JP5120388B2 - Lens barrel and camera - Google Patents

Description

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

  Conventionally, there is a lens barrel in which the front group of the lens and the lens barrier move independently in the optical axis direction and the relative positions of the front group and the lens barrier change (see, for example, Patent Document 1).

Japanese Patent No. 405239

  In the conventional lens barrel described above, in the retracted state, the front group retracts rearward in the optical axis direction with respect to the front group so that the lens barrier can be closed. In the photographing state, the front group is close to the lens barrier, and the lens barrier is retracted to the outside in the optical axis direction with respect to the front group. For this reason, it is necessary to secure a space for retracting the lens barrier on the outer peripheral side of the front group, which is a limitation on downsizing of the lens barrel.

  An object of the present invention is to provide a small lens barrel and a camera provided with a lens barrier.

The invention of claim 1 is disposed on the object side leading end, a shape whose both ends are formed respectively deleted with accommodation space facing across the optical axis lens, the object side of the lens in the closed state a lens barrier which is located, and the lens barrier drive unit for opening and closing the lens barrier, and a moving means for moving the optical axis direction of the relative position between the lens barrier and the lens front by the lens barrier drive unit Symbol The lens barrier is opened from the closed state , and at least a part of the thickness of the lens barrier in the optical axis direction is located on the imaging surface side from the end of the curved surface portion on the subject side of the lens in the accommodation space. as arranged, the lens barrel characterized by comprising a photographing standby state said optical axis direction of the relative position is moved between the lens barrier and the lens by said moving means That.

  According to the present invention, a small lens barrel having a lens barrier can be provided.

It is a figure which shows notionally the longitudinal cross-section of the camera in a photography standby state. It is a figure which shows notionally the longitudinal cross section of the camera in a lens barrel retracted state (reduced cylinder state). It is explanatory drawing of the barrier cylinder helicoid groove | channel and lens chamber drive cam groove | channel in a cam cylinder, (a) shows an imaging | photography standby state, (b) shows a retracted state, respectively. It is a disassembled perspective view of a barrier mechanism part. It is a disassembled perspective view of a barrier frame and a barrier blade | wing. It is the perspective view which looked at the barrier blade from the image plane side. It is the figure which looked at the barrier blade | wing from the to-be-photographed object side. It is sectional drawing of the barrier blade | wing equivalent to the AA arrow of FIG. 4 in an open state. It is sectional drawing of the barrier blade | wing equivalent to the BB arrow of FIG. 4 in an open state. It is a figure of the barrier blade | wing corresponding to the BB arrow of FIG. 4 in a closed state. It is a figure of the state with which the interlocking plate and barrier blade | wing corresponded to CC arrow of FIG. 4 were combined, Comprising: (a) A barrier blade is an open state, (b) is a barrier blade closed state, Each is shown. It is the D section enlarged view of FIG.

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. FIG. 2 is a diagram conceptually showing a vertical cross section of the camera 1 in which the lens barrel 10 is in the retracted state (the state in which the lens barrel is housed in the camera body, the contracted cylinder state).

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 the photographing optical system in the direction parallel to the optical axis OA of the fixed optical system is referred to as “straight forward”, and movement around the optical axis OA is referred to as “rotation”. 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 imaging surface (imaging surface) side is referred to as “back side”.

The camera 1 is a digital camera composed of a body part 2 and a lens barrel 10. The present invention is not limited to a digital camera, and can be applied to, for example, a still camera using a film.
The lens barrel 10 is a so-called collapsible zoom lens that is immersed in the body portion 2 when not in use, protrudes from the body portion 2 when in use, and can change (zoom) the focal length. That is, the lens barrel 10 is contracted and accommodated inside the body portion 2 as shown in FIG. 2 in a non-photographing state where power supply is stopped, and when power is supplied, the body portion 10 is shown in FIG. 2 protrudes to the front side and enters a shooting standby state. In the configuration of the present embodiment, the shooting standby state is set to the wide-angle end in zooming.

The body part 2 includes a sensor unit 3 inside the body housing 2A.
The sensor unit 3 includes an image sensor 3A such as a CCD. The sensor unit 3 is fixed to the CCD table 4 so that the image pickup surface of the image pickup element 3 </ b> A is orthogonal to the optical axis OA of the lens barrel 10. The imaging surface is set to have a predetermined aspect ratio (the length in the X-axis direction is longer than the length in the Y-axis direction). The sensor unit 3 converts an image formed on the imaging surface of the imaging element 3A by the lens barrel 10 into an electrical signal and outputs the electrical signal.

  As described above, the lens barrel 10 is a zoom lens having a variable focal length. The lens barrel 10 includes three sets of lens groups (a first lens group L1, a second lens group L2, and a third lens group L3) that constitute an imaging optical system in the camera 1. These three lens groups form a subject image on the imaging surface of the image sensor 3 </ b> A in the sensor unit 3. In the lens barrel 10, the lens groups L1, L2, and L3 move in the direction of the optical axis OA, and the focal length changes. The third lens unit L3 is a focusing lens unit, and moves in the direction of the optical axis OA to change the imaging position.

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

  Next, the lens barrel 10 will be described in detail with reference to FIG. 3 in addition to FIG. 1 and FIG. 3A and 3B are explanatory views of the barrier cylinder helicoid groove 17B and the lens chamber drive cam groove 17C in the cam cylinder 17, wherein FIG. 3A shows a photographing standby state and FIG. 3B shows a retracted state.

  In the retracted state of (b), the lens barrel 10 includes a rotating cylinder 12, a rectilinear cylinder 13, a first group rectilinear cylinder 14, and a barrier cylinder 15 inside a fixed cylinder 11 that is integrally formed with the body housing 2A. The diameter is sequentially reduced in the Y direction and arranged in a multistage manner. The first group lens chamber 16 is fitted on the inner peripheral side of the barrier cylinder 15, and the cam cylinder 17 is disposed on the inner peripheral side of the first group lens chamber 16. Further, the second lens frame 18 is disposed on the inner peripheral side of the cam cylinder 17, and the shutter mechanism 20 and the third lens frame 30 are disposed on the back side of the second lens frame 18. On the front side of the barrier cylinder 15, there is provided a barrier mechanism 40 that includes a barrier blade that opens and closes and includes the barrier cylinder 15.

The fixed cylinder 11 has a cylindrical shape with a predetermined length in the axial direction (optical axis OA direction), and is fixed to the body housing 2A.
On the inner peripheral surface of the fixed cylinder 11, a rotating cylinder driving helicoid groove 11 </ b> A for moving and driving the rotating cylinder 12 and a rectilinear groove 11 </ b> B for guiding the movement of the rectilinear cylinder 13 are formed. The rectilinear grooves 11B and the rotating cylinder driving helicoid grooves 11A are formed, for example, in three circumferential rows.

The rotating cylinder driving helicoid groove 11A is formed at a predetermined angle with respect to the optical axis OA (in a spiral shape whose position in the optical axis OA direction is displaced in the circumferential direction). As will be described later, a drive pin 12A projecting from the outer periphery of the rotary cylinder 12 is slidably fitted in the rotary cylinder drive helicoid groove 11A.
The rectilinear groove 11B extends in parallel with the optical axis OA (in the Z-axis direction). The rectilinear groove 11B is formed in parallel with the optical axis OA. A rectilinear guide protrusion 13C in a rectilinear cylinder 13 described later is fitted in the rectilinear groove 11B so as to be slidable.

A rotating cylinder 12 is disposed on the inner peripheral side of the fixed cylinder 11.
The rotary cylinder 12 has a cylindrical shape that is slidably fitted to the inner periphery of the fixed cylinder 11 and has a predetermined length in the direction of the optical axis OA.
On the outer periphery of the rotary cylinder 12, a drive pin 12 </ b> A is slidably fitted into the rotary cylinder drive helicoid groove 11 </ b> A so as to be slidable.
A drive input gear 12B is formed on the outer periphery of the rear end portion of the rotary cylinder 12, and this drive input gear 12B is connected to a retractable / zoom drive motor (not shown). Thereby, the rotary cylinder 12 is rotationally driven by the collapsible / zoom drive motor.

Further, on the inner peripheral surface of the rotary cylinder 12, a rectilinear interlocking groove 12 </ b> C is formed for operating the cam cylinder 17 and guiding the movement.
The rectilinear interlocking groove 12C is formed in parallel with the optical axis OA. The rectilinear interlocking grooves 12 </ b> C are formed, for example, as three strips at predetermined intervals in the circumferential direction. A follower pin 17A implanted in a cam cylinder 17 to be described later is fitted in the linearly interlocking groove 12C so as to be slidable.
When the rotary cylinder 12 configured as described above is rotationally driven by a collapsible / zoom drive motor (not shown), the rotary cylinder 12 is linearly operated by the rotary cylinder drive helicoid groove 11A of the fixed cylinder 11 into which the drive pin 12A is fitted. That is, the rotating cylinder 12 moves straight while rotating.

A rectilinear cylinder 13 is disposed on the inner peripheral side of the rotating cylinder 12.
The rectilinear cylinder 13 has a cylindrical shape that is slidably fitted to the inner periphery of the rotating cylinder 12 and is formed to have a predetermined length in the direction of the optical axis OA. Is configured so as not to be relatively movable.
A rectilinear groove 13A is formed on the inner periphery of the rectilinear cylinder 13 in parallel with the optical axis OA. A rectilinear guide 14A projecting from the outer periphery of a first group rectilinear cylinder 14 described later is fitted in the rectilinear groove 13A so as to be slidable.

Further, a cam hole 13 </ b> B is formed in the rectilinear cylinder 13. The cam hole 13B is formed with a predetermined angle with respect to the optical axis OA, and penetrates the rectilinear cylinder 13 inward and outward in the radial direction. A follower pin 17A of a cam cylinder 17 described later is fitted in the cam hole 13B so as to be slidable.
Further, a rectilinear guide protrusion 13 </ b> C is provided on the outer peripheral side of the end of the rectilinear cylinder 13 on the back side. The rectilinear guide protrusion 13C is fitted in the rectilinear groove 11B of the fixed cylinder 11 so as to be slidable.
The rectilinear cylinder 13 configured as described above rotates along with the rectilinear movement of the rotating cylinder 12 while the rectilinear guide protrusion 13C is fitted in the rectilinear groove 11B of the fixed cylinder 11. And move straight along with the rotating cylinder 12.

A first group rectilinear cylinder 14 is disposed on the inner peripheral side of the rectilinear cylinder 13.
The first group rectilinear cylinder 14 has a cylindrical shape that is slidably fitted to the inner periphery of the rectilinear cylinder 13 and is formed in a predetermined length in the direction of the optical axis OA.
A rectilinear guide 14 </ b> A is formed on the outer periphery of the first group rectilinear cylinder 14. The rectilinear guide 14A is fitted in the rectilinear groove 13A of the rectilinear cylinder 13 so as to be slidable.

A rectilinear guide groove 14 </ b> B is formed on the inner periphery of the first group rectilinear cylinder 14. The rectilinear guide groove 14B is formed in parallel with the optical axis OA, and a guide projection 15A projecting on the outer periphery of a barrier cylinder 15 described later is slidably fitted in the rectilinear guide groove 14B. Yes.
In addition, the first group linearly-moving cylinder 14 is engaged with a cam cylinder 17 described later at the end on the back surface side so that it cannot move in the optical axis direction and can rotate relatively.
The first group rectilinear cylinder 14 configured as described above is provided so as to be relatively rotatable with respect to a cam cylinder 17 described later and immovable in the optical axis direction, and the rectilinear guide 14A is a rectilinear groove of the rectilinear cylinder 13. Since it is fitted to 13A, it moves straight along with the cam cylinder 17 without rotating.

A barrier cylinder 15 is arranged on the inner periphery of the first group linearly moving cylinder 14.
The barrier cylinder 15 is a cylindrical shape that is slidably fitted to the inner periphery of the first group rectilinear cylinder 14 and has a predetermined length in the direction of the optical axis OA. As described above, the barrier cylinder 15 constitutes the barrier mechanism 40 including the barrier blades that open and close.

A guide protrusion 15 </ b> A is provided on the outer periphery of the barrier cylinder 15. The guide protrusion 15A is fitted in the rectilinear guide groove 14B of the first group rectilinear cylinder 14 so as to be slidable.
A lens guide groove 15B is formed in the inner periphery of the barrier cylinder 15 in parallel with the optical axis OA. In this lens guide groove 15B, a guide protrusion 16B formed on the outer periphery of a first group lens chamber 16 described later is fitted so as to be slidable.

  Further, a driven key 15 </ b> C is provided in the vicinity of the inner peripheral back side end portion of the barrier cylinder 15. The driven key 15C is slidably fitted in a barrier cylinder helicoid groove 17B formed on the outer periphery of the cam cylinder 17 described later.

The barrier cylinder 15 configured as described above has a guide projection 15A fitted in the straight guide groove 14B of the first group straight advance cylinder 14, so that the driven key 15C is fitted without rotating. The cylinder 17 is operated by the barrier cylinder helicoid groove 17 </ b> B and moves straight along with the rotation of the cam cylinder 17.
The barrier mechanism 40 including the barrier cylinder 15 will be described in detail later.

A first group lens chamber 16 is disposed on the inner peripheral side of the barrier cylinder 15.
The first group lens chamber 16 has a cylindrical shape that is slidably fitted to the inner periphery of the barrier cylinder 15 and has a predetermined length in the direction of the optical axis OA. The first group lens chamber 16 supports the first lens group L1 by a support portion 16A protruding from the inner peripheral side on the front side.

On the outer periphery of the first group lens chamber 16, a guide protrusion 16B is provided in parallel with the optical axis OA. The guide protrusion 16B is fitted in the lens guide groove 15B of the barrier cylinder 15 so as to be slidable.
A cam follower 16 </ b> C projects from the inner periphery of the first group lens chamber 16. The cam follower 16C is slidably fitted in a lens chamber drive cam groove 17C formed on the outer periphery of a cam cylinder 17 described later.

  In the first group lens chamber 16 configured as described above, its cam follower 16C is operated by the lens chamber drive cam groove 17C of the cam cylinder 17, and the guide protrusion 16B is fitted into the lens guide groove 15B of the barrier cylinder 15. Therefore, it moves straight along with the rotation of the cam cylinder 17 without rotating.

  Here, when the first lens group L1 supported by the first group lens chamber 16 is viewed from the front side, the front surface portion of the first lens group L1 is horizontally long at a predetermined aspect ratio in the image sensor 3A of the sensor unit 3 described above. Corresponding to the imaging surface, the upper and lower portions of the first lens unit L1 are cut (see FIG. 4). That is, the upper and lower edges (both sides in the Y-axis direction) of the first lens group L1 are formed in parallel straight lines, and the left and right edges (both sides in the X-axis direction) of the first lens group L1 are arc-shaped (hereinafter, referred to as the following). This shape is called barrel shape). Further, the above barrel shape in the predetermined XY plane is a symmetrical shape with reference to a straight line parallel to the X axis on the predetermined XY plane and intersecting the optical axis OA. The upper and lower cuts of the front surface portion of the first lens group L1 are performed to form spaces for accommodating barrier blades 50 in a barrier mechanism 40 described later above and below the first lens group L1. Thereby, the first lens unit L1 can be protruded to the front side (subject side) as much as possible while suppressing the increase in the outer diameter of the lens barrel 10, and a wide angle of view can be obtained. .

Returning to FIGS. 1 and 2, a cam cylinder 17 is disposed on the inner peripheral side of the first group lens chamber 16.
The cam cylinder 17 has a cylindrical shape that is slidably fitted to the inner periphery of the first group lens chamber 16 and has a predetermined length in the direction of the optical axis OA.
A follower pin 17A projects from the outer periphery of the cam cylinder 17 in the vicinity of the rear side end. The follower pin 17A is slidably fitted into the cam hole 13B of the rectilinear cylinder 13 and penetrates the follower pin 17A, and the tip of the follower pin 17A is slidably fitted in the rectilinear interlocking groove 12C of the rotary cylinder 12.

  Further, as shown in FIG. 3 in which the outer peripheral surface of the cam cylinder 17 is developed and formed on the outer periphery of the cam cylinder 17, a barrier cylinder helicoid groove 17B and a lens chamber drive cam groove 17C are formed. In this embodiment, the barrier cylinder helicoid groove 17B and the lens chamber drive cam groove 17C are each formed in three strips in the circumferential direction. 3A shows a shooting standby state, and FIG. 3B shows a retracted state.

  The barrier cylinder helicoid groove 17B extends to the front surface side with a predetermined angle with respect to the optical axis OA continuously with the retractable expansion / contraction operation part 17Ba extending in a direction orthogonal to the optical axis OA. An extension operation unit 17Bb. The driven key 15C of the barrier cylinder 15 is fitted in the barrier cylinder helicoid groove 17B so as to be slidable. The driven key 15C moves the retractable telescopic operation portion 17Ba between the retracted state shown in FIG. 3B and the photographing standby state shown in FIG. 3A, and further during zooming before the photographing standby state. The extension operation unit 17Bb is set to move.

The lens chamber drive cam groove 17C includes a retractable base portion 17Ca extending in a direction orthogonal to the optical axis OA, and a retractable extension operation portion extending to the front side in parallel with the extension operation portion 17Bb of the barrier cylinder helicoid groove 17B. 17Cb, a standby base portion 17Cc extending in the direction orthogonal to the optical axis OA continuously with the tip of the retractable extension operation portion 17Cb, and continuously extending from the standby base portion 17Cc in parallel with the extension operation portion 17Bb in the barrier cylinder helicoid groove 17B And a zooming operation portion 17Cd extending to the front side.
A cam follower 16C of the first group lens chamber 16 is fitted in the lens chamber drive cam groove 17C so as to be slidable. The cam follower 16C moves the retractable extension operation portion 17Cb from the retracted base 17Ca between the retracted state shown in FIG. 3B to the photographing standby state shown in FIG. 3A, and is positioned at the standby base 17Cc in the photographing standby state. To do. Further, during zooming prior to the shooting standby state, the cam follower 16C is set to move the zooming operation unit 17Cd.

Returning to FIG. 1, a second lens frame driving cam groove 17 </ b> D is formed on the inner periphery of the cam cylinder 17. The second lens frame drive cam groove 17D is formed with a predetermined angle with respect to the optical axis OA, and a second lens frame cam follower 18A protruding from the outer periphery of the second lens frame 18 described later slides. It is fitted so that it can be moved.
In addition, a barrier operation projection 17E for opening and closing a barrier blade 50 in a barrier mechanism 40 described later is provided at a predetermined position on the front side of the cam cylinder 17 (see FIG. 4).

  As the rotating cylinder 12 rotates, the follower pin 17 </ b> A is rotated by the rectilinear interlocking groove 12 </ b> C of the rotating cylinder 12 and the cam cylinder 17 is rectilinearly operated by the cam hole 13 </ b> B of the rectilinear cylinder 13. That is, the cam cylinder 17 moves linearly while rotating as the rotary cylinder 12 rotates.

  The cam cylinder 17 is operated to move and move the barrier cylinder 15 via the driven key 15C fitted to the barrier cylinder helicoid groove 17B, and to the cam follower 16C fitted to the lens chamber drive cam groove 17C. The first group lens chamber 16 is moved through the second lens frame 18 and the second lens frame 18 is moved through the second lens frame cam follower 18A fitted in the second lens frame drive cam groove 17D.

  Here, depending on the shape of the barrier cylinder helicoid groove 17B and the lens chamber drive cam groove 17C described above, the movement situation of the barrier cylinder 15 and the first group lens chamber 16 accompanying the rotation / straight movement of the cam cylinder 17 is different. The relative positions of the barrier cylinder 15 and the first group lens chamber 16 differ between the photographing standby state shown in FIG. 1 and the retracted state shown in FIG.

  That is, in the photographing standby state shown in FIG. 1, the front surface of the first lens unit L <b> 1 held in the first lens unit chamber 16 is more than the inner blade 52 of the barrier blade 50 described later provided on the front surface of the barrier cylinder 15. Projects to the front side. In the retracted state shown in FIG. 2, the front surface of the first lens unit L <b> 1 held in the first group lens chamber 16 is located on the back side of the inner blade 52 of the barrier blade 50. Thereby, the barrier blades 50 can be closed in the retracted state. In other words, in the shooting standby state, the front surface of the first lens unit L1 protrudes to the front side of the barrier blade 50, so that a wider angle of view is obtained.

  With the above structure, the lens barrel 10 is in a photographing standby state in which the rotating cylinder 12 (straight-advanced cylinder 13) and the first-group rectilinear cylinder 14 protrude from the fixed cylinder 11 by a predetermined amount as shown in FIG. 1, and as shown in FIG. In addition, the rotating cylinder 12 and the first group rectilinear cylinder 14 are contracted / expanded between the retracted state in which the fixed cylinder 11 is almost accommodated. Note that the shooting standby state shown in FIG. 1 is the wide-angle side (the end on the side with the shortest focal length) in the zoom range, and from this state, the lens groups L1, L2, and L3 further move in the direction of the optical axis OA. Zooming to the long focus side.

A second lens frame 18 is disposed on the inner peripheral side of the cam cylinder 17.
The second lens frame 18 has a cylindrical shape that is slidably fitted to the inner periphery of the cam cylinder 17 and is formed to have a predetermined length in the direction of the optical axis OA. Holding.
A second lens frame cam follower 18 </ b> A protrudes from the outer periphery of the second lens frame 18. The second lens frame cam follower 18A is slidably fitted in the second lens frame drive cam groove 17D of the cam cylinder 17.
Further, a rectilinear guide groove 18 </ b> B is formed on the outer periphery of the second lens frame 18. A key portion 19B of a rectilinear key 19 described below is slidably fitted in the rectilinear guide groove 18B.

  The rectilinear key 19 includes a rectilinear fitting portion 19A and a key portion 19B extending on the front side. The rectilinear fitting portion 19A is fitted so that the rectilinear key groove 13D provided in the rectilinear cylinder 13 can slide. Further, the key portion 19B is slidably fitted in the rectilinear guide groove 18B of the second lens frame 18 as described above. A cam-side bayonet recess 17E is provided on the inner diameter side of the follower pin 17A planted in the cam cylinder 17, while a key-side protrusion 19E that connects the cam-side bayonet recess 17E with the cam-side bayonet recess 17E. Is provided. And the cam side bayonet recessed part 17E and the key side convex part 19E are the bayonet coupling | bonding. For this reason, the rectilinear key 19 moves in the optical axis direction together with the cam cylinder 17, but rotation is prevented by fitting the rectilinear key groove 13D and the rectilinear fitting portion 19A. The second lens frame 18 is rotated because the second lens frame cam follower 18A is operated by the second lens frame drive cam groove 17D of the cam cylinder 17 and the rectilinear key 19 is fitted in the rectilinear guide groove 18B. Without moving, it moves straight along with the rotation of the cam cylinder 17.

In the photographing standby state shown in FIG. 1, the rotary cylinder 12 (straight-advance cylinder 13) protrudes from the fixed cylinder 11 by a predetermined amount, and the first group linear cylinder 14 protrudes from the rotary cylinder 12 by a predetermined amount. In addition, the front surface of a barrier mechanism 40 (described later) provided on the front surface side of the barrier cylinder 15 substantially coincides with the front surface of the first group rectilinear cylinder 14, and the barrier blades 50 are in an open state.
In the retracted state shown in FIG. 2, the front surface of the rotating cylinder 12 (straight-forward cylinder 13) and the front surface of the first group straight-forward cylinder 14 protrude from the front surface of the fixed cylinder 11 by a predetermined amount. Further, the front surface of the barrier mechanism 40 also substantially coincides with these, and the barrier blade 50 is in a closed state.

Next, in addition to FIGS. 1 to 3 described above, the barrier mechanism 40 will be described in detail with reference to FIGS.
FIG. 4 is an exploded perspective view of the barrier mechanism 40. FIG. 5 is an exploded view of the barrier frame 41 and the barrier blades 50. 6 is a perspective view of the outer blade 51 and the inner blade 52 as seen from the image plane side, and FIG. 7 is a view of the outer blade 51 and the inner blade 52 as seen from the subject side. FIG. 8 is a cross-sectional view of the barrier blade 50 corresponding to the arrow AA in FIG. 4 in an open state. FIG. 9 is a cross-sectional view of the barrier blade 50 corresponding to the arrow BB in FIG. 4 in an open state. FIG. 10 is a view of the barrier blade 50 corresponding to FIG. 9 in a closed state. FIG. 11 is a view of a state in which the interlocking plate 44 and the barrier blade 50 corresponding to the CC arrow of FIG. 4 are combined, where (a) shows the barrier blade 50 in the open state, and (b) shows the state. Each of the barrier blades 50 indicates a closed state. FIG. 12 is an enlarged view of a portion D in FIG.

  As shown in FIG. 4 which is an exploded perspective view of the barrier mechanism 40, a barrier frame 41 is mounted on the front side of the barrier cylinder 15, and between the barrier cylinder 15 and the barrier frame 41, a barrier blade 50 and a sheet 42. The barrier pressing plate 43 and the interlocking plate 44 are arranged in a stacked state. A decorative ring 45 is put on the front side of the barrier frame 41.

The barrier cylinder 15 and the barrier frame 41 have a so-called snap-fit between the protrusion provided on the front side of the barrier cylinder 15 and the engaging part provided on the outer periphery of the barrier frame 41 so that the front side of the barrier cylinder 15 A barrier frame 41 is mounted and integrated.
As described above, the first group lens chamber 16 is disposed on the inner peripheral side of the barrier cylinder 15, and the cam cylinder 17 is disposed on the inner peripheral side of the first group lens chamber 16.
Further, as described above, the barrier operation projection 17E is projected from a predetermined position on the front side of the cam cylinder 17.

  As shown in FIG. 5, the barrier frame 41 is an annular shape having a front plate 41A on the front side, and has a predetermined thickness in the direction of the optical axis OA. The front plate 41A is formed with a barrel-shaped opening 41B (which is slightly smaller) corresponding to the front shape of the first lens unit L1. Further, on the back side of the barrier frame 41, a spring locking portion 41 </ b> C for protruding an end portion of a rotation biasing spring 46 for rotatingly biasing an interlocking plate 44 described later is provided. Two spring locking portions 41C are arranged at symmetrical positions across the optical axis OA.

  The barrier blade 50 includes an outer upper blade 51U, an outer lower blade 51L, an inner upper blade 52U, and an inner lower blade 52L. The outer upper blade 51U and the outer lower blade 51L are formed in a point-symmetric shape across the optical axis OA, and the inner upper blade 52U and the inner lower blade 52L are formed in a point-symmetric shape across the optical axis OA. Therefore, in the following description, the outer upper blade 51U and the outer lower blade 51L are referred to as the “outer blade 51”, and the inner upper blade 52U and the inner lower blade 52L are referred to as “inner unless otherwise required. This will be described as “blade 52”. Further, the blade support shaft 41Da that supports the outer upper blade 51U and the inner upper blade 52U and the blade support shaft 41Db that supports the outer lower blade 51L and the inner lower blade 52L are also combined except when particularly necessary. The blade support portion 41D will be described.

  As shown in FIG. 5, the outer blade 51 is arranged adjacent to the back side of the front plate 41 </ b> A of the barrier frame 41. As shown in FIG. 6, a hole 51 a that fits the blade support shaft 41 </ b> D of the barrier frame 41 is provided at one end in the circumferential direction of the outer blade 51. An operation projection 51b is formed on the outer peripheral side of the hole 51a. Further, an operated protrusion 51 d that is operated by the inner blade 52 protrudes from the rear side of the outer edge of the outer blade 51 in the substantially central portion in the circumferential direction.

  As shown in FIG. 5, the inner blade 52 is disposed adjacent to the back side of the outer blade 51. And as shown in FIG. 6, the hole 52a fitted to the blade | wing support shaft 41D of a barrier frame is provided in the end of the circumferential direction of the inner blade | wing 52. As shown in FIG. On the outer peripheral side of the hole 52a, a spring locking portion 52b that locks the end of a swinging biasing spring 47 that swings and biases the inner blade 52 is formed to protrude forward and backward by a predetermined amount.

  As shown in FIGS. 8 to 10, the outer upper blade 51U and the inner upper blade 52U are swingably supported by a blade support shaft 41Da located on the X axis plus side of the opening 41B. On the other hand, the outer lower blade 51L and the inner lower blade 52L are swingably supported by the blade support shaft 41Db located on the X axis minus side of the opening 41B. The outer upper blade 51U and the inner upper blade 52U swing around the blade support shaft 41Da, and the outer lower blade 51L and the inner lower blade 52L swing around the blade support shaft 41Db, thereby opening the opening 41B. Open and close.

  As shown in FIGS. 8 and 9, when the barrier blade 50 opens the opening 41B of the barrier frame 41 (open state), the outer upper blade 51U and the inner upper blade 52U overlap, and the upper side of the opening 41B. It is accommodated between the opening edge on the Y axis plus side and the outer peripheral surface of the barrier frame 41. Further, the outer lower blade 51L and the inner lower blade 52L overlap and are accommodated between the opening edge on the lower side (Y-axis minus side) of the opening 41B and the outer peripheral surface of the barrier frame 41. In this embodiment, the open state shown in FIGS. 8, 9, and 11A in which the barrier blade 50 opens the opening 41B in this way is the basic state, and the interlocking plate 44 is operated from this open state. As a result, the closed state shown in FIG. 10 and FIG.

  When the barrier blade 50 closes the opening 41B of the barrier frame 41 (closed state), as shown in FIG. 10, the outer upper blade 51U and the inner upper blade 52U are substantially above the opening 41B of the barrier frame 41. The half is covered, and the outer lower blade 51L and the inner lower blade 52L cover the substantially lower half of the opening 41B. That is, the inner edge 52c of the inner upper blade 52U and the inner lower blade 52L match to block the center of the opening 41B, and the gap between the inner upper blade 52U, the outer edge of the inner lower blade 52L, and the edge of the opening 41B, The outer upper blade 51U and the outer lower blade 51L are closed, thereby covering the entire surface of the opening 41B.

  In addition, the inner edge 51c on the inner side (optical axis OA side) of the outer blade 51 is in an opened state, slightly outside the edge of the opening 41B, on the inner side (optical axis side) of the cut end surface of the first lens unit L1. ) Set to be parallel.

  The end surface of the inner edge 51c of the outer blade 51 is formed obliquely at a predetermined angle in a direction spreading toward the back side (a direction in which the back side is away from the optical axis OA) as shown in FIG. ing. The inclination angle of the end surface of the inner edge 51c corresponds to the curved surface of the front surface of the first lens unit L1. This makes it possible to bring the front surface of the first lens unit L1 very close to the outer blade 51 during the shooting standby shown in FIG. 1, and as a result, the first lens unit L1 protrudes to the front side (subject side) as much as possible. A wider angle of view can be obtained. Note that this configuration is not necessary if the front edge of the first lens unit L1 protrudes from the outer blade 51. However, the outer blade 51 is arranged on the outer side (outward side when viewed from the optical axis). Since it becomes necessary, the outer diameter of the lens barrel 10 becomes large. Since the cut end surface of the first lens unit L1 is a portion that is not optically used in the first place, even if the inner edge 51c of the outer blade 51 is slightly overlapped with the front edge of the first lens unit L1, the optical performance is not affected. .

  The inner edge 52c on the inner side (optical axis OA side) of the inner blade 52 is from the upper and lower cut sides of the front surface portion of the first lens unit L1, as shown in FIG. It is located outside and is set so that the front surface of the first lens unit L1 can be brought close to the outer blade 51 without interfering with the inner blade 52.

  The barrier pressing plate 43 has a thin plate shape and is formed in a shape corresponding to the barrier frame 41. The barrier pressing plate 43 is provided with two screw holes at positions symmetrical with respect to the optical axis OA on the substantially X axis. As shown in FIG. 4, a screw 43A is inserted into the hole, and the screw 43A is fastened to a screw receiver 41x of the barrier frame 41 (see FIGS. 5, 9, and 10).

  The interlocking plate 44 is a substantially annular shape that fits inside the barrier frame 41. As shown in FIG. 11, the interlocking plate 44 has a locking boss 44A that locks the end of the rotation biasing spring 46, and a barrier blade 50 (inner And a fixed boss 44B to which an end of a swinging biasing spring 47 that swings and biases the blade 52) is fixed. The locking boss 44 </ b> A and the fixed boss 44 </ b> B are respectively disposed at two symmetrical positions across the optical axis OA.

  In addition, at a predetermined position on the back side of the interlocking plate 44, the operated portion 44C is projected in three locations at equal intervals (120 °) in the circumferential direction. The operated portion 44C has a function of rotating and pressing the interlocking plate 44 clockwise in FIG. 11 when the lens barrel 10 is retracted and rotated and pressed by the barrier operation projection 17E of the cam barrel 17.

  One end of the rotation biasing spring 46 is locked to the spring locking portion 41 </ b> C of the barrier frame 41, and the other end is locked to the locking boss 44 </ b> A of the interlocking plate 44. The rotation urging springs 46 are disposed at two symmetrical positions with respect to the optical axis OA. The rotation urging spring 46 urges the interlocking plate 44 to rotate counterclockwise in FIG. 11 with respect to the barrier frame 41 by its elastic restoring force.

  One end of the swing bias spring 47 is fixed to the fixed boss 44 </ b> B of the interlocking plate 44, and the other end is locked to the spring locking portion 52 b of the inner blade 52. The swing bias spring 47 is provided for each of the two inner blades 52 (the inner upper blade 52U and the inner lower blade 52L). That is, the swing urging springs 47 are disposed at two symmetrical positions with the optical axis OA interposed therebetween. The swing bias spring 47 swings and biases the inner blade 52 toward the closed side by its elastic restoring force.

The inner blade 52 oscillated and biased to the closing side by the oscillating biasing spring 47 causes the end surface 44x provided on the interlocking plate 44 to push up the inner blade 52b by the counterclockwise rotation of the interlocking plate 44, and the inner blade 52b. Rotates counterclockwise, and by this rotation, the operation recess 52d presses the operated protrusion 51d of the outer blade 51 and swings the outer blade 51 to the open state side.
As a result, the outer blade 51 and the inner blade 52 overlap with each other to be in an open state accommodated between the opening edge of the opening 41B and the outer peripheral surface of the barrier frame 41.

  In the barrier mechanism 40 configured as described above, the interlocking plate 44 is positioned at one end in a range in which the interlocking plate 44 can be rotated by the biasing force of the rotation biasing spring 46 (hereinafter referred to as a free position of the interlocking plate 44). ) In this free position, the outer blade 51 and the inner blade 52 overlap each other and are accommodated between the opening edge of the opening 41B and the outer peripheral surface of the barrier frame 41, thereby opening the opening 41B.

  Here, when the lens barrel 10 is retracted, the interlocking plate 44 is rotated by a predetermined angle against the biasing force of the rotation biasing spring 46 by the cam barrel 17. That is, the operated portion 44C of the interlocking plate 44 interferes with the barrier operation protrusion 17E of the cam cylinder 17, and the operated portion 44C is pressed by the barrier operation protrusion 17E. As a result, the interlocking plate 44 rotates by a predetermined angle. It is supposed to be. Thereby, it acts as follows and the barrier blades 50 are in a closed state.

  That is, when the interlocking plate 44 is rotated clockwise in the drawing against the biasing force of the rotation biasing spring 46 from the open state, the blade support shaft 41D that supports the outer blade 51 and the inner blade 52 is supported. The fixed boss 44B moves. As a result, the inner blade 52 is swung to the closing side via the swing biasing spring 47 installed between the fixed boss 44B and the spring locking portion 52b of the inner blade 52. When the inner blade 52 swings to the closing side, the spring locking portion 52b presses the operation projection 51b of the outer blade 51, and swings the outer blade 51 to the closing side. As a result, the outer blade 51 and the inner blade 52 are in a closed state in which the opening 41B is closed.

  When the lens barrel 10 is extended from the retracted state to enter the photographing standby state, the pressing operation on the operated portion 44C of the interlocking plate 44 by the barrier operation protrusion 17E of the cam barrel 17 is released. As a result, the interlocking plate 44 is rotated by the elastic return force of the rotation biasing spring 46 and returns to the free position. As a result, as described above, the outer blade 51 and the inner blade 52 overlap to open the opening 41B.

As described above, the barrier mechanism 40 is opened when the lens barrel 10 shown in FIG. 1 is in a shooting standby state, and the barrier blades 50 are opened and the opening 41B is opened. When the lens barrel 10 shown in FIG. The part 41B is closed by the barrier blade 50.
In the photographing standby state in which the barrier blade 50 of the barrier mechanism 40 shown in FIG. 1 is in the open state, as described above, the barrier blade 50 is overlapped with the outer upper blade 51U and the inner upper blade 52U, and the first lens unit L1. Between the opening edge on the upper side (Y-axis plus side) of the barrel-side opening 41 </ b> B corresponding to the shape of the front surface and the outer peripheral surface of the barrier frame 41. Further, the outer lower blade 51L and the inner lower blade 52L overlap and are accommodated between the opening edge on the lower side (Y-axis minus side) of the opening 41B and the outer peripheral surface of the barrier frame 41. Thereby, the barrier blades 50 can be reasonably accommodated without increasing the outer diameter of the lens barrel 10.

  Further, the end surface of the inner edge 51c of the outer blade 51 of the barrier blade 50 is an inclined surface that spreads to the back side at an angle corresponding to the curved surface of the front surface of the first lens unit L1. As a result, the front surface of the first lens unit L1 can be very close to the outer blade 51, and as a result, the first lens unit L1 projects as far as possible to the front side (subject side) to obtain a wider angle of view. Is possible.

As described above, this embodiment has the following effects.
(1) The front surface portion of the first lens unit L1 located on the foremost side in the lens barrel 10 corresponds to a horizontally long image pickup surface with a predetermined aspect ratio in the image pickup device 3A of the sensor unit 3, and has a predetermined interval in the vertical direction. It has been cut into a barrel shape. And the barrier blade | wing 50 is comprised so that it may be accommodated in the upper and lower part cut off of the 1st lens group L1. Thereby, the barrier blades 50 can be reasonably accommodated without increasing the outer diameter of the lens barrel 10, and the lens barrel 10 can be configured to be small and low cost.

(2) The inner edge 51c of the outer blade 51 that constitutes the barrier blade 50 is formed so as to be inclined in a direction (a direction in which the rear surface is separated from the optical axis OA) spreading toward the rear surface corresponding to the curved surface of the front surface of the first lens unit L1. Has been. As a result, the first lens unit L1 can be positioned closer to the front surface, and a wide angle of view can be obtained.

(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 the present embodiment, the front surface of the first lens unit L1 located on the foremost side in the lens barrel 10 is on the front side of the inner blades 52 constituting the barrier blades 50 and on the rear side of the outer blades 51 during standby for photographing. Located on the side. However, this state is not limited to shooting standby, and may be set to be in such a state when the first lens unit L1 protrudes most. Further, the front surface of the first lens unit L1 may be configured to protrude from the outer blade 51 toward the front surface side.
(2) The collapsible and zoom mechanism is not limited to the configuration described in the above embodiment, and can be changed 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, 3A: imaging device, 10: lens barrel, 15: barrier cylinder, 20: shutter mechanism, 40: barrier mechanism, 41: barrier frame, 41B: opening, 50: barrier blade, 51U: outer upper blade 51L: outer lower blade, 51c: inner edge, 52U: inner upper blade, 52L: inner lower blade, L1: first lens group, OA: optical axis

Claims (6)

Is disposed on the object side leading end, a shape whose both ends are formed respectively deleted with accommodation space facing across the optical axis lens,
A lens barrier located on the subject side of the lens in a closed state ;
A lens barrier driving unit for opening and closing the lens barrier;
And a moving means for moving the optical axis direction of the relative position between the lens barrier and the lens,
With the previous SL lens barrier is opened from the closed state by the lens barrier drive unit, at least a part of the image plane side than the end portion of the curved surface portion of the object side of the lens of the optical axis direction of the thickness of the lens barrier to be placed in the housing space is located in the lens barrel, characterized in that the said optical axis direction of the relative position is moved shooting standby state of the lens barrier and the lens by said moving means . The lens barrel according to claim 1,
The lens barrel characterized in that the accommodation space is formed so that an end surface substantially orthogonal to a direction in which the lens barrier moves when opening and closing is provided on the lens. The lens barrel according to claim 1 or 2,
The lens barrier has an outer blade located on the subject side and an inner blade located on the image side,
In the photographing standby state, at least a part of the inner blade in the thickness direction is located on the imaging surface side from the end of the curved surface portion on the subject side of the lens, and the outer blade is on the subject side of the lens. A lens barrel characterized by being positioned closer to the subject side than an end of the curved surface portion and covering an outer edge portion of the curved surface portion on the subject side surface of the lens. The lens barrel according to claim 3,
A lens barrel characterized in that a part of the outer blade that covers the outer edge portion of the curved surface portion on the subject side surface of the lens has an inclined shape corresponding to the curved surface on the subject side of the lens. The lens barrel according to any one of claims 1 to 4,
An imaging unit on which an image is formed by an optical system including the lens,
The camera is characterized in that the accommodation space is outside an effective optical path through which subject light condensed on the imaging unit passes. The camera according to claim 5,
The imaging unit is a rectangle with a different aspect ratio,
The camera is characterized in that the housing space is formed at a position corresponding to a region outside the short side direction of the imaging unit.

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