Beam adjustment method for optical scanning device and optical scanning device

The invention claimed is: 1. A beam adjustment method for use in an optical scanning device that includes a housing, and a light source for emitting multi-beam light, a holder for holding the light source, an optical element having both a collimator lens function and a cylindrical lens function, an aperture, a deflector, and a focusing optical system that are stored in the housing in alignment in an optical axis direction, the optical scanning device further including a first abutting portion which has a predetermined width in the optical axis direction and on which a part of the holder abuts in a main scanning direction, and a second abutting portion which has a predetermined width in the optical axis direction and on which a part of a peripheral edge of the optical element abuts in a sub scanning direction, the beam adjustment method comprising: a step of allowing a first adjusting tool to hold the holder and allowing a second adjusting tool to hold the optical element, the first adjusting tool being configured to move in the sub scanning direction and the optical axis direction and rotate around an optical axis, and the second adjusting tool being configured to move in the main scanning direction and the optical axis direction; a step of installing the aperture, the deflector, and the focusing optical system at predetermined designed positions in the housing, arranging the holder at a predetermined designed position in a state where a part of the holder held by the first adjusting tool abuts on the first abutting portion, and arranging the optical element at a predetermined designed position in a state where a part of the peripheral edge of the optical element held by the second adjusting tool abuts on the second abutting portion; a step of adjusting the optical axis in the sub scanning direction by moving the first adjusting tool in the sub scanning direction while keeping the holder abutting on the first abutting portion, and adjusting the optical axis in the main scanning direction by moving the second adjusting tool in the main scanning direction while keeping the optical element abutting on the second abutting portion; a step of adjusting a focal position in the main scanning direction such that light beams having passed through the aperture become parallel to each other, by moving the second adjusting tool in the optical axis direction while keeping the optical element abutting on the second abutting portion; a step of adjusting a focal position in the sub scanning direction such that light beams are focused on a defection surface of the deflector or a scanned surface, by integrally moving the first adjusting tool and the second adjusting tool in the optical axis direction while maintaining a positional relationship between the first adjusting tool and the second adjusting tool, keeping the holder abutting on the first abutting portion, and keeping the optical element abutting on the second abutting portion; a step of adjusting a beam pitch by rotating the holder around the optical axis while keeping the holder abutting on the first abutting portion; and a step of fixing the part of the holder to the first abutting portion and fixing the part of the peripheral edge of the optical element to the second abutting portion. 2. The beam adjustment method according to claim 1 , wherein an imaging sensor that can capture an image of a light beam is used, and the imaging sensor is disposed on the optical axis between the focusing optical system and the scanned surface during the step of adjusting the optical axis in the sub scanning direction and the main scanning direction, disposed on the optical axis between the aperture and the deflector during the step of adjusting the focal position in the main scanning direction, and disposed on the scanned surface during the step of adjusting the focal position in the sub scanning direction and the step of adjusting the beam pitch. 3. The beam adjustment method according to claim 1 , wherein a tool including a first substrate and a second substrate is used as the first adjusting tool, the first substrate is movable in the sub scanning direction and the optical axis direction, and the second substrate is rotatably held by the first substrate and holds the holder in a state where the optical axis of the light source matches a rotation axis. 4. An optical scanning device comprising: a light source unit held by a holder and configured to emit multi-beam light; an optical element which has both a collimator lens function and a cylindrical lens function and on which the multi-beam light is incident; an aperture configured to restrict the multi-beam light that has passed through the optical element; a deflector configured to reflect the multi-beam light that has passed through the aperture and cause the multi-beam light to scan a scanned surface in a main scanning direction; a focusing optical system disposed between the deflector and the scanned surface and configured to focus the multi-beam light on the scanned surface; and a housing storing the light source unit, the optical element, the aperture, the deflector, and the focusing optical system that are aligned in an optical axis direction in the stated order, wherein the housing includes: a first abutting portion which has a predetermined width in the optical axis direction and on which a part of the holder abuts in the main scanning direction; a second abutting portion which has a predetermined width in the optical axis direction and on which a part of a peripheral edge of the optical element abuts in a sub scanning direction; a first fixing portion configured to fix the part of the holder to the first abutting portion; and a second fixing portion configured to fix the part of the peripheral edge of the optical element to the second abutting portion, and the holder is positioned in the main scanning direction by abutting on the first abutting portion, and the optical element is positioned in the sub scanning direction by abutting on the second abutting portion.