JP4684766B2 - Lens barrel, lens driving device, camera, and portable information terminal device - Google Patents

Description

  The present invention relates to a lens barrel that retracts a lens group in one form, and extends and uses the lens group to a predetermined position in another form. In particular, the focal length is obtained by relatively moving a plurality of lens groups. The present invention relates to a lens barrel, a lens driving device, a camera, and a portable information terminal device suitable for a zoom lens that can change the zoom lens.

  Recent imaging devices such as digital cameras are equipped with a photographing lens such as a zoom lens whose focal length can be changed. With the progress of high performance and miniaturization of this photographing lens, a lens barrel other than during photographing is used. There is an increase in the use of a so-called collapsible photographic lens that is housed in the image pickup apparatus main body. In order to reduce the size, it is important to reduce the thickness of the lens barrel portion in the retracted state to the limit due to the demand for further thinning.

  As a technique for thinning such an imaging device, a lens barrel retracting mechanism in which the lens barrel is housed in the imaging device main body other than during photographing, and a part of the lens light mainly when the lens barrel is retracted. A configuration for retracting from the axis is used.

Patent Document 1 and Patent Document 2 described later disclose such techniques. According to the configurations disclosed in Patent Document 1 and Patent Document 2, when the lens barrel is stored, a part of the lens is retracted from the optical axis, so that the overall size of the lens barrel in the optical axis direction is reduced. And the thickness of the imaging device can be reduced.
JP 2003-315861 A JP 2003-149723 A

  However, in the configurations disclosed in Patent Document 1 and Patent Document 2, the position of the lens retracted from the optical axis is substantially inside the maximum outer diameter of the lens barrel. Therefore, these lens barrels can reduce the thickness of the imaging device when the lens is housed, but the outer diameter of the lens barrel is smaller than when the lens is not retracted from the optical axis. Increase.

  Accordingly, the size of the lens barrel, for example, the size in a plane orthogonal to the optical axis increases, and as a result, the size of the imaging device, particularly when viewed from the front, increases, There is a problem that the size of the direction is still large, and there is a problem that it takes time to swing a part of the lens when the lens is retracted from the optical axis or when the lens is changed from the retracted position to the photographing position.

  An object of claim 1 of the present invention is to divide the drive mechanism of the retractable lens holding frame that retracts from the lens optical axis at the time of photographing into a drive mechanism that requires high accuracy and a drive mechanism that does not require high accuracy, and It is to reduce the dimension in the photographic optical axis direction without increasing the size of the drive mechanism in the direction perpendicular to the optical axis, and to shorten the time for the swing operation between the photographic position and the retracted position.

  The object of claim 2 of the present invention is to reduce the size in the photographic optical axis direction and simplify the drive control of the retractable lens holding frame, in particular, without newly providing a driving means for retracting the lens holding frame. There is.

  The object of the third aspect of the present invention is to reduce the dimension in the photographing optical axis direction effectively, particularly with a simple configuration.

  A fourth object of the present invention is to make it possible to effectively reduce the dimension in the photographing optical axis direction with a simpler configuration, and to simplify the drive control of the lens holding frame.

  An object of claim 5 of the present invention is to simplify the drive control of the lens holding frame, particularly by making it possible to reduce the dimension in the photographing optical axis direction with a simpler configuration.

  An object of claim 6 of the present invention is to simplify the drive control of the lens holding frame, particularly by making it possible to reduce the dimension in the photographing optical axis direction with a simpler configuration.

  An object of claim 7 of the present invention is to simplify the drive control of the lens holding frame, particularly with a simpler configuration.

In order to solve the above-described problem, in the lens barrel according to claim 1 of the present application, at least a part of the plurality of lens groups is retracted to house the lens group, and at least a part of the lens group is moved to the objective side. A lens barrel that is configured to be photographed by moving; a plurality of lens holding frames that hold the plurality of lens groups for each lens group; and a lens holding frame driving unit that drives the lens holding frame; In a lens barrel comprising
The plurality of lens holding frames position all the lens groups on the same optical axis from the retracted state in a state where photographing is possible, and in the retracted state, at least one lens group among the plurality of lens holding frames is A retractable lens holding frame for holding and moving the at least one lens group to retract outside the maximum outer diameter of the lens barrel of the other lens group;
The drive mechanism for the retractable lens holding frame includes a first drive mechanism that swings the retractable lens holding frame in a direction approaching and separating from the optical axis when switching between a retracted state and a photographable state; The second drive mechanism that moves the retractable lens holding frame in the same direction as the optical axis in a state where photographing is possible is driven by different drive sources, and the retractable lens holding frame is configured to hold the lens group holding position. It has a crank-like bent portion for positioning on the subject side in the optical axis direction from the center position of the swing .

A lens barrel according to a second aspect of the present invention is the lens barrel according to the first aspect, wherein the first drive mechanism of the retractable lens holding frame is capable of photographing with the retracted state of the retractable lens holding frame. to swing operation of switching the bets, characterized in that it is driven by a third driving mechanism for driving the other lens groups other than the retractable lens retaining frame.
The lens barrel according to claim 3 of the present application is the lens barrel according to any one of claims 1 and 2, wherein the second drive mechanism moves the retractable lens holding frame along the optical axis. It is characterized by including the lead screw extended.
A lens barrel according to a fourth aspect of the present invention is the lens barrel according to any one of the first to third aspects, wherein the first driving mechanism includes the retractable lens holding frame and the other lens. An urging means for constantly urging in a direction approaching the optical axis of the group; and a protrusion protruding from the retractable lens holding frame; and the third drive mechanism is configured such that the protrusion is in a retracted state. The retracting lens holding frame is held at the standby position against the urging force of the urging means by pressing the portion, and the urging state is released by releasing the engaged state with the protrusion when the photographing is possible. The third driving mechanism for driving the other lens group is provided with a protrusion for swinging the retractable lens holding frame to the photographing position by the urging force of the urging means.
A lens barrel according to a fifth aspect of the present invention is the lens barrel according to any one of the first to fourth aspects, wherein the first driving mechanism has the retracted state and the shootable state. A guide shaft is provided which serves as a swing center of the retractable lens holding frame when switching, and guides movement in the optical axis direction in the imageable state.
The lens barrel according to claim 6 of the present application is the lens barrel according to any one of claims 1 to 5, wherein the first driving mechanism is a swing that switches between the retracted state and the retracted state. A guide mechanism for operation is provided.
A camera according to a seventh aspect of the present invention uses the lens barrel according to any one of the first to sixth aspects.
A portable information terminal device according to an eighth aspect of the present invention uses the lens barrel according to any one of the first to seventh aspects.

According to the lens barrel of claim 1 of the present application, the drive mechanism of the retractable lens holding frame switches the retractable lens holding frame in the direction intersecting the optical axis when switching between the retracted state and the imageable state. Since the first driving mechanism for swinging and the second driving mechanism for driving the retractable lens holding frame in the lens optical axis direction in the photographing enabled state are driven by different driving sources, the first driving is performed. When the mechanism is retracted / shooting switching, a high-precision feed is unnecessary, and high accuracy is required in the focusing process of the retractable lens holding frame that retracts the second driving mechanism from the lens optical axis at the time of shooting. It can be divided into a drive mechanism. For this reason, it is possible to shorten the time for switching between retracted and photographing, and to reduce the dimension in the photographing optical axis direction without increasing the size in the direction perpendicular to the optical axis of the drive mechanism of the retractable lens holding frame. it can. Further, the retractable lens holding frame has a crank-shaped bent portion for positioning the lens group holding position closer to the subject side in the optical axis direction than the center position of the swing, thereby increasing the focal length on the telephoto side. be able to.

  According to the lens barrel of claim 2 of the present application, the first drive mechanism is driven by the third drive mechanism so as to perform the lateral movement for switching between the retracted state of the retractable lens holding frame and the imageable state. Therefore, a new drive mechanism for switching between collapsible and photographing can be minimized, and the dimensions in the photographing optical axis direction can be effectively reduced with a simple configuration.

  According to the lens barrel of claim 3 of the present application, the second drive mechanism includes the lead screw that extends the retractable lens holding frame along the optical axis. The size can be reduced, and the drive control of the retractable lens holding frame can be simplified.

According to the lens barrel of claim 4 of the present application, the first driving mechanism includes a biasing unit that constantly biases the retractable lens holding frame in a direction approaching the optical axis of the other lens group ; A projection part protruding from the retractable lens holding frame, wherein the third drive mechanism presses the projection part when in the retracted state to resist the biasing force of the biasing means. A projection that holds the holding frame in the standby position and swings the retractable lens holding frame to the imaging position by the urging force of the urging means by releasing the engaged state with the projection when the imaging is possible. Is provided in the third drive mechanism for driving the other lens group, so that the configuration can be made simpler and the drive control of the retractable lens holding frame can be simplified.

  According to the lens barrel of claim 5 of the present application, the first drive mechanism becomes the swing center of the retractable lens holding frame during lateral movement for switching between the retracted state and the imageable state, and the image can be captured. Since the guide shaft for guiding the movement in the optical axis direction is provided in such a state, the retractable lens holding frame can be driven and controlled with a simpler and simpler configuration.

  According to the lens barrel of claim 6 of the present application, the first drive mechanism is provided with a guide mechanism for lateral movement that switches between the retracted state and the retracted state. The lens holding frame can be driven and controlled.

  According to the camera of claim 7 and the portable information terminal device of claim 8 of the present application, the imaging device is reduced by reducing the size in the plane where the optical axis direction and the optical axis perpendicularly intersect when the lens barrel is housed. Overall size reduction and lens holding frame drive control can be simplified.

  Hereinafter, based on an embodiment of the present invention, a lens barrel according to the present invention will be described in detail with reference to the drawings.

  1 to 16 and FIG. 20 show the configuration and various operating states of the main part of the optical system apparatus including the lens barrel according to the first embodiment of the present invention.

  FIG. 1 is a perspective view of the configuration of the lens barrel portion in the retracted storage state in which the lens group is retracted and stored, viewed from the object side, and FIG. 2 shows the configuration of the main part in the state of FIG. FIG. 3 is a perspective view, FIG. 3 is a perspective view of the configuration of the optical system apparatus including the lens barrel and the lens barrier in the retracted state where the lens barrier is closed, and FIG. FIG. 5 is a perspective view of the configuration of the lens unit viewed from the image plane side, and FIG. 5 is a perspective view of the main part of the lens barrel part and the lens barrier part in a state where the lens barrier opened in the photographing state in which the lens group is projected is being closed. FIG. 6 is a perspective view of the configuration viewed from the imaging plane side, and FIG. 7 is a perspective view of the configuration of the main part of the lens barrel portion in the shooting state in which the lens group is projected. Third lens holding frame for holding three lens groups and collision FIG. 8 is a perspective view of the arrangement configuration of the third lens holding frame, the collision preventing piece, and the fourth lens holding frame portion in the retracted state of the lens group, as viewed from the object side. In order to explain the operation of the third lens holding frame and the collision prevention piece for holding the lens group, the arrangement configuration of the third lens holding frame, the collision prevention piece and the fourth lens holding frame portion in the shooting state in which the lens group is projected It is the perspective view seen from the side.

  FIG. 9 shows the lens groups in the lens barrel in which the lens group protrudes (a) in the telephoto position state and in the retracted state in which the lens group is retracted, and (b) in the wide-angle position state in which the lens group protrudes. FIG. 10 is a developed view schematically showing the shape of the cam groove formed in the second rotating cylinder, and FIG. 11 is formed in the cam cylinder. FIG. 12 is a developed view schematically showing the shape of the cam groove, FIG. 12 is a developed view schematically showing the shape of the cam groove and the key groove formed in the first liner and omitting the helicoid. FIG. 13A is a developed view schematically showing the shape of the cam groove and key groove formed in the fixed frame and omitting the helicoid, and FIG. 13B is a detailed view including the helicoid, FIG. 13 (c) is a first rotating mirror that fits into the helicoid 14A is a side view showing the configuration of the third lens holding frame and its driving operation system, FIG. 14B is its perspective view, and FIG. 15A is the third lens holding frame. FIG. 15B is a perspective view showing a state in which the frame is swung to a position where photographing can be performed, FIG. 15B is a perspective view showing a state in which the third lens holding frame is returned to the standby position, and FIG. 15C is a first rotation. FIG. 16A is a diagram showing a protrusion formed at the rear edge of the cylinder, and FIG. 16A shows the third lens holding frame portion from the object side to the imaging plane side in order to explain the operation of the third lens holding frame. FIG. 16B is a perspective view of the third lens holding frame as viewed from the object side, and FIG. 16C is a view of the object side as viewed from the imaging plane side. FIG. 16D is a diagram of the third lens holding frame at a certain time, and FIG. 16D is a diagram of the third lens holding frame as seen from the image forming plane side, in a photographing enabled state. It is a diagram of the third lens holding frame Rutoki. FIG. 20 (a) is a perspective view specifically showing the configuration of the main part of the fourth lens holding frame and its driving operation system, and FIG. 20 (b) is a partially omitted view seen from a different angle. It is a perspective view.

  1 to 16 and FIG. 20, the optical system apparatus including the lens barrel includes a first lens group 11, a second lens group 12, a third lens group 13, a fourth lens group 14, a shutter / aperture unit 15, A solid-state imaging device 16, a first lens holding frame 17, a cover glass 18, a low-pass filter 19, a fixed frame 21, a first rotary cylinder 22, a first liner 23, a second rotary cylinder 24, a second liner 25, Cam cylinder 26, rectilinear cylinder 27, third lens holding frame 31, third group main guide shaft 32, third group sub guide shaft 33, third group lead screw 34, third group female screw member 35, impact prevention piece 36, Compression torsion spring 37, third group photointerrupter 38 (FIGS. 14B and 16A), fourth lens holding frame 41, fourth group sub-guide shaft 42, fourth group spring 43 (FIGS. 7 and 7) 8) 4th group owner Id shaft 44, fourth group lead screw 45, fourth group female screw member 46, fourth group photo interrupter 47, zoom motor 51 (FIG. 1), third group motor 52, fourth group motor 53, barrier control piece 61, A lens barrier 62, a barrier drive system 63, gears 71, 72, 73, 74, a pressing plate 81, and a lens barrel base 82 are provided.

  The shooting state will be described with reference to FIG. 9. The first lens group 11, the second lens group 12, the third lens group 13, and the fourth lens group 14 are sequentially arranged from the object side, and the second lens. A shutter / aperture unit 15 is inserted and disposed between the group 12 and the third lens group 13, and a solid-state imaging configured using a CCD (charge coupled device) or the like on the image plane side of the fourth lens group 14. Element 16 is arranged. The first lens group 11 to the fourth lens group 14 constitute a zoom lens having a variable focal length. The first lens group 11 is composed of one or more lenses, and is fixedly held on the rectilinear cylinder 27 via a first lens holding frame 17 that integrally holds the first lens group 11.

  The second lens group 12 is composed of one or more lenses, and a cam follower formed on a second lens holding frame (not clearly shown) that integrally holds the second lens group 12 is shown in FIG. The cam cylinder 26 is inserted into a cam groove for the second lens group and is engaged with a rectilinear groove 25 a of the second liner 25, and is supported by the cam cylinder 26 and the second liner 25. The shutter / aperture unit 15 includes a shutter and an aperture stop. A cam follower formed integrally with the shutter / aperture unit 15 is inserted into the shutter / aperture cam groove of the cam cylinder 26 shown in FIG. The liner 25 is engaged with the rectilinear groove 25 a and is supported by the cam cylinder 26 and the second liner 25.

  As shown in FIGS. 13 (a) and 13 (b), a straight advance groove and a cam groove along the axial direction are formed on the inner surface of the fixed cylinder of the fixed frame 21, and the helicoid cam groove includes As shown in FIG. 13 (c), a helicoid cam follower formed on the outer peripheral surface of the base end portion of the first rotating cylinder 22 is engaged, and the rectilinear groove of the fixed cylinder of the fixed frame 21 has a first advance groove. A key portion that protrudes from the outer periphery of the base end portion of the liner 23 is engaged. A guide groove is formed along the surface perpendicular to the optical axis on the inner surface of the first rotating cylinder 22, and a follower that is a linear guide member protruding from the outer peripheral surface in the vicinity of the base end portion of the first liner 23. (Or key) is engaged. A straight groove along the optical axis direction is formed on the inner surface of the first liner 23, and the cam follower is provided on the first liner 23 so as to protrude from the outer peripheral surface in the vicinity of the base end portion of the second rotating cylinder 24. An escape groove is formed for inserting the.

  As shown in FIG. 12, a helicoid is formed on the outer peripheral surface of the base end portion of the second rotating cylinder 24 and is screwed into the helicoid provided on the inner periphery of the first liner 23. The cam follower provided on the outer peripheral surface in the vicinity of the base end of the rotating cylinder 24 engages with a linear groove provided on the inner periphery of the first rotating cylinder 22 through the relief groove of the cam follower of the first liner 23. ing. A key portion protruding from the outer periphery of the base end portion of the second liner 25 is engaged with the linear groove provided on the inner periphery of the first liner 23. A guide groove is formed along the surface perpendicular to the optical axis on the inner surface of the second rotating cylinder 24, and a follower (or key) that is a linear guide member protruding from the outer peripheral surface of the second liner 25. Is engaged. With such a configuration, the second liner 25 moves integrally with the second rotating cylinder 24 with respect to the movement in the optical axis direction, but the second rotating cylinder relatively moves with respect to the second liner 25. Reference numeral 24 denotes a rotational movement.

  The cam cylinder 26 (see FIG. 11) fitted to the inner periphery of the second liner 25 has a locking projection protruding from the outer periphery of the base end fitted into the base end of the second rotating cylinder 24. Thus, it rotates integrally with the second rotating cylinder 24. A guide groove is formed on the inner surface of the second liner 25 along a surface perpendicular to the optical axis, and a follower (or key) that is a linear guide member protruding from the outer peripheral surface (front side) of the cam cylinder 26 is provided. Is engaged. With such a configuration, the cam cylinder 26 moves integrally with the second liner 25 with respect to the movement in the optical axis direction, but the cam cylinder 26 can relatively rotate with respect to the second liner 25. It is like that.

  The linear cylinder 27 shown in FIG. 9A is inserted between the second rotary cylinder 24 and the second liner 25 on the base end side, and on the outer peripheral surface near the base end of the linear cylinder 27, A cam follower is protruded, and the cam follower engages with a cam groove formed on the inner peripheral surface of the second rotating cylinder 24, and a rectilinear groove is formed on the inner peripheral surface of the rectilinear cylinder 27 along the axial direction. The key portion of the outer peripheral surface of the second liner 25 is engaged with the straight advance groove. A gear portion is formed on the outer periphery of the base end portion of the first rotating cylinder 22, and the driving force of the zoom motor 51 is appropriately transmitted through the gear and rotated, whereby the first lens group 11, The two lens group 12 and the shutter / aperture unit 15 perform a zooming operation in a predetermined manner.

  Note that the cam groove of the second rotating cylinder 24 that engages with the cam follower of the rectilinear cylinder 27 is shown in FIG. The cam groove of the cam cylinder 26 that engages with the cam follower of the lens holding frame of the second lens group 12 and the cam groove of the cam cylinder 26 that engages with the cam follower of the shutter / aperture unit 15 are shown in FIG. FIG. 12 shows the relief groove of the cam follower of the second rotating cylinder 24 of the first liner 23 and the linear groove of the first liner 23 that engages with the key portion of the second liner 25. 13 shows the rectilinear groove of the fixed frame 21 that engages with the key part of the first liner 23 of the fixed cylinder part, and the cam groove of the fixed frame 21 that engages with the cam follower of the first rotating cylinder 22. Yes.

  That is, generally, the rotating cylinder closest to the outermost fixed cylinder is screwed into the fixed cylinder by the helicoid, and the helicoid moves at a constant speed from the shape. For this reason, in the wide-angle position during which it is gradually driven from the retracted retracted state to the telephoto position via the wide-angle position, it is common that the rotary cylinder is drawn out about halfway.

  On the other hand, in the above-described configuration, the first rotating cylinder 22 is engaged with the fixed cylinder portion of the fixed frame 21 by a helicoid cam groove instead of simply being screwed into the helicoid, so that the first rotating cylinder 22 can be By driving to the wide-angle position, the first rotary cylinder 22 is fully extended to the maximum extension position, and thereafter, the object side end of the cam groove is parallel to the end face of the fixed cylinder as shown in FIG. In the driving from the wide-angle position to the telephoto position, the first rotating cylinder 22 rotates at a fixed position without moving the rotating cylinder in the optical axis direction.

  When the first rotating cylinder 22 moves from the retracted state to the wide-angle position, the first rotating cylinder 22 is initially rotated to the object side and reaches the maximum extending position. When the first rotating cylinder 22 reaches the maximum extending position, for example, a photo reflector, a photo interrupter installed on the fixed frame 21. Alternatively, a zoom position reference signal is generated by a zoom position detector including a leaf switch or the like.

  Therefore, when this zoom position reference signal is generated, it can be considered that the first rotating cylinder 22 has reached the maximum extended position, so that the retractable lens holding frame, that is, the third lens holding frame 31 in this example, is lighted. You can start entering in the axial direction.

  Accordingly, the first rotating cylinder 22 and the first liner 23, which are the lens barrels close to the fixed cylinder portion at an early stage of the extending operation, are fully extended, so that the third lens holding frame 31 (to be described later) A space for insertion on the shaft is secured in advance.

  As will be described later, the zoom position reference signal is generated as soon as the first rotating cylinder 22 reaches the maximum extension position, and the third lens holding frame 31 enters the position immediately after a space for insertion is secured. Thus, it is possible to minimize the time required for shifting from the retracted state to the wide-angle state such as when the power is turned on.

  A projection 22P for projecting the third lens holding frame 31 from the standby position to the shootable position protrudes from the rear end edge of the first rotating cylinder 22 on the imaging surface side. The protrusion 22p (see FIG. 15C) of the first rotary cylinder 22 and the zoom motor 51 constitute a third drive mechanism that drives the other lens groups in the claims. FIG. 15C, FIG. 16C, and FIG. 16D show the shape of the protrusion 22 </ b> P formed on the rear end edge of the first rotating cylinder 22. The protrusion 22p has an arc shape, and can contact the protrusion 31p of the third lens holding frame 31.

  An elastic force is applied to the third lens holding frame 31 by a compression torsion spring 37 so as to swing from the standby position toward the photographing position. The compression torsion spring 37 constantly biases the third lens group 13 in the direction of approaching the optical axes of the first lens group 11, the second lens group 12, and the fourth lens group 14, which are other lens groups. The protrusion 31p and the compression torsion spring 37 constitute a first drive mechanism.

  As shown in FIG. 16C, when the third lens holding frame 31 is in the standby position, the protrusion 22P of the first rotating cylinder 22 comes into contact with the protrusion 31p, and the third lens holding frame 31. Is pressed to the standby position side. When the third lens holding frame 31 swings from the standby position to the photographing position, as shown in FIG. 16D, the protrusion 22P of the first rotating cylinder 22 is separated from the protrusion 31p, and the third lens. The holding frame 31 swings to the photographing position by the urging force of the compression torsion spring 37.

  FIGS. 15A and 15B show the third lens holding frame 31. The third lens group 13 is held by a third lens holding frame 31 (corresponding to a retractable lens holding frame). The third lens holding frame 31 holds the third lens group 13 (the lens group of the retractable lens holding frame) at one end, and the third group whose other end is substantially parallel to the optical axis of the third lens group 13. The main guide shaft 32 is supported so as to be rotatable and slidable along the third group main guide shaft 32. The third group main guide shaft 32 constitutes a guide shaft that guides the movement in the optical axis direction in the imageable state in the claims.

  The third lens holding frame 31 is rotatable about the third group main guide shaft 32 as shown in FIG. The third lens holding frame 31 includes a position on the optical axis where the optical axis of the third lens group 13 is inserted on the optical axis of the lens in the shooting state (a position where photographing can be performed), and a retracted storage as shown in FIG. The third lens group 13 in the state is retracted from the fixed cylinder portion of the fixed frame 21 to the outside, and can swing between the retracted position (collapsed position). The third group main guide shaft 32 serves as a guide shaft in the claims, serves as a guide when the third lens holding frame 31 is moved in the optical axis direction, and a center when the third lens holding frame 31 swings. Become. The motor 52, the gear mechanism, the lead screw 34, the female screw member 35, and the mounting portion 31k constitute a second drive mechanism.

As shown in FIG. 14A, the third lens holding frame 31 is formed with a crank-shaped bent portion 31j, and a stopper 31a and a light shielding piece 31b are projected from the bent portion 31j substantially in the direction of the rotation end. Yes. When the light shielding piece 31b is in the retracted position, it is detected by the third group photo interrupter 38 (see FIG. 14B) so that the third lens group 13 can be detected in the retracted state. A mounting portion 31k is formed on the rotation center side of the third lens holding frame 31, and the third group main guide shaft 32 is slidably inserted through the mounting portion 31k. A groove 31e extending in a direction orthogonal to the axial direction is formed on the outer peripheral surface of the attachment portion 31k. Further, a protrusion 31P that can contact the protrusion 22p of the first rotating cylinder 22 is formed in the vicinity of the mounting portion 31k in parallel to the optical axis. The protrusion 31P is pushed by the protrusion 22p of the first rotating cylinder 22 and pushes down the third lens holding frame 31 to the retracted position against the elastic force of the compression torsion spring 37.

  By the way, from the viewpoint of optical performance, in order to increase the focal length on the telephoto side, the position of the third lens group 13 at the time of telephoto is a position extended to the subject side. On the other hand, the movable amount of the third lens holding frame 31 is determined by the restriction of the length in the optical axis direction of the lens barrel in the retracted state. Therefore, the telephoto side focal length can be made as large as possible by setting the position where the third lens group 13 of the third lens holding frame 31 is held closest to the subject.

  However, if the position of the stopper 31a in the optical axis direction is set at substantially the same position as the third lens group 13, the third group sub-guide shaft 33 (see FIGS. 16A and 16B) that contacts the stopper 31a. ) Becomes longer and the retracted lens barrel becomes larger. For this reason, it is necessary to install the stopper 31a on the in-focus position side as much as possible.

  Therefore, the third lens holding frame 31 is formed in a shape having a crank-shaped bent portion 31j. The third lens holding frame 31 may be composed of two parts. In this case, one is a member provided with the crank-shaped bent portion 31j, and the other is the third lens group 13. It is a member for holding. These two parts are fixed to each other and operate as if they were integrated.

As shown in FIGS. 14A and 14B, when the third lens holding frame 31 is in the retracted position, the female screw member 35 screwed into the third group lead screw 34 is positioned closest to the image plane side. Yes. In a state where the third frame 31 is positioned more even imaging surface side, FIG. 15 (a), the as shown in FIG. 15 (b), the most accumulated elastic repulsive force of the compression torsion spring 37 Yes. The compression torsion spring 37 always applies a moment M1 (see FIG. 15A) in the clockwise direction (direction of entering the optical axis) when viewed from the front of the lens barrel to the third lens holding frame 31, and also the third lens holding frame. 31 is pushed toward the holding plate 81 side.

  A portion of the third lens holding frame 31 through which the main guide shaft 32 is passed is a cylindrical attachment portion 31k. A compression torsion spring 37 is disposed around the main guide shaft 32 passed through the attachment portion 31k, and one end of the compression torsion spring 37 has a crank-shaped bent portion 31j as shown in FIG. It is energized to swing horizontally. The other end of the compression torsion spring 37 is hooked on the fixed frame 21.

  As shown in FIG. 14A, a groove 31e extending in the direction orthogonal to the axial direction is formed on the outer peripheral surface of the mounting portion 31k. The groove 31e is fitted with a protrusion formed on the lower portion of the female screw member 35. When the female screw member 35 moves, the protrusion pushes the edge of the groove 31e to move the attachment portion 31k. When the projection of the female screw member 35 is slidably fitted in the groove 31e, when the third group motor 52 rotates clockwise as viewed from the front of the lens barrel, the lead is connected via a gear mechanism including gears 71 to 74. The screw 34 rotates clockwise, and the female screw member 35 moves toward the subject along the optical axis direction. The guide mechanism for the swing operation for switching between the retracted state and the retracted state in the first drive mechanism is constituted by a protrusion 35a of the female screw member 35 and a groove portion 31e of the mounting portion 31k.

As shown in FIG. 16C, when the first rotating cylinder 22 is in the retracted state, the protrusion 22p of the first rotating cylinder 22 presses the protrusion 31p of the third lens holding frame 31, The three-lens holding frame 31 is in the standby position. When the first rotating cylinder 22 rotates so that the first rotating cylinder 22 changes from the retracted state to the protruding state (see arrow A in FIG. 16C), the protrusion 22p of the first rotating cylinder 22 is The engagement state of the projections 31p of the three-lens holding frame 31 is released, and the third lens-holding frame 31 swings to the photographing position side as shown in FIG. A driving source for swinging the third lens holding frame 31 from the standby position to the photographing position is an urging force M <b> 1 that is a twisting force of the compression torsion spring 37. On the other hand, when the first rotating cylinder 22 rotates in the opposite direction and the protrusion 31p and the protrusion 22p are engaged, the third lens holding frame 31 is in the shooting position against the twisting force of the compression torsion spring 37. Swings to the standby position.

  Since the groove portion 31e is formed in the circumferential direction of the attachment portion 31k and extends in a direction perpendicular to the main guide shaft 32, the third lens holding frame 31 swings along the groove portion 31e. When the third lens holding frame 31 swings from the standby position and changes its posture to the shooting position, the optical axis of the third lens group 13 of the third lens holding frame 31 coincides with the optical axes of the other lens groups 11 to 14. It becomes a state. Therefore, when the lead screw 34 is rotated, the female screw member 35 moves, and the third lens holding frame 31 moves in the axial direction of the lead screw 34.

When the position of the third lens holding frame 31 is changed to the photographing position from the standby position, the light shielding piece 31b of the third frame 31 is moved to disengage from the photo-interrupter 38 as a position detecting device of the third group, photo The interrupter 38 generates a reference signal from L (low level) to H (high level). The position of the third lens group 13 is controlled by pulse counting with reference to this reference signal from the photo interrupter 38. When the third lens holding frame 31 swings from the standby position to the photographing position, the female screw member 35 is located at the position B in FIG. At this time, the stopper 31a contacts the third group sub guide shaft 33, whereby the position on the optical axis of the third lens holding frame 31 is defined. Thereby, the approach operation of the third lens holding frame 31 in the optical axis direction is completed. The light shielding piece 31b can detect and confirm that the third lens holding frame 31 is in the storage position by shielding the photo interrupter 38 shown in FIG.

In the above-described configuration, the compression torsion spring 37 has a mechanism in which the protrusion 31p is formed on the third lens holding frame 31, the protrusion 22p is formed on the first rotating cylinder 22, and the third lens holding frame 31 is swung. constituted by the elastic force and the projection 31p and the protrusion 22p, by forming a high-precision feeding mechanism when taken with the female screw member 35 of the groove 31e and the lead screw 34 of the mounting portion 31k, the groove 31e is a lead screw 34 Therefore, the axial length of the mounting portion 31k can be shortened, and the third group main guide shaft 32 and the lead screw 34 can be shortened. Further, the dimension of the driving mechanism of the third lens holding frame 31 in the optical axis direction can be reduced, and the time for the swinging operation between the photographing position and the retracted position can be shortened. The position of the reference position B and Wide the third lens holding frame 31 (wide-angle) may be the same position.

  The third lens holding frame 31 is always urged in the rotational direction from the storage position toward the position on the optical axis by a compression torsion spring 37 disposed around the third group main guide shaft 32 and is On the third group main guide shaft 32, it is always urged in the direction from the object side to the holding plate 81 on the image plane side (see FIG. 14A).

  As shown in FIG. 14B, a step 37a is formed as a recess in the portion pressed by the compression torsion spring 37 of the fixed frame 21, and the compression torsion spring 37 in this portion is formed. The position of is regulated. That is, the center position of the compression torsion spring 37 does not deviate greatly from the center of the third group main guide shaft 32.

  Next, when the female screw member 35 moves to the wide-angle position (the W position in FIG. 14A), the contact portion 35c of the female screw member 35 presses the front engaging portion 31d, and therefore the third lens holding frame 31. Can move to the subject side along the optical axis direction up to the wide-angle position. The drive source that moves the third lens holding frame 31 back and forth in the optical axis direction is the movement of the female screw member 35, and the drive source that drives the female screw member 35, the lead screw 34, and the gear mechanism is the motor 52.

Further, while the female screw member 35 is located between the B position in FIG. 14A and the telephoto position (T position in FIG. 14A), the compression torsion spring 37 causes the optical screw direction along the optical axis direction. because it is always pressed toward the image surface side, a gap generated between such third group lead screw 34 and the female screw member 35 with the retainer plate 81 are directed to the image side, the third lens holding The frame 31 can secure the positional accuracy in the optical axis direction.

  The female screw member 35 is screwed into a third group lead screw 34 disposed substantially parallel to the optical axis. The female screw member 35 includes a protrusion 35 a (see FIG. 8) that fits into the groove 31 e of the third lens holding frame 31. Further, the female screw member 35 is formed with a rotation stop projection 35b (see FIG. 8) as a rotation stop for preventing the female screw member 35 from rotating with the rotation of the third group lead screw 34. 35a is fitted and slid in a guide groove (not shown) formed in the fixed frame 21 parallel to the optical axis direction.

  That is, the female screw member 35 is prevented from rotating by the rotation stop projection 35b being fitted in a guide groove extending in a direction parallel to the screw 34 of the fixed frame 21, so that the rotation of the third group lead screw 34 Move forward and backward along the optical axis.

  As the third group lead screw 34 rotates in the reverse direction (counterclockwise rotation), the position of the compression torsion spring 37 on the optical axis of the female screw member 35 moves from the telephoto position T to the retracted position B through the wide-angle position W. The third lens holding frame 31 maintains the position on the optical axis restricted by the third group sub guide shaft 33 by the urging force toward the image surface and the urging force toward the image surface side, while moving from the object side to the image surface side. Move gradually.

  When the female screw member 35 reaches the retracted position B and the first rotating cylinder 22 rotates in the retracted direction, the protruding portion 31p of the third lens holding frame 31 and the protruding portion 22p of the first rotating cylinder 22 are brought into a non-contact state. Due to the elastic force of the compression torsion spring 37, the third lens holding frame 31 swings from the photographing position to the retracted position.

  The retracted position of the third lens holding frame 31 is a position moved to the image plane side by a predetermined pulse count from the time when the storage reference signal that changes from H to L of the photo interrupter 38 is generated. After the third lens holding frame 31 has moved to the reference position B, the first lens group 11, the second lens group 12, and the shutter / aperture unit 15 are allowed to move to the retracted storage position.

  In this example, in the storing operation, the fourth lens holding frame 41 first moves to the storing position before the third lens holding frame 31 moves to the storing position. The first storage position of the fourth lens holding frame 41 is predetermined from the generation of the storage reference signal of the fourth lens holding frame 41 that changes from H to L generated by the fourth group reference detector (fourth group photo interrupter 47). Is the position moved to the image plane side by the number of pulse counts. After the first storing operation of the fourth group lens holding frame 41 is completed, the storing operation of the third lens holding frame 31 is permitted.

  That is, the reverse rotation of the motor 52 is started by permitting the start of the storing operation of the third lens holding frame 31, and the predetermined number of pulses are reversely rotated. As a result, the third lens holding frame 31 retracts from the subject side toward the image plane side and returns to the reference position B. When the third lens holding frame 31 returns to the reference position B, the motor 52 stops, and instead the reverse rotation of the motor 51 is started, and the retracting operation of the first rotating cylinder 22 is started. The retracting operation of the first rotating cylinder 22 is due to the reverse rotation of the motor 51.

  Due to the reverse rotation of the first rotating cylinder 22, the protruding portion 22 p of the first rotating cylinder 22 and the protruding portion 31 p of the third lens holding frame 31 come into contact with each other, and the protruding portion 31 P is impacted by being pushed by the protruding portion 22 p. It turns to the prevention piece 36 side. When the projection 31P is pushed by the rotation of the first rotating cylinder 22 and the third lens holding frame 31 rotates and reaches the retracted position, the impact prevention piece 36 is contacted and the light shielding portion 31b is brought to the photo interrupter 38. The output of (see FIG. 16A) is changed from H to L. As a result, the third lens holding frame 31 has reached the retracted position, the female screw member 35 stops at the reference position B, the rotation of the motor 51 stops, and the retracting operation of the first rotating cylinder 22 is completed.

  The component located closer to the subject side than the third lens holding frame 31 is closer to the image plane than the position immediately before the third lens holding frame 31 is retracted after the retraction operation of the third lens holding frame 31 is completed. To position. As a result, the first rotating cylinder 22 and the like can be safely retracted to the main body side without interference with the third lens holding frame 31.

  When the position of the first rotary cylinder 22 or the like is set by a zoom motor 51 configured using a general DC (direct current) motor, an encoder directly fixed to the output shaft of the zoom motor 51 and the vicinity thereof For example, a drive pulse is detected by the installed zoom count detector including a photo interrupter 51a, and the position of the rotary cylinder 22 can be set by the number of drive pulses.

  Here, the drive source for moving the first rotary cylinder 22 is a DC motor, and detection of the drive position is achieved by a detector using an encoder and a photo interrupter. The same function can be achieved even if replaced with.

  By the way, the collision preventing piece 36 is rotatably supported by the fixed frame 21 in the vicinity of the third group main guide shaft 32 as shown in FIGS. It is always urged by a spring or the like in a rotating direction for projecting 36a to the photographing optical axis position side.

  When the third lens holding frame 31 is located at the retracted position, the collision preventing piece 36 is pushed out by the third lens holding frame 31 having a rotational force equal to or greater than its urging force, and the third lens holding frame 31. The position is more outwardly biased (in particular, see FIGS. 2 and 7).

  When the third lens holding frame 31 rotates and moves to the position on the optical axis, the collision preventing piece 36 is disengaged from the third lens holding frame 31, and the locking projection 36a is photographed by the urging force. The locking projection 36a is rotated from the inner surface of the fixed cylinder of the fixed frame 21 by rotating in a direction protruding toward the optical axis.

  At this time, the second rotating cylinder 24, the second liner 25, the cam cylinder 26, and the rectilinear cylinder 27, including the first rotating cylinder 22 and the first liner 23, all come from the protruding position of the locking protrusion 36a. Is also located on the object side, the locking projection 36a protrudes inwardly from the outer peripheral edges of the proximal ends of the first rotating cylinder 22 and the first liner 23 (particularly FIGS. 5, 6 and 8). reference).

  By doing so, even if the first rotating cylinder 22 is forcibly rotated manually and moved to the storage position side, the collision preventing piece 36 first contacts the first rotating cylinder 22. Since the base end portion of the first rotating cylinder 22 cannot be moved to the image plane side with respect to the position of the collision prevention piece 36 in the optical axis direction, avoiding contact with the third lens holding frame 31 is avoided. Can do.

  Accordingly, it is possible to prevent the third lens holding frame 31 from being destroyed or damaged by a strong external force. The first rotating cylinder 22 can be moved to the storage position only after the third lens holding frame 31 has been normally moved to the storage and retracting position.

  Therefore, when a large pressure is applied to the front end side of the lens barrel due to dropping or the like in a shooting state in which the lens barrel protrudes, the collision preventing piece 36 is locked to the first rotating cylinder 22 and the first liner 23. The projection 36a is engaged, and the third lens group beyond the first rotating cylinder 22 and the first liner 23 (and the second rotating cylinder 24, the second liner 25, the cam cylinder 26, and the rectilinear cylinder 27). The backward movement toward the side 13 is prevented, and the third lens holding frame 31 and the third lens group 13 are prevented from being damaged.

  The third group lead screw 34 is rotationally driven in both forward and reverse directions by the third group motor 52. The rotation of the third group motor 52 is transmitted to the third group lead screw 34 through the gear 71, the gear 72, the gear 73, and the gear 74 in order.

  Next, a driving configuration of the fourth lens group 14 as an optical element disposed on the image plane side of the third lens holding frame 31 will be described. In addition to FIGS. 7 and 8, the description will be given mainly with reference to FIGS. 20A and 20B which are perspective views showing the fourth group drive system.

  When the third lens holding frame 31 shifts from the retracted state to the shootable state, the fourth lens group 14 generates an approach completion signal when the third lens holding frame 31 is in a shootable state. Movement of the fourth lens group 14 is permitted.

  In this case, the fourth lens group 14 used as a focus lens for focusing, that is, focusing, is held by a fourth lens holding frame 41 as shown in FIGS. The fourth lens holding frame 41 is fixed to the lens barrel base 82 and is fitted to the fourth group main guide shaft 44 arranged in parallel to the optical axis. The fourth lens holding frame 41 is parallel to the optical axis and parallel to the optical axis. And a sub-rotation portion 41b that regulates the rotation of the fourth lens holding frame 41.

  With such a configuration, the fourth lens holding frame 41 can freely move along the fourth group main guide shaft 44, that is, along the optical axis direction. As a drive source for driving the fourth lens holding frame 41, a fourth group motor 53 consisting of a stepping motor is provided in this case, and a fourth group lead screw 45 is provided on the output shaft of the fourth group motor 53. Is formed. The fourth group lead screw 45 is screwed with a fourth group female screw member 46 in which a female screw is formed.

  The fourth lens holding frame 41 has a space for inserting the fourth group female screw member 46. This space is formed on the image side with an engaging portion 41c that engages with the fourth group female screw member 46 on a plane perpendicular to the optical axis, and the fourth lens holding frame 41 is subject to the subject by the fourth group spring 43. By urging to the side, the fourth lens holding frame 41 is always in contact with and engaged with the fourth group female screw member 46. The fourth group female screw member 46 has a projecting portion 46a projecting in the radial direction, and this projecting portion 46a is provided on one side of the space where the fourth group female screw member 46 of the fourth lens holding frame 41 is inserted. By engaging with the hole 41d, the function of preventing the rotation of the fourth group female screw member 46 is exhibited.

  In this way, when the fourth group motor 53, which is a stepping motor, is driven to rotate, the fourth group lead screw 45 rotates, and the fourth group female screw member 46 moves in the direction of the fourth group lead screw 45, that is, the light. It moves forward and backward along the axial direction. Since the fourth lens holding frame 41 is engaged with the fourth group female screw member 46, the fourth lens holding frame 41 moves along the optical axis following the movement of the fourth group female screw member 46. . At this time, the fourth group lead screw 45 is formed on the output shaft of the fourth group motor 53. However, the fourth group motor 53 and the fourth group lead screw 45 are separately configured and connected by a gear or the like. By doing so, the fourth group lead screw 45 may be rotated so as to transmit the rotation.

  The fourth lens holding frame 41 is formed with a light shielding piece 41e that shields the optical path of the fourth group photo interrupter 47 provided on the lens barrel base 82, and the fourth group lens holding frame 41 is moved to a predetermined position. Thus, the optical path of the fourth group photo interrupter 47 can be shielded / transmitted. In this case, the moment when the fourth lens holding frame 41 is moved to the light-transmitting state due to the movement of the fourth lens holding frame 41 is recognized as the reference position, and the pulse waveform is energized by an arbitrary number of pulses from that position. The fourth lens holding frame 41 can be moved to a desired position by rotating the group motor 53.

  The outer periphery of the fourth lens holding frame 41 is formed with a recess 41f for avoiding interference by escaping the light interrupting piece 31b for the photo interrupter of the third lens holding frame 31 in the optical axis direction. The amount of movement of the fourth lens holding frame 41 can be increased, and the photographing distance range that can be focused can be widened. As described above, the engagement structure between the fourth lens holding frame 41 and the fourth group female screw member 46 has play in the optical axis direction, but the fourth lens holding frame 41 is moved by the fourth group spring 43. By always urging the subject side, the fourth lens holding frame 41 can control the position in the optical axis direction with high accuracy.

  The storage position of the first rotating cylinder 22, the first liner 23, the first lens group 11, the second lens group 12, and the shutter / aperture unit 15 is a zoom made of a photo reflector or the like installed on the fixed frame 21. Control is performed based on a zoom position reference signal generated by the position detector.

  That is, after the zoom position storage reference signal changes from H to L, the image signal moves to the image plane side by a predetermined number of drive pulses generated by a pinion gear functioning as an encoder and a zoom count detector installed in the vicinity thereof. It is possible to complete the storing operation.

  At the time of storage, the fourth lens holding frame 41 is located at the first storage position as described above. However, when the first rotary cylinder 22 moves to the storage position, the first rotary cylinder 22 is moved. Alternatively, the most proximal end surface of the first liner 23 comes into contact with and presses the fourth lens holding frame 41 and is finally moved to the second storage position of the fourth lens holding frame 41.

  By such an operation, the fourth lens holding frame 41 is accurately moved to the storage position without requiring complicated adjustment even if the mounting position of the fourth group photointerrupter 47 in the optical axis direction varies. It becomes possible. Such an effect can be achieved because the length of the engagement space provided in the fourth lens holding frame 41 in the optical axis direction is larger than the thickness of the fourth group female screw member 46.

In this case, the zoom motor 51 for moving the first lens group 11, the second lens group 12, and the shutter / aperture unit 15 is configured using a DC motor. The third group motor 52 for driving the third lens group 13 and the fourth group motor 53 for driving the fourth lens group 14 are generally configured by using pulse motors, and are mutually connected by software, for example. Driven in cooperation, an appropriate zooming operation mainly by the first to third lens groups 11 to 13 and an appropriate focusing operation mainly by the fourth lens group 14 are achieved.
[Drive control of each lens group]
Next, drive control of each lens group constituting the lens barrel will be described in detail with reference to FIGS.

  FIG. 21 is a block diagram schematically showing the configuration of the drive control system, FIG. 22 is a timing chart showing a sequence when the barrier is opened in the startup sequence, and FIG. 23 is a sequence from opening the barrier to closing the barrier in the startup sequence. FIG. 24 is a timing chart illustrating the reset sequence, FIG. 24A is a timing chart illustrating the reset sequence, FIG. 25 is a timing chart illustrating the storage sequence when the barrier is closed, and FIG. 26 is a flowchart illustrating the zoom sequence. 27 is a timing chart showing a zoom sequence during zooming from the wide-angle position to the telephoto position, and FIG. 28 is a timing chart showing a zoom sequence during zooming from the telephoto position to the wide-angle position.

  21 includes a central processing unit 501, a motor driver 502, first and second group DC motors 503, a first aperture motor 504, a second aperture motor 505, a shutter motor 506, and a third group pulse. Motor 507, fourth group pulse motor 508, first to second group photo interrupter 509, first to second group photo reflector 510, third group photo interrupter 351, fourth group photo interrupter 512, first to second group It has a photo interrupter driving circuit 513, first to second group photo reflector driving circuits 514, a third group photo interrupter driving circuit 515, and a fourth group photo interrupter driving circuit 516.

  The central processing unit 501 gives instructions to the motor driver 502 such as initial setting of the motor driver 502, selection of a driving motor, setting of driving voltage, and driving direction. In accordance with a command from the central processing unit 501, the motor driver 502 includes a first to second group DC motor 503, a first aperture motor 504, a second aperture motor 505, a shutter motor 506, a third group pulse motor 507, and The motor system such as the fourth group pulse motor 508 is controlled.

  The first to second group DC motors 503 drive the first group lens system 11 and the second group lens system 12. In a normal case, the first group lens system 11 and the second group lens system 12 are independently driven via a cam mechanism that responds to the driving force of the first to second group DC motors 503. The first aperture motor 504 and the second aperture motor 505 drive the aperture of the shutter / aperture unit 15.

  The shutter motor 506 drives the shutter of the shutter / aperture unit 15. The third group pulse motor 507 drives the third group lens system 13. The fourth group pulse motor 508 drives the fourth group lens system 14.

  The central processing unit 501 includes the first to second group photointerrupter driving circuits 513, the first to second group photoreflector driving circuits 514, the third group photointerrupter driving circuit 515, and the fourth group photointerrupter driving circuit 516. The first and second group photo interrupters 509, the first and second group photo reflectors 510, the third group photo interrupter 351, and the fourth group photo interrupter 512 serving as position detecting devices are supplied with power. The position information signals detected by the second group photo interrupter 509, the first to second group photo reflectors 510, the third group photo interrupter 351, and the fourth group photo interrupter 512 are acquired.

  The first to second group photo interrupter driving circuits 513, the first to second group photo reflector driving circuits 514, the third group photo interrupter driving circuit 515, and the fourth group photo interrupter driving circuit 516 are further divided into the first to second groups. The photointerrupter 509, the first to second group photoreflectors 510, the third group photointerrupter 351, and the fourth group photointerrupter 512 have a function of appropriately controlling the light emission currents and the output signal levels.

The motor driver 502 receives a command from the central processing unit 501 and executes the command, and the first to second group DC motors 503, the first aperture motor 504, the second aperture motor 505, and the shutter motor. A designated voltage is set for a selected motor among the motor 506, the third group pulse motor 507, and the fourth group pulse motor 508, and drive control is performed according to the drive command timing.
[Startup sequence]
A drive sequence at the time of opening the barrier in such a startup sequence by the drive control system will be described with reference to FIG.

  When the lens barrier 62 is opened, the barrier switch signal (barrier SW) changes from H to L, and the initial setting of the lens barrel system is started. The lens barrier 62 may be operated by mechanically opening the lens barrier 62 with an operation lever or the like, and the barrier may be operated by operating the barrier switch.

  The initial setting is initialization of the motor driver 502 that drives the motor system, first to second group photointerrupter drive circuits 513, first to second group photoreflector drive circuits 514, third group photointerrupter drive circuits 515, and First-second group photointerrupter 509, first-second group photoreflector 510, third-group photointerrupter 351, and fourth-group photo, which are position detection devices that detect positions via a fourth-group photointerrupter drive circuit 516. The interrupter 512 and the like are initialized.

  The detection result by the first and second group photo interrupters 509 for detecting the positions of the first and second groups is the storage position, and the detection result by the third group photo interrupter 351 for detecting the position of the third group is stored. Position. When the detection result by the fourth group photo interrupter 512 for detecting the position of the fourth group is the storage position, the first to second group DC motors 503 are driven in the wide-angle position direction. The driving amount by the first to second group DC motors 503 is detected by the first to second group photointerrupters 509 for detecting the movement amounts of the first to second groups. The amount of movement is detected by counting the edge portions of the pulse-like signal (PI signal) by the first to second group photointerrupters 509.

  In the start-up period immediately after the start of start-up of the first to second group DC motors 503, the drive voltage is set lower than the steady voltage in order to prevent an inrush current by the DC motor. After the start-up period is completed, the drive voltage is increased to a steady voltage.

  A barrier switch (barrier SW) monitoring period is set immediately after the start of activation of the first to second group DC motors 503, and the state of the barrier switch signal is monitored by the central processing unit 501. During this period, if the barrier switch signal is in the open state, the shutter motor 506 for driving the shutter performs full open control to set the shutter in the fully open state.

  Next, intermediate diaphragm control is performed by the first and second diaphragm driving motors 504 and 505 to set the intermediate diaphragm state. In this example, an intermediate aperture state is set, but an open aperture (maximum aperture) state may be set.

  Next, the fourth lens group 14 is driven in advance by the fourth group pulse motor 508. By performing the preceding drive of the fourth lens group 14, the total time from the start of driving of the first and second lens groups to the completion of driving of the final fourth lens group 14 is shortened. In addition, by setting the pulse rate at the time of driving the fourth group pulse motor 508 at the time of the preceding drive to be slower than at the time of the normal drive, the torque at the time of driving becomes large, and it is possible to escape from the catching of the mechanism part. Become.

  Note that the drive amount by the fourth group pulse motor 508 during the preceding drive is set to an amount that does not cause interference between the fourth lens group 14 and the third lens group 13.

  When the preceding driving of the fourth lens group 14 is completed, the process waits for the reference position to be detected by the first and second group photo reflectors 510. The position where the reference position signal (HP signal) from the first to second group photo reflectors 510 has changed from H to L becomes the reference position (HP position) of the first to second lens groups 11 to 12.

  When the photo reflector 510 detects the reference positions (HP positions) of the first to second lens groups 11 to 12, the position information of the first to second lens groups 11 to 12 is reset. The movement amount control of the first and second lens groups is performed by counting the amount of movement to the wide-angle position (Wide) on the basis of this position by counting pulse signals (PI signals) from the first to second group photointerrupters 509. I do. The wide-angle position is set in advance, but can be changed by storing it in a nonvolatile memory such as an EEPROM and rewriting it.

  The specified pulse period before reaching the wide-angle position is a stop control period, and the drive voltage is lowered according to the number of remaining pulses up to the wide-angle position to reduce the overrun when reaching the wide-angle position. When the PI signal from the first to second group photointerrupters 509 is counted and reaches the wide-angle position, brake control is performed to stop driving the first to second lens groups 11 to 12. The amount of overrun during this braking period is also counted, and the final positions of the first to second lens groups 11 to 12 are determined.

  Further, when the photo interrupter 509 detects the reference position (HP position) of the first to second lens groups 11 to 12, the third group pulse motor 507 starts driving in the wide angle direction. Prior to this, the engagement between the protrusion 21p and the protrusion 22p is released by the rotation of the first rotating cylinder 22, and the third lens holding frame 31 is moved from the first to the first by the urging force of the compression torsion spring 37. It is located at the photographing position on the optical axis of the two lens groups 11-12.

  The control of the third lens group 13 and the control of the first to second lens groups 11 to 12 are parallel control. The driving time of the third lens group 13 is shortened by setting the pulse rate at the time of driving the third group pulse motor to be higher (faster) than at the time of normal driving.

The photointerrupter 511, the reference position of the third lens group 13 of the third lens holding frame 31 (HP position) is detected, the central processing unit 501 resets the position information of the third lens group 13 of the EEPROM . Instead of detecting the HP position of the photo interrupter 511, it may be detected that the female screw member 35 is positioned at the reference position B by the number of pulses of the motor 52.

  The third group pulse motor 507 drives the amount of movement to the wide-angle position with a pulse signal using this position as a reference. The wide-angle position is stored in advance in a nonvolatile memory such as an EEPROM, but can be changed by rewriting.

  The final stop position of the third lens group 13 is a position in consideration of the overrun of the first to second lens groups 11 to 12. That is, since the stop position of the first to second lens groups 11 to 12 is the wide angle position + the overrun amount, the stop position of the third lens group 13 also exceeds the overrun of the first to second lens groups 11 to 12. The wide angle position considered is + α.

  The value of α is obtained by, for example, linear calculation from the number of pulses between zoom positions of the first to second lens groups 11 to 12, the amount of overrun, and the number of pulses between zoom positions of the third lens group 13. It is done. The zoom position is one section of the sections obtained by dividing the wide angle to the telephoto (between WT) into 16 equal parts.

  When the driving of the first to second lens groups 11 to 12 is completed and the driving of the third lens group 13 detects the reference position (HP position: reference position B) of the third lens group 13, the number of pulses is equal to or greater than the specified number of pulses. When driven, the fourth group pulse motor 508 starts to be driven in the wide angle infinite position direction.

  When driving of the first to second lens groups 11 to 12 is not completed, or when the third lens group 13 is not driven more than a specified pulse from the reference position, the first to second lens groups 11 to 12 are used. Until the third lens group 13 is driven from the reference position by a predetermined pulse or more.

  If the fourth group pulse motor 508 is driven in a state where the driving of the first to second lens groups 11 to 12 is not completed, the three motors are driven simultaneously, resulting in an increase in current consumption. Therefore, in this example, simultaneous driving is performed only for the third lens group 13 and the fourth lens group 14. Further, when the fourth lens group 14 is driven before the position of the third lens group 13 reaches a position equal to or greater than the specified number of pulses from the reference position, interference between the third lens group 13 and the fourth lens group 14 occurs. Therefore, after the specified number of pulses, the driving of the fourth lens group 14 is started.

  The fourth lens group 14 side waits for detection of the reference position by the fourth group photo interrupter 512. In addition, the current consumption is reduced by setting the driving voltage when driving the fourth group pulse motor 508 to be lower than that during normal driving. The position where the reference position signal (HP signal) by the fourth group photo interrupter 512 changes from L to H becomes the reference position (HP position) of the fourth lens group 14. When the reference position (HP position) of the fourth lens group 14 is detected, the position information of the fourth lens group 14 is reset. The fourth group pulse motor 508 drives the amount of movement to the wide angle infinite position with this position as a reference. The wide-angle infinite position is set in advance, but can be changed by storing it in a nonvolatile memory such as an EEPROM and rewriting it.

  As shown in the timing chart of FIG. 22, in this example, the simultaneous drive motor is limited to two motors, so that the startup time is shortened by optimal driving while suppressing current consumption.

Next, a case where the barrier switch signal changes to the closed state during the barrier switch monitoring period immediately after the start of the activation of the first to second group DC motors 503 will be described with reference to FIG. If the barrier switch signal changes from the open state to the closed state during this period, the driving of the first to second group DC motors 503 is stopped. After that, the driving of the first to second group DC motors 503 corresponding to the movement amount or the specified number of pulses in the storage direction is started. In this case, the driving voltage is set to a low voltage so that destruction or breakage does not occur even when the operating unit collides with the storage end. Such control makes it possible to prevent interference with the barrier.
[Reset sequence]
Further, the detection result by the first to second group photo reflectors 510 is not the storage position (reference position (HP) signal = L), or the detection result by the third group photo interrupter 351 is not the storage position (reference position (HP)). If the signal detected by the fourth group photo interrupter 512 is not the storage position (reference position (HP) signal = H), reset sequence driving is performed. Such a reset sequence will be described with reference to FIG. 24A is a schematic diagram showing the flow of the reset sequence in each situation, and FIG. 24B is a timing chart of the reset sequence.

<When 1-2 Group HP Signal = H, 3rd Group HP Signal = L, 4th Group HP Signal = L>
First, as a reset operation of the first to second lens groups 11 to 12, the reference position (HP position) of the first to second lens groups 11 to 12 is detected and moved to the wide angle position (1-2 group: Reset). . Next, as the storing operation of the fourth lens group 14, the reference position (HP position) of the fourth lens group 14 is detected and moved to the storing position (fourth group: storage). Next, as a reset operation of the third lens group 13, a reference position (HP position) of the third lens group 13 is detected and moved to a wide angle position (third group: Reset). Finally, as a reset operation of the fourth lens group 14, a reference position (HP signal) of the fourth lens group 14 is detected and moved to a wide angle infinite position (fourth group: Reset).

<When 1-2 Group HP Signal = H, 3rd Group HP Signal = L, 4th Group HP Signal = H>
First, as the retracting operation of the first to second lens groups 11 to 12, the first to second lens groups 11 to 12 are driven in the telephoto direction (Tele), and the specified pulse is driven after the falling edge of the reference signal is detected (1- Group 2: evacuation). Next, as the storing operation of the fourth lens group 14, the reference position (HP position) of the fourth lens group 14 is detected and moved to the storing position (fourth group: storage). Next, as a reset operation of the first to second lens groups 11 to 12, the reference position (HP position) of the first to second lens groups 11 to 12 is detected and moved to the wide angle position (1-2 group: Reset). Next, as a reset operation of the third lens group 13, a reference position (HP position) of the third lens group 13 is detected and moved to a wide angle position (third group: Reset). Finally, as a reset operation of the fourth lens group 14, a reference position (HP signal) of the fourth lens group 14 is detected and moved to a wide angle infinite position (fourth group: Reset).

<When Group 1-2 HP Signal = H, Group 3 HP Signal = H, Group 4 HP Signal = L When Group 1-2 HP Signal = H, Group 3 HP Signal = H, Group 4 HP Signal = H>
First, as the retracting operation of the first to second lens groups 11 to 12, the first to second lens groups 11 to 12 are driven in the telephoto direction, and the specified pulse is driven after the falling edge of the reference signal is detected (1-2 group). : Evacuation). Next, as the storing operation of the fourth lens group 14, the reference position (HP position) of the fourth lens group 14 is detected and moved to the storing position (fourth group: storage).

  If the reference position (HP position) of the fourth lens group 14 can be detected, the reference position (HP position) of the third lens group 13 is detected and moved to the storage position as the storage operation of the third lens group 13. (Group 3: storage).

  When the reference position (HP position) of the fourth lens group 14 cannot be detected, since the interference with the third lens group 13 is assumed, the storage operation of the third lens group 13 is performed first (Group 3: storage). ).

  When the storage operation of the third lens group 13 is completed, the storage operation of the fourth lens group 14 is continued (fourth group: storage). If the HP position cannot be detected during the retracting operation of the third lens group 13, interference with the fourth lens group 14 is assumed. Therefore, as the retracting operation of the third lens group 13, the third lens group 13 is moved in the telephoto direction. Drive the specified number of pulses (Group 3: evacuation).

  Thereafter, the storage operation of the fourth lens group 14 (fourth group: storage) and the storage operation of the third lens group 13 are performed (third group: storage).

  Next, as the reset operation of the first to second lens groups 11 to 12, the reference position (HP position) of the first to second lens groups 11 to 12 is detected and moved to the wide angle position (1-2 group). : Reset). Next, as a reset operation of the third lens group 13, a reference position (HP position) of the third lens group 13 is detected and moved to a wide angle position (third group: Reset). Finally, as the reset operation of the fourth lens group 14, the reference position (HP signal) of the fourth group is detected and moved to the wide angle infinite position (fourth group: Reset).

<When Group 1-2 HP Signal = L, Group 3 HP Signal = L, Group 4 HP Signal = L When Group 1-2 HP Signal = L, Group 3 HP Signal = L, Group 4 HP Signal = H>
First, as the storing operation of the fourth lens group 14, the reference position (HP position) of the fourth lens group 14 is detected and moved to the storing position (fourth group: storage). Next, as the storage operation of the third lens group 13, the reference position (HP position) of the third lens group 13 is detected and moved to the storage position (third group: storage). Next, as a reset operation of the first to second lens groups 11 to 12, the reference position (HP position) of the first to second lens groups 11 to 12 is detected and moved to the wide angle position (1-2 group: Reset). Next, as a reset operation of the third lens group 13, a reference position (HP position) of the third lens group 13 is detected and moved to a wide angle position (third group: Reset). Finally, as a reset operation of the fourth lens group 14, a reference position (HP signal) of the fourth lens group 14 is detected and moved to a wide angle infinite position (fourth group: Reset).

<When Group 1-2 HP Signal = L, Group 3 HP Signal = H, Group 4 HP Signal = L When Group 1-2 HP Signal = L, Group 3 HP Signal = H, Group 4 HP Signal = H>
First, as the storing operation of the fourth lens group 14, the reference position (HP position) of the fourth lens group 14 is detected and moved to the storing position (fourth group: storage). When the reference position (HP position) of the fourth lens group 14 can be detected, the reference position (HP position) of the third group is detected and moved to the storage position as the storage operation of the third lens group 13 ( Group 3: storage).

  When the reference position (HP position) of the fourth lens group 14 cannot be detected, it is assumed that the fourth lens group 14 interferes with the third lens group 13, and therefore the storage operation of the third group is performed first (third group: storage). When the storage operation of the third lens group 13 is completed, the storage operation of the fourth lens group 14 is continued (fourth group: storage).

  If the HP position cannot be detected during the retracting operation of the third lens group 13, it is assumed that the interference with the fourth lens group 14 occurs. Therefore, as the retracting operation of the third lens group 13, the third lens group 13 is moved in the telephoto direction. Drive the specified number of pulses (Group 3: evacuation). Thereafter, the storage operation of the fourth lens group 14 (fourth group: storage) and the storage operation of the third lens group 13 are performed (third group: storage).

Next, as a reset operation of the first to second lens groups 11 to 12, the reference position (HP position) of the first to second lens groups 11 to 12 is detected and moved to the wide angle position. (1-2 Group: Reset) Next, as the reset operation of the third lens group 13, the reference position (HP position) of the third lens group 13 is detected and moved to the wide angle position (3rd group: Reset). Finally, as a reset operation of the fourth lens group 14, a reference position (HP signal) of the fourth lens group 14 is detected and moved to a wide angle infinite position (fourth group: Reset).
[Storage sequence]
By closing the lens barrier 62, the barrier switch signal changes from L to H, and the storing operation is started. As described above, the lens barrier 62 may be operated by mechanically closing the lens barrier with an operation lever or the like. However, the lens barrier 62 is closed by operating the barrier switch. There is also.

  The shutter motor 506 controls the shutter to be fully closed, and sets the shutter of the shutter / aperture unit 15 to the fully closed state. Next, intermediate diaphragm control is performed by the first and second diaphragm driving motors 504 and 505, and the diaphragm of the shutter / diaphragm unit 15 is set to the intermediate diaphragm state. Next, the fourth lens group 14 is housed and driven by the fourth group pulse motor 508. The fourth group pulse motor 508 starts to be driven in the storage position direction, and the fourth group photo interrupter 512 waits for the reference position detection.

  The fourth position photo interrupter 512 is pulse-driven by the storage position movement amount from the position where the reference position signal (HP signal) changes from H to L to the storage position. The storage position movement amount is set in advance, but can be changed by storing it in a nonvolatile memory such as an EEPROM and rewriting it.

  Next, the third lens group 13 is housed and driven by a third group pulse motor 507 (motor 52). The third group pulse motor 507 (motor 52) is rotated by a predetermined number of pulses to move the third lens holding frame 31 to the movement start reference position B. The storage position movement amount is preset and stored in a non-volatile memory such as an EEPROM, but can be changed by rewriting.

  When the third lens holding frame 31 reaches the reference position B, the third group pulse motor (the motor 52 is stopped, and then the first to second lens groups 11 to 12 are driven by the first to second group DC motors 503. The storage drive is performed.

  The first to second group DC motors 503 are started to be driven in the storage position direction, and the reference position detection waiting by the first to second group photo reflectors 510 is awaited. The amount of movement of the storage position from the location where the reference position signal (HP signal) by the first to second group photoreflectors 510 has changed from L to H to the storage position is represented by a pulse-like signal by the first to second group photointerrupters 509 ( The movement amount control of the first to second lens groups 11 to 12 is performed by counting the (PI signal). The storage position movement amount is set in advance, but can be changed by storing it in a nonvolatile memory such as an EEPROM and rewriting it.

  The DC motor 503, that is, the motor 51 that drives the first rotating cylinder 22 rotates the first rotating cylinder 22 so as to be accommodated in the retracted direction, thereby causing the protrusion 31p and the protrusion 22p to interfere with each other and holding the third lens. The frame 31 is returned to the retracted position.

When the first and second lens groups 11 to 12 are housed and driven, the PI signal from the first and second group photointerrupters 509 is counted and the housing position is reached without dropping the voltage before stopping. The brake control is performed to stop the driving of the first to second lens groups 11 to 12. This is to reduce the midway stop caused by dropping the voltage.
[Variation sequence]
Next, the zooming operation sequence will be described with reference to the flowchart shown in FIG.

  When the zooming process is started by operating the zoom lever or the zoom button, it is first determined whether or not the fourth lens group 14 needs to be retracted (step S11). The determination in step S11 is zooming from telephoto to wide-angle, and it is assumed that retraction processing is necessary when the fourth lens group 14 is positioned closer to the predetermined position than the predetermined position. Next, the magnification driving direction is determined (step S12). In the case of zooming from wide angle to telephoto, the first to second group DC motors 503 are operated to start driving the first to second lens groups 11 to 12 (step S13).

  Next, it is determined whether or not the first to second lens groups 11 to 12 are stopped (step S14). The determination in step S14 is that the zoom drive switch that is activated by the zooming operation through the zoom lever or the zoom button is turned off or reaches a position that is a predetermined amount from the telephoto position when driving from wide angle to telephoto. The first and second lens groups 11 to 12 are stopped when any of the conditions of a predetermined amount before the wide angle position is reached during driving from the telephoto to the wide angle. .

  When stopping the first to second lens groups 11 to 12, it is determined whether or not the third lens group 13 is being driven (step S15). The first to second lens groups 11 to 12 are stopped (step S16), and the first to second lens groups 11 to 12 are braked (step S17). Next, the zoom drive direction is determined (step S18). If the zoom is from wide angle to telephoto, position correction drive of the third lens group 13 is performed (step S19), and aperture drive is performed. (Step S20), the process ends (returns to the operation standby state).

  If it is determined in step S11 that the fourth lens group 14 needs to be retracted, the fourth lens group 14 is retracted (step S21), and the process proceeds to step S12. If it is determined in step S12 that the zooming drive direction is zooming from telephoto to wide angle, the third lens group 13 is retracted (step S22), and the process proceeds to step S14.

  If it is determined in step S14 that the driving is continued without stopping the first to second lens groups 11 to 12, it is determined whether or not the third lens group 13 is being driven ( Step S23) When the third lens group 13 is stopped, it is determined whether or not driving of the third lens group 13 is started (step S24).

  The determination items in this step S24 are (1) whether the first to second lens groups 11 to 12 have been driven by a predetermined driving amount or more after the start of driving of the first to second lens groups 11 to 12; When the third lens group 13 is driven by resuming driving when driving to the telephoto, and the first to second lens groups 11 to 12 pass a predetermined zoom point, the position of the third lens group 13 is the first position. (3) The third lens group 13 is in a driving state due to resumption of driving when driving from the telephoto to the wide angle, and the first to second lenses When the groups 11 to 12 pass a predetermined zoom point, the position of the third lens group 13 is closer to the position of the first to second lens groups 11 to 12 than a predetermined amount. If any of the above conditions is met in step S24, driving of the third lens group 13 is permitted.

  When the driving of the third lens group 13 is permitted in step S24, the driving of the third lens group 13 is started (step S25), and the process returns to step S14. If the driving of the third lens group 13 is not permitted in step S24, the process directly returns to step S14.

  If it is determined in step S23 that the third lens group 13 is being driven, it is determined whether or not to stop driving the third lens group 13 (step S26). The determination in step S26 is whether the position of the third lens group 13 is closer than the predetermined amount to the positions of the first to second lens groups 11 to 12 during driving from wide angle to telephoto or when driving from telephoto to wide angle. In this case, the driving of the third lens group 13 is permitted to stop when the position of the third lens group 13 is a predetermined amount or more away from the positions of the first to second lens groups 11 to 12. Shall. If the drive stop of the third lens group 13 is permitted in step S26, the stop operation of the third lens group 13 is started (step S27), and the process returns to step S14. If stop of driving of the third lens group 13 is not permitted in step S26, the process returns to step S14 as it is.

If it is determined in step S15 that the third lens group 13 is being driven, a stop operation of the third lens group 13 is started (step S28), and the process proceeds to step S16. If it is determined in step S18 that the zooming driving direction is zooming from telephoto to wide angle, a backlash operation is performed (step S29), and the process proceeds to step S19.
[Variable operation]
Next, the scaling operation according to this flowchart will be specifically described for each scaling operation direction.
[From wide angle to telephoto direction]
First, the zooming operation from wide angle to telephoto will be described with reference to the timing chart shown in FIG. By depressing the telephoto button of the zooming buttons, the telephoto switch signal changes from H to L, and the zooming sequence in the telephoto direction is started. First, the retraction determination of the 4th lens group 14 is implemented (step S11).

As described above, when the fourth lens group 14 is retracted, the fourth lens group 14 is retracted only when the following condition is satisfied simultaneously (AND condition).
(1) The zooming drive from telephoto to wide angle.
(2) The fourth lens group 14 is located closer to the drawing position than the predetermined position (retraction threshold value).

  However, when driving from wide angle to telephoto, the above-described condition is not satisfied, and therefore the fourth lens group 14 is not retracted.

  Next, it is determined whether or not the third lens group 13 is driven to retract according to the driving direction (step S12). In the case of zooming from wide angle to telephoto, the retracting drive of the third lens group 13 is not necessary. And the drive of the 1st-2nd lens groups 11-12 by the 1st-2nd group DC motor 503 is started (step S13).

  In the start-up period immediately after the start of start-up of the first to second group DC motors 503, the drive voltage is set lower than the steady voltage in order to prevent an inrush current due to the DC motor. After the start-up period is completed, the drive voltage is raised to a steady voltage.

  The driving voltage between the wide angle and the telephoto is set lower than the driving voltage between the storage and the wide angle position. This is because high speed is required between the storage and wide-angle positions, so a high voltage is set. Between wide-angle and telephoto, an appropriate voltage is applied to stop at a desired location by operating the zoom button. It is set.

  The movement amount control by driving the first to second lens groups 11 to 12 is performed by counting pulse-like signals (PI signals) from the first to second group photointerrupters 509. Further, 17 zoom points are set as a reference for control by dividing the wide-angle to telephoto range into, for example, 16 equal parts.

Next, it is determined whether to stop the first to second lens groups 11 to 12 (step S14). When stopping the driving of the first to second lens groups 11 to 12, stop processing is performed when any one of the following conditions is satisfied (OR condition).
(1) When the telephoto zoom drive switch that is activated by a zooming operation via a zoom lever or a zoom button is turned off, that is, changes from L to H.
(2) When reaching a position a predetermined amount before the telephoto position during driving from wide angle to telephoto.

  When the first to second lens groups 11 to 12 are continuing to be driven, the drive start / stop determination is made according to the state of the third lens group 13 (whether driving or stopped) (step S23).

  If the state of the third lens group 13 is stopped, it is determined whether or not the driving of the third lens group 13 is appropriate (step S24). If permitted, the driving of the third lens group 13 is started.

In the drive start determination of the third lens group 13 in step S24, the drive of the third lens group 13 is started when any one of the following conditions is satisfied.
(1) The case where the first to second lens groups 11 to 12 are driven by a specified driving amount or more after the first to second lens groups 11 to 12 are driven.
(2) When driving from wide angle to telephoto, the third lens group 13 is in a driving state by resuming driving, and when the first to second lens groups 11 to 12 pass a predetermined zoom point, the third lens group 13 is driven. When the position of the lens group 13 is away from the position of the first to second lens groups 11 to 12 by a predetermined amount or more.

If the third lens group 13 is being driven, it is determined whether or not to stop driving the third lens group 13 (step S26). If permitted, the third lens group 13 is driven. Stop. In determining whether to stop the driving of the third lens group 13, the driving of the third lens group 13 is stopped when the following condition is satisfied.
(1) When the third lens group 13 comes closer to the first to second lens groups 11 to 12 than the predetermined amount during driving from wide angle to telephoto.

  That is, when the first to second lens groups 11 to 12 are activated and the driving amount of the first to second lens groups 11 to 12 is equal to or greater than the prescribed pulse, driving of the third lens group 13 is started. If the position of the third lens group 13 approaches the first to second lens groups 11 to 12 during the simultaneous driving and approaches a predetermined amount, the driving of the third lens group 13 is stopped. Thereafter, when the first to second lens groups 11 to 12 are moved away from the third lens group 13 and separated from a predetermined amount, the driving of the third lens group 13 is resumed. The driving / stopping of the third lens group 13 is repeated according to the positional relationship between the first to second lens groups 11 to 12 and the third lens group 13.

  As a result, it is possible to perform variable power driving while maintaining the distance between the groups. In addition, by starting the driving of the third lens group 13 after the driving of the specified amount or more after starting, the influence of the inrush current of the first to second group DC motors 503 can be avoided, and the current consumption is reduced. Contribute to.

  When the telephoto switch signal changes from L to H before the initial driving of the third lens group 13 is started, stop control of the first to second lens groups 11 to 12 is performed without simultaneous driving of the third lens group 13. If the third lens group 13 is being driven even though the first and second lens groups 11 to 12 are determined to be stopped in the stop determination, the stop operation of the third lens group 13 is started. . Then, the stop operation of the first to second lens groups 11 to 12 is started.

  During the stop operation, a low speed control period is set, and the drive voltage is lowered according to the number of remaining pulses up to the target position. This reduces the amount of overrun when the target position is reached. When the PI signal from the first to second group photo interrupters 509 is counted and the target position is reached, brake control is performed to stop the driving of the first to second lens groups 11 to 12. The amount of overrun during the braking period is also counted, and the final first to second lens groups 11 to 12 are determined.

After the first to second lens groups 11 to 12 are stopped, the position of the third lens group 13 is corrected and driven. This calculates the stop position of the 3rd lens group 13 corresponding to the final stop position of the 1st-2nd lens groups 11-12, and drives to that position. From the position information for each zoom point of the first to second lens groups 11 to 12 and the position information for each zoom point of the third lens group 13, the first corresponding to the stop position of the first to second lens groups 11 to 12. The target stop position of the three lens group 13 is interpolated. Thereafter, aperture driving is performed to set the aperture position corresponding to the stopped zoom position (step S20).
[From telephoto to wide angle]
Next, the zooming operation from telephoto to wide angle will be described with reference to the timing chart shown in FIG. By depressing the wide-angle button among the zoom buttons, the wide-angle switch signal is changed from H to L, and the magnification changing sequence in the wide-angle direction is started. First, the retraction determination of the fourth lens group 14 is performed.

As described above, when the fourth lens group 14 is retracted, the fourth lens group 14 is retracted only when the following condition is satisfied simultaneously (AND condition).
(1) When zooming from telephoto to wide angle.
(2) When the fourth lens group 14 is located closer to the delivery side than the predetermined position (retraction threshold value).

  During driving from telephoto to wide angle, when the position of the fourth lens group 14 is closer to the predetermined position, the fourth lens group 14 is driven to retract. The retracted amount is retracted to an area where no interference with the fourth lens group 14 occurs when the third lens group 13 is zoomed.

  Next, the third lens group 13 is retracted. In order to prevent interference with the first to second lens groups 11 to 12 due to the start of driving of the first to second lens groups 11 to 12, the third lens group 13 is driven in advance by a specified amount. Then, the first to second group DC motor 503 starts driving the first to second lens groups 11 to 12.

  In the start-up period immediately after the start of start-up of the first to second group DC motors 503, the drive voltage is set lower than the steady voltage in order to prevent an inrush current by the DC motor. After the start-up period is completed, the drive voltage is raised to a steady voltage. The control of the movement amount by driving the first to second lens groups 11 to 12 is performed by counting pulse signals (PI signals) from the first to second group photointerrupters 509. As described above, the zoom point to be used as a reference for control is set by dividing the wide angle to the telephoto range into, for example, 16 equal parts.

In determining whether to stop driving the first to second lens groups 11 to 12, stop processing is performed when any of the following conditions is satisfied as described above.
(1) A wide-angle zoom drive switch that is activated by a zooming operation via a zoom lever or a zoom button is turned off, that is, changes from L to H.
(2) When reaching a position a predetermined amount away from the wide-angle position during driving from telephoto to wide-angle.

  In the case where the driving of the first to second lens groups 11 to 12 is continuing, the driving start or driving stop is determined according to the state of the third lens group 13 (whether driving or stopping). If the state of the third lens group 13 is stopped, the drive start determination of the third lens group 13 is performed, and if the drive start is permitted, the drive of the third lens group 13 is started.

In determining whether to start driving the third lens group 13, the driving of the third lens group 13 is started when any one of the following conditions is satisfied.
(1) The first to second lens groups 11 to 12 are driven by a specified driving amount or more after the first to second lens groups 11 to 12 are driven.
(2) When the third lens group 13 is driven by resuming driving when driving from telephoto to wide-angle, and the first to second lens groups 11 to 12 pass a predetermined zoom point, the third lens The group 13 is closer to the first to second lens groups 11 to 12 than a predetermined amount.

  If the third lens group 13 is being driven, it is determined whether to stop driving the third lens group 13, and if permitted, the driving of the third lens group 13 is stopped.

In determining whether to stop driving the third lens group 13, the driving of the third lens group 13 is stopped when the following condition is satisfied.
(1) The position of the third lens group 13 is separated from the positions of the first to second lens groups 11 to 12 by a predetermined amount or more during driving from telephoto to wide angle.

  That is, when the first to second lens groups 11 to 12 are activated and the driving amount of the first to second lens groups 11 to 12 is equal to or greater than a specified amount, driving of the third lens group 13 is started. If the position of the third lens group 13 is separated from the first to second lens groups 11 to 12 during the simultaneous driving and is more than a predetermined amount, the driving of the third lens group 13 is stopped. Thereafter, when the first to second lens groups 11 to 12 approach the third group and approach the specified pulse or more, the driving of the third lens group 13 is resumed. The driving / stopping of the third lens group 13 is repeated depending on the positional relationship between the first to second lens groups 11 to 12 and the third lens group 13.

  As a result, variable power driving is possible with the group kept. Further, by driving the third lens group 13 after a predetermined pulse or more has elapsed at the time of activation, the influence of the inrush current of the first to second group DC motors 503 can be avoided, and current consumption is reduced.

  In the driving of the third lens group 13 when the first to second lens groups 11 to 12 are driven, when the driving is performed in the wide-angle direction, the rattling control for removing the rattling at the time of stop is performed. Although necessary, during zooming, rattling control is prohibited, and intermittent control of the third lens group 13 is made smooth.

  If the wide-angle SW signal changes from L to H before the initial driving of the third lens group 13 is started, stop control of the first to second lens groups 11 to 12 is performed without simultaneous driving of the third lens group 13. It will be. When it is determined that the first and second lens groups 11 to 12 are stopped, if the third lens group 13 is being driven, a stop operation is started. Then, the stop operation of the first to second lens groups 11 to 12 is started.

  During the stop operation, a low speed control period is set, and the drive voltage is lowered according to the number of remaining pulses up to the target position. This reduces the amount of overrun when the target position is reached. The PI signals from the first and second group photo interrupters 509 are counted, and when the first and second lens groups 11 to 12 reach the target position, the driving of the first and second lens groups 11 to 12 is stopped. Therefore, brake control is performed. The amount of overrun during the braking period is also counted, and the final first to second lens groups 11 to 12 are determined.

  Further, during the operation from the telephoto to the wide-angle direction, a backlash removal operation (backlash operation) for backlash removal is performed.

  After the first to second lens groups 11 to 12 are stopped, the position of the third lens group 13 is corrected and driven. This calculates the stop position of the 3rd lens group 13 corresponding to the final stop position of the 1st-2nd lens groups 11-12, and drives to that position.

  In the correction driving of the position of the third lens group 13, the first to first lens positions are calculated from the position information for each zoom point of the first to second lens groups 11 to 12 and the position information for each zoom point of the third lens group 13. The target stop position of the third lens group 13 corresponding to the stop positions of the second lens groups 11 to 12 is interpolated.

  When driving in the wide-angle direction, play control is performed to remove play when stopped. Thereafter, aperture driving is performed to set the aperture position corresponding to the stopped zoom position.

  In this example, in the zooming operation between the wide angle and the telephoto, the driving voltage of the first to second group DC motors 503 during the wide angle direction operation is higher than the drive voltage of the first to second group DC motors 503 during the telephoto direction operation. The drive voltage is set high. Also in the third group pulse motor 507, the pulse rate is set to be faster in the wide-angle direction operation than in the telephoto direction operation. Further, in order to keep the first to second lens groups 11 to 12 and the third lens group 13 between, the third lens group 11 to the third lens group 13 according to the positional relationship between the first and second lens groups 11 to 12 and the third lens group 13. Intermittent control of the lens group 13 is performed. Therefore, at the time of driving in the telephoto direction, the driving speed of the third lens group 13 is set to be equal to or faster than the driving speed of the first to second lens groups 11 to 12.

  Similarly, in the wide-angle direction driving, the driving speed of the third lens group 13 is set to be equal to or faster than the driving speed of the first to second lens groups 11 to 12. By doing so, the third lens group 13 is not separated from the first to second lens groups 11 to 12 during the telephoto operation, and the third lens group 13 is used for the first to first operation during the wide-angle operation. The second lens groups 11 to 12 are driven without being caught up.

  As shown in FIG. 9, a solid-state image pickup device 16 such as a CCD (charge coupled device) solid-state image pickup device is disposed behind the fourth lens group 14, that is, on the side far from the object. Is configured such that a subject image is formed on its input surface. Various optical filters such as a low-pass filter, a cover glass, and other optical elements are appropriately provided on the input surface side of the solid-state imaging device 16 as necessary.

  The lens barrier 62 shown in FIGS. 3 to 5 covers the object side of the first lens group 11 in the housed state, and protects the lens group from contamination or damage. The lens barrier 62 is driven back and forth in a direction orthogonal to the photographing optical axis by a barrier driving system 63. 3 and 4 show a state in which the lens barrier 62 is closed, and FIG. 5 shows a state in which the lens barrier 62 is almost opened. The barrier drive system 63 operates the barrier operation unit (see the barrier operation unit 301 in FIG. 17A) to move the lens barrier 62 to the closed position (FIGS. 3 and 4) and the open position (from the position in FIG. 5). Further, it is driven between a position away from the photographing optical axis). The barrier drive system 63 has a function of biasing the lens barrier 62 in the closing direction at the closing position and in the opening direction at the opening position.

  Therefore, if the lens barrier 62 is operated in the opening direction with the lens barrier 62 closed, the lens barrier 62 shifts to the open state semi-automatically from where the lens barrier 62 has passed a predetermined position. Further, when the lens barrier 62 is closed from the opened state, the lens barrier 62 is not necessarily the same as the predetermined position when the lens barrier 62 is opened, but a smooth operation can be expected if it has a certain degree of hysteresis characteristics. ) After that, semi-automatically moves to the closed state.

  The barrier control piece 61 is provided on the side portion of the fixed frame 21 (the opening position of the lens barrier 62) so as to be slidable in the direction along the photographing optical axis, and is appropriately biased toward the object side by a spring or the like. In the retracted state, the engagement portion formed by bending the barrier control piece 61 is engaged with the base end surfaces of the first rotating cylinder 22 and the first liner 23, and is biased toward the image surface side against the urging force. The lens barrier 62 is not touched. In the photographing state, the lens barrier 62 is completely separated from the lens groups and their holding frames. In this state, the barrier control piece 61 is disengaged from the engaging portion, biased toward the object side by the biasing force, and the barrier blocking portion at the tip projects into the forward / backward path of the lens barrier 62.

  In this state, when the lens barrier 62 is rapidly operated when trying to shift to the retracted state, the lens barrier 62 may hit the lens barrel. However, the barrier blocking portion at the tip of the barrier control piece 61 is used as the lens barrier. The lens barrier 62 is prevented from entering the lens barrel portion. When each lens group is housed and in the housed state, the proximal end surfaces of the first rotating cylinder 22 and the first liner 23 are engaged with the bent engagement portions of the barrier control piece 61, and the urging force is applied. Therefore, the lens barrier 62 can be moved to the front portion of the lens barrel, and the lens barrier 62 is correctly set at the closed position. In this way, interference between the lens barrier 62 and the lens barrel portion of the lens group can be effectively prevented.

  In the above description, the case where the third lens group 13 is configured to be retracted out of the optical axis has been described. In the case of the configuration of the present invention, when the lens group having the smallest outer diameter is retracted to the outside of the optical axis, and when swinging from the retracted position to the imaging position or vice versa, the optical axis direction of the lens at the imaging position When moving forward / backward, the swing mechanism and the forward / backward mechanism are configured separately to reduce the length of the swing mechanism in the lens optical axis direction, effectively reducing the lens barrel projection size when retracted. can do.

  The retractable lens group is a lens group that is as far as possible from the image plane when extended, so that the drive mechanism (at least one of the length of the main shaft and the length of the lead screw) of the retractable lens group can be shortened. The thickness of the barrel can be reduced, that is, the dimension in the optical axis direction can be reduced. Since the lens group located behind the shutter having the aperture function and closest to the shutter is the retractable lens group, the lens group having the smallest outer diameter and not leaving the image plane can be used as the retractable lens group. It is easy to evacuate without having to consider interference with a shutter that covers a plane perpendicular to the optical axis, or avoiding the position of the shutter.

  In this case, the lens configuration includes four groups of a first lens group having a positive power, a second lens group having a negative power, a third lens group having a positive power, and a fourth lens group having a positive power. The zooming is performed by changing at least the distance between the first lens group and the second lens group, the distance between the second lens group and the third lens group, and the distance between the third lens group and the fourth lens group, Focusing is performed by correcting the position of the image plane on the imaging plane by moving the fourth lens group.

  A shutter having a diaphragm function is positioned in front of the third lens group. By making the lens configuration into a four-group configuration and the third lens group as the retractable lens group, the lens group having the smallest outer diameter that is as far as possible from the image plane can be used as the retractable lens group, and the lens barrel projection size is small. The lens barrel can be made thin.

In addition, the third lens group having a zoom ratio of 4 times or more and a four-group lens configuration is a retractable lens group, so that a lens barrel size (projection size and thickness) is reduced while realizing a high zoom ratio. A torso can be provided. The lens configuration is a three-group lens configuration of a first lens group having a positive power, a second lens group having a negative power, and a third lens group having a positive power, and the third lens group can be used as a retracting lens group. Good. The first lens group having negative power, the second lens group having positive power, and the third lens group having positive power have a three-group lens structure, and the third lens group or the second lens group is a retractable lens. It is good as a group. Each lens group may be composed of one or more lenses, and the lens group here refers to one or more lenses that move together. Therefore, all the lens groups may be constituted by one lens.
(Second Embodiment)
Next, a second embodiment of the present invention in which a camera is configured by adopting an optical system apparatus including a lens barrel according to the present invention as shown in the first embodiment described above as a photographing optical system. Will be described with reference to FIGS. 17 is a perspective view showing the appearance of the camera as seen from the front side that is the object, that is, the subject side, and FIG. 18 is a perspective view showing the appearance of the camera as seen from the back side that is the photographer side. These are block diagrams which show the function structure of a camera.

  Although a camera is described here, a camera in which a camera function is incorporated in a portable information terminal device such as a so-called PDA (personal data assistant) or a cellular phone has recently appeared. Many of such portable information terminal devices have substantially the same functions and configurations as the camera, although the appearance is slightly different, and the lens mirror according to the present invention is included in such a portable information terminal device. You may employ | adopt the optical system apparatus containing a pipe | tube.

  As shown in FIGS. 17 and 18, the camera includes a photographing lens 101, a shutter button 102, a zoom lever 103, a finder 104, a strobe 105, a liquid crystal monitor 106, an operation button 107, a power switch 108, a memory card slot 109, a communication card. A slot 110 and a barrier operation unit 301 are provided. Furthermore, as shown in FIG. 19, the camera also includes a light receiving element 201, a signal processing device 202, an image processing device 203, a central processing unit (CPU) 204, a semiconductor memory 205, a communication card 206, and the like. Further, although not clearly shown, each of these units is operated by being fed by a battery as a driving power source.

  The camera includes a photographic lens 101 and a light receiving element 201 as an area sensor such as a CCD (charge coupled device) imaging device, and is an object to be photographed, that is, a subject formed by the photographic lens 101 that is a photographing optical system. The image is read by the light receiving element 201. As the photographing lens 101, an optical system apparatus including the lens barrel according to the present invention as described in the first embodiment is used. Specifically, the optical system apparatus is configured by using a lens or the like that is an optical element constituting the lens barrel. The lens barrel has a mechanism for holding each lens and the like so that the lens can be moved at least for each lens group. The photographing lens 101 incorporated in the camera is usually incorporated in the form of this optical system device.

  The output of the light receiving element 201 is processed by the signal processing device 202 controlled by the central processing unit 204 and converted into digital image information. The image information digitized by the signal processing device 202 is subjected to predetermined image processing in the image processing device 203 which is also controlled by the central processing unit 204 and then recorded in the semiconductor memory 205 such as a nonvolatile memory. In this case, the semiconductor memory 205 may be a memory card loaded in the memory card slot 109 or a semiconductor memory built in the camera body. The liquid crystal monitor 106 can display an image being photographed, or can display an image recorded in the semiconductor memory 205. The image recorded in the semiconductor memory 205 can also be transmitted to the outside via a communication card 206 or the like loaded in the communication card slot 110. Note that the central processing unit 501 shown in FIG. 21 for driving control of each lens described above may be included in the central processing unit 204, and is configured using another microprocessor linked thereto. May be.

  When the camera is carried, the photographing lens 101 is in a retracted state and buried in the camera body as shown in FIG. 17A, and the lens barrier 62 is closed. When the user operates the barrier operation unit 301 to open the lens barrier 62, the power is turned on, the lens barrel is extended as shown in FIG. 17B, and the camera body is projected from the camera body. To do. At this time, in the lens barrel of the photographing lens 101, the optical systems of the respective groups constituting the zoom lens are disposed at, for example, a wide-angle position. By operating the zoom lever 103, the optical systems of the respective groups are disposed. Is changed, and the zooming operation to the telephoto end can be performed.

  Note that it is desirable that the optical system of the finder 104 is also scaled in conjunction with the change in the angle of view of the photographing lens 101.

  In many cases, focusing is performed by half-pressing the shutter button 102. Focusing in the zoom lens according to the present invention can be performed mainly by moving the fourth lens group 14. When the shutter button 102 is further pushed down to the fully depressed state, photographing is performed, and then the processing as described above is performed.

  When the image recorded in the semiconductor memory 205 is displayed on the liquid crystal monitor 106 or transmitted to the outside via the communication card 206 or the like, the operation button 107 is operated in a predetermined manner. The semiconductor memory 205 and the communication card 206 are used by being loaded into dedicated or general-purpose slots such as the memory card slot 109 and the communication card slot 110, respectively.

  When the photographic lens 101 is in the retracted state, the third lens group 13 is retracted from the optical axis and housed in parallel with the first lens group 11 and the second lens group 12, so that the camera Thinning can be realized.

  Normally, the finder mechanism is arranged on the upper side of the lens barrel to facilitate camera operation. When the lens barrel includes a zoom magnifying mechanism, the finder mechanism also requires a zoom magnifying mechanism. Therefore, a drive source (such as a DC motor or a pulse motor) for achieving zoom zooming operation and a transmission mechanism (such as a gear coupling mechanism) for transmitting the driving force are disposed in the immediate vicinity of the finder mechanism. It is desirable.

  For example, when the finder mechanism is installed on the upper left side of the lens barrel, the variable magnification drive source and the transmission mechanism are installed on the upper right side of the lens barrel, so that the limited space is effectively used.

  Next, when retracting the retractable lens holding frame, the retractable lens holding frame is naturally installed below the lens barrel from the remaining space (the lower right side or the lower left side of the lens barrel). In this embodiment, a space for the retractable lens holding frame is installed on the lower right side of the lens barrel, and a driving source and a driving mechanism for driving the focusing lens group are arranged on the lower left side of the lens barrel. Thus, the lens barrel can be reduced in size by effectively using the upper left, upper right, lower right, and lower left corners of a normal circular lens barrel.

The perspective view which looked at the structure of the principal part of the lens barrel part in the retracted accommodation state which retracted and accommodated the lens group of the optical system apparatus containing the lens barrel based on the 1st Embodiment of this invention from the object side. is there. It is the perspective view which looked at the structure of the principal part in the state of FIG. 1 from the image plane side. It is the typical perspective view which looked at the composition of the principal part of the optical system apparatus containing the lens barrel and lens barrier in the retracted storage state which closed the lens barrier from the object side. FIG. 4 is a schematic perspective view of the configuration of the main part in the state of FIG. 3 viewed from the image plane side. FIG. 3 is a schematic perspective view of the configuration of the main part of the lens barrel part and the lens barrier part viewed from the image plane side in a state where the lens barrier opened in the photographing state in which the lens group is projected is being closed. It is the perspective view which looked at the structure of the principal part of the lens barrel part in the imaging | photography state which protruded the lens group from the image plane side. In order to explain the operation of the third lens holding frame for holding the third lens group and the projection, the arrangement of the third lens holding frame, the projection, the collision prevention piece, and the fourth lens holding frame in the retracted state of the lens group. It is the perspective view which looked at the structure from the object side. In order to explain the operation of the third lens holding frame that holds the third lens group and the collision prevention piece, the third lens holding frame, the protrusion, the collision prevention piece, and the fourth lens holding frame portion in the shooting state in which the lens group is projected. It is the perspective view which looked at the arrangement composition of from the object side. (A) shows a state of projecting to a telephoto position, and (b) shows a state of projecting to a wide-angle position. In both figures, a lens group is arranged in the upper half and lower half with the lens optical axis as a boundary. FIG. 3 is a longitudinal sectional view showing main parts of each lens group, lens holding frame, and various lens barrels in a lens barrel in a photographing state in which the lens is projected and in a retracted retracted state in which the lens barrel is retracted; It is an expanded view which expands and shows typically the shape of the cam groove formed in the 2nd rotation cylinder. It is an expanded view which develops and shows typically the shape of the cam groove formed in the cam cylinder. FIG. 4 is a development view schematically showing the shape of the cam groove and the key groove formed in the first liner and omitting the helicoid. FIG. 5 is a development view schematically showing the shape of the cam groove and key groove formed in the fixed frame and omitting the helicoid. FIG. 14 is a developed view schematically showing a helicoid added to FIG. It is a perspective view which shows the external appearance of the 1st rotation cylinder fitted to a helicoid. It is a side view which shows the structure of a 3rd lens holding frame and a drive operation system. It is a perspective view of Fig.14 (a). It is a perspective view showing the state where the third lens holding frame is positioned at the photographing position by the third lens holding frame, its protrusion, and the driving operation system. FIG. 10 is a perspective view showing a state in which the third lens holding frame is positioned at the retracted position by the protrusion and the driving operation system of the third lens holding frame. It is a perspective view of the projection part formed in the rear-end edge part of the 1st rotation cylinder. FIG. 6 is a front view of the third lens holding frame portion as viewed from the image plane side in order to explain the operation of the third lens holding frame. It is a perspective view which mainly shows a shutter part. It is a figure which shows the state which contacted the projection part of the 3rd lens holding frame, and the projection part of the 1st rotation cylinder, and located the 3rd lens holding frame in the retracted position. It is a figure which shows the state which made the projection part of the 3rd lens holding frame and the projection part of the 1st rotary cylinder non-contact and located the 3rd lens holding frame in the imaging position. It is the perspective view seen from the object side which shows typically the appearance composition of the camera concerning a 2nd embodiment of the present invention, and (a) is the state where the photographing lens is retracted in the body of the camera, b) shows a state in which the taking lens protrudes from the body of the camera. It is the perspective view seen from the photographer side which shows typically the external appearance structure of the camera of FIG. It is a block diagram which shows typically the function structure of the camera of FIG. (A) is a perspective view schematically showing the configuration of a main part of the fourth lens holding frame and its drive operation system, and (b) is a perspective view showing a state viewed from a different angle with a part thereof omitted. FIG. It is a block diagram which shows typically the structure of a drive control system. It is a timing chart which shows the sequence at the time of the barrier opening in a starting sequence. It is a timing chart which shows the sequence at the time of barrier closing from barrier opening in a starting sequence. The reset sequence will be described, where (a) is a chart and (b) is a timing chart. It is a timing chart which shows the storage sequence at the time of a barrier closing. It is a flowchart which shows a zoom sequence. 6 is a timing chart showing a zoom sequence during zooming from a wide-angle position to a telephoto position. 6 is a timing chart showing a zoom sequence during zooming from a telephoto position to a wide-angle position.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 1st lens group 12 2nd lens group 13 3rd lens group 14 4th lens group 15 Shutter / aperture unit 16 Solid-state image sensor 17 Lens holding frame 18 Cover glass 19 Low pass filter 21 Fixed frame 22 1st rotary cylinder 22p 1st Projection part of 1 rotation cylinder 23 1st liner 24 2nd rotation cylinder 25 2nd liner 26 Cam cylinder 27 Straight advance cylinder 31 3rd lens holding frame 31p Projection part of 3rd lens holding frame 32 3rd group main guide Axis 33 Third group sub guide shaft 34 Third group lead screw 35 Third group female screw member 36 Collision preventing piece 37 Compression torsion spring 38 Third group photo interrupter (position detecting device)
41 4th lens holding frame 42 4th group sub guide shaft 43 4th group spring 44 4th group main guide shaft 45 4th group lead screw 46 4th group female screw member 47 4th group photo interrupter 51 Zoom motor 52 3rd group Motor 53 Fourth group motor 61 Barrier control piece 62 Lens barrier 63 Barrier drive system 71, 72, 73, 74 Gear 81 Holding plate 82 Lens barrel base 101 Shooting lens 102 Shutter button 103 Zoom lever 104 Viewfinder 105 Strobe 106 Liquid crystal monitor 107 Operation Button 108 Power switch 109 Memory card slot 110 Communication card slot 201 Light receiving element (area sensor)
202 Signal Processing Unit 203 Image Processing Unit 204 Central Processing Unit (CPU)
205 Semiconductor memory 206 Communication card 301 Barrier operation unit 501 Central processing unit 502 Motor driver 503 First to second group DC (direct current) motor 504 First aperture motor 505 Second aperture motor 506 Shutter motor 507 Third group Pulse motor 508 Fourth group pulse motor 509 First to second group photo interrupters 510 First to second group photo reflectors 511 Third group photo interrupters 512 Fourth group photo interrupters 513 First to second group photo interrupter drive circuits 514 First to second group photo reflector drive circuit 515 Third group photo interrupter drive circuit 516 Fourth group photo interrupter drive circuit

Claims (8)

A lens barrel in which at least a part of a plurality of lens groups is retracted to move to a state of being photographed by moving at least a part of the lens groups from a retracted state in which the lens group is housed to the object side. In a lens barrel comprising a plurality of lens holding frames for holding each lens group for each lens group, and lens holding frame driving means for driving the lens holding frame,
The plurality of lens holding frames position all the lens groups on the same optical axis from the retracted state in a state where photographing is possible, and in the retracted state, at least one lens group among the plurality of lens holding frames is A retractable lens holding frame for holding and moving the at least one lens group to retract outside the maximum outer diameter of the lens barrel of the other lens group;
The drive mechanism for the retractable lens holding frame includes a first drive mechanism that swings the retractable lens holding frame in a direction approaching and separating from the optical axis when switching between a retracted state and a photographable state; The second drive mechanism that moves the retractable lens holding frame in the same direction as the optical axis in a state where photographing is possible is driven by different drive sources, and the retractable lens holding frame is configured to hold the lens group holding position. A lens barrel having a crank-shaped bent portion for positioning on the subject side in the optical axis direction from the center position of the swing .   2. The lens barrel according to claim 1, wherein the first driving mechanism of the retractable lens holding frame performs a swing operation for switching between the retracted state and the imageable state of the retractable lens holding frame. A lens barrel driven by a third drive mechanism that drives a lens group other than the retractable lens holding frame.   3. The lens barrel according to claim 1, wherein the second drive mechanism includes a lead screw that extends the retractable lens holding frame along the optical axis. 4. Torso. 4. The lens barrel according to claim 1, wherein the first driving mechanism always attaches the retractable lens holding frame in a direction approaching an optical axis of the other lens group. 5. An urging means for urging and a protrusion protruding from the retractable lens holding frame, and the third drive mechanism urges the urging means by pressing the protrusion when in the retracted state. The retractable lens holding frame is held at the standby position against the force, and the retracted lens holding frame is released by the biasing force of the biasing means by releasing the engagement state with the protrusion when the photographing is possible. A lens barrel comprising a third driving mechanism for driving the other lens group, with a projection for swinging the lens to the photographing position .   5. The lens barrel according to claim 1, wherein the first drive mechanism has a swing center of the retractable lens holding frame when switching between the retracted state and the imageable state. A lens barrel comprising a guide shaft that guides movement in the optical axis direction in the state in which photographing is possible.   6. The lens barrel according to claim 1, wherein the first drive mechanism includes a guide mechanism for a swing operation that switches between the retracted state and the retracted state. Lens barrel characterized by.   A camera using the lens barrel according to any one of claims 1 to 6.   A portable information terminal device using the lens barrel according to any one of claims 1 to 6.

Images