reflection layer is formed on the reflection area. The protection layer is formed on the reflection area on which the reflection layer is formed and the attachment area. Material of the protection layer is homogeneous across the reflection area and the attachment area.

Abstract: A plastic lens molding tool, including: a first mirror surface block; a second mirror surface block disposed opposite the first block, wherein the first mirror surface block includes a transfer surface with a curvature-radius center position that is transferable to an optical element; a first nested block arranged in contact with the first mirror surface block to form a reference rib groove on a border surface between the first mirror surface block and the first nested block; and a second nested block arranged in contact with the first mirror surface block at a side opposite the first nested block.

Abstract: A plastic lens molding tool, including: a first mirror surface block; a second mirror surface block disposed opposite the first block, wherein the first mirror surface block includes a transfer surface with a curvature-radius center position that is transferable to an optical element; a first nested block arranged in contact with the first mirror surface block to form a reference rib groove on a border surface between the first mirror surface block and the first nested block; and a second nested block arranged in contact with the first mirror surface block at a side opposite the first nested block.

Abstract: Method and apparatus for optical scanning includes a sliding bed and a center adjusting unit. The sliding bed predetermines a position of an optical element in a light axis direction. The optical element has at least one lens surface to be have been subjected to a precision-figure transferring and optically scanning at least one light beam generated by a plurality of light sources and deflected by a rotary mirror. The center adjusting unit moves the optical element to make a lateral center of a curvature radius of the optical element exactly on a light axis center. This paper also describes an optical element itself, a method and apparatus for positioning and fixing the optical element. This paper further describes a molding tool for making the optical element.

Abstract: A mirror includes a substrate, a reflection layer, and a protection layer. The substrate includes a surface having an attachment area and a reflection area. The reflection layer is formed on the reflection area. The protection layer is formed on the reflection area on which the reflection layer is formed and the attachment area. Material of the protection layer is homogeneous across the reflection area and the attachment area.

Abstract: An optical element including a plurality of reference members formed on a first side surface, and a method and apparatus for fixedly joining the optical element with the first side surface facing down. The method includes providing a surface including a specific position where the optical element is placed, applying an adhesive agent to a predetermined spot within the specific position in which the optical element is placed, placing the optical element therein, causing the optical element to have convex warpage, and curing the adhesive agent. The apparatus includes mechanisms configured to apply an adhesive agent to a predetermined spot within a specific position of a surface on where the optical element is placed, and to place the optical element therein, and first and second light sources configured to cause the optical element to have convex warpage, and to cure the adhesive agent, respectively.

Abstract: An optical element including a plurality of reference members formed on a first side surface, and a method and apparatus for fixedly joining the optical element with the first side surface facing down. The method includes providing a surface including a specific position where the optical element is placed, applying an adhesive agent to a predetermined spot within the specific position in which the optical element is placed, placing the optical element therein, causing the optical element to have convex warpage, and curing the adhesive agent. The apparatus includes mechanisms configured to apply an adhesive agent to a predetermined spot within a specific position of a surface on where the optical element is placed, and to place the optical element therein, and first and second light sources configured to cause the optical element to have convex warpage, and to cure the adhesive agent, respectively.

Abstract: An optical scanning device configured to irradiate an object with light generating from a light source via at least one mirror with a first end portion and second end portion which are attached to a housing and to scan the object with the irradiating light is provided, wherein the first end portion of the at least one mirror is movably supported by the housing and the second end portion of the at least one mirror is bonded to the housing.

Abstract: Method and apparatus for optical scanning includes a sliding bed and a center adjusting unit. The sliding bed predetermines a position of an optical element in a light axis direction. The optical element has at least one lens surface to be have been subjected to a precision-figure transferring and optically scanning at least one light beam generated by a plurality of light sources and deflected by a rotary mirror. The center adjusting unit moves the optical element to make a lateral center of a curvature radius of the optical element exactly on a light axis center. This paper also describes an optical element itself, a method and apparatus for positioning and fixing the optical element. This paper further describes a molding tool for making the optical element.

Abstract: Method and apparatus for optical scanning includes a sliding bed and a center adjusting unit. The sliding bed predetermines a position of an optical element in a light axis direction. The optical element has at least one lens surface to be have been subjected to a precision-figure transferring and optically scanning at least one light beam generated by a plurality of light sources and deflected by a rotary mirror. The center adjusting unit moves the optical element to make a lateral center of a curvature radius of the optical element exactly on a light axis center. This paper also describes an optical element itself, a method and apparatus for positioning and fixing the optical element. This paper further describes a molding tool for making the optical element.

Abstract: A polygon mirror scanner is disclosed, comprising a rotor having a rotating shaft, a polygon mirror having a regular prism and having a mirror surface on each side thereof, and a magnet; a bearing device, rotatably bearing the rotor, having a radial bearing, a thrust bearing, and a stator yoke; and a stator having a coil facing the magnet with a predetermined distance therebetween, wherein the radial bearing and the thrust bearing are exchangeable at the end of their useful life while maintaining a desired level of high precision and tolerances for proper and efficient operation of the polygon mirror scanner.

Abstract: A polygon mirror scanner is disclosed, comprising a rotor having a rotating shaft, a polygon mirror having a regular prism and having a mirror surface on each side thereof, and a magnet; a bearing device, rotatably bearing the rotor, having a radial bearing, a thrust bearing, and a stator yoke; and a stator having a coil facing the magnet with a predetermined distance therebetween, wherein the radial bearing and the thrust bearing are exchangeable at the end of their useful life while maintaining a desired level of high precision and tolerances for proper and efficient operation of the polygon mirror scanner.

Abstract: An optical element including a plurality of reference members formed on a first side surface, and a method and apparatus for fixedly joining the optical element with the first side surface facing down. The method includes providing a surface including a specific position where the optical element is placed, applying an adhesive agent to a predetermined spot within the specific position in which the optical element is placed, placing the optical element therein, causing the optical element to have convex warpage, and curing the adhesive agent. The apparatus includes mechanisms configured to apply an adhesive agent to a predetermined spot within a specific position of a surface on where the optical element is placed, and to place the optical element therein, and first and second light sources configured to cause the optical element to have convex warpage, and to cure the adhesive agent, respectively.

Abstract: A polygon mirror scanner is disclosed, comprising a rotor having a rotating shaft, a polygon mirror having a regular prism and having a mirror surface on each side thereof, and a magnet; a bearing device, rotatably bearing the rotor, having a radial bearing, a thrust bearing, and a stator yoke; and a stator having a coil facing the magnet with a predetermined distance therebetween, wherein the radial bearing and the thrust bearing are exchangeable at the end of their useful life while maintaining a desired level of high precision and tolerances for proper and efficient operation of the polygon mirror scanner.

Abstract: Method and apparatus for optical scanning includes a sliding bed and a center adjusting unit. The sliding bed predetermines a position of an optical element in a light axis direction. The optical element has at least one lens surface to be have been subjected to a precision-figure transferring and optically scanning at least one light beam generated by a plurality of light sources and deflected by a rotary mirror. The center adjusting unit moves the optical element to make a lateral center of a curvature radius of the optical element exactly on a light axis center. This paper also describes an optical element itself, a method and apparatus for positioning and fixing the optical element. This paper further describes a molding tool for making the optical element.

Abstract: A polygon mirror scanner is disclosed, comprising a rotor having a rotating shaft, a polygon mirror having a regular prism and having a mirror surface on each side thereof, and a magnet; a bearing device, rotatably bearing the rotor, having a radial bearing, a thrust bearing, and a stator yoke; and a stator having a coil facing the magnet with a predetermined distance therebetween, wherein the radial bearing and the thrust bearing are exchangeable at the end of their useful life while maintaining a desired level of high precision and tolerances for proper and efficient operation of the polygon mirror scanner.

Abstract: A rotary body for use in a polygonal mirror type scanner includes an element for causing the rotary body to rotate. The element is mounted to a mounting portion by press fitting while a stress ascribable to press fitting is prevented from being transferred to the side of the rotary body. The mounting portion is formed integrally with one of opposite major surfaces of the rotary body perpendicular to the side. The rotary body includes a minimum number of parts, does not need highly accurate adhesion, has high durability, and is easy to produce and free from deformation apt to occur on its side.