An optical element position control mechanism includes an optical element holding member which holds an optical element of a photographing system and is guided in an optical axis direction; a drive mechanism for moving the optical element holding member in the optical axis direction; and a biasing device including an arm which is swingable about a swing axis, the swing axis being substantially orthogonal to the optical axis, and the arm extending substantially orthogonal to the swing axis and having a free end portion which engages with the optical element holding member to bias the optical element holding member in the optical axis direction.
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1. An optical element position control mechanism comprising:
an optical element holding member which holds an optical element of a plurality of optical elements of a photographing system and is guided in an optical axis direction;
a drive mechanism for moving said optical element holding member in said optical axis direction;
a biasing device including an arm which is swingable about a swing axis, said swing axis being substantially orthogonal to said optical axis, and said arm extending substantially orthogonal to said swing axis and having a free end portion which engages with said optical element holding member to bias said optical element holding member in said optical axis direction; and
a rotational ring that rotates to move at least one of said optical element elements, wherein said rotational ring is provided separately from said optical element, and wherein said drive mechanism and biasing device are positioned radially outside said rotational ring.
2. The optical element position control mechanism according to
a coiled portion supported by a support member provided separately from said optical element holding member, a central axis of said coiled portion being substantially coincident with said swing axis;
a first arm portion which constitutes said arm and extends radially outwards from said coiled portion to be engaged with said optical element holding member at the free end portion thereof; and
a second arm portion which extends radially outward from said coiled portion to be engaged with said support member,
wherein said torsion spring varies an amount of resilient deformation thereof in a direction of rotation of said torsion spring about said central axis of said coiled portion in accordance with movement of said optical element holding member.
3. The optical element position control mechanism according to
4. The optical element position control mechanism according to
wherein said biasing device comprises a lever biasing member for biasing said lever in one of forward and reverse rotational directions about said swing axis.
5. The optical element position control mechanism according to
a coiled portion supported by said support member, a central axis of said coiled portion being substantially coincident with said swing axis;
a first arm portion which extends radially outwards from said coiled portion to be engaged with said lever; and
a second arm portion which extends radially outwards from said coiled portion to be engaged with a spring-hooked portion of said support member,
wherein said torsion spring varies an amount of resilient deformation thereof in a direction of rotation of said torsion spring about said central axis of said coiled portion in accordance with a swing movement of said lever.
6. The optical element position control mechanism according to
7. The optical element position control mechanism according to
8. The optical element position control mechanism according to
9. The optical element position control mechanism according to
a screw shaft which rotates on an axis thereof parallel to said optical axis; and
a nut which is screw-engaged with said screw shaft and moves forward and rearward in said optical axis direction by forward and reverse rotations of said screw shaft,
wherein a position of said optical element holding member in said optical axis direction is determined by contact of said optical element holding member with said nut, and
wherein said biasing device biases said optical element holding member in a direction to bring said optical element holding member into contact with said nut.
10. The optical element position control mechanism according to
a guide member including at least one guide surface inclined with respect to said optical axis direction; and
a follower which projects from said optical element holding member to slide on said guide surface,
wherein said follower is pressed against said guide surface of said guide member by a biasing force of said biasing device.
11. The optical element position control mechanism according to
wherein a lead groove serving as a cam groove, in which said follower is slidably engaged, is formed on a peripheral surface of said cam shaft, and
wherein said guide surface is positioned inside said lead groove.
12. The optical element position control mechanism according to
a stationary cylindrical portion positioned inside said biasing device and surrounding said photographing optical system; and
a protective wall member provided as a separate element from said stationary cylindrical portion, and fixed to said stationary cylindrical portion to create an accommodation space between an outer peripheral surface of said stationary cylindrical portion and said protective wall member, said biasing device being accommodated in said accommodation space.
13. The optical element position control mechanism according to
14. The optical element position control mechanism according to
15. The optical element position control mechanism according to
16. The optical element position control mechanism according to
17. The optical element position control mechanism according to
18. The optical element position control mechanism according to
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1. Field of the Invention
The present invention relates to a mechanism for controlling the position of an optical element in an optical apparatus, more specifically to a structure which provides an optical element holding member, movable in an optical axis direction, with a biasing force in the moving direction of the optical element holding member.
2. Description of the Related Art
In optical apparatuses such as cameras, it is often the case that a biasing force in an optical axis direction is imparted to an optical element holding member which holds an optical element and can move in the optical axis direction for the purpose of providing the optical element holding member with a role in functioning as a part of the drive mechanism for driving the optical element holding member, eliminating backlash in the drive mechanism or stabilizing the position of the optical element holding member. The biasing device for biasing the optical element holding member is usually made of an extension or compression spring which is installed so that the axis thereof extends in the optical axis direction. This configuration is disclosed in, e.g., Japanese Unexamined Patent Publication 2000-206391.
In the structure for installation of the extension or compression spring that has been widely used as a biasing device for biasing the optical element holding member, one and the other ends of the spring are respectively engaged with the optical element holding member and a separate support member (e.g., a stationary member) which is not moved with the optical element holding member so that the amount of movement of the optical element holding member directly influences on the amount of extension of the spring. The variation range of the spring load increases as the amount of extension of the spring increases.
Meanwhile, the output of the motor or actuator which serves as an element of the drive mechanism for the optical element holding member is determined to be capable of accommodating the maximum load of the biasing device for biasing the optical element holding member. Namely, the greater the maximum load of the spring member, the stronger the drive source for the optical element holding member is required, which is disadvantageous with regard to the power consumption, the production cost and miniaturization of the apparatus containing the drive source. However, in the conventional installation structure of the extension or compression spring for an optical element holding member, the spring load, which is varied according to the amount of spring extension, tends to have a large variation range, and accordingly, it is difficult to minimize the maximum spring load.
In the extension or compression spring, it is possible to achieve a reduction in load variation of the spring for a certain amount of movement of the optical element holding member by adopting an extension or compression spring having a longer length. However, in optical devices produced in recent years which are in strong demand to be miniaturized, increasing the length of the spring runs counter to space saving and thus cannot be easily adopted. In particular, in zoom lens barrels, the desire to make them compact in the lens barrel accommodated state in which no picture taking is performed has been great, and a retractable lens barrel structure in which the distances between a plurality of optical elements in the optical axis direction are minimized as much as possible to achieve a reduction of the length of the lens barrel when the lens barrel is accommodated is often adopted. Therefore, the length of the optical element holding member in the moving direction thereof is subjected to constraints of the length of the retracted lens barrel, so that it has been difficult to adopt a long spring as the biasing device for biasing the optical element holding member. As a result, the aforementioned problem of the spring load having a large variation range easily occurs.
Additionally, although the variation range of the spring load can be reduced by reducing the amount of movement of the optical element holding member, the amount of movement of the optical element holding member (namely, the amount of movement of the optical element held by the optical element holding member) is originally determined to satisfy a required optical performance, and this optical performance may not be obtained if the amount of movement of the optical element holding member is limited. For instance, in the zoom lens barrel which is constructed so as to be as small as possible in the optical axis direction when the zoom lens barrel comes into the lens barrel accommodated state as mentioned above and which is designed as a high powered lens, the amount of movement of the optical element holding member tends to be great.
The present invention provides an optical element position control mechanism in which the load variation of the spring for biasing the optical element holding member that is caused by movement of the optical element holding member is small even though the mechanism can be structured in a space-saving manner, and in which both miniaturization and low power consumption are achieved at a high level.
In addition, the present invention provides an optical element position control mechanism which includes such a biasing device which has reduced load variation, wherein the biasing device is securely protected from damage which may be caused by external or internal contact of other elements or an assembly worker's hand with the biasing device.
According to an aspect of the present invention, an optical element position control mechanism is provided, including an optical element holding member which holds an optical element of a photographing system and is guided in an optical axis direction; a drive mechanism for moving the optical element holding member in the optical axis direction; and a biasing device including an arm which is swingable about a swing axis, the swing axis being substantially orthogonal to the optical axis, and the arm extending substantially orthogonal to the swing axis and having a free end portion which engages with the optical element holding member to bias the optical element holding member in the optical axis direction.
It is desirable for the biasing device to include a torsion spring including a coiled portion supported by a support member provided separately from the optical element holding member, a central axis of the coiled portion being substantially coincident with the swing axis; a first arm portion which constitutes the arm and extends radially outwards from the coiled portion to be engaged with the optical element holding member at the free end portion thereof; and a second arm portion which extends radially outward from the coiled portion to be engaged with the support member. The torsion spring varies an amount of resilient deformation thereof in a direction of rotation of the torsion spring about the central axis of the coiled portion in accordance with movement of the optical element holding member.
It is desirable for an amount of angular displacement of the first arm portion in a rotation direction thereof from a free state of the first arm portion at which the first arm portion is disengaged from the optical element holding member until when the first arm portion comes into a force-applied state at which the first arm portion is engaged with the optical element holding member to be greater than an amount of angular displacement of the first arm portion in the rotation direction thereof between a forward movement limit and a rearward movement limit of the optical element holding member in the force-applied state.
It is desirable for the arm of the biasing device to include a lever pivoted at one end thereof on a support member, which is provided separately from the optical element holding member, the other end of the lever being engaged with the optical element holding member, and for the biasing device to include a lever biasing member for biasing the lever in one of forward and reverse rotational directions about the swing axis.
It is desirable for the lever biasing member includes a torsion spring including a coiled portion supported by the support member, a central axis of the coiled portion being substantially coincident with the swing axis; a first arm portion which extends radially from the coiled portion outwards to be engaged with the lever; and a second arm portion which extends radially outwards from the coiled portion to be engaged with a spring-hooked portion of the support member. The torsion spring varies an amount of resilient deformation thereof in a direction of rotation of the torsion spring about the central axis of the coiled portion in accordance with a swing movement of the lever.
It is desirable for the lever biasing member to include an extension spring, one end and the other end of which are engaged with the lever and the support member, respectively, a length of the extension spring varying in accordance with a swing movement of the lever.
It is desirable for a distance from the swing axis to an engaging portion of the lever which engages with the extension spring to be smaller than a distance from the swing axis to an engaging portion of the lever which engages with the optical element holding member.
It is desirable for the optical element position control mechanism to include a rotational ring which moves at least one optical element provided separately from the optical element by rotation of the rotational ring, and for the drive mechanism and the biasing device to be positioned radially outside the rotational ring. According to this configuration, the biasing device can be configured with no restrictions of a movable member such as a rotational ring.
It is desirable for the swing axis and the free end portion of the arm of the biasing device to be positioned outside the rotational ring in one and the other of two spaces provided on both sides of a plane, respectively, which is substantially parallel to the swing axis and lies on the optical axis. Accordingly, the load variation of the biasing device can be reduced in an effective manner, and also space utilization can be enhanced.
It is desirable for the drive mechanism to include a screw shaft which rotates on an axis thereof parallel to the optical axis; and a nut which is screw-engaged with the screw shaft and moves forward and rearward in the optical axis direction by forward and reverse rotations of the screw shaft. A position of the optical element holding member in the optical axis direction is determined by contact of the optical element holding member with the nut. The biasing device biases the optical element holding member in a direction to bring the optical element holding member into contact with the nut.
It is desirable for the drive mechanism to include a guide member including at least one guide surface inclined with respect to the optical axis direction; and a follower which projects from the optical element holding member to slide on the guide surface. The follower is pressed against the guide surface of the guide member by a biasing force of the biasing device.
It is desirable for the guide member to include a cam shaft extending in the optical axis direction, wherein a lead groove serving as a cam groove, in which the follower is slidably engaged, is formed on a peripheral surface of the cam shaft, and the guide surface is positioned inside the lead groove.
It is desirable for the optical element position control mechanism to include a stationary cylindrical portion positioned inside the biasing device and surrounding the photographing optical system; and a protective wall member provided as a separate element from the stationary cylindrical portion, and fixed to the stationary cylindrical portion to create an accommodation space between an outer peripheral surface of the stationary cylindrical portion and the protective wall member, the biasing device being accommodated in the accommodation space.
It is desirable for the protective wall member to be integral with an image pickup device holder which holds an image pickup device so that the image pickup device lies at an image forming position.
It is desirable for one of the stationary cylindrical member and the protective wall member to include a swing movement support projection which supports a swing center portion of the biasing device to allow a swing movement of the arm about the swing axis.
It is desirable for the protective wall member to include a side wall portion substantially parallel to a swing plane in which the arm of the biasing device swings about the swing axis.
It is desirable for the stationary cylindrical member to include a rotational-ring guide mechanism, provided on an inner peripheral surface of the stationary cylindrical member almost over an entire circumferential range of the stationary cylindrical member, for rotationally guiding a rotational ring, positioned inside the stationary cylindrical member, to control a position of the rotational ring in the optical axis direction. The rotational ring moves at least one optical element provided separately from the optical element by rotation of the rotational ring.
It is desirable for the optical element holding member to be guided linearly without rotating about the optical axis.
It is desirable for the drive mechanism to include a motor and a reduction gear train.
According to the present invention, an optical element position control mechanism is achieved in which load variation of the spring for biasing the optical element holding member that is caused by movement of the optical element holding member is small even though the mechanism can be structured in a space-saving manner, and in which both miniaturization and low power consumption are achieved at a high level.
In addition, the biasing device can be securely protected independently of the shape of the stationary cylindrical member because the biasing device that biases the optical element holding member by swinging about an axis substantially orthogonal to a plane parallel to the optical axis is installed between the stationary cylindrical member and the protective wall member that is provided as a separate member from the stationary cylindrical member.
The present disclosure relates to subject matter contained in Japanese Patent Applications No. 2007-291656 (filed on Nov. 9, 2007) and No. 2008-174689 (filed on Jul. 3, 2008) which are expressly incorporated herein by reference in their entireties.
The present invention will be described below in detail with reference to the accompanying drawings in which:
Firstly, the overall structure of a zoom lens barrel 1 to which an optical element position control mechanism according to the present invention is applied will be hereinafter discussed with reference mainly to
The zoom lens barrel 1 is provided with a photographing optical system which includes a first lens group LG1, a second lens group LG2, a set of shutter blades (mechanical shutter) S that also serves as a diaphragm, a third lens group LG3, a low-pass filter (optical filter) LPF and an image-pickup device (image sensor) 24 such as CCD or CMOS, in that order from the object side. This photographing optical system is configured as a zoom optical system. A focal-length varying operation (zooming operation) is performed by moving the first lens group LG1 and the second lens group LG2 along an optical axis O of the photographing optical system in a predetermined moving manner, and a focusing operation is carried out by moving the third lens group LG3 along the optical axis O. In the following descriptions, the expression “optical axis direction” includes the direction parallel to the optical axis O of the photographing optical system.
The zoom lens barrel 1 is provided with a housing (support member) 22 which supports the optical system from the first lens group LG1 to the third lens group LG3 inside the housing 22 to allow these lens groups to move in the optical axis direction. The zoom lens barrel 1 is provided with an image-pickup device holder (image-pickup device holding member) 23 which is fixed to the back of the housing 22. An opening is formed in a central portion of the image-pickup device holder 23, and the image-pickup device 24 is held in the opening via an image-pickup device frame 62. A filter frame 21 which is fixed to the front of the image-pickup device frame 62 holds the low-pass filter LPF. A packing (sealing member) 61 for dust prevention is tightly held between the low-pass filter LPF and the image-pickup device 24. The image-pickup device frame 62 is supported by the image-pickup device holder 23 to make a tilt adjustment of the image-pickup device frame 62 relative to the image-pickup device holder 23 possible.
The housing 22 is provided around a cylindrical portion (stationary cylindrical portion) 22a thereof with a zoom motor support portion 22b, an AF mechanism mounting portion 22c and a front wall portion 22d. The cylindrical portion 22a surrounds the optical axis O, the zoom motor support portion 22b supports a zoom motor 32, the AF mechanism mounting portion 22c supports an AF motor (an element of a drive mechanism) 30, and the front wall portion 22d is positioned in front of the AF mechanism mounting portion 22c. The cylindrical portion 22a supports the aforementioned optical elements such as each lens group inside the cylindrical portion 22a and forms a substantial outer-shape of the zoom lens barrel 1. The zoom motor support portion 22b, the AF mechanism mounting portion 22c and the front wall portion 22d are positioned radially outside the cylindrical portion 22a about the optical axis O. As shown in
The zoom lens barrel 1 is provided with a third lens group frame (optical element holding member) 51 which holds the third lens group LG3. The third lens group frame 51 is provided with a pair of guide arm portions 51b and 51c which are formed to extend from a central lens holding portion 51a of the third lens group frame 51 in substantially opposite radial directions symmetrical with respect to the optical axis O. The guide arm portion 51b is provided in the vicinity of the radially outer end thereof with a pair of guide holes (front and rear guide holes which align in the optical axis direction) 51d into which a third lens group guide shaft (advancing/retracting movement guide member) 52 is inserted to be freely slidable relative to the pair of guide holes 51d. The third lens group guide shaft 52 is fixed at the front and rear ends thereof to the housing 22 and the image-pickup device holder 23, respectively. As shown in
The zoom lens barrel 1 is provided inside the zoom motor support portion 22b of the housing 22 with a reduction gear train which transfers the driving force of the zoom motor 32 to a zoom gear 31 (see
The zoom lens barrel 1 is provided inside the cylindrical portion 22a of the housing 22 with a first advancing barrel 13 and a linear guide ring 10 which are supported inside the cylindrical portion 22a with the cam ring 11 being positioned between the first advancing barrel 13 and the linear guide ring 10. The first advancing barrel 13 is guided linearly in the optical axis direction by the engagement of linear guide projections 13a which project radially outwards from the first advancing barrel 13 with linear guide grooves 22h which are formed on an inner peripheral surface of the cylindrical portion 22a, respectively, and the linear guide ring 10 is guided linearly in the optical axis direction by the engagement of linear guide projections 10a which project radially outwards from the linear guide ring 10 with linear guide grooves 22i which are formed on an inner peripheral surface of the cylindrical portion 22a, respectively. Each of the first advancing barrel 13 and the linear guide ring 10 is coupled to the cam ring 11 to be rotatable relative to the cam ring 11 and to move with the cam ring 11 in the optical axis direction.
The linear guide ring 10 guides a second lens group moving frame 8 linearly in the optical axis direction by linear guide keys 10b (see
The cam ring 11 is provided on an inner peripheral surface thereof with second-lens-group control cams 11c, and the second lens group moving frame 8 is provided on an outer peripheral surface thereof with cam followers 8a, for moving the second lens group LG2, which are slidably engaged in the second-lens-group control cams 11c, respectively. Since the second lens group moving frame 8 is guided linearly in the optical axis direction via the linear guide ring 10, a rotation of the cam ring 11 causes the second lens group moving frame 8 (the second lens group LG2) to move in the optical axis direction in a predetermined moving manner in accordance with the contours of the second-lens-group control cam grooves 11c.
The second advancing barrel 12 is provided with cam followers 12b, for moving the first lens group LG1, which project radially inwards, and the cam ring 11 is provided on an outer peripheral surface thereof with first-lens-group control cam grooves 11d in which the cam followers 12b are slidably engaged, respectively. Since the second advancing barrel 12 is guided linearly in the optical axis direction via the first advancing barrel 13, a rotation of the cam ring 11 causes the second advancing barrel 12 (the first lens group LG1) to move in the optical axis direction in a predetermined moving manner in accordance with the contours of the first-lens-group control cam grooves 11d.
The second lens group moving frame 8 and the second advancing barrel 12 are biased in opposite directions away from each other by an inter-lens-group biasing spring 27 to improve the degree of precision of the engagement between each cam follower 8a and the associated second-lens-control cam groove 11c and the degree of precision of the engagement between each cam follower 12b and the associated first-lens-group control cam groove 11d.
The zoom lens barrel 1 is provided inside the second lens group moving frame 8 with a shutter unit 15 including the shutter blades S which is supported by the second lens group moving frame 8. The zoom lens barrel 1 is provided behind the second lens group moving frame 8 with a rear-mounted limit member 5, and the second lens group moving frame 8 and the rear-mounted limit member 5 are provided with a guide projection 8b and a guide projection 5a as a pair of projections which project in directions toward each other along a direction parallel to the optical axis O. The shutter unit 15 is supported by the two guide projections 8b and 5a to be slidable thereon in the optical axis direction.
A decorative plate 16 having a photographing aperture 16a is fixed to the front end of the second advancing barrel 12, and the zoom lens barrel 1 is provided immediately behind the decorative plate 16 with a set of protective barrier blades 17 which opens and shuts the photographing aperture 16a that is positioned in front of the first lens group LG1.
Operations of the zoom lens barrel 1 that has the above described structure will be discussed hereinafter. In the lens barrel accommodated state shown in
Namely, the amount of advancement of the first lens group LG1 from the lens barrel accommodated state is determined by the sum of the amount of forward movement of the cam ring 11 relative to the housing 22 and the amount of advancement of the second advancing barrel 12 relative to the cam ring 11, and the amount of advancement of the second lens group LG2 from the lens barrel accommodated state is determined by the sum of the amount of forward movement of the cam ring 11 relative to the housing 22 and the amount of advancement of the second lens group moving frame 8 relative to the cam ring 11. A zooming operation is carried out by moving the first lens group LG1 and the second lens group LG2 on the optical axis O while changing the air distance between the first lens group LG1 and the second lens group LG2. Driving the zoom motor 32 in a barrel-advancing direction so as to advance the zoom lens barrel from the lens barrel accommodated state shown in
The set of shutter blades S are positioned behind the second lens group LG2 when the zoom lens barrel 1 is in a ready-to-photograph state as shown in
The third lens group frame 51 that supports the third lens group LG3 can be moved forward and rearward in the optical axis direction by the AF motor 30 independently of the above described driving operations of the first lens group LG1 and the second lens group LG2 that are performed by the zoom motor 32. In addition, when the zoom lens barrel 1 is in a ready-to-photograph state at any focal length from the wide-angle extremity to the telephoto extremity, the third lens group frame 51 that supports the third lens group LG3 is moved along the optical axis direction to perform a focusing operation by driving the AF motor 30 in accordance with object distance information obtained by a distance measuring device (not shown) provided in, e.g., the camera to which the zoom lens barrel 1 is mounted.
The details of the position control mechanism for controlling the position of the third lens group frame 51 will be discussed hereinafter. As described above, the AF mechanism mounting portion 22c is formed on the housing 22 so as to be positioned outside the cylindrical portion 22a, and the front wall portion 22d is formed on the housing 22 so as to be positioned in front of the AF mechanism mounting portion 22c to face thereto. The AF motor 30 is fixed to the front of the AF mechanism mounting portion 22c by a set screw 33 so that a pinion 30a fixed on the rotary shaft of the AF motor 30 projects rearward from the back surface of the AF mechanism mounting portion 22c (
The third lens group frame 51 is provided at the radially outer end of the guide arm portion 51b with a nut abutting portion 51f. A through hole into which the lead screw 36 is inserted is formed through the nut abutting portion 51f. An AF nut (an element of the drive mechanism) 37 which is screw-engaged with the lead screw 36 is installed in front of the nut abutting portion 51f. The AF nut 37 is prevented from rotating by the engagement of an anti-rotation recess 37a (see
The zoom lens barrel 1 is provided therein with a torsion spring 38 serving as a biasing device which gives the third lens group frame 51 a biasing force in a direction to move the third lens group frame 51 along the optical axis O. The torsion spring 38 has a coiled portion (swing center portion) 38a. The coiled portion 38a is supported by a spring support projection (swing movement support projection) 22j formed on the housing 22. The spring support projection 22j is shaped into a cylindrical projection and formed on an outer surface of the cylindrical portion 22a with the axis of the spring support projection 22j extending in a direction substantially orthogonal to a vertical plane P1 (see
The torsion spring 38 is provided with a short support arm portion (second arm portion) 38b and a long biasing arm portion (arm/first arm portion) 38c each of which projects radially outward from the coiled portion 38a. The short support arm portion 38b is hooked onto a spring hook (projection) 22k (see
When in a free state where the biasing arm portion 38c is not hooked on the spring hook 51h, the biasing arm portion 38c extends vertically downward from the coiled portion 38a with respect to
In this manner, the third lens group frame 51, to which a biasing force toward the front in the optical axis direction is applied by the torsion spring 38, is prevented from moving forward by the abutment of the nut abutting portion 51f against the AF nut 37. Namely, as shown in
An origin position sensor 40 for detecting the limit of rearward movement of the third lens group frame 51 in the optical axis direction that is moved by the AF motor 30 is installed in the housing 22. The origin position sensor 40 is made of a photo-interrupter which includes a body having a U-shaped cross section with a light emitter and a light receiver which are provided thereon so as to face each other with a predetermined distance therebetween, and it is detected that the third lens group frame 51 is positioned at the limit of rearward movement thereof when a sensor interrupt plate 51i formed integral with the third lens group frame 51 passes between the light emitter and the light receiver. The AF motor 30 is a stepping motor. The amount of movement of the third lens group LG3 when a focusing operation is performed is calculated as the number of steps for driving the AF motor 30 with the limit of rearward movement being taken as the point of origin.
The limit of rearward movement of the third lens group frame 51 in the range of movement thereof that is controlled by the AF motor 30 is shown by a solid line in
To reduce the load variation, namely, to reduce the difference in length of the extension spring 38′ between the maximum length Lmax and the minimum length Lmin, it is conceivable that an extension spring having a longer length in a free state will be adopted as the extension spring 38′. However, if such a long extension spring is adopted as the extension spring 38′, a corresponding larger space will be necessary, which runs counter to the demand for miniaturization of the zoom lens barrel. The comparative example shown in
If the range of movement of the third lens group frame 51′ is reduced (if the limit of rearward movement of the third lens group frame 51′ is set in front of that shown by a solid line in
Although the extension spring 38′ is used in the comparative example shown in
In contrast, in the above described embodiment of the optical element position control mechanism that uses the torsion spring 38 as a biasing device for biasing the third lens group frame 51, the load variation of the torsion spring 38 is far smaller than that in the comparative example and also the maximum load of the spring is smaller than that in the comparative example even though the torsion spring 38 is a biasing device installed in an installation space which is equal in size to that in the comparative example as can be understood by the comparison between the graphs in
As described above, in the torsion spring 38, the amount of angular displacement (θv) of the biasing arm portion 38c in the force-applied state between the limit of forward movement and the limit of rearward movement of the third lens group frame 51 is smaller than the minimum swing angle (θmin) of the biasing arm portion 38c, which ranges from a free state thereof until when the torsion spring 38 comes into the force-applied state, and a conditional expression “θv/θmin<1” is satisfied, which minimizes the load variation in the force-applied state. Although the degree of the minimum swing angle θmin is set to substantially a half rotation in the embodiment shown in
Also, one of the factors which have minimized the load variation of the torsion spring 38 is the length of the biasing arm portion 38c from the coiled portion 38a, about which the biasing arm portion 38c swings, to the force application point (working point) on the third lens group frame 51. The greater the length of the biasing arm portion 38 from the swing axis 38x to the force application point, i.e., the greater the radius of rotation of the swing operation of the torsion spring 38 in the vicinity of the free end thereof, the smaller the displacement angle (θv) of the biasing arm portion 38c per unit of displacement of the third lens group frame 51, thereby making it possible to curb variations in the spring load. Assuming a horizontal plane P2 which is substantially parallel to the swing axis 38x of the torsion spring 38 and includes the optical axis O, the spring hook 51h at which the biasing arm portion 38c is hooked onto the third lens group frame 51 is positioned in the area above the horizontal plane P2 as shown in
In addition, also in regard to the shape of the front projection view of the zoom lens barrel 1, the position control mechanism for controlling the position of the third lens group frame 51 that includes the torsion spring 38 has been installed in the zoom lens barrel 1 in a space saving manner. As shown in
As described above, the mechanism for biasing the third lens group frame 51 by the torsion spring 38 in the above described embodiment of the optical element position control mechanism can reduce load on the AF motor 30 to thereby achieve a reduction in power consumption of the AF motor 30 while contributing to miniaturization of the zoom lens barrel 1, especially to a reduction of the length of the zoom lens barrel 1 in the accommodated state.
A second embodiment of the optical element position control mechanism according to the present invention will be hereinafter discussed with reference to
A torsion spring (biasing device) 138 is supported by an outer peripheral surface of a cylinder-shaped spring support projection (swing movement support portion) 122j with a coiled portion (swing center portion) 138a of the torsion spring 138 being fitted on the spring support projection 122j and with the axis of the coiled portion 138a extending in a direction orthogonal to the optical axis O. The position of the spring support projection 122j is fixed. The torsion spring 138 includes a support arm portion (second arm portion) 138b and a biasing arm portion (arm/first arm portion) 138c both of which project radially outwards from the coiled portion 138a, and the support arm portion 138b is engaged with a fixed projection 122k while the free end of the biasing arm portion 138c is engaged with a spring hook (projection) 151c of the lens frame 151. In this spring-engaged state, the biasing arm portion 138c of the torsion spring 138 can swing about a swing axis 138x which is substantially orthogonal to the optical axis O and substantially coincident with the axis of the coiled portion 138a that is supported by the spring support projection 122j, and biases the lens frame 151 forward in the optical axis direction (leftward direction with respect to
According to the torsion spring 138, in a similar manner to the torsion spring 38 of the first embodiment, variations of the spring load in the force-applied state can be reduced and loads on the motor 130 can be reduced when the lens frame 151 is moved forward and rearward in the optical axis direction via the motor 130 and the lead cam shaft 136. In addition, similar to the position control mechanism for controlling the position of the third lens group frame 51 that includes the torsion spring 38, the space for the installation of the torsion spring 138 does not increase even if the amount of rotation of the biasing arm portion 138c is changed when the torsion spring 138 is brought to come into the force-applied state from a free state, hence, the position control mechanism for controlling the position of the lens frame 151 that includes the torsion spring 138 is installed in a space saving manner. Additionally, as can be understood from the second embodiment shown in
The torsion spring 38 that is made of a single torsion spring in the above described first embodiment is the biasing device which biases the third lens group frame 51, and the torsion spring 138 that is made of a single torsion spring in the above described second embodiment is the biasing device which biases the lens frame 151. However, the biasing device is not limited to such a single torsion spring if the biasing device satisfies the requirement that the biasing device gives a biasing force to the optical element holding member (51 or 151) via a swingable force-applied portion (arm) capable of swinging about the swing axis which is substantially orthogonal to the optical axis of the optical element held by the optical element holding member.
Third through fifth embodiments of zoom lens barrels that use different biasing devices will be hereinafter discussed with reference to
In the third embodiment shown in
The swing lever 70 itself has no resiliency in the swinging direction thereof. However, with a biasing force given to the swing lever 70 from the torsion spring 238, a combination of the biasing arm portion 238c of the torsion spring 238 and the swing lever 70 substantially functions as a swingable force-applied portion, similar to the biasing arm portion 38c of the torsion spring 38 in the first embodiment of the optical element position control mechanism or the biasing arm portion 138c of the biasing spring 138 in the second embodiment of the optical element position control mechanism. Therefore, just like the biasing devices of the previous (first and second) embodiments, the load on the AF motor 30 can be reduced by reducing the load variation in the force-applied state to the third lens group frame 51 even through the biasing device can be arranged in a space-saving manner in the optical axis direction. Unlike the third embodiment, it is possible to make the coiled portion 238a of the torsion spring 238 supported by a support portion different from the swing support projection 22m of the swing lever 70.
A fourth embodiment shown in
A fifth embodiment shown in
In the fourth embodiment, it is desirable that the ratio between the length of the main arm 70b of the swing lever 70 (D1) and the length of the spring-hooked arm 70c (D2) satisfy the following conditional expression: D2<D1/2. Likewise, in the fifth embodiment, it is desirable that the ratio between the length of the main arm 70b of the swing lever 70 (D1) and the length of the spring-hooked arm 70d (D3) satisfy the following conditional expression: D3<D1/2.
As can be understood from the fourth and fifth embodiments, with the swing lever 70 provided as a biasing device for biasing the third lens group frame 51, the load variation of the biasing device can be reduced by a structure which is designed compact in the optical axis direction even if an extension spring which expands and contracts in the axial direction thereof is adopted instead of a torsion spring. From this point of view, a similar effect is obtained even if the extension spring 338 or 438 in the fourth or fifth embodiment is replaced by a biasing device composed of a combination of a compression spring and a swing lever.
Although the support arm portion 38b of the torsion spring 38 in the first embodiment, the support arm portion 238b of the torsion spring 238 in the third embodiment, and one end of each of the extension springs 338 and 438 of the fourth and fifth embodiments are each engaged with a projection (22k, 122k, 22n, 22p or 22q) formed on the housing 22, the member on which this projection is formed is not limited to a stationary member such as the housing 22 and can be a movable member as long as the relative position in the optical axis direction between the member on which the projection is formed and at least the optical element holding member corresponding to the third lens group frame 51 varies. Likewise, the support member which pivots the lever member 70 in the third through fifth embodiments is not limited to a stationary member such as the housing 22 and can be a movable member as long as the relative position between the member on which the projection is formed and at least the optical element holding member corresponding to the third lens group frame 51 varies.
In the biasing device in each of the above described embodiments of the zoom lens barrels, the effect of reducing the load variation of the biasing device increases as the distance from the swing axis to the force-applied portion to the optical element holding member is increased. However, increasing this distance causes an increase of the length of the force-applied portion, thus increasing a possibility of the force-applied portion interfering with other elements of the lens barrel. Consequently, the biasing device needs to be installed radially outer part of the lens barrel, not in a radially central portion thereof where movable members are densely arranged. However, if the biasing device is installed in a radially outer part of the lens barrel, it is desirable for the biasing device to be protected because the chance of the biasing device being deformed by elements in the close vicinity thereof contacting the biasing device from the outer side and of positional errors occurring increases. Nevertheless, it is sometimes difficult to protect the biasing device by a housing of the lens barrel.
For instance, in the first embodiment of the optical element holding mechanism, by lengthening the biasing arm portion 38c with the torsion spring 38 being positioned outside the cylindrical portion 22a of the housing 22, the effect of reducing the load variation of the biasing device can be obtained even though the torsion spring 38 is not protected by the housing 22 as shown in
In order to protect the torsion spring 38 under such conditions, in the zoom lens barrel 1, the image-pickup device holder 23 that is fixed to the back of the housing 22 is provided with a protective wall portion (protective wall member) 23c which covers the outside of the torsion spring 38. As shown in
When the image-pickup device holder 23 is fixed to the housing 22, the image-pickup device holder 23 is made to slide on the housing 22 forwardly with the side edge of the box-shaped portion 23e being slidingly supported by the stepped portion 22r-1 of the lower support portion 22r thereon. Subsequently, upon the main part of the image-pickup holder 23 coming into contact with a rear surface of the housing 22, the front edge of the protective wall portion 23c also comes into contact with the front wall portion 22d and engages with the stepped portion 22d-1. Thereupon, the protective wall portion 23c totally covers the outside of the torsion spring 38 as shown in
In this manner, the torsion spring 38 that is positioned outside the housing 22 can be protected from damage because the image-pickup device holder 23 that is fixed to the housing 22 is provided with the protective wall portion 23c that covers the outside of the torsion spring 38 in a state where the image-pickup device holder 23 is fixed to the housing 22. Specifically, the biasing device protective structure for protecting the torsion spring 38 from damage is superior in its capability of reliably protecting the torsion spring 38 independently of the shape of the housing 22 even in a structure in which it is difficult to form a wall portion for covering the torsion spring 38 on the outside of the cylindrical portion 22a by plastic molding. In the housing 22, each of the front wall portion 22d and the lower support portion 22r, both of which are made to contact the protective wall portion 23c, is a plate-like portion projecting from an outer peripheral surface of the cylindrical portion 22a and can be molded by drawing out a molding die in the same direction as the spring support projection 22j, thus being capable of being molded as a part of the housing 22, unlike the protective wall portion 23c.
Although the torsion spring 38 of the first embodiment has been illustrated as an element which is to be protected by the protective wall portion 23c of the image-pickup device holder 23 in the above descriptions, the biasing device protective structure using the protective wall portion 23c is applicable to the biasing device of the other embodiments described above. The swing lever 70 in each of the third through fifth embodiments has the merit of not being easily deformed compared with the biasing arm portion 38c of the torsion spring 38 if something were to externally contact the swing lever 70, and accordingly, the biasing device protective structure using the protective wall portion 23c is effective especially when the biasing device is a torsion spring.
Additionally, although
Although the above described embodiments according to the present invention have been discussed with reference to the accompanied drawings, the present invention is not limited solely to these particular embodiments. For instance, although an optical element moved forward and rearward in the optical axis direction is provided as a lens group for focusing in the above illustrated embodiments, the present invention is also applicable to a position control mechanism for controlling the position of an optical element other than a lens group for focusing.
In addition, although the biasing device in each of the above described embodiments imparts a biasing force forward in the optical axis direction to the optical element holding member, the present invention is not limited to this particular biasing direction of the biasing device. Namely, the biasing device can be of a type which imparts a biasing force rearward in the optical axis direction, i.e., in a direction opposite to that of the optical element holding member.
In addition, although the spring support projection 22j and the swing support projection 22m, which support the torsion spring 38 and the swing lever 70, respectively, are formed on the cylindrical portion 22a of the housing 22 in each of the above described first, third, fourth and fifth embodiments, it is possible for similar swing member support projections to be formed on the protective wall portion 23c of the image-pickup device holder 23.
Obvious changes may be made in the specific embodiments of the present invention described herein, such modifications being within the spirit and scope of the invention claimed. It is indicated that all matter contained herein is illustrative and does not limit the scope of the present invention.
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