JP2003015006A - Mechanism for adjusting position of movable lens - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a mechanism which makes a movable lens advance and retreat to/from an optical path advancing in a perpendicular direction and also adjusts the position of the movable lens as the movable lens advances with a movable lens position adjustment mechanism which makes the beam diameter of light of an optical scanner for performing write scanning that gives exposure to an image carrying medium advance and retreat to/from the optical path to perform write scanning by combining a plurality of lenses. SOLUTION: A lens frame 30 holding the movable lens 11 is supported by a guide frame 21 in a plane crossing orthogonally the optical path S0 in a freely slidable way, and the movable lens 11 is made to advance and retreat to/from the optical path S0 with the sliding. A stretching male screw part 28 supporting a positioning block 27 at the point part in a freely turnable way is screwed into a stretching female screw part 25 formed at a regulating wall 12b of the guide frame 21. One face of the positioning block 27 and the front face of the lens frame 30 are formed on planes that almost coincide with each other, and the lens frame 30 is allowed to abut on the positioning block 27 to stop with the fluctuations of an arm 32. The position of the movable lens 11 is adjusted by turning the stretching male screw 28 to change the positions of the positioning block 27.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a beam diameter of a laser beam of an optical scanning device for performing writing and scanning of an image by exposing the image carrier such as a photosensitive material or a photosensitive drum while traveling the laser beam. The present invention relates to a moving lens position adjusting mechanism that adjusts the insertion position of the moving lens when the moving lens is moved back and forth in the optical path.

[0002]

2. Description of the Related Art At the time of printing or plate-making, a halftone dot image is formed directly on a photosensitive material based on integrated digital image data of characters, figures, patterns, etc. There is a direct platemaking system that creates a plate. In this direct plate making system, a photosensitive material mounted and held on the inner surface of a cylindrical drum is moved along the central axis of the drum, or while moving the drum along the central axis.
There is one in which a cylindrical inner surface scanning device is used in which writing scanning is performed by sequentially irradiating a laser beam containing image information by a deflecting unit that rotates about the central axis and applying exposure.

As such a cylindrical inner surface scanning device, there is one in which the resolution of an image formed on a photosensitive material can be changed as desired. In the cylindrical inner surface scanning device disclosed in Japanese Unexamined Patent Publication No. 7-92413, an iris is arranged in front of an imaging lens provided in a scanning head, and a diaphragm diameter of the iris is adjusted to perform writing scanning. The resolution is adjusted by changing the beam diameter of the laser beam.

On the other hand, as described in Japanese Patent Application Laid-Open No. 7-92413, a conventional cylindrical inner surface scanning device of this type has a structure in which the optical path from the laser light source to the scanning head is arranged in the same plane. ing. In the structure in which the optical paths are arranged in the same plane, the optical elements for guiding the optical paths and adjusting the light rays are arranged in the horizontal plane, and the installation space for this kind of optical scanning device becomes large. There is a risk. Therefore, it is possible to increase the height and reduce the installation space by guiding a part of the optical path in the vertical direction, returning it to the horizontal direction again, and arranging the optical path in each of the two overlapping horizontal planes. Be seen.

[0005]

By the way, in the structure in which the iris is used for adjusting the resolution, the brightness varies depending on the aperture diameter, so that the brightness is kept constant by interposing an ND filter or the like. Is done. That is, since the brightness is unified in the minimum diaphragm, the filter is interposed in the state where the diaphragm diameter is large, and thus the light amount for writing scanning may be wasted. Therefore, there is a mechanism in which a plurality of lenses are used instead of the iris and the beam diameter is adjusted by the combination thereof. For example, three lenses are used, and the beam diameter is changed between a state in which none of the lenses enter the optical path and a state in which any two lenses are combined and enter the optical path. . That is, these lenses are moved so that they can move back and forth in the optical path.

When a mechanism for adjusting the beam diameter is provided with a lens capable of advancing and retracting with respect to the optical path, when this adjusting mechanism is arranged with respect to the horizontal optical path, when it is arranged with respect to the vertical optical path. In comparison, the installation space for this optical scanning device cannot be made sufficiently small. Therefore, the advantage of the structure in which the installation space is narrowed by providing the structure in which the optical paths are arranged so as to overlap two horizontal planes is not sufficiently exerted. On the other hand, with the structure in which the lens is moved back and forth with respect to the horizontal optical path, the optical axis of the lens can be easily aligned with the axis of the laser beam by positioning the lens with its own weight in the inserted state. However, in the case of arranging with respect to the vertical optical path, the lens that advances and retracts with respect to the optical path must be moved in the horizontal direction, and positioning must be performed reliably during insertion.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a position adjusting mechanism for a moving lens, which can be moved forward and backward with respect to a vertical optical path of an optical scanning device and can be surely positioned at the time of insertion.

[0008]

As a technical means for achieving the above object, a position adjusting mechanism for a moving lens according to the present invention includes a guide frame member arranged in an optical path of an object for moving the lens forward and backward, Guided by the inner wall of the guide frame member,
A lens frame that holds the lens and that moves in a direction orthogonal to the optical path; a lens frame driving unit that moves the lens frame by connecting the lens frame to the lens frame; A positioning member for positioning the lens frame in a state of being inserted in the position, and a lid for closing the guide frame member. The lens frame driving means moves the lens frame to hold it in the lens frame. The position of the lens is determined by advancing and retracting the lens with respect to the optical path and contacting an appropriate portion of the lens frame with the positioning member with the lens inserted in the optical path.

For example, when the beam diameter is changed by advancing and retracting three lenses with respect to the optical path, the guide frame member is provided for each lens. When the lens is inserted into the optical path, the lens frame driving means guides the lens frame by the guide frame member to move the lens frame. When the lens frame moves to an appropriate position, the positioning means positions the lens frame. In this state, the lens is inserted into the optical path, and its optical axis coincides with the optical path axis.

According to a second aspect of the present invention, there is provided a position adjusting mechanism for a movable lens, wherein the positioning member is provided at an appropriate position of the guide frame member, engages with and disengages from the positioning member, and stops the lens frame when engaged. The joint portion is provided on the lens frame, the positioning member is movable with respect to the guide frame member, and the position of the lens is adjusted by adjusting the stop position of the lens frame.

When the engaging portion provided on the lens frame comes into contact with the positioning member, the movement of the lens frame is stopped and the lens is positioned at a predetermined position in the optical path at this position. By moving this positioning member with respect to the guide frame member, the position at which the engaging portion abuts can be changed. Therefore, by setting this position to an appropriate position, the position of the lens can be adjusted.

According to a third aspect of the present invention, there is provided a movable lens position adjusting mechanism, wherein the positioning member is provided on the lid body.
The lens frame is provided with an engaging portion that engages with and disengages from the positioning member and stops the lens frame at the time of engagement, and the lid is movable with respect to the guide frame member to adjust the stop position of the lens frame. It is characterized in that the position of the position of is adjusted.

When the lid is closed, the position of the positioning member can be adjusted by adjusting the position with respect to the guide frame member. Therefore, the mounting position of the lid can be adjusted to adjust the position of the lens when it is inserted into the optical path.

The position adjusting mechanism of the movable lens according to the invention of claim 4 is characterized in that the engaging portion is a tip edge portion of the lens frame.

When the engaging portion provided on the front edge of the lens frame comes into contact with the positioning member, the lens frame is stopped. Therefore, at this stop position, the lens can be adjusted to a predetermined position in the optical path. Good.

The position adjusting mechanism for a movable lens according to the invention of claim 5 is characterized in that the engaging portion is formed into a flat surface by chamfering the tip corner portion of the lens frame.

A surface matching the chamfered flat surface is formed on the positioning member, and the lens is stopped at the position where these surfaces come into close contact with each other due to the movement of the lens frame. Therefore, the lens is stable at the stop position.

Further, the position adjusting mechanism of the movable lens according to the invention of claim 6 is characterized in that the engaging portion is a circular arc surface in which a tip corner portion of the lens frame is formed in a circular arc shape.

If the surface of the positioning member that comes into contact with the engaging portion is formed into a flat surface and the engaging portion is formed into an arcuate surface, the lens frame stops in the state of point contact between them. Since the stop position of the lens frame can be determined by adjusting the point contact state, the adjustment work can be easily performed.

In the movable lens position adjusting mechanism according to the seventh aspect of the present invention, the biasing means is interposed between the lid and the lens frame to press the lens frame against the bottom surface of the guide frame member. Is characterized by.

It is desirable that the position of the lens on the optical path be constant when it is inserted in the optical path. Therefore, the lens frame is brought into contact with and guided by the bottom surface or the ceiling surface of the guide frame member. To press the lens frame against the bottom surface, the lens frame can be pressed into contact with the lid body. Further, a biasing means such as a leaf spring is interposed between the lid and the lens frame to press the lens frame against the bottom surface.

[0022]

BEST MODE FOR CARRYING OUT THE INVENTION The position adjusting mechanism for a moving lens according to the present invention will be specifically described below based on the illustrated preferred embodiments.

FIG. 11 is a schematic front view for explaining the structure of a cylindrical inner surface scanning apparatus suitable for including a moving lens whose position is adjusted by this position adjusting mechanism, and FIG. 12 is a left side view. . A laser light source 2 composed of a semiconductor laser device is arranged on the upper surface of the base plate 1, and in front of it,
The collimator lens 3, the beam expander 4, and the shutter device 5 are sequentially arranged, and the laser beam emitted from the laser light source 2 is converged into a parallel beam and adjusted to an appropriate size. A reflecting mirror 6 is arranged in front of the shutter device 5 so that a racer ray that has traveled in a substantially horizontal plane up to then is reflected in a substantially right angle direction and travels downward in a vertical plane to travel along an optical path S ₀ . It will be. A reflecting mirror 7 is arranged at the end of the optical path S ₀ , and the laser beam traveling in the vertical plane is reflected so as to proceed in the horizontal plane. A condenser lens 8 is arranged in front of the reflecting mirror 7, and collects a laser beam to enter a scan prism 9 arranged in front of the condenser lens 8. This scan prism 9
Is rotated about the optical axis of the condenser lens 8 by the scan motor 10, and the photosensitive material held on a cylindrical surface (not shown) is sequentially irradiated with a laser beam to perform writing scanning.

In the optical path S ₀ , as shown in FIG. 12, moving lenses 11, 12, 13 for changing the beam diameter of the laser beam.
Is provided. That is, these three moving lenses
Reference numerals 11, 12, and 13 are provided so as to be movable back and forth with respect to the optical path S ₀ , and the beam diameter of the laser beam is changed by changing the combination of the moving lenses 11, 12, and 13 to be moved in.

The moving lenses 11, 12, 13 are moved back and forth with respect to the optical path S ₀ , and the moving lenses 11, 12,
The 13 optical axis must coincide with the central axis of the optical path S ₀ . This position adjusting mechanism of the movable lens 11 is shown in FIGS.
It is shown in 10. A similar mechanism is used for the movable lenses 12 and 13. Further, FIGS. 1 to 5 show a first embodiment, and FIGS. 6 to 10 show a second embodiment.

FIG. 1 is an exploded perspective view showing a schematic structure of a position adjusting mechanism for a moving lens according to the first embodiment. Optical path S
_{At 0} , a guide frame 21 as a guide frame member is arranged. As shown in FIG. 2, the guide frame 21 is formed in a substantially rectangular shape, and a pair of guide walls 21a are provided on both sides of the moving area of the moving lens 11, and a restriction wall 21b is provided at the back. No wall is provided at the facing portion of the restriction wall 21b, and an opening is formed in a state in which a lid described later is covered. The bottom plate 21c of the guide frame 21 has a substantially circular opening near the restriction wall 21b.
22 are formed. This guide frame 21 has an optical path S ₀
The optical path S ₀ passes through the center of the opening 22 in the state where the optical path S ₀ is arranged. A slit portion 23 having an appropriate width is formed from the end of the bottom plate 21c opposite to the side where the restriction wall 21b is provided to the vicinity of the opening 22. Guide wall 21
A female screw portion 24 is formed at an appropriate position on the upper surface of a. Further, a mounting flange 21d protruding outward is provided at an end of the regulation wall 21b of the guide wall 21a. An adjusting female screw portion 25 penetrating the inside and outside of the regulating wall 21b is formed at one end of the regulating wall 21b, and a guide groove 26 is formed on the inner surface of the guide wall 21a facing the adjusting female screw portion 25. Has been formed.

A positioning block 27 as a positioning member shown in FIG. 4 is engaged with the guide groove 26. The positioning block 27 is formed in a substantially right-angled triangular prism, and a guide protrusion (not shown) with which the guide groove 26 engages is formed on one of two orthogonal surfaces, and the guide groove 26 is formed in the guide groove 26. It is guided and slides. An adjusting male screw 28 that is screwed into the adjusting female screw portion 25 is rotatably planted on the other of the two orthogonal surfaces. The adjusting male screw 28 can be rotated from the outside of the regulation wall 21b by using an appropriate tool. The surface including the hypotenuse of the positioning block 27 is formed into a flat surface and serves as a restriction surface.

A movable lens 11 is attached to the guide frame 21.
The lens frame 30 holding the lens is guided by the guide wall 21a and is slidably accommodated in the direction along the guide wall 21a. The corners of the tip of the lens frame 30 are chamfered,
The chamfered part 30
The plane formed on a is made to coincide with the regulation surface of the positioning block 27. A female screw portion 31 is formed on the side of the lens frame 30 opposite to the side where the chamfered portion 30a is formed with the movable lens 11 interposed therebetween, and the input pin 32a screwed into the female screw portion 31 is implanted. An arm (see FIG. 1) which is a lens frame driving means for sliding the moving lens 11 is connected.

The lens frame 30 holding the moving lens 11 is housed in the guide frame 21, and the lid 35 is used as the guide frame.
Covered by 21. As shown in FIG. 3, the lid 35 is covered with the guide frame 21, and an opening 36 is provided at a portion facing the opening 22, and a slit 37 is provided at a portion facing the slit 23. Are formed respectively. Also,
With the guide frame 21 covered, the female screw portion 24
A through hole 38 through which the fixing screw penetrates is formed in a portion facing to.

As shown in FIG. 1, when covering the lid 35,
A leaf spring 39 as an urging means is interposed between the lid 35 and the lens frame 30. Therefore, the lens frame 30 is
The bottom plate 21c of the guide frame 21 is pressed by the restoring force of 39. In addition, the input pin that is planted by being screwed into the female screw portion 24 of the lens frame 30 with the lid 35 covered.
32a projects from the slit 37 of the lid 35, and the tip of the arm 32 is rotatably connected to the input pin 32a. The arm 32 is connected to a drive mechanism (not shown) so as to swing.

The operation of the moving lens position adjusting mechanism according to the first embodiment of the present invention constructed as described above will be described below. The positioning block 27 is attached to the guide frame 21 in advance. At this time, the positioning block
The adjusting male screw 28 of 27 is screwed from the inside of the guide frame 21 to the adjusting female screw part 25, and the guide projection (not shown) of the positioning block 27 and the guide groove 26 are matched. When the adjusting male screw 28 is rotated in this state, the adjusting female screw part
It moves with respect to the adjusting female screw portion 25 in a screwing relationship with 25.
Therefore, the positioning block 27 moves back and forth according to the rotating direction of the adjusting male screw 28. The lens frame 30 is accommodated in the guide frame 21, the lid 35 is covered, and the fixing screw that penetrates the through hole 38 of the lid 35 is fastened to the female screw portion 24 of the guide frame 21 to fix the lid 35. Further, when the lid 35 is put on, the leaf spring 39 is interposed between the lid 35 and the lens frame 30. If the lens frame 30 is formed with a portion that supports the end of the leaf spring 39, the work of mounting the leaf spring 39 becomes simple. An input pin is previously provided on the female screw portion 31 of the lens frame 30.
32a is screwed and planted, the tip of the input pin 32a is projected from the slit 37, and the tip of the arm 32 is connected to the projected tip.

When the arm 32 swings, the lens frame
30 slides with respect to the guide frame 21 in a plane orthogonal to the optical path S ₀ . When the lens frame 30 moves in the direction of entering the optical path S ₀ , the chamfered portion 30a formed at the tip of the lens frame 30 contacts the regulating surface of the positioning block 27 and enters to that position. By the sliding of the lens frame 30, the moving lens 11 moves and moves back and forth with respect to the optical path S ₀ . When the movable lens 11 enters the optical path S ₀ , its optical axis and the central axis of the optical path S ₀ need to be substantially aligned with each other. This position adjustment is performed by moving the positioning block 27 with respect to the guide frame 21.

The adjusting male screw 28 is screwed into the adjusting female screw portion 25 of the guide frame 21, and the head of the adjusting male screw 28 is exposed on the outer side surface of the regulating wall 21b. When the adjusting male screw 28 is rotated by connecting an appropriate tool to the head portion, the adjusting male screw 28 moves forward and backward with respect to the adjusting female screw portion 25. Therefore, the positioning block 27 provided at the tip of the adjusting male screw 28 advances and retreats with respect to the guide frame 21 in the direction orthogonal to the optical path S _0. Therefore, if the advancing and retracting position is adjusted, the entrance end of the lens frame 30 is terminated. The position can be adjusted, and the moving lens 11 can be adjusted by adjusting this position.
When the light enters the optical path S ₀ , its optical axis and the central axis of the optical path S ₀ can be made to substantially coincide with each other. Further, since the lens frame 30 is pressed against the bottom plate 21c of the guide frame 21 by the leaf spring 39, the moving lens 11 in the optical path S ₀ can be positioned at a fixed position.

Next, the moving lens position adjusting mechanism 40 according to the second embodiment shown in FIGS. 6 to 10 will be described. The guide frame 41 formed in a substantially rectangular shape includes a pair of guide walls 41a along the moving direction of the moving lens 11 and a restriction wall 41b at the back.
And are provided. A substantially circular opening 42 is formed in the bottom plate 41c of the guide frame 41 in the vicinity of the restriction wall 41b. In a state where the guide frame 41 is disposed in the optical path S _0, so that the opening 42 is an optical path S ₀ passes. Further, a slit portion 43 is formed on the bottom plate 41c. A female screw portion 44 is formed at an appropriate position on the upper surface of the guide wall 41a. Further, a mounting flange 41d protruding outward is provided at an end of the regulation wall 41b of the guide wall 41a. Further, as shown in FIG. 10, one of the guide walls 41a of the guide frame 41 is provided with an adjusting through hole 41e penetrating the guide wall 41a.

On the guide frame 41, the moving lens 11
The lens frame 50 holding the lens is guided by the guide wall 41a and is slidably accommodated in the direction along the guide wall 41a. The front end of the lens frame 50 is formed into a semicircular outer shape to serve as an engaging portion 51. At the base end of the lens frame 50, an arm 52 that is a lens frame driving means for sliding the moving lens 11 is provided.
A female screw portion 53 is formed for implanting the input pin 52a (see FIG. 6) that is connected to the input pin 52a.

The lens frame 50 holding the movable lens 11 is housed in the guide frame 41, and the lid 55 is used as the guide frame.
Covered by 41. As shown in FIG. 8 and FIG. 10, the lid 55 covers the guide frame 41 in the opening portion.
An opening portion 56 is formed in a portion facing 42, and a slit portion 57 is formed in a portion facing the slit portion 43. Further, in a state of being covered with the guide frame 41, a portion facing the female screw portion 44 is provided in a longitudinal direction of the guide wall 41a,
That is, a long hole 58 whose longitudinal direction is the moving direction of the moving lens 11 is formed.

A pair of locking projections 59 are provided as engaging portions on the peripheral edge of the opening 56 on the back surface side of the lid 55.
As shown in FIG. 8, the surface of the locking projection 59 facing the opening 56 is a flat surface which forms an angle of about 45 degrees with the longitudinal direction of the lid body 55 to form an engaging surface 59a. In addition, a pair of driven protrusions 60 are provided on the back surface of the lid body 55 opposite to the side where the opening portion 56 is formed at appropriate intervals. The pair of driven projections 60 are arranged such that the adjusting through hole 41e is located between the driven projections 60 in a state where the lid 55 is covered with the guide frame 41.

The operation of the movable lens position adjusting mechanism according to the second embodiment of the present invention constructed as described above will be described below. The lens frame 50 is housed in the guide frame 41, the lid body 55 is covered, and the fixing screw penetrating the elongated hole 58 is temporarily fixed to the female screw portion 44. In this state, the shaft portion of the eccentric pin is inserted into the adjusting through hole 41e so that the eccentric portion of the eccentric pin, which is eccentric to the shaft portion, contacts the inner surface of the pair of driven protrusions 60. An input pin 52a is screwed into a female screw portion 53 of the lens frame 50 and is planted. The tip portion of the arm 52 is connected to the input pin 52a and the guide frame 41 is set at a predetermined position of the optical path S _0. . In this state, the optical path S ₀ is set to pass through the center of the opening 42.

On the other hand, when the arm 52 is swung, the lens frame 50 moves, so that the lens frame 50 is moved to a position where the moving lens 11 overlaps the openings 42 and 56.
At this time, the front end of the lens frame 50 is brought into contact with the locking protrusion 59 provided on the lid 55. In this state, when the shaft portion of the eccentric pin is rotated from the outside of the guide frame 41 using an appropriate tool, the eccentric portion turns. Since the eccentric portion is in contact with the inner side surfaces of the pair of driven protrusions 60, the lid body 55 slides according to the rotation direction. Therefore, the locking projection 59 slightly moves in the moving direction of the movable lens 11, and the position where the engaging portion 51 of the lens frame 50 abuts is changed. Therefore, by adjusting the position of the locking projection 59, the position of the moving lens 11 when it enters is changed. The position of the locking projection 59 is adjusted so that the optical axis of the moving lens 11 substantially coincides with the center of the optical path S ₀ . At this time, since the engaging portion 51 of the lens frame 50 is formed in an arcuate surface and the engaging surface 59a of the locking projection 59 is formed in a flat surface, the lens frame 50 and the locking projection 59 are As a result of point contact, the adjustment work can be performed more easily than in the case of surface contact. After this adjustment, the fixing screws that have been temporarily fixed are tightened to fix the lid body 55 to the guide frame 41. At this time, the position of the lid 55 with respect to the guide frame 41 is adjusted so that the lens frame 50 maintains the guide frame 41 in contact with the bottom plate 41c.

In the first and second embodiments, when the position adjustment of the moving lens when entering the optical path S ₀ is completed, any one of the moving lenses 11, 12 and 13 is made to enter. However, the optical axes of all the movable lenses 11, 12, and 13 are substantially coincident with the center of the optical path S ₀ . By changing the combination of the movable lens 11, 12, 13 to enter the optical path S _0, it is possible to change the beam diameter of the laser beam passing through the optical path S _0. In these embodiments, three moving lenses 11, 12, and 13 are used. For example, the moving lenses 11, 12, and 13 are retracted from the optical path S _0, and the moving lenses 11 and 12 are set to the optical paths. state of being entered into S _0, it is possible to change the beam diameter of the laser beam in such a state that is advanced to move the lens 11 and 13 in the optical path S _0.

In the embodiment described above, the case where the position adjusting mechanism for the moving lens according to the present invention is mounted on the cylindrical inner surface scanning device has been described. However, if the optical device needs to change the beam diameter of the light beam, It can be used for any device.

[0042]

As described above, according to the position adjusting mechanism of the moving lens according to the present invention, the lens frame holding the lens is moved by the lens frame driving means to move the lens forward and backward with respect to the optical path. I decided to do so,
Even if this optical path is an optical path that advances in the vertical direction, the lens can be reliably advanced and retracted. Therefore, it is possible to change the beam diameter of the light beam to a desired size and perform exposure with a desired resolution. Moreover, since the lens frame is stopped in contact with the positioning member, the movable lens can be reliably positioned.

According to the moving lens position adjusting mechanism of the second aspect of the present invention, since the positioning member is movable with respect to the guide frame member, the contact position with the lens frame can be adjusted. The position of the moving lens when entering the optical path can be easily adjusted.

According to the movable lens position adjusting mechanism of the third aspect of the invention, since the position of the positioning member can be changed by moving the lid with respect to the guide frame member, the position of the positioning member can be engaged with the lid. By doing so, the stop position of the lens frame to be stopped can be easily adjusted, and the position of the movable lens held by the lens frame can be easily positioned.

Further, according to the moving lens position adjusting mechanism of the invention of claim 4, since the engaging portion is formed by a part of the lens frame, a separate member for forming the engaging portion is not required,
Does not increase the number of parts.

According to the moving lens position adjusting mechanism of the fifth aspect of the invention, the movement of the lens frame is stopped by the surface contact between the positioning member and the engaging portion.

According to the moving lens position adjusting mechanism of the sixth aspect of the present invention, the movement of the lens frame is stopped by the point contact between the positioning member and the engaging portion. For example, in the case of surface contact, it is necessary to process with high accuracy to the extent that the contact surfaces come into close contact with each other, but in the case of point contact, one may be formed in an appropriate arc shape,
It is not necessary to increase the processing accuracy.

According to the moving lens position adjusting mechanism of the seventh aspect of the present invention, the lens frame can be reliably brought into contact with the bottom surface of the guide frame member, so that the position of the moving lens in the optical path can be kept constant. Can be kept.

[Brief description of drawings]

FIG. 1 is an exploded perspective view showing a schematic structure of a moving lens position adjusting mechanism according to a first embodiment of the present invention.

FIG. 2 is a plan view of a guide frame that is a guide frame member of the moving lens position adjusting mechanism according to the first embodiment.

FIG. 3 is a plan view of a lid body of the moving lens position adjusting mechanism according to the first embodiment.

FIG. 4 is a plan view of a lens frame holding a moving lens of the moving lens position adjusting mechanism according to the first embodiment.

FIG. 5 is a front sectional view showing the structure of the position adjusting mechanism of the moving lens according to the first embodiment.

FIG. 6 is an exploded perspective view showing a schematic structure of a moving lens position adjusting mechanism according to a second embodiment of the present invention.

FIG. 7 is a front view of a guide frame that is a guide frame member of the moving lens position adjusting mechanism according to the first embodiment.

FIG. 8 is a bottom view of the lid of the moving lens position adjusting mechanism according to the first embodiment.

FIG. 9 is a plan view of a lens frame holding a moving lens of the moving lens position adjusting mechanism according to the first embodiment.

FIG. 10 is a front sectional view showing the structure of the position adjusting mechanism of the moving lens according to the first embodiment.

FIG. 11 is a front view for explaining a schematic structure of a cylindrical inner surface scanning device suitable for mounting the position adjusting mechanism for the movable lens according to the present invention.

FIG. 12 is a left side view of the cylindrical inner surface scanning device.

[Explanation of symbols]

11 Moving lens 12 moving lens 13 Moving lens 20 Position adjustment mechanism 21 Guide frame (guide frame member) 21a guide wall 21b regulatory wall 21c bottom plate 22 opening 25 Adjusting female thread 26 Guide groove 27 Positioning block (positioning member) 28 Adjustment male screw 30 lens frame 30a Chamfer 31 Female thread 32 arms 32a input pin 35 lid 36 openings 38 through hole 39 Leaf spring (biasing means) 40 Position adjustment mechanism 41 Guide frame (guide frame member) 41c bottom plate 41e through hole for adjustment 42 opening 44 Female thread 50 lens frame 51 Engagement part 52 arm 52a input pin 53 Female thread 55 Lid 56 opening 58 long hole 59 Locking protrusion (engagement part) 59a Engagement surface 60 Followed protrusion

Claims (7)

[Claims] 1. A guide frame member arranged in an optical path of a lens to be moved back and forth, and a lens holding the lens, which is guided by an inner wall of the guide frame member and moves in a direction orthogonal to the optical path. A frame; a lens frame driving unit that is connected to the lens frame and moves the lens frame; a positioning member that positions the lens frame in a state where the lens is inserted at a desired position with respect to the optical path; A lid for closing the guide frame member, and moving the lens frame by the lens frame driving means,
The position of the lens is determined by advancing and retracting the lens held by the lens frame with respect to the optical path, and an appropriate portion of the lens frame contacts the positioning member with the lens inserted in the optical path. And a moving lens position adjustment mechanism. 2. The positioning member is provided at an appropriate position of the guide frame member, an engaging portion for engaging and disengaging the positioning member and stopping the lens frame at the time of engagement is provided on the lens frame, and the positioning member is the guide frame member. The movable lens position adjusting mechanism according to claim 1, wherein the position of the lens is adjusted by adjusting the stop position of the lens frame so as to be movable with respect to. 3. The positioning member is provided on the lid body, and the lens frame is provided with an engaging portion for engaging and disengaging the positioning member and stopping the lens frame at the time of engagement, and moving the lid body with respect to the guide frame member. The position adjusting mechanism for the movable lens according to claim 1, wherein the position of the lens is adjusted by adjusting the stop position of the lens frame as possible. 4. The position adjusting mechanism for a movable lens according to claim 2, wherein the engaging portion is a tip edge portion of a lens frame. 5. The position adjusting mechanism for a movable lens according to claim 4, wherein the engaging portion is formed into a flat surface by chamfering a tip corner portion of the lens frame. 6. The position adjusting mechanism for a movable lens according to claim 4, wherein the engaging portion is an arc surface in which a tip corner portion of the lens frame is formed in an arc shape. 7. The lens frame is pressed against the bottom surface of the guide frame member by interposing an urging means between the lid and the lens frame. A position adjusting mechanism for the moving lens described.