JP4668606B2 - Tandem laser scanning unit - Google Patents

Description

  The present invention relates to an adjustment mechanism for a scanning optical system of a tandem laser scanning unit used in a color laser printer or the like.

  A tandem laser scanning unit (LSU) is a scanning optical system that deflects laser light emitted from a laser light source by a polygon mirror, and forms a scanning line for each color component by an fθ lens composed of a plurality of lenses and a deflection mirror. A plurality of photosensitive drums arranged corresponding to each scanning line are provided, and a color image is formed by multiple printing on one sheet.

  In order to maintain high drawing quality, it is desirable to form each scanning line on the photosensitive drum as a straight line having as little curvature as possible. Further, it is desirable to form a straight line with no inclination along the bus line of the photosensitive drum. In particular, in tandem color printers, if the curve (BOW) and slope (SKEW) of the scanning line differ for each color component, color misregistration occurs in the printing result, so the BOW of the scanning line formed by each scanning optical system And SKEW needs to be kept very low. Therefore, at the design stage of the optical system, each lens, mirror, etc. are designed so that the BOW and SKEW of the scanning line of each scanning optical system fall within the allowable range.

  However, even if lenses, mirrors, and the like constituting the optical system are created as designed values, performance as designed cannot be obtained if there is an assembly error of each component. For this reason, the mounting angle of the fθ lens can be adjusted for each color component so that BOW and SKEW can be corrected. For example, BOW correction requires both ends of the fθ lens to be adjusted by the same amount. For this reason, shims are attached to the abutting surfaces of the housing located at both ends of the fθ lens so that the fθ lens is rotated around an axis parallel to the main scanning direction. Is rotated by a minute angle (β rotation).

Further, in Patent Documents 1 and 2 below, the BOW is corrected by rotating the fθ lens by β using an adjustment screw, and the fθ lens is mounted using an adjustment plate that can be rotated by inserting an eccentric pin. There has been disclosed a tandem scanning optical apparatus capable of correcting skew by rotating a minute angle (γ rotation) about an axis parallel to the sub-scanning direction.
JP2000-22214A JP 2000-22214

  However, the method of attaching the shim and adjusting the angle of the fθ lens requires that the fθ lens must be removed each time adjustment is performed, and thus there is a problem that the fθ lens becomes dirty or dust is generated during work. It was.

  Further, in the BOW correction using the adjustment screw described above, a complicated and time-consuming work is required in which the adjustment screw must be turned using a tool to finely adjust the angle of the fθ lens. In addition, in the SKEW correction using the adjustment plate described above, an eccentric pin is inserted into the engagement hole formed on one side in the longitudinal direction of the adjustment plate with the screw fixing the adjustment plate loosened during adjustment. Therefore, the complicated work of having to rotate the adjusting plate is necessary.

  The present invention has been made in view of the above-described problems of the prior art. The BOW and SKEW of the scanning optical system for each color component generated due to errors in assembling of optical components or the like can be obtained without removing the fθ lens. It is an object of the present invention to provide a tandem laser scanning unit (LSU) that can be corrected more easily than the above method.

  In order to solve the above problems, in the present invention, a light source that emits a plurality of light beams, a polygon mirror that deflects the plurality of light beams, a first lens through which the plurality of light beams pass, and the plurality of light beams respectively pass. In a tandem laser scanning unit having a plurality of second lenses and a housing, at least one of the second lenses includes a β rotation adjustment mechanism that is adjusted by a minute angle around an axis parallel to the main scanning direction, The β rotation adjusting mechanism includes a support portion including a portion formed so that a cross-sectional shape having a plurality of radial lengths extends in the axial direction, and is disposed at one end of the support portion so as to protrude outside the housing. Two adjustment members each having an adjustment knob portion, and the support portion abuts on the at least one second lens and rotates the adjustment member to rotate the at least one adjustment member. The tandem laser scanning unit is characterized in that the second lens is a mechanism that adjusts a minute angle about an axis parallel to the main scanning direction.

  Furthermore, the present invention includes a γ rotation adjustment mechanism in which at least one of the second lenses is adjusted to rotate by a minute angle around an axis parallel to the optical axis of the lens, and the γ rotation adjustment mechanism includes a plurality of γ rotation adjustment mechanisms. An adjustment member having a support portion including a portion formed so that a cross-sectional shape having a length in the radial direction extends in the axial direction, and an adjustment knob portion provided at one end of the support portion and projecting outside the housing. The support portion abuts on the at least one second lens, and rotates the adjustment member to adjust the at least one second lens by a small angle around an axis parallel to the optical axis of the lens. A tandem laser scanning unit is provided.

  With the above configuration, the present invention can adjust BOW and SKEW for each color component without removing the fθ lens (second lens) for forming the scanning line.

  Further, according to the present invention, the cross-sectional shape of the support portion is a polygon, and each side of the polygon is parallel to a side facing the rotation center axis of the adjustment member, and a distance between each facing side is Unlike the distance between opposite sides of adjacent sides, the polygon has a distance between a plurality of opposite sides.

  Further, the present invention is arranged such that the adjustment member is inserted into a predetermined hole formed in the housing, and one surface of the support portion abuts in the vicinity of a longitudinal end portion of the at least one second lens. The surface of the support portion facing the one surface is disposed so as to abut on a predetermined position of the housing.

  Therefore, according to the present invention, the adjustment member can be digitally rotated at a predetermined angle, and further, the current rotation amount can be confirmed visually, so that adjustment of BOW and SKEW can be easily performed. .

  Furthermore, the present invention provides the tandem laser scanning unit according to any one of claims 1 to 3, wherein a cross-sectional shape of the support portion is an ellipse.

  In the invention, it is preferable that the adjustment member is inserted into a predetermined hole formed in the housing, and a part of the support portion is in contact with a vicinity of a longitudinal end portion of the at least one second lens. Further, it is characterized in that the vicinity of the lens contact portion of the support portion on the opposite side to the rotation axis is in contact with a predetermined position of the housing.

  In the present invention, only one of the plurality of second lenses may not include the β rotation adjustment mechanism, and only one of the plurality of second lenses may include the γ. The rotation adjustment mechanism is not provided.

  Therefore, according to the above configuration, the present invention can easily correct BOW and SKEW of the scanning optical system for each color component caused by an assembly error of the optical component, etc., without removing the fθ lens, compared to the conventional method. A tandem laser scanning unit (LSU) can be provided.

  Hereinafter, specific embodiments of a tandem laser scanning unit (LSU) according to the present invention will be described.

  FIG. 1 is a side view (right side) of an LSU according to an embodiment of the present invention. This LSU has a single polygon mirror, a single first fθ lens that scans laser light toward four photosensitive drums for each color component of black, cyan, yellow, and magenta, a plurality of deflection mirrors, and The invention is applied to a tandem color printer that includes a scanning optical system including four second fθ lenses and obtains a color print by performing multiple printing on one sheet.

  As shown in FIG. 1, the LSU of the embodiment includes a housing 10 and various optical systems provided in the housing 10. As shown in FIG. 1, when the LSU is installed in the printer, a drum support 12 including a photosensitive drum is disposed below the LSU. The housing 10 includes a scanning optical system for guiding laser light from a light source to each photosensitive drum, that is, a polygon mirror 40, a first fθ lens 50, and a second fθ lens extending in the left-right direction of the housing 10 (vertical direction on the paper surface). 52, 54, 56, 58 and deflection mirrors 61, 62, 63, 64, 65, 66, 67 are arranged as shown. The drum support 12 is provided with first, second, third, and fourth photosensitive drums 152, 154, 156, and 158 on which scanning lines are formed by a scanning optical system. The four photosensitive drums 152, 154, 156, and 158 are provided in parallel so that the rotation axes are parallel to each other. Around each photosensitive drum, a unit for executing each process of development, transfer, and cleaning in addition to the exposure process by the scanning optical system is arranged, but the illustration is omitted here.

  The print paper is supplied from, for example, the left side in FIG. 1, and is developed with toners of the respective color components, and the first photoconductor drum 152, the second photoconductor drum 154, the third photoconductor drum 156, and the fourth photoconductor drum. Patterns are transferred in the order of the photosensitive drum 158, and these are multiplex-printed to form a color image on the paper.

  First, the arrangement of the optical components of the scanning optical system will be described with reference to FIGS. 2 is a plan view of the housing 10 of FIG. 1 as viewed from above (the upper side of FIG. 2 is the left side of the LSU, and the lower side of the page is the right side of the LSU). The housing 10 includes a light source unit 20 that emits four laser beams arranged in the sub-scanning direction, a collimator mirror 30 that deflects the laser beam emitted by the light source unit 20 to a predetermined position of the polygon mirror 40, and a laser beam. A polygon mirror 40, which is a deflector deflecting in the main scanning direction, and the laser light deflected by the polygon mirror 40 are transmitted and have power in the main scanning direction and the sub-scanning direction. , 65, 67, the first fθ lens 50 is provided.

  Further, the housing 10 includes a second fθ lens 52 that is an imaging optical system that transmits the laser light deflected by the deflection mirror 61 in order to form a scanning line on the first photosensitive drum 152, and the fθ lens. 52 includes a deflection mirror 62 that deflects the laser light transmitted through the first photosensitive drum 152 toward the first photosensitive drum 152, and is deflected by the deflection mirror 63 to form a scanning line on the second photosensitive drum 154. The second fθ lens 54 that can adjust the mounting angle (β rotation and γ rotation described later), which is an imaging optical system that transmits the laser light, and the laser light transmitted through the fθ lens 54 to the second photosensitive drum 154 And an imaging optical system that transmits the laser light deflected by the deflection mirror 65 in order to form a scanning line on the third photosensitive drum 156. There is provided a second fθ lens 56 capable of adjusting the mounting angle, a deflection mirror 66 for deflecting the laser beam transmitted through the fθ lens 56 toward the third photosensitive drum 156, and on the fourth photosensitive drum 158. A second fθ lens having an adjustable mounting angle, which is an imaging optical system that transmits the laser beam deflected by the deflection mirror 67 and forms the scanning line on the fourth photosensitive drum 158 in order to form a scanning line. 58.

  FIG. 3 is a view of the light source unit 20 as viewed from the direction of the arrow A along a cut surface perpendicular to the paper surface passing through the broken line a in FIG. 2, and the optical path of the laser emitted from the light source unit 20 and transmitted through the first fθ lens 50. Although the direction is actually reflected by the collimating mirror 30 and the polygon mirror 40 and changes its direction, it is a diagram schematically shown as a straight line. The light source unit 20 emits the divergent light of the semiconductor laser from each of the four emission ends 21a, 21b, 21c, and 21d arranged in the sub-scanning line direction, and four collimating lenses 22a that convert the four laser lights into parallel light. , 22b, 22c, and 22d. The light source unit 20 is provided with a cylindrical lens 24 having power only in the sub-scanning direction. The laser beams emitted from the collimating lenses 22a, 22b, 22c, and 22d form images on the photosensitive drums 152, 154, 156, and 158, respectively.

  The four laser beams emitted from the light source unit 20 are reflected by the polygon mirror 40 as parallel light in the main scanning direction, and form an image on each photosensitive drum by the power of the fθ lens. The polygon mirror 40 rotates clockwise in FIG. 2, and the reflected light beam is scanned in the direction indicated by the arrow y. Further, in the sub-scanning direction, as shown in FIG. 3, the cylindrical lens 24 of the light source unit 20 squeezes the individual laser beam diameters of the four laser beams and also squeezes the relative positions of the laser beams. An image is formed once in the vicinity of the polygon mirror 40 via the collimator mirror 30 and then incident on the first fθ lens, and is formed on each photosensitive drum by the power of each fθ lens. As described above, once the laser beam is imaged in the vicinity of the polygon mirror 40, it is possible to prevent the scanning position from being shifted due to the inclination (surface tilt) of the reflection surface of the polygon mirror 40.

  The deflecting mirror 61 is attached at its left and right ends in the longitudinal direction by holding springs 611 (right) and 612 (left) so that the reflecting surface and the side surface (lower side in the figure) are directed to the reflecting surface back surface and other side surfaces, respectively. Further, it is supported and fixed to the corresponding mirror support portion of the housing 10 at two points on the back surface of the reflecting surface and one point on the side surface (upper side in the drawing). The deflecting mirrors 63 and 65 have the same configuration. The deflecting mirror 63 is urged by pressing springs 631 and 632, and the deflecting mirror 65 is urged by pressing springs 651 and 652, and is supported and fixed to the housing 10.

  The deflection mirror 62 attaches the reflection surface and the side surface (lower side in the figure) to the direction of the back surface of the reflection surface and the other side surface by holding springs 621 (right) and 622 (left), respectively, at both left and right ends in the longitudinal direction. It is energized. The deflection mirror 62 has a left end supported and fixed to the corresponding mirror support portion of the housing 10 at two points on the back surface of the reflection surface and one point on the side surface (upper side in the figure), as with the deflection mirror 61. At the right end, one point that contacts the back surface of the reflecting surface is the support portion of the housing 10, and the other point is the head of the adjustment screw 623. The adjustment screw 623 can be rotated by a driver or the like to adjust the amount of protrusion from the housing 10, thereby adjusting the angle of the deflecting mirror 62 in contact with the minute amount. The deflecting mirrors 64 and 66 have the same configuration. The deflecting mirror 64 is urged by pressing springs 641 and 642, and the deflecting mirror 66 is biased by pressing springs 661 and 662, respectively. Is supported by the head of the adjusting screw 643, and one point on the back surface of the reflecting surface at the right end of the deflecting mirror 66 is supported by the head of the adjusting screw 663. By the adjusting screws 643 and 663, the angle of the deflecting mirrors 64 and 66 can be adjusted by a minute amount.

  Similarly to the deflection mirror 62, the deflection mirror 67 has left and right ends in the longitudinal direction at the reflection surface and the side surface (lower right side in the figure) with the back surface of the reflection surface by holding springs 671 (right) and 672 (left), respectively. It is biased towards the other side. The left end of the deflection mirror 67 is supported and fixed at the corresponding mirror support portion of the housing 10 at two points on the back surface of the reflecting surface and one point on the side surface (upper left side in the drawing). One point that contacts the back surface is a support portion of the housing 10, and the other point is a tip portion of the adjustment screw 673. The adjustment screw 673 rotates the head exposed on the upper side of the housing 10 with a screwdriver or the like to adjust the amount of protrusion to the inside of the housing 10, thereby adjusting the angle of the deflecting mirror 67 to be in contact with the minute amount. Can be adjusted.

  The fθ lens 52 is urged by holding springs 521 (right) and 524 (left) at both left and right ends in the longitudinal direction. The holding spring 521 presses the right end of the fθ lens 52 from the emission side along the optical axis direction by the central convex portion 522 and presses the right end of the fθ lens 52 from the lower side in the drawing along the sub-scanning direction by the tip portion 523 ( FIG. 1). The right end of the fθ lens 52 is supported and fixed on the inner wall of the housing 10 formed in an L shape. In addition, since the structure by the presser spring 524 at the left end of the fθ lens 52 is the same as that at the right end, detailed description is omitted.

  FIG. 4 shows an enlarged view of both ends of the fθ lens 54. FIG. 4A shows the right side, and B shows the left side. The fθ lens 54 is urged by left and right ends in the longitudinal direction by holding springs 541 (right) and 544 (left). In FIG. 4A, the holding spring 541 has the central convex portion 542 to bring the fθ lens 54 from the emission side along the optical axis direction, and the tip portion 543 to bring the fθ lens 54 from the lower direction along the sub-scanning direction. Pressing. Further, the fθ lens 54 is supported at two places on a frame portion parallel to the sub-scanning direction on the optical axis direction incident side, one place is the contact portion 141 of the housing 10, and the other place is the housing 10. It is the polygonal column part of the adjustment member 547 inserted from the hole on the right side surface. The frame portion on the optical axis direction incident side of the fθ lens 54 has a sufficient surface on which the contact portion 141 and the adjustment member 547 can contact. Further, the upper side in the drawing of the outer wall of the end portion in the sub-scanning direction formed in parallel with the main scanning direction of the fθ lens 54 (direction perpendicular to the paper surface) is an adjustment member 549 inserted from the hole on the right side surface of the housing 10. It is supported by the polygonal column part.

  In FIG. 4B, the holding spring 544 has the fθ lens 54 from the emission side along the optical axis direction by the central convex portion 545 and the fθ lens 54 from the lower direction in the drawing along the sub-scanning direction by the tip portion 546. Pressing. Further, the fθ lens 54 is supported at two places on a frame portion parallel to the sub-scanning direction on the optical axis direction incident side, one place is the contact portion 142 of the housing 10, and the other place is the housing 10. It is the polygonal column part of the adjustment member 548 inserted from the hole on the left side surface. The frame portion on the optical axis direction incident side of the fθ lens 54 has a sufficient surface on which the contact portion 142 and the adjustment member 548 can contact. Further, the upper side in the figure of the outer wall of the end portion in the sub-scanning direction formed in parallel with the main scanning direction of the fθ lens 54 (direction perpendicular to the paper surface) is supported by the contact surface 144 of the housing 10. As will be described in detail later, by rotating the adjustment member 547 and the adjustment member 548 by the same angle, the fθ lens 54 rotates β (rotation about an axis parallel to the main scanning direction), and BOW can be corrected. . Further, by rotating the adjustment member 549, the fθ lens 54 rotates γ (rotation about an axis parallel to the optical axis direction), and SKEW can be corrected.

  FIG. 5A shows the right side of the fθ lens 56. The configuration of the holding spring 561, the central convex portion 562, the tip portion 563, the contact portion 161, the adjustment member 567, and the adjustment member 569 with respect to the fθ lens 56 is fθ. Since it is the same as the lens 54, description is abbreviate | omitted. Similarly in FIG. 5B, the configuration of the holding spring 564, the central convex portion 565, the tip end portion 566, the abutting portion 162, and the adjusting member 568 with respect to the fθ lens 56 is the same as that of the fθ lens 54, and thus the description thereof is omitted. .

  The fθ lens 58 is biased by holding springs 581 (right) and 584 (left) at both left and right ends in the longitudinal direction. In FIG. 6A, the holding spring 581 has the tip portion 583 to bring the fθ lens 58 from the emission side along the optical axis direction, and the center convex portion 582 to bring the fθ lens 58 from the right side in the sub-scanning direction. Pressing. Further, the fθ lens 58 is supported at two places on the frame portion parallel to the sub-scanning direction on the incident side in the optical axis direction, one place is a contact portion 181 of the housing 10, and the other place is the housing 10. It is the polygonal column part of the adjustment member 587 inserted from the hole on the right side surface. Note that the frame portion on the optical axis direction incident side of the fθ lens 58 has a sufficient surface on which the contact portion 181 and the adjustment member 587 can contact. Further, the left side of the outer wall of the end portion in the sub-scanning direction formed in parallel to the main scanning direction of the fθ lens 58 (direction perpendicular to the paper surface) is an adjustment member 589 inserted from the hole on the right side surface of the housing 10. It is supported by the polygonal column part.

  In FIG. 6B, the holding spring 584 has the tip portion 586 from the emission side of the fθ lens 58 along the optical axis direction, and the central convex portion 585 from the left side in the drawing along the fθ lens 58 along the sub-scanning direction. Pressing. Further, the fθ lens 58 is supported at two places on a frame portion parallel to the sub-scanning direction on the optical axis direction incident side, one place is a contact portion 182 of the housing 10, and the other place is the housing 10. It is the polygonal column part of the adjustment member 588 inserted from the hole on the left side surface. Note that the frame portion on the optical axis direction incident side of the fθ lens 58 has a sufficient surface on which the contact portion 182 and the adjustment member 588 can contact. Further, the right side in the figure of the outer wall of the end portion in the sub-scanning direction formed in parallel to the main scanning direction (direction perpendicular to the paper surface) of the fθ lens 58 is supported by the contact surface 184 of the housing 10. As will be described in detail later, by rotating the adjustment member 587 and the adjustment member 588 at the same angle, the fθ lens 58 rotates β (rotation about an axis parallel to the main scanning direction), and BOW can be corrected. . Further, by rotating the adjustment member 589, the fθ lens 58 rotates γ (rotation about an axis parallel to the optical axis direction), and SKEW can be corrected.

  Next, the BOW and SKEW adjustment mechanisms in the embodiment of the present invention will be described. BOW and SKEW adjustment is performed using each adjustment member that supports a part of the fθ lenses 54, 56, and 58. In this embodiment, the fθ lens 52 is rotated without an adjustment mechanism in order to correct BOW and SKEW of the other photosensitive drums 154, 156, and 158 along the scanning line formed on the photosensitive drum 152. Without being fixed. The fθ lenses 54, 56, and 58 are adjusted lenses having power in both the main scanning direction and the sub-scanning direction in order to correct the BOW of the scanning lines formed on the photosensitive drums 154, 156, and 158, respectively. It is arranged so as to be capable of fine angle rotation adjustment stepwise around a rotation axis parallel to the main scanning direction. On the other hand, the fθ lenses 54, 56, and 58 are anamorphic adjusted lenses having main power in the sub-scanning direction in order to correct the skew of the scanning lines formed on the photosensitive drums 154, 156, and 158, respectively. It is arranged so that it can be rotated by a small angle stepwise around a rotation axis parallel to the optical axis of the fθ lens.

  Here, the adjustment member will be described with reference to FIG. The adjustment members 547, 548, 549, 567, 568, 569, 587, 588, and 589 in FIGS. 1 to 5 are all the same shape and size (hereinafter referred to simply as “adjustment member unless an individual adjustment member is specified). "). The adjustment member includes a head portion 701, an adjustment knob portion 702, a tearing portion 703, an engagement portion 704, and a polygonal column portion 705.

  The diameter of the head 701 is set larger than the hole for the adjustment member formed on the side surface of the housing 10 in order to prevent the entire adjustment member from entering the housing 10. An adjustment knob portion 702 extending in the diameter direction is formed on the head portion 701 (FIG. 7A). The rotation direction of the adjustment knob portion 702 in the adjustment member axial direction and the rotation direction of the polygonal column portion 705 are formed to have a certain directional relationship. When the adjustment member is fitted into a predetermined hole of the housing 10, the head 701 and the adjustment knob 702 protrude outside the housing 10. Accordingly, when performing the adjustment, the operator can pinch the adjustment knob portion 702 from the outside of the housing 10 with his / her finger and rotate the adjustment member around its axis, so that it is not necessary to remove the fθ lens to be adjusted. Further, the adjustment amount of the fθ lens can be visually confirmed by the angle of the adjustment knob portion 702.

  From the head portion 701, a cracked portion 703 having a smaller diameter than the head portion 701 and having the same central axis and an engaging portion 704 are sequentially arranged so as to pass through a hole for an adjustment member formed on the side surface of the housing 10. It extends and is connected to the polygonal column portion 705 (FIG. 7B). The formation of the tearing portion 703 is optional and may be omitted. The engaging portion 704 is a cylindrical portion that engages with the housing 10, has a diameter larger than that of the tear 703, and its axial length is the same as or slightly larger than the thickness of the hole portion of the housing 10. Is set. Since the engaging portion 704 engages with a hole for an adjustment member formed on the side surface of the housing 10, it is preferable that the surface is relatively smooth so that the adjustment member rotates smoothly when the adjustment member is rotated. . It is preferable that the head portion 701, the adjustment knob portion 702, the tearing portion 703, the engaging portion 704, and the polygonal column portion 705 are integrally formed. Examples of the material of the adjustment member include metal.

The polygonal column portion 705 is set to have a length in the axial direction so that the polygonal column portion 705 can sufficiently come into contact with the fθ lens when fitted into a predetermined position of the housing 10. Moreover, the polygonal column part 705 in the embodiment of the present invention is a dodecagon, and the diagonal surfaces are parallel to each other, and the diagonal surfaces have different distances (surface intervals). That is, as shown in FIG. 7C, the polygonal column portion 705 is formed such that the surface intervals are d ₁ , d ₂ , d ₃ , and d ₄ each time it rotates 30 ° around the axis. (D ₁ <d ₂ <d ₃ <d ₄ ). Hereinafter, both surfaces having a surface interval of d ₁ are referred to as D ₁ surface, and similarly, as D ₂ surface, D ₃ surface, and D ₄ surface. In other words, the β rotation amount or γ rotation amount of the fθ lenses 54, 56, and 58 is determined by the difference in the surface spacing, as will be described later.

The β rotation adjusting mechanism of the fθ lenses 54, 56, and 58 will be described with reference to FIGS. As described above, in the fθ lenses 54 and 56, the arrangement of the adjustment member for β rotation is the same as that of the fθ lens, but the fθ lens 58 is arranged differently on the left and right. Therefore, the explanatory diagrams of FIGS. 8 and 9 show the right side of the lens for the fθ lenses 54 and 56 and the left side of the lens for the fθ lens 58. Moreover, in FIG. 8, the polygonal column part of the adjustment member is shown as an ellipse for simplification. Further, the following description will be made with the fθ lens 54 as a representative. During β rotation adjustment, the adjustment members 547 and 548 on the left and right of the fθ lens 54 are rotated at the same angle. As described above, the adjustment member 547 is in contact with the incident side surface of the fθ lens 54 in the optical axis direction (the bottom surface in the figure). In the embodiment of the present invention, in the initial state, as shown in FIG. 9A, the upper D ₁ surface of the adjustment member 547 in the drawing is brought into contact with the frame portion on the bottom surface of the fθ lens 54, and the lower side by abutting the D ₁ side to the abutting surfaces 145 of the housing 10, the bottom surface of the fθ lens 54 (i.e., sub-scanning direction) and the abutting surfaces 145 are disposed in parallel. Further, a contact portion 141, but the contact portion 147 (D ₁ side of the adjusting member 547 and the fθ lens 54 abuts a surface, wherein the perpendicular of abutting surfaces 145 passing through the central axis of the adjusting member 547 fθ lens The distance from the point 54 is assumed to be L (FIG. 8A). The distance d _B of the to the contact portion 147 from the abutting surface 145 is equal to the spacing of polygonal prism portion of the adjusting member 547, in this initial state is a _{d B} = d _1. In this initial state, the β rotation amount of the fθ lens 54 is 0 °.

The adjustment member 547, as shown in FIG. 8 (B), (although the clockwise in this embodiment, may also be in either direction) to rotate clockwise 30 ° rotation (30 ° adjustment), D ₂ surface thereof Abutting on the fθ lens 54, d _B = d ₂ (strictly speaking, since the D ₂ surface and the bottom surface of the fθ lens 54 are not parallel, FIG. 9B (although this diagram is rotated 90 °)) As shown in FIG. 4, the right side of the upper D ₂ surface comes into contact with the bottom surface of the fθ lens 54, and the contact portion 147 is a point where the perpendicular of the contact surface 145 passing through the central axis of the adjustment member 547 intersects the fθ lens 54. Then, d _B is slightly larger than d ₂ , but it is negligible in the following calculation, so it is considered that d _B = d _2. Thereafter, the same applies to 60 ° and 90 ° adjustments. ), The fθ lens 54 has a contact portion 141. As a fulcrum, it rotates a predetermined amount β clockwise. That is, if β rotation amount at 30 ° adjustment is θ ₃₀ , Δd _B = d ₂ −d ₁ , so tan θ ₃₀ = Δd _B / L = (d ₂ −d ₁ ) / L and θ ₃₀ = tan ^-1 {(d ₂ -d ₁ ) / L}. Further, when the adjustment member 547 is rotated 30 ° clockwise (60 ° adjustment), as shown in FIG. 8C, d _B = d ₃ and when the β rotation amount from the initial state is θ ₆₀ , Since Δd _B = d ₃ -d ₁ , tan θ ₆₀ = (d ₃ -d ₁ ) / L, and θ ₆₀ = tan ⁻¹ {(d ₃ -d ₁ ) / L}. Further, when the adjustment member 547 is rotated 30 ° clockwise (90 ° adjustment), as shown in FIG. 8D, d _B = d ₄ (> d ₃ ), and the β rotation amount from the initial state is Assuming θ ₉₀ , Δd _B = d ₄ -d ₁ , so tan θ ₉₀ = (d ₄ -d ₁ ) / L, and θ ₉₀ = tan ^-1 {(d ₄ -d ₁ ) / L} Become. The functions related to the β rotation of the contact portion 148, the abutting surface 146, the fθ lens 54, and the like related to the adjustment member 548 of the fθ lens 54 are the same as those in FIG. Omitted.

In one example of an embodiment according to the present invention, an actual measurement value ΔBOW [mm] of BOW printed on a print sheet by a scanning line formed on the photosensitive drum 54 by laser light passing through the fθ lens 54 is ΔBOW = ΔBOW ₀ × θ = ΔBOW ₀ × tan ⁻¹ (Δd _B / L). Here, ΔBOW ₀ is a correction amount [mm] per ₁ deg of β rotation. For example, when the design value is ΔBOW ₀ = 0.078 [mm / deg] and Δd _B = d2-d1 at the time of 30 ° adjustment is 0.07 [mm], the correction amount ΔBOW is ΔBOW = 0.078 × tan ^{− 1} (0.07 / 13) = 0.023 [mm]. Therefore, the BOW on the actual print paper can be corrected by about 23 μm by rotating the adjustment members 547 and 548 by 30 °.

A β rotation adjusting mechanism of the fθ lens 54 according to another embodiment of the present invention will be described with reference to FIGS. 10 and 11. FIG. 10 (A) shows the initial state, and FIG. 10 (B) shows the time of 90 ° adjustment. In the present embodiment, the abutting surface 145 and the bottom surface of the fθ lens 54 are arranged in parallel during 90 ° adjustment. In the initial state (d _B = d ₁ ), the bottom surface of the fθ lens 54 contacts the contact portion 147 of the adjustment member 547 and the contact portion 141 of the housing 10, and at the same time, the contact portion 149 located in the middle thereof. Also abut. With this configuration, the β rotation amount of the fθ lens 54 can maintain the initial state even without the adjustment member 547. This embodiment can also be performed by the contact portion 150 on the left end side of the fθ lens 54. Further, the fθ lens 56 can be similarly implemented by the abutting portions 169 and 170, and the fθ lens 58 can be similarly implemented by the abutting portions 189 and 190.

  According to the above configuration, each time the adjustment member is rotated by 30 °, the fθ lenses 54, 56, and 58 can be respectively rotated and adjusted by a predetermined minute angle around an axis parallel to the main scanning direction. It is possible to change the degree of BOW of the scanning lines formed on the photosensitive drums 154, 156, and 158. Therefore, when the BOW of the scanning line is detected by inspection after assembling the parts, the adjustment members 547 (548), 567 (568), and 587 (588) are respectively rotated and adjusted from the side surface of the housing 10. Can easily correct BOW. Further, since the adjustment members 547 (548), 567 (568), and 587 (588) can be adjusted stepwise (digitally), both ends of the fθ lens can be adjusted by the same amount. Further, the adjustment amount on both sides of each fθ lens can be visually confirmed by the angle of the adjustment knob. Further, since the adjustment can be performed from the side surface of the housing 10, the access is very good.

  As described above, by providing the β rotation adjustment mechanism in the fθ lenses 54, 56, and 58, the BOW of the scanning lines formed on the respective photosensitive drums 154, 156, and 158 can be corrected independently. Therefore, occurrence of color misregistration during color printing can be prevented.

The γ rotation adjusting mechanism of the fθ lenses 54, 56, and 58 will be described with reference to FIG. In this explanatory diagram, any of the fθ lenses 54, 56, and 58 is viewed from the optical axis direction emission side. Hereinafter, the fθ lens 54 will be described as a representative, but the fθ lenses 56 and 58 also have similar functions by corresponding configurations. The γ rotation adjustment is performed only on the right side of the fθ lens 54 (with respect to the housing 10) using the adjustment member 549. As described above, the adjustment member 549 is in contact with the upper side wall (the lower side wall in the drawing) of the fθ lens 54 in the sub-scanning direction. In the embodiment of the present invention, in the initial state, _one of the D ₁ surfaces of the adjustment member 549 is brought into contact with the fθ lens 54 and the other of the D ₁ surfaces is brought into contact with the contact surface 143 of the housing 10. The fθ lens 54 is disposed so that the main scanning direction (that is, the lower side wall in the figure) and the contact surface 143 are parallel to each other. Further, an abutting portion 144 which is the axis of the γ rotation, the distance to the fθ lens 54 at the tip of the D ₁ side of the adjusting member 549 in the initial state and in contact sides and W. The contact portion 151 is a portion of the fθ lens 54 with which the tip side of the adjustment member 549 contacts, and the distance d _S from the contact surface 143 to the contact portion 151 is the surface of the polygonal column portion of the adjustment member 549. Equal to the interval, in this state d _S = d ₁ . In the initial state, the γ rotation amount of the fθ lens 54 is 0 °. In addition, a contact portion 152 that is located on the inner side in the main scanning direction of the fθ lens 54 than the adjustment member 549 and is in contact with the fθ lens 54 may be provided so that d _S can be maintained at d _1. Good. When this contact portion 152 is provided, d _S can be maintained at d ₁ without using the adjustment member 549.

When the adjustment member 549 is rotated by 30 ° (the rotation direction of the adjustment member may be any) (adjustment by 30 °), d _S = d ₂ , and the fθ lens 54 rotates clockwise in the drawing with the contact portion 144 as a fulcrum. It rotates by a predetermined amount γ. That is, assuming that the amount of γ rotation at the time of 30 ° adjustment is θ ₃₀ , Δd _S = d ₂ −d ₁ , so tan θ ₃₀ = (d ₂ −d ₁ ) / W, and θ ₃₀ = tan ⁻¹ { (d ₂ -d ₁ ) / W}. Further, when the adjustment member 549 is rotated by 30 ° in the same direction (60 ° adjustment), d _S = d ₃ , and when the γ rotation amount from the initial state is θ ₆₀ , Δd _S = d ₃ -d ₁ . Therefore, tan θ ₆₀ = (d ₃ -d ₁ ) / W, and θ ₆₀ = tan ^-1 {(d ₃ -d ₁ ) / W}. Further, when the adjustment member 549 is rotated 30 ° in the same direction (90 ° adjustment), if the γ rotation amount from the initial state is θ ₉₀ , Δd _S = d ₄ −d ₁ , so tan θ ₉₀ = (d ₄ −d ₁ ) / W, and θ ₉₀ = tan ⁻¹ {(d ₄ −d ₁ ) / W}.

In one example of the embodiment according to the present invention, the measured value ΔSKEW [mm] of SKEW printed on the printing paper by the scanning line formed on the photosensitive drum 54 by the laser light passing through the fθ lens 54 is ΔSKEW = ΔSKEW ₀ × θ = ΔSKEW ₀ × tan ⁻¹ (Δd _S / L). Here, ΔSKEW ₀ is a correction amount [mm] per 1 [deg] of γ rotation. For example, when the design value is ΔSKEW ₀ = 3.847 [mm / deg] and Δd _S = d ₂ -d ₁ at the time of 30 ° adjustment is 0.07 [mm], the correction amount ΔSKEW is ΔSKEW = 3.847 × tan ^-1 (0.07 / 168) = 0.092 [mm]. Therefore, the skew on the actual print paper can be corrected by about 92 μm by rotating the adjustment member 549 by 30 °.

  According to the above configuration, every time the adjustment member is manually rotated by 30 °, the fθ lenses 54, 56, and 58 can be rotated and adjusted by a predetermined minute angle around an axis parallel to the optical axis direction, As a result, the degree of SKEW of the scanning lines formed on the respective photosensitive drums 154, 156, 158 can be changed. Therefore, when the SKEW of the scanning line is detected by inspection after assembling the parts, the SKEW can be easily corrected by rotating the adjustment members 549, 569, and 589 from the side surface of the housing 10 respectively. it can. Further, the adjustment amount of each fθ lens can be visually confirmed by the angle of the adjustment knob. Further, since the adjustment can be performed from the side surface of the housing 10, the access is very good.

  As described above, by providing the fθ lenses 54, 56, and 58 with the γ rotation adjusting mechanism, the skew of the scanning lines formed on the respective photosensitive drums 154, 156, and 158 can be corrected independently. Therefore, occurrence of color misregistration during color printing can be prevented.

  In the embodiment of the present invention, the adjustment member has a dodecagonal shape, but the shape is not particularly limited. For example, even if the corresponding portion of the adjustment member has an elliptical shape, it is possible to perform β rotation and γ rotation adjustment, and the same effect that adjustment can be easily performed from the outside of the housing can be obtained.

In an actual product, as a part cost, the method using the adjustment member is higher than the conventional method using the shim for β rotation adjustment. However, if the housing accuracy is brought close to the design value target, the specification may be entered even when BOW and SKEW are not adjusted. Therefore, in the present invention, as in the above-described embodiment, the housing 10 has a preliminarily applied reference surface (for example, the contact portions 149, 150, and 152 in the fθ lens 54). A method can be used in which only the hole on the side surface of the housing 10 is closed with a low-cost seal without attaching a member. Therefore, if the adjustment member is inserted from the side surface of the housing 10 and adjusted only at a place where adjustment is necessary, the number of adjustment members used can be saved.
Summary (effect of the invention)

As described above, according to the present invention, the BOW and SKEW of the scanning optical system for each color component generated due to the mounting error of the optical component can be obtained by using the rotation adjusting mechanism without removing the fθ lens. Thus, the correction can be performed more easily than the conventional method. This adjustment makes it possible to form a scanning line without BOW or SKEW for each scanning optical system, and to prevent color misregistration when applied to a color printer or the like.

It is a side view of LSU by embodiment of this invention. It is a top view of LSU by the embodiment of the present invention. It is a figure explaining a light source part and an optical path. 1 is a side view of an fθ lens according to an embodiment of the present invention. 1 is a side view of an fθ lens according to an embodiment of the present invention. 1 is a side view of an fθ lens according to an embodiment of the present invention. It is a figure which shows the adjustment member by embodiment of this invention. It is a figure explaining beta rotation by the embodiment of the present invention. It is the figure which expanded the adjustment member of FIG. It is a figure explaining (beta) rotation by other embodiment of this invention. It is the figure which expanded the adjustment member of FIG. It is a figure explaining (gamma) rotation by embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Housing 12 Drum support stand 20 Light source part 22 (22a, 22b, 22c, 22d) Collimating lens 24 Cylindrical lens 30 Collimating mirror 40 Polygon mirror 50 1st f (theta) lens 52,54,56,58 2nd f (theta) lens 152,154, 156, 158 Photosensitive drums 547, 548, 549 Adjustment member 567, 568, 569 Adjustment member 587, 588, 589 Adjustment member

Claims (6)

A tandem having a light source that emits a plurality of light beams, a polygon mirror that deflects the plurality of light beams, a first lens through which the plurality of light beams pass, a plurality of second lenses through which the plurality of light beams pass, and a housing In the laser scanning unit,
At least one of the second lenses includes a β rotation adjustment mechanism that is finely rotated around an axis parallel to the main scanning direction,
The β rotation adjusting mechanism is provided at a first support portion including a portion formed so that a cross-sectional shape having a plurality of radial lengths extends in the axial direction, and one end of the first support portion. A first adjustment member having a first adjustment knob portion projecting from the first lens at each end in the main scanning direction of the second lens,
The cross-sectional shape of the first support portion is a polygon, and each side of the polygon is parallel to the side facing the rotation center axis of the first adjustment member, and the distance between each facing side is Unlike the distance between opposite sides of adjacent sides, the polygon has a distance between a plurality of opposite sides,
One surface of the first support portion is in contact with the at least one second lens, and a surface of the first support portion facing the one surface is in contact with a predetermined position of the housing, A tandem laser scanning unit characterized in that the at least one second lens is rotated by a minute angle around an axis parallel to the main scanning direction by rotating one adjusting member.   The first adjustment member is inserted into a predetermined hole formed in the housing, and is arranged so that one surface of the first support portion abuts in the vicinity of a longitudinal end portion of the at least one second lens. The tandem laser scanning unit according to claim 1, wherein:   3. The tandem laser scanning unit according to claim 1, wherein only one of the plurality of second lenses does not include the β rotation adjustment mechanism. 4. At least one of the second lenses includes a γ rotation adjustment mechanism that is finely rotated around an axis parallel to the optical axis of the lens,
The γ rotation adjusting mechanism includes a second support portion including a portion formed such that a cross-sectional shape having a plurality of radial lengths extends in the axial direction, and is provided at one end of the second support portion. A second adjustment member having a second adjustment knob portion protruding from the second lens and provided on one end side in the main scanning direction of the second lens,
The cross-sectional shape of the second support portion is a polygon, and each side of the polygon is parallel to the side facing the rotation center axis of the second adjustment member, and the distance between the facing sides is Unlike the distance between opposite sides of adjacent sides, the polygon has a distance between a plurality of opposite sides,
One surface of the second support portion abuts on the at least one second lens, and a surface of the second support portion facing the one surface abuts on a predetermined position of the housing, 4. A mechanism for rotating the at least one second lens by a minute angle around an axis parallel to the optical axis of the lens by rotating the adjusting member. The tandem laser scanning unit according to any one of the above.   The second adjustment member is inserted into a predetermined hole formed in the housing, and is arranged so that one surface of the second support portion abuts in the vicinity of a longitudinal end portion of the at least one second lens. The tandem laser scanning unit according to claim 4, wherein:   6. The tandem laser scanning unit according to claim 4, wherein only one of the plurality of second lenses does not include the γ rotation adjusting mechanism. 7.

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