JP2011017790A - Lens barrel and camera - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens barrel capable of obtaining good optical performance.SOLUTION: The lens barrel 3 includes: a cylindrical first lens holding part 10 holding a first lens group L1; a cylindrical second lens holding part 50 holding a second lens group L2; a cam cylinder 40 wherein an inside cam groove 42 driving one of the first lens holding part 10 and the second lens holding part 50 is formed on the inner circumference surface while an outside cam groove 41 driving the other of the first lens holding part 10 and the second lens holding part 50 is formed on the outer circumference surface; a first straight guide 22 regulating rotation around the optical axis of the first lens holding part 10 or an axis parallel to the optical axis; and a second straight guide 81 regulating rotation around the optical axis of the second lens holding part 50 or an axis parallel to the optical axis. Relative movement of the second straight guide 81 to the first straight guide 22 is restricted in the circumference direction around the rotation axis of the cam cylinder 40.

Description

  The present invention relates to a lens barrel and a camera.

  There is a lens barrel in which cams are provided on the inner and outer circumferences of a cylindrical surface, the first lens group is moved by the cam on the inner circumferential surface, and the second lens group is moved by the cam on the outer circumferential surface. In such a configuration, conventionally, the rectilinear guide members for guiding the rectilinear movement of the first lens group and the second lens group are separately provided (see, for example, Patent Document 1).

JP 2004-85932 A

  However, when the rectilinear guide member is composed of two parts, accuracy may be reduced due to accumulation or backlash of accuracy errors of each part, and good optical performance may not be obtained.

  An object of the present invention is to provide a lens barrel and a camera that can obtain good optical performance.

  The present invention solves the above problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this.

The invention described in claim 1 is a cylindrical first lens holding portion (10) for holding the first lens group (L1) and a cylindrical second lens holding portion for holding the second lens group (L2). (50) and an inner cam groove (42) for driving one of the first lens holding portion (10) and the second lens holding portion (50) is formed on the inner peripheral surface, and the first lens holding is formed on the outer peripheral surface. A cam cylinder (40) in which an outer cam groove (41) for driving the other of the part (10) and the second lens holding part (50) is formed, and the optical axis or light of the first lens holding part (10). The first rectilinear guide (22) that restricts rotation about an axis parallel to the axis and the optical axis of the second lens holding part (50) or rotation about an axis parallel to the optical axis are restricted. The first straight guide (2 in the circumferential direction around the rotation axis of the cam cylinder (40)) ) Comprise a second rectilinear guide relative movement is restricted (81), a relative, a lens barrel, wherein (3).
The invention described in claim 2 is the lens barrel (3) according to claim 1, wherein the first rectilinear guide (22) and the second rectilinear guide (81) are integrally formed. A lens barrel (3).
The invention according to claim 3 is the lens barrel (3) according to claim 2, wherein the first rectilinear guide (22) and the second rectilinear guide (81) are fixed to each other. This is a lens barrel (3).
The invention according to claim 4 is the lens barrel according to any one of claims 1 to 3, wherein the first rectilinear guide and the second rectilinear guide are one part. This is a featured lens barrel.
The invention according to claim 5 is the lens barrel (3) according to any one of claims 1 to 4, wherein the first rectilinear guide (22) and the second rectilinear guide (81) are arranged. The second rectilinear guide (81) includes a third rectilinear guide (72) that guides the rectilinear guide. The second rectilinear guide (81) extends in parallel with the optical axis direction and guides the frame of the second lens holding portion (50) ( 81), the third rectilinear guide (72) includes a third extending portion (72) that extends parallel to the optical axis direction and guides the second rectilinear guide (81). The lens barrel (3) characterized in that at least a part of the extending part (81) and the third extending part (72) are arranged on the same diameter with the optical axis as the center. It is.
Invention of Claim 6 is a camera (1) provided with the lens-barrel (3) of any one of Claims 1-5.
Note that the configuration described with reference numerals may be modified as appropriate, and at least a part of the configuration may be replaced with another component.

  ADVANTAGE OF THE INVENTION According to this invention, the lens barrel and camera which can obtain favorable optical performance can be provided.

It is a figure which shows notionally the longitudinal cross-section of the camera in a photography standby state. It is AA sectional drawing in FIG. It is BB sectional drawing in FIG. It is a partial cross section perspective view in the tele end of the lens-barrel of a camera. It is a conceptual diagram explaining the expansion-contraction operation state of a lens barrel, (a) shows a retracted state, (b) shows a photographing standby state, and (c) shows a maximum extension state. It is the perspective view which looked at the rectilinear guide cylinder in a lens barrel from the diagonal front side. It is a perspective view of the 2nd group rectilinear guide base which constitutes a rectilinear guide cylinder.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a diagram conceptually showing a longitudinal section of the camera 1 in a shooting standby state. 2 is a cross-sectional view taken along line AA in FIG. 3 is a cross-sectional view taken along the line BB in FIG. FIG. 4 is a partial cross-sectional perspective view at the tele end of the lens barrel 3 of the camera 1. FIGS. 5A and 5B are conceptual diagrams for explaining a telescopic operation state of the lens barrel 3. FIG. 5A is a retracted state, FIG. 5B is a photographing standby state (wide end), and FIG. 5C is a maximum extended state (tele end). ) Respectively.

  Each drawing is provided with an XYZ orthogonal coordinate system for easy explanation and understanding. In this coordinate system, the direction toward the left side as viewed from the photographer at the position of the camera 1 when the photographer shoots a horizontally long image with the optical axis OA being horizontal (hereinafter referred to as a normal position) is defined as the X plus direction. Further, the direction toward the upper side in the normal position is defined as the Y plus direction. Further, the direction toward the subject at the normal position is defined as the Z plus direction. In the following description, unless otherwise specified, movement in a direction parallel to the optical axis OA of the fixed optical system in the photographing optical system is referred to as “straight forward”, and movement around the optical axis OA is referred to as “rotation”. Further, the direction parallel to the optical axis OA of the photographing optical system is referred to as “front-rear”, the subject side is referred to as “front side”, and the other end side is referred to as “back side”.

The camera 1 is a digital camera composed of a body part 2 and a lens barrel 3.
The lens barrel 3 is a so-called collapsible zoom lens that can be immersed in the body portion 2 when not in use, protrude from the body portion 2 when in use, and further change (zoom) the focal length. That is, the lens barrel 3 is retracted and accommodated inside the body portion 2 as shown in FIG. 5A in a non-photographing state where the power is not turned on, and when the power is turned on, the lens barrel 3 is shown in FIG. Thus, it projects to the front side of the body part 2 and enters a photographing standby state. In the configuration of the present embodiment, the shooting standby state is set to the wide end in zooming. The lens barrel 3 extends from the photographing standby state at the wide end to the tele end shown in FIG.
The present invention is not limited to a digital camera, and can be applied to, for example, a still camera using a film.

The body part 2 includes a sensor unit 4 inside the body housing 2A.
The sensor unit 4 includes an image sensor 4A such as a CCD. The sensor unit 4 is fixed to the body housing 2A so that the image pickup surface of the image pickup element 4A is orthogonal to the optical axis OA of the lens barrel 3. The sensor unit 4 converts an image formed on the imaging surface of the imaging element 4A by the lens barrel 3 into an electrical signal and outputs the electrical signal.

  As described above, the lens barrel 3 is a zoom lens having a variable focal length. The lens barrel 3 includes two sets of lens groups (a first lens group L1 and a second lens group L2) that form an imaging optical system in the camera 1. The lens groups L <b> 1 and L <b> 2 form a subject image on the imaging surface of the imaging element 4 </ b> A in the sensor unit 4. The focal length of the lens barrel 3 is changed by the displacement of the lens groups L1 and L2 in the direction of the optical axis OA.

  In the camera 1, the lens group (the first lens group L 1 and the second lens group L 2) included in the lens barrel 3 forms an image of subject image light on the light receiving surface of the image sensor 4 A in the sensor unit 4. By pressing a release button (not shown), the image information of the subject converted into an electric signal by the sensor unit 40 is recorded (photographed) in a storage device (not shown). All the operation control in the camera 10 including the photographing is performed by a control device (not shown).

Next, the lens barrel 3 will be described in detail with reference to FIGS. 6 and 7 in addition to FIGS. 1 to 5 described above.
FIG. 6 is a perspective view of the rectilinear guide tube 20 in the lens barrel 3 as viewed from the oblique front side. FIG. 7 is a perspective view of the second group rectilinear guide base 80 constituting the rectilinear guide cylinder 20.

  In the lens barrel 3, a first lens holding frame 10, a rectilinear guide tube 20, and a cam outer tube 30 are arranged in a multistage manner in order of increasing diameter in order from the objective (subject) side. The cam outer cylinder 30 is provided in a fixed cylinder 60 configured integrally with the body housing 2A. A cam inner cylinder 40 is disposed inside the first lens holding frame 10, and a second lens holding frame 50 is disposed inside the cam inner cylinder 40. That is, the cam inner cylinder 40 is provided between the first lens holding frame 10 on the outer peripheral side and the second lens holding frame 50 on the inner peripheral side.

The fixed cylinder 60 has a cylindrical shape with a predetermined length in the axial direction (optical axis OA direction).
A rectilinear groove 61 for guiding the movement of the cam outer cylinder 30 and a helicoid groove 62 for moving and driving the cam outer cylinder 30 are formed on the inner peripheral surface of the fixed cylinder 60. The rectilinear groove 61 extends parallel to the optical axis OA (in the Z-axis direction). The helicoid groove 62 is formed at a predetermined angle with respect to the optical axis OA (in a spiral shape in which the position in the optical axis OA direction is displaced in the circumferential direction). The rectilinear groove 61 and the helicoid groove 62 are formed, for example, in two pieces in the circumferential direction.

A guide protrusion 71 of an end face plate 70 of the cam outer cylinder 30 to be described later is fitted in the rectilinear groove 61 so as to be slidable.
In the helicoid groove 62, a drive pin 31 protruding from the outer periphery of the cam outer cylinder 30 is fitted so as to be slidable.

The cam outer cylinder 30 has a cylindrical shape that fits on the inner periphery of the fixed cylinder 60 and is formed to have a predetermined length in the direction of the optical axis OA.
On the outer periphery of the cam outer cylinder 30, a drive pin 31 that is slidably fitted in the helicoid groove 62 is projected.
Formed on the inner peripheral surface of the cam outer cylinder 30 are a cam groove 32 for moving and driving the cam inner cylinder 40 and a rectilinear interlocking groove 33 for guiding the movement of the cam inner cylinder 40.

The cam groove 32 is formed so that the position in the optical axis OA direction is displaced in a predetermined relationship in the circumferential direction. In this embodiment, three cam grooves 32 are formed in the circumferential direction. A cam pin 21 in a straight guide cylinder 20 described later is fitted in the cam groove 32.
The rectilinear interlocking groove 33 is formed in parallel with the optical axis OA. Two straight advancement interlocking grooves 33 are formed at predetermined intervals in the circumferential direction. An interlocking pin 43 implanted in a cam inner cylinder 40 to be described later is fitted in the rectilinear interlocking groove 33 so as to be slidable.
An end face plate 70 is provided at the rear end of the cam outer cylinder 30. The end face plate 70 is provided at the end of the cam outer cylinder 30 so as not to be relatively movable in the direction of the optical axis OA and to be relatively rotatable.

The end face plate 70 includes guide protrusions 71 on the outer peripheral edge thereof. The guide protrusion 71 is provided in correspondence with the rectilinear groove 61 of the fixed cylinder 60 and is slidably fitted in the rectilinear groove 61 of the fixed cylinder 60.
Further, the end face plate 70 is provided with a rectilinear guide 72 for guiding the movement of the cam inner cylinder 40 described later on the front side thereof.

  The rectilinear guide 72 is a thin plate having an arc shape centered on the optical axis OA and having a predetermined width in the circumferential direction, and is formed to have a predetermined length in the optical axis OA direction. Two rectilinear guides 72 are provided at substantially equal intervals in the circumferential direction (that is, at intervals of approximately 180 °). The rectilinear guide 72 is fitted in a rectilinear guide hole 83 in the rectilinear guide cylinder 20 described later so as to be slidable.

The cam outer cylinder 30 is rotationally driven by a drive motor or the like (not shown) and is rotated with respect to the fixed cylinder 60.
When the cam outer cylinder 30 is driven to rotate, the cam outer cylinder 30 is moved by the helicoid groove 62 of the fixed cylinder 60 via the drive pin 31, and moves in the direction of the optical axis OA according to the displacement of the helicoid groove 62. On the other hand, the end face plate 70 moves in the direction of the optical axis OA along with the cam outer cylinder 30 without rotating because the rectilinear guide 72 is defined by the rectilinear groove 61 of the fixed or the like 60. That is, the cam outer cylinder 30 goes straight while rotating, and the end face plate 70 goes straight without rotating.

As shown in FIG. 6, the rectilinear guide tube 20 is formed in a substantially cylindrical shape having a predetermined width in the direction of the optical axis OA.
A cam pin 21 projects from the outer periphery of the rectilinear guide tube 20. Three cam pins 21 are provided at predetermined intervals in the circumferential direction. Each cam pin 21 is slidably fitted in a cam groove 32 formed on the inner peripheral surface of the cam outer cylinder 30.

A first rectilinear guide groove 22 is formed on the inner peripheral surface of the rectilinear guide tube 20.
The first rectilinear guide groove 22 is formed with a predetermined width and a predetermined depth. Three first straight guide grooves 22 are provided at predetermined intervals in the circumferential direction. In the first rectilinear guide groove 22, a rectilinear projection 11 in the first lens holding frame 10 described later is fitted so as to be slidable.

Further, as shown in FIGS. 2 and 6, the rectilinear guide tube 20 includes a second group rectilinear guide 81 (81A, 81B) on the inner peripheral side thereof.
The second group rectilinear guides 81 are provided at two locations (that is, 180 ° intervals) at equal intervals in the circumferential direction. One second group linear guide 81A is formed in a flat plate shape having a predetermined width in the circumferential direction. The other second group rectilinear guide 81B has an arc shape centered on the optical axis OA, and its width is narrower than that of the second group rectilinear guide 81A.

The second group rectilinear guide 81 (81A, 81B) has an optical axis OA from the inner peripheral side front end portion of the support arm portion 82 (82A, 82B) projecting on the inner peripheral side of the rear side end portion of the rectilinear guide tube 20. Is extended to a predetermined length toward the front surface side in parallel with the head. Accordingly, the second group rectilinear guide 81 (81A, 81B) is located further on the inner peripheral side of the cam inner cylinder 40 arranged on the inner peripheral side of the rectilinear guide cylinder 20. That is, the support arm portion 82 located on the back side of the cam inner cylinder 40 bypasses the back side of the cam inner cylinder 40 located on the inner peripheral side of the rectilinear guide cylinder 20 and avoids interference in a state where the cam inner cylinder 40 is avoided. The second group linearly moving guide 81 is supported on the inner peripheral side. As a result, the second group linear guide 81 is positioned so as to overlap with the cam inner tube 40 in the radial direction.
The second group rectilinear guide 81 (81A, 81B) is slidably fitted in a rectilinear guide slit 54 in the second lens holding frame 50 described later.

  Further, a rectilinear guide hole 83 is formed in the support arm portion 82 (82A, 82B). The rectilinear guide hole 83 has a shape corresponding to the rectilinear guide 72 in the end face plate 70 attached to the cam outer cylinder 30 and is formed through the support arm portion 82 in the front and rear directions in the optical axis OA direction. As described above, the straight guide 72 is fitted in the straight guide hole 83 so as to be slidable. Thus, since the guide hole 83 through which the rectilinear guide 72 passes is formed in the support arm part 82 for providing the second group rectilinear guide 81 (81A, 81B), it is necessary to provide a place for forming the guide hole 83 separately. There is no space efficiency.

Furthermore, since the guide hole 83 through which the rectilinear guide 72 passes is formed in the support arm portion 82 for providing the second group rectilinear guide 81 (81A, 81B), the following effects are also produced.
When the second group rectilinear guide base 80 receives force F in the rectilinear guide hole 83 (point D1 in the figure) in the counterclockwise direction in the circumferential direction, the second group rectilinear guide base 80 is moved to the second group rectilinear guide 81A (point C in the figure). ) Receives a force F in the clockwise direction in the circumferential direction. At this time, deflection occurs at point C and point D1 (region of dimension l1).
If the dimension between the point A and the point D2 when the position of the rectilinear guide hole 83 in the circumferential direction is shifted by 90 degrees in the clockwise direction is l2, l1 <l2. A force F is applied to the points C2 and D2 regardless of whether the dimension between them is 11 or l2. Therefore, the shorter the dimension l, the smaller the amount of deflection between point C and point D of the second group rectilinear guide base 80.
In this embodiment, since the rectilinear guide hole 83 and the second group rectilinear guide 81 are arranged at positions overlapping in the circumferential direction (that is, the distance between the point C and the point D2 is short), the second group rectilinear guide base 80 deflection is reduced. Thus, since the deflection of the second group rectilinear guide base 80 is small, the positional accuracy of the cam inner tube 40 in the optical axis direction is high, and the positional accuracy of each lens in the optical axis direction is high.

The rectilinear guide tube 20 further includes an engagement inner edge portion 84 on the inner peripheral side of the rear side end portion thereof.
The engagement inner edge portion 84 is formed so as to protrude toward the inner peripheral side with a substantially rectangular cross-sectional shape along the end surface on the back side of the rectilinear guide tube 20. The engagement inner edge portion 84 is formed in a region excluding the formation region of the second group rectilinear guide 81 (82A, 82B). The engagement inner edge portion 84 is slidably fitted in an engagement groove 44 formed in the cam inner cylinder 40 described later.

  The rectilinear guide cylinder 20 configured as described above is moved and operated via the cam pin 21 by the cam groove 32 in accordance with the rotation of the cam outer cylinder 30 (and the rectilinear advance associated with the rotation). It moves straight along 72.

Here, as shown in FIG. 6, the rectilinear guide cylinder 20 is formed by assembling two parts of a main body portion 20 </ b> A and a second group rectilinear guide base portion 80.
The main body 20A is a cylindrical member having a predetermined thickness and a predetermined length in the direction of the optical axis OA, and includes a first rectilinear guide groove 22 on the inner peripheral surface. Further, the main body portion 20A includes an engagement protrusion 23 on the inner peripheral edge on the back side. The engaging protrusions 23 are each formed with a predetermined width in the circumferential direction at positions (three locations in the circumferential direction) corresponding to the engaging claws 85 provided in the second group linear guide base 80 described later.

  As shown in FIG. 7, the second group rectilinear guide base 80 has an annular shape with an outer diameter coinciding with the main body 20 </ b> A. The above-described second group linear guide 81 (81A, 81B) extending from the inner peripheral side tip of the support arm portion 82 (82A, 82B) is provided. The second group rectilinear guide base 80 includes an engaging claw 85 on the front side.

The engaging claw 85 is a so-called snap fit provided on the outer peripheral side of the arm portion protruding to the front surface side with a back surface that engages with the engaging protrusion 23 in the main body portion 20A and a tapered tip end surface that tapers. . The engaging claws 85 are formed at predetermined intervals in the circumferential direction at three predetermined intervals.
When the second claw guide base 80 matches the predetermined position with respect to the main body portion 20A, the engaging claw 85 comes into contact with the engaging protrusion 23 of the main body portion 20A and the arm portion is on the inner peripheral side. And is engaged with the front side of the engagement protrusion 23 in the main body 20A as shown in FIG.

  In this manner, the main body 20A and the second group linear guide base 80 are coupled by the engaging claws 85 to constitute the linear guide cylinder 20 as one component. For this reason, the rotation of the second rectilinear guide 81 in the circumferential direction with respect to the first rectilinear guide groove 22 is restricted. That is, the rotation of the second rectilinear guide 81 and the first rectilinear guide groove 22 in the circumferential direction around the rotation axis of the cam inner cylinder 40 is restricted. In addition, it is good also as a structure fixed together using an adhesive agent as needed to the junction part of 20 A of main-body parts and the 2nd group rectilinear guide base 80. FIG. As described above, by forming the linear guide cylinder 20 having a complicated shape by assembling and forming the two parts of the main body portion 20A and the second group linear guide base portion 80, production can be facilitated and the cost can be reduced. Become.

The first lens holding frame 10 is formed in a cylindrical shape that fits on the inner periphery of the rectilinear guide tube 20.
On the front side of the first lens holding frame 10, the first lens unit L1 is mounted.
A rectilinear protrusion 11 is provided on the outer periphery of the first lens holding frame 10. The rectilinear guide protrusions 11 are provided at three locations in the circumferential direction corresponding to the first rectilinear guide grooves 22 in the rectilinear guide tube 20. As described above, the rectilinear protrusion 11 is fitted in the first rectilinear guide groove 22 of the rectilinear guide tube 20 so as to be slidable.
In addition, a drive cam pin 12 projects from the inner periphery of the first lens holding frame 10. The drive cam pin 12 is slidably fitted in an outer peripheral cam groove 41 formed on the outer peripheral surface of a cam inner cylinder 40 described later.
Thereby, the first lens holding frame 10 is provided so as to be movable in the direction of the optical axis OA along the first rectilinear guide groove 22 of the rectilinear guide cylinder 20 in a state in which the rotation about the optical axis OA is restricted. ing. The movement operation of the first lens holding frame 10 is performed via the drive cam pin 12 by the outer peripheral cam groove 41 in accordance with the rotation of the cam inner cylinder 40 described later.

The cam inner cylinder 40 is formed in a cylindrical shape with an outer diameter that fits into the inner periphery of the first lens holding frame 10. The inner diameter is set so as to be fitted to the outer periphery of the second lens holding frame 50.
The cam inner cylinder 40 has an outer peripheral cam groove 41 for driving the first lens holding frame 10 on the outer peripheral surface, and an inner peripheral cam groove 42 for driving the second lens holding frame 50 on the inner peripheral surface. That is, the cam inner cylinder 40 has cam grooves (an outer peripheral cam groove 41 and an inner peripheral cam groove 42) formed on the inner and outer peripheral surfaces thereof.

The outer peripheral cam groove 41 is formed such that the position of the optical axis OA is displaced in a predetermined relationship in the circumferential direction. As described above, the drive cam pin 12 protruding from the inner periphery of the first lens holding frame 10 is fitted in the outer cam groove 41 so as to be slidable.
The inner circumferential cam groove 42 is formed such that the position of the optical axis OA is displaced in a predetermined relationship in the circumferential direction. A cam pin 53 protruding from the outer periphery of a second lens holding frame 50 described later is fitted in the inner peripheral cam groove 42 so as to be slidable.
In addition, an engagement groove 44 is formed in the circumferential direction orthogonal to the optical axis OA in the vicinity of the rear end portion of the cam inner tube 40. An engagement inner edge portion 84 of the rectilinear guide tube 20 is fitted in the engagement groove 44 so as to be movable (rotatable) in the circumferential direction and immovable in the direction of the optical axis OA.

Further, an interlocking pin 43 projects from the outer peripheral side of the rear end portion of the cam inner cylinder 40.
Two interlocking pins 43 are provided at equal intervals in the circumferential direction of the cam inner cylinder 40 (that is, at intervals of 180 °). The interlocking pin 43 is provided with its axial direction along the radial direction of the cam inner cylinder 40 (radially from the optical axis OA). The interlocking pin 43 is formed in a shaft shape having a predetermined diameter with stainless alloy steel or the like, and is implanted (or insert-molded) in the cam inner tube 40. The interlocking pin 43 may be integrally formed with the same material as the cam inner tube 40.
The interlocking pin 43 is located on the back side of the rectilinear guide cylinder 20 and is slidably fitted in the rectilinear interlocking groove 33 of the cam outer cylinder 30 as described above.

The cam inner cylinder 40 having the above configuration rotates in conjunction with the rotation of the cam outer cylinder 30 via an interlocking pin 43. In addition, since the engagement inner edge portion 84 of the rectilinear guide cylinder 20 that moves linearly by the rotation of the cam outer cylinder 30 is fitted in the engagement groove 44, the cam inner cylinder 40 is attached to the rectilinear guide cylinder 20. Go straight ahead.
That is, the cam inner cylinder 40 rotates as the cam outer cylinder 30 rotates, and moves linearly as the rectilinear guide cylinder 20 advances straight due to the rotation of the cam outer cylinder 30.
Relative movement of the cam inner cylinder 40 relative to the cam outer cylinder 30 in the straight movement direction is allowed by the movement of the interlocking pin 43 along the straight movement interlocking groove 33.
The cam inner cylinder 40 is rotated by the first lens holding frame 10 (first lens group L1) located on the outer peripheral side and the second lens holding frame 50 (second lens) described later located on the inner peripheral side. Both groups L2) are moved.

  In the configuration as described above, the rectilinear guide cylinder 20 and the cam inner cylinder 40 rotate relative to each other, but their positions in the optical axis direction OA are basically unchanged. That is, the interlocking pin 43 provided in the cam inner cylinder 40 rotates with respect to the rectilinear guide cylinder 20, but the relative position in the optical axis OA direction with respect to the rear end face of the rectilinear guide cylinder 20 does not change.

Here, a circular leaf spring 90 is provided on an end surface of the rectilinear guide tube 20 on the back side.
The circular leaf spring 90 is formed in an annular shape corresponding to the end surface on the back side of the rectilinear guide tube 20. The circular leaf spring 90 is interposed between the rectilinear guide tube 20 and the interlocking pin 43, and widens the distance between them at least in the rotation range of the interlocking pin 43 with respect to the rectilinear guide tube 20 in the zooming range of the lens barrel 3. It is formed so as to be biased in the direction. The urging force of the circular leaf spring 90 acts on the engagement groove 44 in the cam inner cylinder 40 so as to press the engagement inner edge portion 84 of the rectilinear guide cylinder 20 toward the front side. As a result, the fitting gap between the engagement groove 44 and the engagement inner edge portion 84 is unevenly distributed on one side (rear side), and there is a backlash (relative to the cam inner cylinder 40) at the time of relative rotation of both of them during zooming operation. The backlash of the straight guide tube 20 is prevented. Thereby, it is possible to suppress the deterioration of the optical performance caused by the backlash between the cam inner cylinder 40 and the straight guide cylinder 20.

The second lens holding frame 50 includes a substantially cylindrical outer peripheral portion 51 that fits on the inner periphery of the cam inner tube 40, and an inner peripheral portion 52 that supports the second lens group L2.
A second lens group L2 is attached to the inner peripheral portion 52.
A cam pin 53 projects from the outer periphery of the outer peripheral portion 51. A plurality of cam pins 53 are provided at predetermined intervals in the circumferential direction corresponding to the inner circumferential cam grooves 42 in the cam inner cylinder 40. As described above, the cam pin 53 is fitted in the inner peripheral cam groove 42 of the cam inner cylinder 40 so as to be slidable.

Moreover, the outer peripheral part 51 is provided with the rectilinear guide slit 54 (54A, 54B). The rectilinear guide slits 54 (54A, 54B) are set at positions corresponding to the circumferential direction with the second group rectilinear guides 81 (82A, 82B) in the rectilinear guide cylinder 20, respectively.
The rectilinear guide slit 54 has a width corresponding to that of the second group rectilinear guide 81 and is formed through the outer peripheral portion 51 in the direction of the optical axis OA. As described above, the second group linear guide 81 is fitted in the linear guide slit 54 so as to be slidable in the direction of the optical axis OA.
As a result, the second lens holding frame 50 is provided so as to be movable in the direction of the optical axis OA in a state regulated by the second group rectilinear guide 81 in the rectilinear guide cylinder 20 and restricted in rotation about the optical axis OA. It has been.

  The second lens holding frame 50 is moved and operated via the cam pin 53 according to the displacement of the inner peripheral cam groove 42 in the cam inner cylinder 40 in the optical axis OA direction by the rotation of the cam inner cylinder 40, and goes straight along the group linear guide 81. Driven. As described above, the cam inner cylinder 40 rotates as the cam outer cylinder 30 rotates. Therefore, the second lens holding frame 50 is driven straight by the rotation of the cam outer cylinder 30.

  The lens barrel 3 configured as described above has a first lens group L1 (first lens holding frame 10) and a second lens group L2 (second lens) by rotationally driving the cam outer cylinder 30 by a drive motor (not shown). The holding frame 50) is moved and operated in the optical axis direction. Along with this, the lens barrel 3 expands and contracts. That is, the lens barrel 3 sandwiches the photographing standby state (wide end) shown in FIG. 5 (b) between the retracted state shown in FIG. 5 (a) and the telephoto end shown in FIG. 5 (c). It expands and contracts.

  In the retracted state shown in FIG. 5A, the cam outer cylinder 30, the rectilinear guide cylinder 20, the first lens holding frame 10, the cam inner cylinder 40, and the second lens holding frame 50 are substantially overlapped inside the fixed cylinder 60. It is stored in the state. This retracted state is a state during non-photographing when the camera 1 is not turned on.

When the power source of the camera 1 is turned on from the retracted state, the cam outer cylinder 30 is driven to rotate by a predetermined angle to enter the photographing standby state (wide end) shown in FIGS. 1 and 5B.
That is, when the cam outer cylinder 30 is driven to rotate, the cam outer cylinder 30 advances straight while rotating and protrudes from the fixed cylinder 60 to a predetermined position. As the cam outer cylinder 30 rotates and goes straight, the cam inner cylinder 40 also goes straight while rotating. As the cam inner cylinder 40 advances straight, the rectilinear guide cylinder 20 advances straight. The first lens holding frame 10 (first lens group L1) and the second lens holding frame 50 (second lens group L2) are linearly operated in a predetermined relationship by the rotation of the cam inner cylinder 40. Thereby, the first lens group L and the second lens group L2 become the positions of the focal lengths at the wide end in the lens barrel 3.

  The lens barrel 3 zooms to the telephoto side according to the operation of the camera 1 with the photographing standby state at the wide end as a reference position during photographing. Zooming to the telephoto side is performed by rotation of the cam outer cylinder 30. The rotation of the cam outer cylinder 30 is in the same direction as the drive from the retracted state to the photographing standby state described above.

In zooming to the telephoto side, the cam inner cylinder 40 rotates straight by the rotation driving of the cam outer cylinder 30, and accordingly, the straight guide cylinder 20 advances straight. The first lens holding frame 10 (first lens group L1) and the second lens holding frame 50 (second lens group L2) are linearly operated in a predetermined relationship by the rotation of the cam inner cylinder 40.
At the telephoto end shown in FIGS. 4 and 5C, the first lens group L and the second lens group L2 are the longest focal length positions in the lens barrel 3. This is the state in which the lens barrel 3 is most extended.

As described above, this embodiment has the following effects.
(1) The lens barrel 3 moves and drives the first lens holding frame 10 positioned on the outer peripheral side and the second lens holding frame 50 positioned on the inner peripheral side by the cam inner cylinder 40. Further, in the rectilinear guide cylinder 20, the first rectilinear guide groove 22 guides the movement parallel to the optical axis OA of the first lens holding frame 10, and the second group rectilinear guide 82 is the optical axis of the second lens holding frame 50. Guides movement parallel to OA. That is, the single linear guide cylinder 20 guides the movement of the first lens holding frame 10 and the second lens holding frame 50 positioned on the inner and outer circumferences of the cam inner cylinder 40 in parallel with the optical axis OA. Thereby, compared with the structure which guides with each separate member, the precision fall which arises by accumulation | storage of the precision error of parts, or rattling can be prevented. Accordingly, the relative positional accuracy of the first lens group L1 held by the first lens holding frame 10 and the second lens group L2 held by the second lens holding frame 50 can be increased, and high optical performance can be obtained.

(2) Since the guide hole 83 through which the rectilinear guide 72 passes is formed in the support arm portion 82 for providing the second group rectilinear guide 81 (81A, 81B), it is not necessary to provide a place for forming the guide hole 83 separately. , Space efficient.
Furthermore, since the guide hole 83 through which the rectilinear guide 72 passes is formed in the support arm portion 82 for providing the second group rectilinear guide 81 (81A, 81B), the following effects are also produced.
When the second group rectilinear guide base 80 receives force F in the rectilinear guide hole 83 (point D1 in the figure) in the counterclockwise direction in the circumferential direction, the second group rectilinear guide base 80 is moved to the second group rectilinear guide 81A (point C in the figure). ) Receives a force F in the clockwise direction in the circumferential direction. At this time, deflection occurs at point C and point D1 (region of dimension l1).
If the dimension between the point C and the point D2 when the position of the rectilinear guide hole 83 in the circumferential direction is shifted by 90 degrees clockwise is l2, l1 <l2. A force F is applied to the points C2 and D2 regardless of whether the dimension between them is 11 or l2. Therefore, the shorter the dimension l, the smaller the amount of deflection between point C and point D of the second group rectilinear guide base 80.
In this embodiment, since the rectilinear guide hole 83 and the second group rectilinear guide 81 are arranged at positions overlapping in the circumferential direction (that is, the distance between the point C and the point D2 is short), the second group rectilinear guide base 80 deflection is reduced. Thus, since the deflection of the second group rectilinear guide base 80 is small, the positional accuracy of the cam inner tube 40 in the optical axis direction is high, and the positional accuracy of each lens in the optical axis direction is high.

(3) The rectilinear guide cylinder 20 in the lens barrel 3 is formed by connecting the main body 20A and the second group rectilinear guide base 80 by an engaging claw 85. As a result, the production of the straight guide cylinder 20 having a complicated shape is facilitated, and the cost can be reduced.

(Deformation)
The present invention is not limited to the above-described embodiment, and various modifications and changes as described below are possible, and these are also within the scope of the present invention.
(1) In this embodiment, all the members are basically configured in a cylindrical shape centered on the optical axis OA, and the cam outer cylinder 30 and the cam inner cylinder 40 are configured to rotate around the optical axis OA. ing. However, the present invention is not limited to this, and in the circumferential direction of rotation, if one of the rectilinear guides is restricted from rotating relative to the other rectilinear guide, it rotates around an axis eccentric from the optical axis OA. It is good also as composition to do.

(2) In this embodiment, the rectilinear guide tube 20 is configured by combining two parts, that is, the main body 20A and the second group rectilinear guide base 80. However, it does not necessarily have to be constituted by two parts, and may be formed as one part from the beginning by integral molding or the like. By forming it as one component, even higher accuracy can be obtained. Conversely, three parts may be combined, and even when two parts are combined, the divided structure and the like can be set as appropriate.

  In addition, although embodiment and a deformation | transformation form can also be used in combination as appropriate, detailed description is abbreviate | omitted. Further, the present invention is not limited to the embodiment described above.

  1: camera 1, 3: lens barrel, L1: first lens group, L2: second lens group, 10: first lens holding frame, 20: rectilinear guide cylinder, 20A: main body, 22: first rectilinear guide Groove: 40: cam inner cylinder, 41: outer cam groove, 42: inner cam groove, 72: rectilinear guide, 80: second group rectilinear guide base, 81: second group rectilinear guide

Claims (6)

A cylindrical first lens holding portion for holding the first lens group;
A cylindrical second lens holding portion for holding the second lens group;
An inner cam groove for driving one of the first lens holding portion and the second lens holding portion is formed on the inner peripheral surface, and an outer cam for driving the other of the first lens holding portion and the second lens holding portion on the outer peripheral surface. A cam cylinder in which a groove is formed;
A first rectilinear guide for restricting rotation about the optical axis of the first lens holding portion or an axis parallel to the optical axis;
The rotation about the optical axis of the second lens holding portion or an axis parallel to the optical axis is restricted, and the relative movement with respect to the first rectilinear guide in the circumferential direction around the rotation axis of the cam cylinder is restricted. A second straight traveling guide,
A lens barrel. The lens barrel according to claim 1,
The first rectilinear guide and the second rectilinear guide are formed integrally;
A lens barrel characterized by The lens barrel according to claim 2,
The first rectilinear guide and the second rectilinear guide are fixed to each other;
A lens barrel characterized by The lens barrel according to any one of claims 1 to 3,
The first rectilinear guide and the second rectilinear guide are one part,
A lens barrel characterized by The lens barrel according to any one of claims 1 to 4,
A third rectilinear guide for rectilinearly guiding the first rectilinear guide and the second rectilinear guide;
The second rectilinear guide has a second extending portion that extends in parallel with the optical axis direction and guides the second lens holding frame,
The third rectilinear guide includes a third extending portion that extends parallel to the optical axis direction and guides the second rectilinear guide,
The second extending portion and the third extending portion are at least partially disposed on the same diameter centered on the optical axis;
A lens barrel characterized by   A camera provided with the lens barrel of any one of Claims 1-5.

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