JP2001235667A - Lens device and method for assembling it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens device which is easily assembled and by which a flexible printed board is safely guided by forming the width of the inserting part of the flexible printed board formed at the inside of a lens barrel so as to be reduced, and an assembling method thereof. SOLUTION: The inside of the inserting path 62 into which the flexible printed board 60 is inserted is bisected by attaching a partitioning plate 64. In the case of inserting the flexible printed board 60 formed so as to make the width of an end part large into the inserting path 62, the end part whose width is large of the flexible printed board 60 is firstly inserted into the inserting path 62 in a state that the partitioning plate 64 is not attached, and the partitioning plate 64 is attached at the inside of the inserting path 62 after inserting it. Then, the flexible printed board 60 is inserted into the inserting path 62 without having play in a width direction. Also, the inside of the inserting path 62 becomes a complete cylindrical shape. Therefore, even though the flexible printed board 60 is moved, it is not caught and safely guided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens device,
In particular, the present invention relates to a lens device used for a retractable camera having a zoom function and an assembling method thereof.

[0002]

2. Description of the Related Art In recent years, there has been an increase in the number of lens devices used in electronic still cameras and the like in which an actuator is housed in a lens barrel due to a demand for compactness.
In this type of lens device, a unit such as a shutter and a control unit of the camera body are connected by a flexible printed circuit board so that drive control of a shutter and an aperture can be performed from the camera body side. The flexible printed circuit board is provided inside the lens barrel with a loop to withstand movement due to zooming or collapsing, and the loop is attached to the lens barrel in order to prevent the movement from moving. It is passed through the formed insertion passage.

[0003] By the way, a flexible printed circuit board is
Generally, it is formed in a belt shape, but its both ends are formed wider than the intermediate portion for connection. For this reason, the insertion passage formed in the lens barrel is formed to have substantially the same width as the width of the both-end connection portion so that the both-end connection portion of the flexible printed circuit board can be inserted.

However, if the width of the insertion passage is formed to be the same as the width of the connection portion at both ends of the flexible printed circuit board, the inserted flexible printed circuit board has play in the width direction, and a runaway occurs as the loop moves. There is a disadvantage that it will.

In order to prevent this, as shown in FIG. 14, a partition 3 having a predetermined height is conventionally provided in an insertion passage 2 provided in a lens barrel 1, and the partition 3 is used to form a flexible printed circuit board. The movement in the width direction was restricted. That is, a partition 3 is formed in the insertion passage 2 while leaving a gap 4 at the upper portion through which both ends of the flexible printed circuit board can be inserted.
The flexible printed circuit board that has been inserted is restricted by the partition 3 from moving in the width direction.

[0006] Alternatively, instead of preventing the flexible printed circuit board from running out through the insertion path as described above,
As disclosed in Japanese Utility Model Publication No. 4-23232,
A guide mechanism for the flexible printed circuit board is separately provided, and the guide mechanism prevents the flexible printed circuit board from running out.

[0007]

However, in the method of restricting the movement of the flexible printed circuit board in the width direction by forming a screen in the insertion passage, when the loop of the flexible printed circuit board moves, the loop is formed above the screen. There has been a problem that the flexible printed circuit board is damaged by being caught or a loop being caught in the gap. In addition, both ends must be passed through a narrow gap, and the assembling work is extremely troublesome.

Further, the method of separately providing a guide mechanism for the flexible printed circuit board has a drawback that the lens device becomes large.

The present invention has been made in view of such circumstances, and has as its object to provide a lens device which can be easily assembled and can safely guide a flexible printed circuit board, and a method of assembling the same.

[0010]

In order to achieve the above object, the present invention provides a lens apparatus having a flexible printed circuit board disposed in a lens barrel, wherein the flexible printed circuit board is inserted into the lens barrel. A lens device is provided, wherein a passage is formed, and the width of the inner peripheral portion of the insertion passage is reduced.

Further, in order to achieve the above object, the present invention is characterized in that a partition plate is attached to an inner peripheral portion of the insertion passage and the width thereof is reduced. A lens device is provided.

According to another aspect of the present invention, there is provided a method of assembling a lens device in which a flexible printed circuit board is disposed in a lens barrel, wherein the flexible printed circuit board is inserted into an insertion passage formed in the lens barrel. A method of assembling a lens device, comprising: inserting a partition plate in an insertion passage according to the width of an insertion portion of a flexible printed board after the insertion.

According to the present invention, the insertion path of the flexible printed circuit board is formed in the lens barrel. A partition plate is attached to the inner peripheral portion of the insertion passage so that the width thereof can be reduced. This allows
For example, when a flexible printed circuit board having both ends formed wide is inserted into the insertion passage, the insertion can be performed as follows. That is, first, one wide portion of the flexible printed circuit board is inserted into the insertion passage without the partition plate attached. Next, a partition plate is attached to the insertion passage according to the width of the inserted flexible printed circuit board.
Thereby, the flexible printed circuit board can be inserted into the insertion passage without having play in the width direction. Further, since no gap is formed in the upper part of the partition plate as in the related art, even if the flexible printed circuit board is moved, the flexible printed circuit board can be safely guided without being caught. Furthermore, when the wide portion is inserted, the partition can be inserted with the partition plate removed, so that the insertion can be performed easily and the lens device can be assembled in a short time.

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of a lens device and a method for assembling the same according to the present invention will be described below in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view showing an external configuration of an electronic still camera to which a lens device according to the present invention is applied.

As shown in FIG. 1, the electronic still camera 1 has a camera body formed in a rectangular box shape.
A lens device 2, a finder window 3, a strobe light control sensor 4, a self-timer lamp 5, and the like are provided on a front portion thereof. In addition, a pop-up strobe 6, a release switch 7 and the like are provided on an upper surface thereof, and a finder eyepiece, a liquid crystal display panel, operation keys, and the like (not shown) are provided on a rear surface thereof. The electronic still camera 1 is a retractable type, and the lens device 2 is used only when used.
The lens barrel extends from the camera body and projects from the front of the camera body.

FIG. 2 is an exploded perspective view of the lens device 2 applied to the electronic still camera 1 described above. Also, FIG.
FIG. 5 is a side sectional view of a lens device 2 applied to the electronic still camera 1 described above. FIG. 3 shows a state in which the lens device 2 is in the retracted position, and FIG.
5 and FIG. 5 show a state where the lens device 2 is in the tele position and a state where the lens device 2 is in the wide position, respectively.

As shown in FIGS. 2 to 5, the lens device 2 includes a first lens 11, a second lens 12, a first lens barrel 13, a second lens barrel 14, a moving barrel 15, a fixed barrel 16, a rotating barrel 16. It comprises a cylinder 17 and an aperture shutter unit 18.

The rotary cylinder 17 has a gear portion 17a on its outer peripheral surface.
Are formed. The drive of the zoom motor 19 is transmitted to the gear portion 17a. The rotation cylinder 17 is rotated while being in contact with the outer periphery of the fixed cylinder 16 by transmitting the drive of the zoom motor 19 to the gear portion 17a.

In the lens device 2, when the rotary cylinder 17 rotates in the "storage rotation range" from the "initial position" to the "intermediate position", the state changes from the retracted position shown in FIG.
The state is changed to the tele position shown in FIG. Also, the rotating cylinder 17
Is rotated in the "magnification rotation range" from the "intermediate position" to the "end position", so that the state is changed from the tele position shown in FIG. 4 to the wide position shown in FIG.

A second lens barrel 1 is provided on the inner peripheral surface of the rotary barrel 17.
A cam unit 21 for the second lens for moving the lens 4 in the direction of the optical axis 20 and a straight guide groove 22 for the moving cylinder for guiding the moving cylinder 15 in the direction of the optical axis 20 are formed. The second lens cam unit 21 and the moving cylinder straight guide groove 22 are formed at three divided positions around the optical axis 20.

The fixed barrel 16 has a second lens barrel 1 on its peripheral surface.
A second lens straight guide opening 23 for guiding the lens 4 in the direction of the optical axis 20 and a cam 24 for the moving cylinder for moving the moving cylinder 15 in the direction of the optical axis 20 are formed. . The second lens rectilinear guide opening 23 and the moving barrel cam 24 are formed at three divided positions around the optical axis 20.

The movable barrel 15 is provided with a movable barrel cam follower 25 on its outer peripheral surface. The movable cylinder cam follower 25 is provided at three divided positions around the optical axis 20. The movable cylinder cam 24 formed on the fixed cylinder 16 and the movable cylinder linear guide groove 22 formed on the rotary cylinder 17. And is engaged with. When the rotating barrel 17 rotates by the action of the moving barrel cam 24 and the moving barrel straight guide groove 22, the moving barrel 15 moves in the direction of the optical axis 20 while rotating with respect to the fixed barrel 16.

The movable barrel 15 is provided with a first lens cam 26 for moving the first lens barrel 13 in the direction of the optical axis 20 on the inner peripheral surface thereof. The first lens cam 26 is provided at three divided positions around the optical axis 20.

The first lens barrel 13 has a straight guide groove 27 formed on the inner peripheral surface thereof. The rectilinear guide groove 27 has a rectilinear guide protrusion 30 formed on the second lens barrel 14.
Are engaged.

The first lens barrel 13 is provided with a first lens cam follower 28 on its outer peripheral surface.
The first lens cam follower 28 is provided at three divided positions around the optical axis 20, and is engaged with the first lens cam 26 formed on the inner peripheral surface of the movable barrel 15. The first lens cam 26 and a second lens barrel 14 described later
When the movable barrel 15 is rotated by the action of the straight traveling guide, the first lens barrel 13 moves the optical axis 2 with respect to the movable barrel 15.
It moves straight in the direction of 0.

The first lens 11 is held at the inner periphery of the distal end of the first lens barrel 13 and moves together with the first lens barrel 13.

The second lens barrel 14 is provided with a second lens cam follower unit 29 on the outer peripheral surface thereof. The cam follower unit 29 for the second lens is
, And is engaged with the second lens cam unit 21 and the second lens straight guide opening 23. When the rotary barrel 17 rotates by the action of the second lens cam unit 21 and the second lens straight guide opening 23, the second lens barrel 14 moves straight in the direction of the optical axis 20 with respect to the fixed barrel 16. Move.

A pair of springs 37 are mounted on the second lens barrel 14 between the second lens barrel 14 and the fixed barrel 16. The spring 37 is provided at two divided positions around the optical axis 20 and urges the second lens barrel 14 toward the image forming surface.

An arm 38 is integrally formed at the front end of the second lens barrel 14. This arm 38
Are formed at predetermined intervals at two locations on the outer periphery of the second lens barrel 14, and have a narrow width and extend toward the subject side from the front end of the second lens barrel 14.

A linear guide projection 30 is integrally formed on the outer periphery of the distal end of the arm 38. The rectilinear guide projection 30 is engaged with a rectilinear guide groove 27 formed on the inner peripheral surface of the first lens barrel 13, and has side wall surfaces 30 a, 3 a
Ob is in contact with inner wall surfaces 27a and 27b of the linear guide groove 27. The first lens barrel 13 is guided linearly in the direction of the optical axis 20 with respect to the second lens barrel 14 by the action of the straight guide projection 30 and the straight guide groove 27.

Here, the second lens barrel 14 is formed by a mold using an elastic material such as a plastic material. Each of the arms 38 is formed such that its distal end extends outward in the radial direction. Therefore, when the rectilinear guide protrusion 30 is engaged with the rectilinear guide groove 27, the bottom surface 27c of the rectilinear guide groove 27
0c is pressed outward in the radial direction. As a result, the first lens barrel 13 is supported so as not to be inclined with respect to the second lens barrel 14.

By the way, as described above, the straight guide projection 3
0 slides while pressing the bottom surface 27c of the rectilinear guide groove 27 in the radial direction, but when the sliding portion is brought into surface contact and slid, the relative movement between the first lens barrel 13 and the second lens barrel 14 is reduced. Load may be applied to the temporary movement and rotation of the rotary cylinder 17, and the zooming speed may be reduced.

In order to reduce the sliding resistance, the outer peripheral surface 30c of the straight guide projection 30 is formed in a hemispherical shape. That is, a cross section along the direction of the optical axis 20;
The cross section in the direction crossing the optical axis 20 is formed in an arc shape. Thereby, the first lens barrel 13 and the second
The relative movement with respect to the lens barrel 14 and the rotation of the rotary barrel 17 can be performed smoothly.

The second lens 12 is provided movably in the direction of the optical axis 20 in the second lens barrel 14. Specifically, as shown in FIGS. 3 to 5, the second lens 12
It is held by a second lens frame 33 provided in the lens barrel 14. The second lens frame 33 is movably supported in the second lens barrel 14 along the optical axis 20 by the feed screw 31 and the guide rod 32. Feed screw 31
Is connected to the output shaft of the focus motor 34,
It is rotated by being driven by the focus motor 34. When the feed screw 32 rotates, the second lens 12 moves the optical axis 20 according to the lead.
Move in the direction of.

The movement of the second lens 12 is caused by the second movement.
The process is performed between the “origin position” closest to the image plane 10 a with respect to the lens barrel 14 and a position farther from the origin position toward the subject. Then, at the time of zooming, the second lens 12 is located at the origin position.

The aperture shutter unit 18 is attached to the second lens frame 33. The aperture shutter unit 18 includes an aperture and a shutter (not shown), and operates by being driven by an aperture motor and a shutter motor (not shown), respectively.

The aperture shutter unit 18 is of a program type and operates based on an operation signal output from a control unit of the camera body. Then, the operation signal is transmitted from the camera body side to the aperture shutter unit 18 via the flexible printed circuit board 60 disposed in the second lens barrel 14.

The flexible printed circuit board 60 is shown in FIGS.
As shown in FIG. 5, the second lens barrel 14 is disposed along the inner peripheral surface of the second lens barrel 14 in parallel with the optical axis 20, and one end thereof is connected to the aperture shutter unit 18. On the other hand, the other end is connected and fixed to a substrate provided on the camera body, whereby the aperture shutter unit 18 and the control unit of the camera body are electrically connected.

The flexible printed circuit board 60
Is provided with a loop 60d so as to withstand movement due to zooming, collapsing, and the like, and is passed through the insertion passage 62 in order to prevent a runaway accompanying the movement.

The insertion passage 62 is, as shown in FIGS.
It is formed integrally with the inner peripheral portion of the second lens barrel 14 along the direction of the optical axis 20. As shown in FIG. 6, the shape of the second lens barrel 14 is substantially rectangular in cross section by using a part of the inner peripheral surface of the second lens barrel 14. A partition plate 64 is detachably mounted in the insertion passage 62, and by attaching the partition plate 64, the optical axis 2
It is divided into two along the 0 direction.

Here, the partition plate 64 is formed in a rectangular plate shape, and the upper surface 62a and the lower surface 62b of the insertion passage 62 are formed.
The upper and lower edges of the partition plate insertion grooves 65 are fitted into the insertion passage 62.

Incidentally, the flexible printed circuit board 60
When assembling the lens device 2, one end thereof is previously set to the aperture shutter unit 1 as shown in FIG.
8 and is integrated with the aperture shutter unit 18. At the time of assembling the lens device 2, after attaching the aperture shutter unit 18 to the second lens frame 33, the other end is passed through the insertion passage 62, and the portion in contact with the fixed barrel 16 is fixed, and provided on the camera body. And fixed to the board.

Here, as shown in FIG. 12, the flexible printed circuit board 60 is formed in a strip shape, but its width is not constant, and the connecting portions 60a at both ends (only one side is shown in FIG. 12) are connected to the equipment. It is formed wider than the width of the intermediate portion 60b for connection. Therefore, as shown in FIG. 13, the insertion path 62 is connected to the connecting portion 60a of the flexible printed circuit board 60.
There in order to be able to insert, and is formed in substantially the same or slightly larger as the width d ₁ of the width D ₁ is connected portion 60a.

On the other hand, as described above, the width D ₁ of the insertion passage 62 is changed to the width d of the connection portion 60 a of the flexible printed circuit board 60.
_If it is formed substantially the same as ₁ , there is a problem that the intermediate portion 60b inserted into the insertion passage 62 has play.

Therefore, after the connecting portion a of the flexible printed circuit board 60 is inserted into the insertion passage 62, a partition plate 64 is attached to the insertion passage 62, and the horizontal width of the insertion passage 62 is reduced by the partition plate 64. As a result, the intermediate portion 60b of the flexible printed circuit board 60 inserted into the insertion passage 62 has no play in the width direction, and can move stably.

In order to eliminate the play of the intermediate portion 60b, the partition plate 64 is formed between the partition plate 64 and the inner wall surface of the insertion passage 62 as shown in FIG. width D ₂ is attached to a position such that substantially the same width as the lateral width d ₂ of the intermediate portion 60b of the flexible printed circuit board 60.

FIG. 7 is an exploded view showing the structure of the moving barrel cam 24 provided on the fixed barrel 16. As shown in the figure, the moving cylinder cam 24 includes a storage guiding section 40 and a moving cylinder movement preventing section 41.

The storage guide section 40 is a range in which the movable cylinder cam follower 25 slides due to the rotation of the rotary cylinder 17 in the “storage rotation range”. The storage guide section 40 includes the fixed cylinder 1
"Retreat position" in which the movable cylinder 15 is retracted inside with respect to 6.
And the optical axis 2 between the “projected position” extended to the subject side.
Move in the direction of 0. When the movable barrel 15 is in the retracted position, the lens device 2 is in the retracted position.

The moving cylinder movement preventing section 41 is a range in which the moving cylinder cam follower 25 slides by the rotation of the rotating cylinder 17 in the “magnification rotation range”, and the rotation of the moving cylinder 15 around the optical axis 20. Is formed in an arc shape along the direction around the optical axis 20 so as to allow the movement of the movable cylinder 15 in the direction of the optical axis 20. That is, the movable barrel 15 is maintained at the “projected position” while the lens apparatus 2 is zoomed between the telephoto position and the wide position.

FIG. 8 is an exploded view showing the structure of the first lens cam 26 provided in the movable barrel 15. As shown in the figure, the first lens cam 26 is provided in the storage preparation guide section 4.
2. First lens movement prevention unit 43 and zooming guide unit 44
It is composed of

The storage preparation guide section 42 moves the rotary cylinder 17 up to the “rotational position A” between the “initial position” and the “intermediate position”.
In the rotation range of the movable barrel 15 corresponding to the rotation range, the first lens cam follower 28 slides. The storage preparation guide section 42 is provided with the first lens barrel 13
Is moved between a "retreat position" in which the inside is retracted and a "storage preparation position" slightly protruding toward the subject. When the first lens barrel 13 is at the "retreat position", the lens device 2 is in the retracted position.

The first lens movement preventing section 43 is
7 in the rotation range of the movable barrel 15 according to the “storage rotation range”.
This is the range in which the lens cam follower 28 slides. The first lens movement prevention unit 43 allows the first lens barrel 13 to move in the direction around the optical axis 20 so as not to move in the direction of the optical axis 20 from the “storage preparation position” while allowing the rotation of the movable barrel 15. Are formed along an arc. In other words, the first lens barrel 13 is maintained at the "storage preparation position" until the lens device 2 changes from the retracted position to the telephoto position.
The first lens movement prevention unit 43 is configured to rotate the rotary cylinder 17 in the range from the “rotational position A” to the “intermediate position”.
The lens barrel 13 is maintained at the "storage preparation position".

The variable power guide section 44 is a range in which the first lens cam follower 28 slides in the rotation range of the movable barrel 15 according to the “variable rotation range” of the rotary barrel 17. The zooming guide section 44 is used to change the focal length of the first lens barrel 13.
Is moved in the direction of the optical axis 20. Note that the above-described storage preparation guide section 42 is not always necessary, and the storage preparation guide section 42 is omitted, and the entire rotation range of the movable barrel 15 according to the “storage rotation range” of the rotary barrel 17 is used as the first lens movement prevention section 43. Is also good.

FIG. 9 is a perspective view showing a configuration of a main part of the second lens cam follower unit 29. As shown in FIG. As shown in the figure, the second lens cam follower unit 29 is composed of two main cam followers 46 and a sub cam follower 47 which are arranged at predetermined intervals in the direction of the optical axis 20.

The main cam follower 46 and the sub cam follower 47
Includes the first engaging portions 48 and 49 and the second engaging portion 5 respectively.
0 and 51 are provided. First engagement portions 48, 49
Have the same diameter, and engage with the second lens straight guide opening 23, respectively. Second engagement portions 50, 5
Numerals 1 each have a tapered frustoconical cross section (truncated cone), and the diameter of the main cam follower 46 is larger than that of the sub cam follower 47 on the object side. Note that one of the first engagement portions 48 and 49 only needs to be engaged with the second lens rectilinear guide opening 23.
Either one of the first engagement portions 48 and 49 may be thin.

FIG. 10 shows the cam unit 21 for the second lens.
FIG. 2 is a development view showing a configuration of a main part of FIG. As shown in the drawing, the second lens cam unit 21 includes a sub cam groove 54 and a main cam groove 55.

The second engaging portion 51 of the sub cam follower 47 enters the sub cam groove 54, and the second engaging portion 50 of the main cam follower 46 enters the main cam groove 55. The auxiliary cam groove 54 and the main cam groove 55 are provided with zooming guides 56 and 57 for moving the second lens 12 in the direction of the optical axis 20 in order to change the focal length, Storage guide 5 for moving second lens 12 from 57 to “storage position”
8, 59.

When the rotary barrel 17 rotates toward the "end position" within the "variable rotation range", the second lens barrel 14 faces the imaging surface. It is a curved trajectory that moves in the “retracting direction”.

The storage guides 58, 59 are linear
a, 59a and bent portions 58b, 59b.

When the rotary barrel 17 is rotated toward the "intermediate position" in the range from the "initial position" to the "rotational position B", the straight portions 58a and 59a move the second lens barrel 14 toward the subject. It is a linear trajectory that guides in the “extending direction” that is extended toward the vehicle.

On the other hand, the bent portions 58b and 59b form an image of the second lens barrel 14 when the rotary barrel 17 is rotated toward the "intermediate position" in the range from the "rotational position B" to the "intermediate position". It is a curved locus that changes the moving direction of the second lens barrel 14 so as to move in the “retracting direction” in which it is retracted toward the surface side.

By the way, the movement trajectory of the main cam follower 46 and the sub cam follower 47 at the bent portions 58b and 59b has a curved shape with the convex facing the subject. The radius of curvature of the locus of movement of the main cam follower 46 that passes through the imaging surface side of the main cam follower 46 is smaller than the radius of curvature of the sub cam follower 47 by the amount that the diameter of the sub cam follower 47 is smaller than the main cam follower 46. Is smaller than the radius of curvature of the movement trajectory that passes through the most image forming surface side.

The sub-cam groove 54 has the same width as the second engaging portion 51 of the sub-cam follower 47 in the range of the bent portion 58b, and the second engaging portion 51 of the sub-cam follower 47 in the range other than the bent portion 58b. The width is formed wider than the diameter of the portion 51. Therefore, the sub cam groove 54 engages with the second engaging portion 51 of the sub cam follower 47 in the range of the bent portion 58b, and does not engage in the range other than the bent portion 58b.

The main cam groove 55 is formed to have a width that engages with the second engaging portion 50 of the main cam follower 46 in a range other than the bent portion 59b, and the second engaging portion 50 of the main cam follower 46 is formed in the range of the bent portion 59b. It is formed wider than the diameter of the joint 50. For this reason, the second engagement portion 50 of the main cam follower 46
Are engaged in a range other than the bent portion 59b of the main cam groove 55. As described above, since the auxiliary cam grooves 58b having a large radius of curvature are used in the bent portions 58b and 59b that change the moving direction of the second lens barrel 14, the second lens barrel 14 can be moved smoothly.

It is to be noted that the second engaging portions 51 and 52 overlap with each other in a slight range of the boundary between the bent portions 58b and 59b and the zooming guides 56 and 57 or the storing guides 58a and 59a. An engaging portion may be provided.

Next, the operation of the lens device 2 configured as described above will be described.

When the lens device 2 is in the retracted position, FIG.
As shown in (1), the movable barrel 15 and the first lens barrel 13 are housed inside the fixed barrel 16, respectively.

By driving the zoom motor 19, the rotary cylinder 1
7 is rotated from the “initial position” to the “end position”, the rotation of the rotary cylinder 17 is
Is transmitted to the movable cylinder cam follower 25 via the Thereby, the movable barrel 15 rotates in conjunction with the rotating barrel 17.

The movable cylinder 15 includes a movable cylinder cam follower 25 provided on the outer periphery thereof, a movable cylinder linear guide groove 22 formed in the rotary cylinder 17, and a movable cylinder cam 24 formed in the fixed cylinder 16. When rotated, it moves in the direction of the optical axis 20 with the rotation.

On the other hand, the first lens barrel 13 has a first lens cam follower 28 provided on the outer peripheral portion thereof.
And the linear guide groove 27 formed on the inner peripheral surface thereof is engaged with the linear guide protrusion 30 formed on the second lens barrel 14. When the moving cylinder 15 rotates, the moving cylinder 16
With respect to the optical axis 20.

Further, in the second lens barrel 14, since the main cam follower 46 provided on the outer peripheral portion is engaged with the second lens rectilinear guide opening 23 and the main cam groove 55, the rotary barrel 17 rotates. Then, in conjunction with this, it moves straight in the direction of the optical axis 20.

FIG. 11 is an explanatory diagram showing the movement trajectories of the first lens barrel 13, the second lens barrel 14, the movable barrel 15, and the like.

In the figure, the thick line (E) represents the movement locus of the first lens barrel 13, and the thick line (F) represents the movement locus of the second lens barrel 14. In addition, thin line (G)
Represents the movement locus of the first lens barrel 13 with respect to the moving barrel 15, and the thin line (J) represents the movement locus of the moving barrel 15.

When the lens device 2 is in the retracted position,
The second lens barrel 14 is located at the “storage position C” closest to the image plane, and the first lens barrel 13 is
Is located at the “storage position D” close to.

While the rotating barrel 17 rotates from the “initial position” to the “rotating position A”, the first lens cam follower 28 provided on the outer peripheral portion of the first lens barrel 13 stores the first lens cam 26. The preparation guide 42 is slid. For this reason, the first lens barrel 13 moves from the “retreat position H” of the thin line (G) to the “storage preparation position I” while the rotary barrel 17 rotates from the “initial position” to the “rotation position A”. It is paid out.

On the other hand, during this time, the movable cylinder cam follower 25 provided on the outer peripheral portion of the movable cylinder 15 slides on the storage guide portion 40 of the movable cylinder cam 24. Therefore, the moving cylinder 15
While the rotary cylinder 17 rotates from the “initial position” to the “rotational position A”, it is fed from the “retreat position K” of the thin line (J) toward the “projection position L”.

Here, the first lens barrel 13 is provided with a moving barrel 15
The first lens barrel 13 moves in the direction of the optical axis 20 by the extension of the moving barrel 15 plus the extension of the first lens barrel 13 to the "storage preparation position I". To the position M of the thick line (E).

While the rotary barrel 17 rotates from the “rotational position A” to the “intermediate position”, the first lens cam follower 28 provided in the first lens barrel 13
Of the first lens movement blocking portion 43 of the first lens. For this reason,
The first lens barrel 13 is prevented from moving in the direction of the optical axis 20 with respect to the movable barrel 16. Accordingly, during this time, the first lens barrel 13 moves together with the movable barrel 15.

While the rotary barrel 17 rotates from the “initial position” to the “rotational position B”, the second lens barrel 14 keeps the main cam groove 5
7 is moved by a main cam follower 46 which engages.

On the other hand, when the rotary cylinder 17 rotates to the “rotational position B”, the second lens cam follower unit 29
It enters the bent portions 58b and 59b of the lens cam unit 21 which change the moving direction of the second lens barrel 14.
When the second lens cam follower unit 29 enters the bent portions 58b and 59b, the engagement between the main cam groove 55 and the main cam follower 46 is released, and the sub cam groove 54 and the sub cam follower 47 are engaged. For this reason, at the bent portions 58 b and 59 b of the second lens cam unit 21, the second cam follower 47 engaging with the sub
The lens barrel 14 is moved.

Here, the auxiliary cam groove 54 has a bent portion 68
At b, the inner radius of the opposing wall surface has a larger radius of curvature than the main cam groove 55. Therefore, the bent portion 58
In b and 59b, the second lens barrel 14 is smoothly engaged because it is engaged with the bent portion 58b of the sub cam groove 64 having a large radius of curvature as compared with engaging with the bent portion 59b of the main cam groove 55 having a small radius of curvature. , And the rotational load of the rotary cylinder 17 can be reduced.

When the rotary cylinder 17 rotates to the "intermediate position",
As shown in FIG. 4, the lens device 2 is in the tele position. In this state, the movable barrel 15 is moved to the “projecting position L” with respect to the fixed barrel 16.

While the rotary barrel 17 rotates from the "rotational position A" to the "rotational position B", the first lens barrel 13 does not move in the direction of the optical axis 20 with respect to the movable barrel 15; (G) is located at “storage preparation position I”. Accordingly, during this time, the first lens barrel 13 is moved in the direction of the optical axis 20 by the movement of the moving barrel 15 and moves to the position O in the thick line (E).

When the lens device 2 is in the telephoto position, the engagement between the sub cam follower 47 and the sub cam groove 64 is released, and the main cam follower 46 engages with the main cam groove 55 instead. The engagement position is the bent portion 59b.
The second lens barrel 14 is located at the position N of the thick line (F).

As described above, the “storage rotation range” of the rotary cylinder 17
During the rotation of the first lens 11, the first lens 11
The movement of the lens barrel 13 is stopped, and the lens barrel 13 is moved in the direction of the optical axis 20 only by the movement of the movable barrel 15 with respect to the fixed barrel 16.

After the lens device 2 is in the telephoto position, the rotary barrel 17 is rotated in the "magnification rotation range".

When the rotary cylinder 17 rotates in the “magnification rotation range”, the movable cylinder cam follower 25 provided on the outer peripheral portion of the movable cylinder 15 slides the movable cylinder movement blocking portion 41 of the movable cylinder cam 24. Move. For this reason, the movable cylinder 15 is maintained at the “projecting position L”.

When the rotary barrel 17 rotates in the “magnification rotation range”, the first lens cam follower 28 provided on the outer peripheral portion of the first lens barrel 13 changes the magnification of the first lens cam 26. The guide 44 is slid. Therefore, the first lens barrel 13 is moved in the direction of the optical axis 20 with respect to the movable barrel 15 by an amount corresponding to the displacement of the zooming guide portion 44 in the direction of the optical axis 20.

Therefore, the "variable rotation range" of the rotary cylinder 17
During the rotation of the first lens 11, the movement of the movable barrel 15 with respect to the fixed barrel 16 is stopped, and the first lens 11 is moved in the direction of the optical axis 20 only by the movement of the first lens barrel 13 with respect to the movable barrel 15.

When the rotary barrel 17 rotates in the “magnification rotation range”, the main cam follower 46 provided on the second lens barrel 14 slides on the zoom guide 57 in the main cam groove 55. . For this reason, the second lens barrel 14 is moved in accordance with the displacement of the zooming guide portion 57 in the direction of the optical axis 20.

The first lens barrel 13 and the second lens barrel 14 are different from each other by the optical axis 2 so that their distances are different during zooming.
It is moved in the direction of 0. During this time, the second lens barrel 14
By the bias of the spring 37 in the direction of the optical axis 20, the play between the second lens cam follower unit 29 and the second lens cam unit 21 is absorbed, and the inclination with respect to the fixed cylinder 16 is also corrected. And the first lens barrel 13 is
Since the rotation about the optical axis is stopped by the rectilinear guide projection 30 of the second lens barrel 14 and pressed in the radial direction, the optical axis of the first lens 11 The inclination with respect to the optical axis can be suppressed as much as possible.

Next, a method of assembling the lens device 2 configured as described above will be described.

First, the aperture shutter unit 18 is attached to the second lens frame 33 assembled to the second lens barrel 14. The aperture shutter unit 18 includes:
As shown in FIG. 12, one end of the flexible printed circuit board 60 is connected in advance.

Next, as shown in FIGS. 13A and 13B, the connecting portion 60a at the tip of the flexible printed circuit board 60 attached to the aperture shutter unit 18 is connected to the second
It passes through an insertion passage 62 formed in the lens barrel 14. On this occasion,
Since the insertion passage 62 is formed with a width substantially equal to the width of the connection portion 60 of the flexible printed circuit board 60,
The connecting portion 60a can be easily inserted.

Next, as shown in FIG. 9B, the partition plate 6 is inserted into the insertion passage 62 through which the flexible printed circuit board 60 is inserted.
4 is attached. That is, the partition plate 62 is fitted into the insertion grooves 65 formed in the insertion passage 62. As a result, the inside of the insertion passage 62 is divided into two, and the width thereof is reduced. As a result, there is no play in the width direction of the intermediate portion 60b of the flexible printed circuit board 60 inserted into the insertion passage 62.

Next, the second lens barrel 14 is moved to the first lens barrel 1
3 is fitted into the inner peripheral portion. At this time, the first lens barrel 13 is arranged such that the straight guide projection 30 provided on the arm 38 of the second lens barrel 14 engages with the straight guide groove 27 formed on the inner peripheral surface of the first lens barrel 13. Into the inner peripheral portion of the second lens barrel 14.

Next, as shown in FIG. 2, the flexible printed circuit board 60 inserted into the insertion path 62 is
Once bent at a predetermined position to form a loop 60d,
The bent portion 60c is inserted again into the insertion passage 62.

Next, the first lens barrel 13 is fitted into the inner peripheral part of the movable barrel 15. At this time, the first lens cam follower 28 formed on the outer peripheral portion of the first lens barrel 13
The first lens barrel 13 is fitted into the movable barrel 15 so as to engage with the first lens cam 26 formed on the inner peripheral portion of the lens barrel 5.

Next, the movable barrel 15 is fitted into the inner periphery of the fixed barrel 16. At this time, the movable cylinder 15 is fixed to the fixed cylinder 16 so that the movable cylinder cam follower 25 formed on the outer periphery of the movable cylinder 15 is engaged with the movable cylinder cam 24 formed on the fixed cylinder 16.
And the movable barrel 15 is fixed such that the second lens cam follower unit 29 formed in the second lens barrel 14 engages with the second lens straight guide opening 23 formed in the fixed barrel 16. Fit into tube 16.

Next, the fixed cylinder 16 is fitted into the inner periphery of the rotary cylinder 17. At this time, the second lens barrel 14
The fixed barrel 16 is fitted into the rotating barrel 17 so that the lens cam follower unit 29 engages with the second lens cam unit 21 formed on the rotating barrel 17.

Next, a portion of the flexible printed circuit board 60 inserted into the insertion passage 62 and in contact with the fixed cylinder 16 is fixed to the fixed cylinder 16. Then, the connection portion 60a at the tip is connected and fixed to the substrate of the camera body.

As described above, the lens device 2 is assembled.
As described above, according to the lens device 2 of the present embodiment, the width of the insertion passage 62 through which the flexible printed circuit board 60 passes can be reduced by the partition plate 64 at the inner peripheral portion. Even if it is formed wider than the intermediate portion 60b, it can be smoothly and smoothly inserted into the insertion passage 62. Thereby, the lens device 2 can be easily assembled, and the productivity is improved.

The insertion passage 62 into which the partition plate 64 is inserted.
Is divided into two parts to form a complete cylinder. For this reason,
A gap is formed in the upper part of the partition plate 64 unlike the related art, and the flexible printed board 60 is not caught in the gap and is not damaged.

In this embodiment, an example has been described in which only one partition plate 64 is attached to the insertion passage 62, but a plurality of partition plates 64 may be attached. Thus, a plurality of flexible printed circuit board insertion paths can be formed in the insertion path 62.

Further, in the present embodiment, the partition plate 64 is attached at only one location in the insertion passage 62, but may be attached at a plurality of locations. Thus, the width of the insertion passage 62 can be adjusted.

Further, in the present embodiment, the width of the inside of the insertion passage 62 is reduced by attaching the partition plate 64 in the insertion passage 62, but the inside of the insertion passage 62 is a rod-shaped member. The width may be reduced by filling with.

Further, in the present embodiment, an example has been described in which the present invention is applied to the insertion path for a flexible printed circuit board connected to an aperture shutter unit. However, the insertion path for a flexible printed circuit board connected to another device is described. The same can be applied to.

In the above-described embodiment, the second lens barrel 14 is arranged inside the first lens barrel 13. Grooves may be provided, and the linear guide projections of the second lens barrel 14 may be engaged with these linear guide grooves from outside.

In the above-described embodiment, the first lens barrel 13 is provided with the straight guide groove 27 and the second lens barrel 14 is provided with the straight guide projection 30. A guide protrusion may be provided, and a straight guide groove may be provided in the second lens barrel 14.

Further, in the above embodiment, the zoom lens has a two-group configuration. However, the present invention is not limited to this, and may have a configuration of three or more groups.

The present invention can be applied not only to a zoom lens camera, but also to a bifocal camera that switches between a telephoto position, a wide position, and a retracted position, for example.

Further, in the above embodiment, the tele position is set between the retracted position and the wide position, but it is also possible to set the wide position between the retracted position and the tele position. In this case, the boundary between the variable power guide and the storage guide is the wide position.

In the above embodiment, the straight guide groove 27, the arm 38 and the straight guide projection 30 are provided at two positions around the optical axis. However, the straight guide groove 27, the arm 38 and the straight Each of the guide protrusions 30 has a length of 3 around the optical axis.
It may be provided at the division position.

[0115]

As described above, according to the present invention, the width of the insertion passage through which the flexible printed circuit board is inserted can be freely reduced. Thus, for example, even if a flexible printed circuit board having both ends formed wider is used, if the width of the insertion path is reduced after insertion, the flexible printed circuit board can be inserted into the insertion path without play in the width direction. Can be penetrated. In addition, since the width is reduced after the insertion, the insertion operation is simplified, and the assembly of the lens device is simplified.

Further, even when the width of the insertion passage is reduced by the partition plate, the inside of the insertion passage becomes completely cylindrical, so that even if the flexible printed circuit board is moved, it can be safely guided without being caught. Furthermore, when the wide portion is inserted, the partition can be inserted with the partition plate removed, so that the insertion can be performed easily and the lens device can be assembled in a short time.

[Brief description of the drawings]

FIG. 1 is a perspective view showing an external configuration of an electronic still camera.

FIG. 2 is an exploded perspective view of the lens device.

FIG. 3 is a sectional view showing the lens device in a retracted position.

FIG. 4 is a sectional view showing the lens device in a telephoto position;

FIG. 5 is a sectional view showing the lens device in a wide position.

FIG. 6 is a sectional view of the first lens barrel and the second lens barrel cut along a direction intersecting the optical axis;

FIG. 7 is a development view showing a cam for a movable cylinder provided on a fixed cylinder.

FIG. 8 is a developed view showing a first lens cam provided on the movable barrel.

FIG. 9 is a perspective view showing a configuration of a main part of a second lens cam follower unit.

FIG. 10 is a developed view showing a configuration of a main part of the second lens cam unit.

FIG. 11 is an explanatory diagram showing a movement trajectory of a first lens barrel, a second lens barrel, a movable barrel, and the like.

FIG. 12 is a perspective view showing a configuration of a flexible printed circuit board having one end connected to an aperture shutter unit.

FIG. 13 is a perspective view illustrating a method of assembling the lens device.

FIG. 14 is a front view showing a configuration of a conventional insertion passage.

[Explanation of symbols]

11 first lens, 12 second lens, 13 first lens barrel, 14 second lens barrel, 15 moving barrel, 16 fixed barrel, 17 rotating barrel, 18 aperture shutter unit, 2
2 ... linear guide groove for moving cylinder, 23 ... linear guide closing for second lens, 24 ... cam for moving cylinder, 27 ... linear guide groove
30: straight guide projection, 37: spring, 38: arm, 60
... Flexible printed circuit board, 60a ... Connection part, 60b
... intermediate part, 60c ... bent part, 60d ... loop, 62 ... insertion passage, 64 ... partition plate, 65 ... partition plate insertion groove

Claims (3)

[Claims] 1. A lens device in which a flexible printed circuit board is disposed in a lens barrel, wherein an insertion path of the flexible printed circuit board is formed in the lens barrel, and the insertion path is formed in an inner peripheral portion thereof. A lens device characterized in that the width is formed so as to be reduced. 2. The lens device according to claim 1, wherein a partition plate is attached to an inner peripheral portion of the insertion passage, and a width of the insertion passage is reduced. 3. A method of assembling a lens device in which a flexible printed circuit board is disposed in a lens barrel, wherein the flexible printed circuit board is inserted into an insertion passage formed in the lens barrel, and then the flexible printed circuit board insertion section is inserted. A method of assembling a lens device, comprising: attaching a partition plate in an insertion passage according to the width of the lens device.