JP2006064881A - Lens drive device and imaging apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens drive device which has a structure for making an electronic camera provided with a collapsible lens small in size and low in profile and is highly resistant tagainst impact caused by falling or the like, and to provide an imaging apparatus. <P>SOLUTION: The lens drive device is provided with: a lens frame for storing a lens; a cammed member disposed on the outer circumference of the lens frame; a lens frame storage member disposed on the outer circumference of the lens frame so as to be almost concentric with the lens frame; a cam member disposed between the lens frame storage member and the lens frame; a first cam part on the imaging side and a second cam part on the subject side which are disposed in series on the cam member; a guide section for guiding the cammed member disposed in the lens frame storage member; and a pressing means for pressing the cammed member. The cammed member has, in the end on the subject side, a lead-in part for the cammed member which is continuous with the second cam part. The first cam part and second cam part are projected out by allowing the insertion of the cammed member. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a lens driving device and an imaging device in an electronic camera (digital camera) or the like, and in particular, a lens in a retractable electronic camera in which a lens is housed in a camera body when not photographing and the lens protrudes toward a subject only when photographing. The present invention relates to a driving device and an imaging device.

  Unlike a camera using a film, an electronic camera (digital camera) has an increase in the size of the device itself despite the increase in the number of pixels such as a CCD (charge coupled device) used as an imaging device. Therefore, miniaturization and thinning are progressing. To reduce the size and thickness of the camera, the lens is housed in the camera body when not shooting, and the lens is protruded toward the subject only when shooting. The lens diameter regulates the thickness of the camera. The length of the lens system is such that the axis is the camera's height direction and the height direction is pointed at the subject when shooting, or the optical axis is bent at a right angle with a prism or reflecting mirror so that the thickness direction can be pointed at the subject. A method that does not change the value has been put into practical use.

  Among these, in the retractable camera, the thickness of the camera is regulated by the thickness of the lens system. That is, in order to obtain a certain resolving power, it is necessary to use a plurality of lenses, and the thickness of the camera cannot be reduced below the thickness of the lens to be used. Also, when a cam ring is used for projecting the lens system to the front of the camera during shooting, autofocus, zooming, etc., the cam ring height may exceed the lens system thickness. It also affects the camera thickness.

  That is, as schematically shown in FIG. 9, for example, a single-focus lens 90 without zooming is retracted, and a pin 92 protruding from the lens barrel 91 is provided with a cam groove 93 shown in FIG. By rotating the cam ring 94 (the cylindrical cam ring developed in a plane), the focal point at the photographing position is adjusted to infinity from the collapsed state (the pin position 92a shown in FIGS. 9B and 9A). It is moved to the position (the pin position 92b shown in FIG. 9C and FIG. 9A), and further autofocus is performed to bring the closest position into focus (FIGS. 9D and 9A). When moving to the pin position 92c shown), the height of the cam groove 93 in the optical axis direction may be as high as the lens barrel 91. In order to move the cam pin 92 accurately, the cam ring 94 is required. Light of cam groove 93 Become necessary more available L in both sides, the height of the cam ring 94 becomes greater than the thickness of the lens.

  In addition, a cam pin 92 used for such movement of the lens system has conventionally used a taper pin as indicated by 95 in FIG. However, the taper pin does not fall off when the camera is dropped, for example, so that the cam ring has a certain thickness, so that the cam ring having a cam groove 96 needs to have a certain thickness. It will become a factor to inhibit. Helicoids were also used to move the lens barrel in these small cameras, but the angle can be changed if there is a need to change the angle of the cam for lens extension and autofocus, for example. There was no problem.

  Regarding reducing the axial length without increasing the radial dimension of the cam cylinder, for example, in Patent Document 1, one cam cylinder includes the first cam groove with the largest pressure angle and the smallest cam. The groove is arranged at a position shifted in the optical axis direction at substantially the same position with respect to the circumferential direction, and a third cam groove whose pressure angle is intermediate between the first and second cam grooves is defined as the first and second cam grooves. 2 shows a lens barrel that is disposed at a position shifted in the circumferential direction with respect to the two cam grooves so as to reduce the axial length of the cam barrel.

  In addition, the first lens group frame provided with pins on the outer periphery, the second lens group frame capable of moving forward and backward relative to the first lens group frame in the optical axis direction, and the inner surface A cam frame provided with a cam groove that engages with a pin of the first lens group frame; and a biasing means that biases the pin so as to contact the second lens group frame. There has been proposed a lens driving device that is compact so that the position of the second lens group frame relative to the lens group frame can be regulated, and further, a load that rotates the cam cylinder when the inclination angle of the cam groove provided in the cam cylinder is large. Therefore, there has also been proposed a lens barrel in which cam grooves are provided at intervals of 120 degrees in the cam cylinder and the cam grooves are formed at 120 degrees or more in the circumferential direction of the cam cylinder.

Japanese Patent Laid-Open No. 10-73752

  An object of the present invention is to provide a lens driving device and an imaging device having a structure for miniaturizing an electronic camera or the like provided with a retractable lens.

In order to solve the above problems, a lens driving device according to the present invention provides:
A lens frame that houses at least one lens, a cam member provided on the outer periphery of the lens frame, a cam member provided on the outer peripheral position of the lens frame, and a continuous member provided on the cam member A first cam portion on the imaging side and a second cam portion on the subject side,
The cam member includes an introduction portion of the cam member to be connected to the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. It is provided in.

  As described above, since the first and second cam portions of the cam member are configured so that the cam member can be inserted, even if there is an impact unlike the conventional taper pin, the cam member Since the member does not come off the cam portion, and the cam member can be made thin using metal or the like, the lens driving device can be made smaller and the cam member in the lens driving device is provided on the subject side. Since the introduction portion of the cam member is provided in the second cam portion, the end portion in the optical axis direction of the cam portion can be opened, and the length of the cam member in the optical axis direction can be shortened. A lens driving device that can be reduced in size and that has an open end in the optical axis direction and has a spring property on the cam member, is strong against impacts such as dropping, and can be easily incorporated into the cam member can be provided. .

In order to solve the above-described problem, a lens driving device according to the present invention is
A lens frame that houses at least one lens, a cammed member provided on the outer periphery of the lens frame, and a lens frame storage member provided substantially concentrically with the lens frame at the outer peripheral position of the lens frame A cam member provided between the lens frame housing member and the lens frame, a continuous first cam portion on the imaging side and a second cam portion on the subject side provided on the cam member, A guide portion for guiding the cam member provided in the lens frame housing member, and a biasing means for biasing the cam member;
The cam member includes an introduction portion of the cam member to be connected to the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. It is provided in.

Furthermore, in order to solve the above-mentioned problem, the lens driving device in the present invention is
A lens frame that houses at least one lens, a cammed member provided on the outer periphery of the lens frame, and a lens frame storage member provided substantially concentrically with the lens frame at the outer peripheral position of the lens frame A cam member provided between the lens frame housing member and the lens frame, a continuous first cam portion on the imaging side and a second cam portion on the subject side provided on the cam member, A guide portion for guiding the cam member provided in the lens frame housing member, and a biasing means for biasing the cam member;
The cam member includes an introduction portion of the cam member to be continuous with the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. Provided,
The lens frame is movable in a substantially optical axis direction by being driven by the first cam portion or the second cam portion while the cam member is guided by the guide portion.
The urging means abuts and urges the cam member within a driving range in which the cam member is driven by the second cam portion.

And in order to solve the said subject, the imaging device in this invention is the following.
An imaging device comprising a lens, an imaging device, and a lens driving device,
The lens driving device includes a lens frame that houses at least one lens, a cammed member provided on an outer periphery of the lens frame, an outer peripheral position of the lens frame, and substantially concentric with the lens frame. A lens frame storage member, a cam member provided between the lens frame storage member and the lens frame, a first cam portion on the imaging side provided on the cam member, and a first cam portion on the subject side. Two cam portions, a guide portion that guides the cam member provided in the lens frame housing member, and a biasing means that biases the cam member,
The cam member includes an introduction portion of the cam member to be continuous with the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. Provided,
The lens frame is movable in a substantially optical axis direction by being driven by the first cam portion or the second cam portion while the cam member is guided by the guide portion.
The urging means abuts and urges the cam member within a range where the cam member is driven by the second cam portion.

  By configuring the lens driving device and the imaging device in this way, the cam member is biased to the imaging side by the biasing means in the second cam portion on the subject side of the cam member. Shaking is eliminated by the force means. In the second cam portion, the cam member only needs to have the contact surface of the cam member only on the imaging side, which is coupled with the presence of the cam member introduction portion in the second cam portion of the cam member. Thus, the length of the cam member in the optical axis direction can be shortened accordingly. Further, since the first and second cam portions are configured so that the cam member can be inserted, it is possible to prevent an accident that the cam member is disengaged from the cam portion even when an impact such as dropping occurs. Provided is a lens driving device in which a cam member is easily incorporated by the introduction portion in the second cam portion provided on the object side of the member, and the cam member has a spring property and is resistant to an impact such as dropping. be able to.

  The biasing means is disposed outside the lens frame housing member, and further disposed on the outer periphery of the lens frame housing member, thereby providing a lens driving device and an imaging device that are more easily assembled. be able to.

  Further, in a preferred embodiment of the present invention, the urging means is constituted by a leaf spring.

  Further, the gradient of the first cam portion with respect to the optical axis is steeper than the gradient of the second cam portion, and the first cam portion is an extension region of the lens frame, and the second cam portion By setting the cam portion to the auto focus area, the lens can be quickly extended when the lens is extended, and fine focusing can be performed with a gentle inclination with respect to the auto focus. The urging unit is urged toward the image pickup side by the urging means, but is not urged by the first cam unit, so that the cam member can be driven even if the cam unit has a different inclination. Both can be performed with substantially the same torque.

  As described above, according to the present invention, a lens driving device such as a camera equipped with a retractable lens and an imaging device can be reduced in size and can be tough against impacts.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the dimensions, materials, shapes, relative arrangements, and the like of the components described in this embodiment are not intended to limit the scope of the present invention unless otherwise specified, but are merely illustrative examples. Not too much.

  1 to 4 are diagrams for explaining an outline of an example of an electronic camera including a lens driving device and an imaging device according to the present invention. FIG. 1 illustrates the electronic camera 10 in a non-photographing state on the front side (subject side). 2 is a perspective view showing the electronic camera 10 from the back side, FIG. 3 is a view of the electronic camera 10 viewed from the front side, and FIG. 4 is a view of the electronic camera 10 viewed from the back side. .

  The illustrated electronic camera 10 has an imaging device body 11, and an imaging lens body 21 (see FIG. 3) is mounted on the front surface (front surface: subject) side of the imaging device body 11. The imaging lens body 21 constitutes a part of a lens unit. Although not shown, the lens unit further includes a shutter mechanism and a CCD (charge coupled device).

  Further, a slide cover portion 12 is attached to the imaging device main body 11, and the slide cover portion 12 is supported by the imaging device main body 11 so as to be slidable in a direction indicated by a solid line arrow in FIG. 12, the imaging lens body 21 is protected during non-shooting. That is, the slide cover unit 12 is slidable between a first position that covers the imaging lens body 21 and a second position that exposes the imaging lens body 21.

  The slide cover part 12 includes a front part (lens cover part) 12a located on the front side, a right side part 12b located on the right side when viewed from the front side, and a back part (display part cover part) located on the back side. 12c, and is slidably disposed on the imaging device body 11 such that the imaging device body 11 is sandwiched between the front surface portion 12a and the back surface portion 12c. In the illustrated example, the strobe light emitting portion 13 is formed from the front surface portion 12a to the right side surface portion 12b, that is, over two surfaces (on the end side in the direction in which the slide cover portion 12 opens, and at least the front surface of the slide cover portion 12 and A strobe light emitting portion is formed on the side surface continuous with the front surface), and light is emitted from the strobe light emitting portion 13 during flash photography. In the above-described example, the imaging device 16 is configured by the imaging device body 11, the imaging lens body 21, and the slide cover unit 12.

  As shown in FIG. 2, a display unit (for example, a liquid crystal display) 14 is disposed on the back surface of the imaging apparatus main body 11, and an operation unit 15 is disposed. The operation unit 15 includes, for example, a release button, A mode dial and various function keys are provided. When the slide cover portion 12 is positioned at the first position described above, a part of the liquid crystal display 14 is covered by the back surface portion 12c (the back surface portion 12c covers the entire liquid crystal display 14). However, it is sufficient to cover at least a part of the liquid crystal display 14).

  Referring to FIGS. 3 and 4, when photographing with electronic camera 10, slide cover portion 12 is slid from the first position to the second position. Thereby, as shown in FIG. 3, the imaging lens body 21 is exposed, the main power supply is turned on, and the liquid crystal display 14 is brightened. At this time, as shown in FIG. 4, the back surface portion 12 c of the slide cover portion 12 slides, and the entire liquid crystal display 14 is exposed. Further, the strobe light emitting unit 13 is moved further outward than the mounting position of the imaging lens body 21 by the slide of the slide cover 12, so that the imaging lens body 21 and the strobe light emitting unit 13 can be used for strobe shooting. The distance is increased, and the red-eye phenomenon can be prevented.

  As shown in FIG. 3, the shutter button 22 is disposed on one end portion side of the upper surface of the imaging apparatus main body 11, and the slide cover portion 12 is in the end portion direction opposite to the one end portion side where the shutter button 22 is disposed. Slide to. As a result, when the electronic camera 10 is held with both hands for shooting, the slide cover unit 12 can be slid with a hand different from the hand that operates the shutter button.

  When performing strobe shooting, the operation unit 15 turns on the strobe shooting mode and sets various shooting modes, an image playback mode, a flash waiting time, and the like. Examples of the various shooting modes include “normal shooting”, “continuous shooting”, “fine shooting”, “still image”, and “moving image”, and the image reproduction mode includes “still image” and “moving image”. And so on. When the image reproduction mode is set, the photographed image is reproduced and displayed on the liquid crystal screen 14 after photographing. These various shooting modes, image reproduction modes, flash waiting times, and the like are called operation modes, and the microprocessor (control means and power-on means: not shown) housed in the imaging apparatus main body 11 is in accordance with the operation mode. It is possible to control the light emission from the strobe light emitting unit 13 such as changing the intensity and color of the light or blinking.

  The shutter mechanism described above has, for example, an autofocus (AF) mechanism, a diaphragm mechanism, a filter mechanism, and the like, and controls exposure at the time of release. An optical image of a subject or the like incident from the imaging lens body 21 is formed on the CCD, and the optical image is converted into an electrical signal. The output signal (electrical signal) from the CCD is sampled at a predetermined sampling frequency by the microprocessor and converted into a digital value (digital image data). The digital image data is divided into a color difference component and a luminance component, for example, JPEG. (Joint Photographic Experts Group) compliant processing such as orthogonal transformation and Huffman encoding / decoding for image compression / decompression is performed. The image data compressed in this way is temporarily stored in the memory.

  That is, in the illustrated electronic camera, an image captured by the CCD is displayed in real time on the liquid crystal display 14 before the release button or shutter button 22 is pressed, and the liquid crystal display 14 electronically confirms the imaging field of view. The electronic viewfinder function is provided, and the image is taken by operating the release button or the like while observing the electronic viewfinder. At this time, if necessary, the strobe light emitting section 13 is caused to emit light and image data obtained by imaging is displayed on the liquid crystal display 14 as an imaging result at any time when a reproduction operation is performed using a function key.

  In this way, digital image data before and during imaging is displayed in real time on the liquid crystal display 14 and functions as an electronic viewfinder. Further, the digital image data after imaging and the recorded image data decompressed and restored are stored. Is displayed. The liquid crystal display 14 displays a mode display such as the operating state of the electronic camera. Note that a battery is used as a power supply unit of the electronic camera, and a Ni-Cd (nickel cadmium) battery, a nickel hydrogen battery, a lithium battery, or the like is used as the battery.

  In the illustrated electronic camera, the strobe light emitting unit 13 is formed over at least one side continuous from the front surface (subject side surface) of the imaging device 16 to the front surface. Light can be emitted from the light emitting unit 13, and the light emission state of the strobe light emitting unit 13 can be easily visually recognized not only from the subject side but also from the photographer side.

  Further, here, the strobe light emitting unit 13 is disposed on the slide cover unit (lens cover) 12 that protects the imaging lens body 21, and the front surface of the slide cover unit 12 and the slide cover unit 12 are opened on the end side in the direction in which the slide cover unit 12 opens. Since the strobe light emitting unit 13 is formed at least on the side surface continuous with the front surface, when the image pickup lens body 21 is exposed by sliding the slide cover 12, the distance between the strobe light emitting unit 13 and the image pickup lens body 21. This increases the red-eye phenomenon that occurs during flash photography.

  Furthermore, the slide cover portion 12 has a front portion and a back portion, and when the imaging lens body 21 is covered by the front portion, at least a part of the liquid crystal display 14 is covered by the back portion. During non-photographing, the imaging lens body 21 is protected by the slide cover 12 and the liquid crystal display 14 is also protected. The main power supply is turned on when the slide cover portion 12 is slid to expose the imaging lens body 21, and the slide cover portion 12 is slid together with this, and the imaging lens body 21 is covered by the slide cover portion 12. In this case, since the power is turned off, the use operation matches the on / off of the main power, and the power is not forgotten.

  In addition, the shutter button 22 is arranged on one end side of the upper surface of the image pickup apparatus main body, and the slide cover unit 12 is slid in the direction opposite to the one end side where the shutter button 22 is arranged. Therefore, when the electronic camera 10 is gripped with both hands for shooting, the slide cover portion 12 can be slid with a hand different from the hand (finger) that operates the shutter button 22, and the operability is improved. Will be.

  5 to 8 are diagrams for explaining an embodiment of the lens driving device and the imaging device. The imaging lens body 21 described above is a single focus lens that can move a plurality of lenses as an example, and is housed in the imaging device main body 11 of the electronic camera 10 and is projected at the time of shooting when not shooting. It is a retractable type.

  5A is a perspective view of the lens body 21 incorporating the lens driving device in a state in which the cam ring 53 that is a cam member and the linear ring 52 that is a lens frame housing member are incorporated, and FIG. FIG. 5C is a perspective view showing the assembled state of the cam ring 53, and FIG. 5C is a perspective view of only the lens frame 50 accommodating and integrating the plurality of lenses 51 as viewed from the rear side. 6 is a perspective view showing the relationship between the cam ring 53 and the cam pin 54 which is a member to be cammed, FIG. 7 is a perspective view showing a drive system of the cam ring 53, and FIG. 8 is provided on the cam ring, linear ring and lens frame. It is a schematic diagram for demonstrating the motion of a cam pin.

  As shown in FIG. 5C, the imaging lens body 21 constituting the lens driving device includes a lens frame 50 that integrally holds a plurality of lenses 51, and a lens frame as shown in FIG. 50, a cam ring 53 that is a cam member provided around the cam ring 53, and a linear ring 52 that is a lens frame housing member provided around the cam ring 53 as shown in FIG. Although the upper side is the subject side and the lower side is not shown, a CCD or the like as an image sensor is disposed.

  Among these, the lens frame 50 is provided with three screw holes 55 as shown in FIG. 5C at equal intervals, and cam pins using parallel pins as camped members are provided in the screw holes 55. 54 is screwed and planted. As shown in FIG. 6, the cam pins 54 are cam grooves 56 and 63 which are cam portions provided on the cam ring 53, and linear grooves which are guide portions provided on the linear ring 52 shown in FIG. 62 is inserted and protrudes to the outside of the linear ring 52 as shown in FIG.

  As shown in FIGS. 5B and 6, the cam ring 53 has a steep cam groove 56 that is the first cam portion and a gently inclined cam groove 63 that is the second cam portion. The driving force from the motor 70 shown in FIG. 7 is transmitted to a rotation transmission groove 57 provided at the bottom of the rotation transmission groove 57 via a driving system including a worm gear 71, spur gears 72, 73, 74, 75, and the like. And can be rotated. Among these, the steep cam groove 56 which is the first cam portion is a lens feeding cam groove for changing the imaging lens body 21 from the non-photographing state to the photographing state, and is a gentle cam which is the second cam portion. The inclined cam groove 63 is an autofocus cam groove.

  As described above, since the cam pins 54 protrude through the cam grooves 56 and 63 to the outside of the linear ring 52, unlike the case where a taper pin is used as in the prior art, there is an impact. Since the cam pin 54 does not come off from the cam grooves 56 and 63, the thickness of the cam ring 53 can be reduced using metal or the like, and the imaging lens body 21 can be made compact accordingly. Further, the gently inclined cam groove 63 as the second cam portion is opened with an introduction portion for inserting the cam pin 54 into the cam groove 63 in the upper portion of the figure, and the opening portion is provided. Further, the length of the cam ring 53 in the optical axis direction can be shortened to reduce the total length of the imaging lens body 21, and the cam upper portion 65 has a spring property, is strong against an impact such as a drop, and the cam pin 54 is easily incorporated. The lens body 21 can be provided.

  On the other hand, as shown in FIG. 5 (A), the linear ring 52 is provided with a linear groove 62 as a guide part for moving the cam pin 54 only in the optical axis direction. 63, the cam pin 54 that is inserted through the linear groove 62 and has an end protruding outside the linear ring 52 can be guided only by the linear groove 62 and can only move straight in the optical axis direction while limiting the movement range. ing. Further, in the linear ring 52, when the cam pin 54 moving in the linear groove 62 reaches the cam groove 63 in the cam ring 53, the cam pin 54 is pressed against the imaging side. 53, the coil portion is held by a pin 58 arranged at a position corresponding to the vicinity of the center of the second cam groove 63, and one end is locked by the pin 60 and the other end can be locked by the pin 61. The leaf spring 59 is provided. In the following description, the case where the leaf spring 59 is used will be described as an example, but it is needless to say that a coil spring may be used.

  Next, the operation of the lens driving device will be described with reference to FIG. 8. FIG. 8A shows the cam ring shown in FIGS. 5B and 6 in the imaging lens body 21 having the lens driving device shown in FIG. FIG. 8B similarly shows clearly the relationship between the movement of the cam pin 54 moved by the cam grooves 56 and 63 in the cam ring 53 and the leaf spring 59. Further, only the pin 58 for holding the linear groove 62 in the linear ring 52 and the coil portion in the leaf spring 59, the pin 60 for locking one end and the other end, and the pin 61 are shown.

  8C, 8D, and 8E show that the imaging lens body 21 can be photographed from the state (C) in which the imaging lens body 21 is housed in the imaging apparatus body 11 of the electronic camera 10 at the time of non-shooting. The movement of the cam ring 53, cam pin 54, and leaf spring 59 in the linear ring 52 centered on the linear groove 62 in each of the state (D) where the lens has reached the position and the state (E) where the imaging lens body 21 has reached the closest photographing position. During this time, the cam ring 53 rotates the motor 70 shown in FIG. 7 through the drive system constituted by the worm gear 71, spur gears 72, 73, 74, 75, etc., as shown in FIG. 6 and 7 is transmitted to the rotation transmission groove 57 and moves in the direction of the arrow 64 to move the cam pin 54.

  First, FIG. 8C shows a state in which the imaging lens body 21 is not housed in the imaging device body 11 of the electronic camera 10, and the cam pin 54 is located at the lowermost end of the linear groove 62, and the leaf spring One end of 59 is attached to the pin 61. In this state, when the slide cover 12 is slid to the photographing state as described above, the rotation of the motor 70 shown in FIG. 7 is transmitted to the rotation transmission groove 57 shown in FIG. 5B and FIG. 53 moves in the direction of the arrow 64 to move the cam pin 54.

  As described above, the cam groove 56 is a cam groove for extending the lens for changing the imaging lens body 21 from the non-photographing state to the photographing state, and the cam pin 54 is positioned at the position shown in FIG. When it reaches the end of the cam groove 63 with a slanted inclination, the imaging lens body 21 becomes a shootable position and is focused at infinity. At this time, the leaf spring 59 whose one end is on the pin 61 comes into contact with the cam pin 54.

  Then, when a distance measuring device (not shown) measures the distance from the camera to the subject, it is given as a position signal in the cam groove 63 of the cam ring 53 to the motor 70 shown in FIG. Is transmitted to the rotation transmission groove 57, the cam ring 53 is further rotated in the direction of the arrow 64, and the cam pin 54 moves upward (subject side) in the figure. At this time, one end of the leaf spring 59 is applied to the cam pin 54 and urges the cam pin 54 in the direction of the cam groove 63. Since the cam groove 63 is gently inclined, the motor 70 shown in FIG. The drive torque is not greatly different from that when the cam pin 54 is moved by the cam groove 56, and is made uniform.

  When the camera and the subject are at the closest distance that can be handled by the camera, the cam pin 54 moves to the position shown in FIG. 8E and stops there. At this time, in the figure of the cam groove 63, nothing is lost above the cam pin 54 due to the presence of the introduction portion of the cam groove 63. However, the cam pin 54 is firmly held by one end of the leaf spring 59, so The body 21 will not rattle. In addition, when one end of the leaf spring 59 is put on the cam pin 54 even at a portion of the cam groove 56 having a steep inclination, a space for installing the spring is required, but this is an autofocus region that requires accuracy. By using only the gently inclined cam groove 63, such a space becomes unnecessary. Furthermore, since a parallel pin is used as the cam pin 54 and protrudes to the outside of the linear ring 52, the cam pin 54 does not come off even when an impact is applied.

  By configuring the lens driving device in this way, the length of the cam member in the optical axis direction can be shortened, so that it is optimal for configuring a small and thin electronic camera, and the electronic camera is accidentally dropped, etc. Thus, it is possible to provide a lens driving device and an imaging device that are strong against the impact caused by the above, have no rattling of the lens frame, and have good assemblability.

  According to the present invention, a small and thin lens driving device and an imaging device can be provided.

It is the perspective view which showed the non-photographing state from the front side (object side) in an example electronic camera provided with the lens drive device and imaging device of this invention. It is the perspective view which showed the non-photographing state from the back side in an example electronic camera provided with the lens drive device and imaging device of this invention. It is the perspective view which looked at the time of imaging | photography in the example electronic camera provided with the lens drive device and imaging device of this invention from the front side (subject side). It is the perspective view which looked at the time of imaging | photography in the example electronic camera provided with the lens drive device and imaging device of this invention from the back side. (A) is a perspective view of a state in which a cam ring and a linear ring are incorporated in an imaging lens body incorporating a lens driving device according to the present invention, (B) is a perspective view showing a cam ring by taking a linear ring, (C). FIG. 4 is a perspective view of only the lens body viewed from the rear side on the camera side. It is the perspective view which showed the relationship between a cam ring and a cam pin. It is the perspective view which showed the drive system of the cam ring. It is a schematic diagram for demonstrating a motion of the cam pin provided in the cam ring, the linear ring, and the lens frame. It is a figure for demonstrating the conventional lens drive device. It is an example of the taper pin and cam groove which are used for the conventional lens drive device.

Explanation of symbols

50 Lens frame 51 Lens 52 Linear ring 53 Cam ring 54 Cam pin 55 Screw hole 56, 63 Cam groove 57 Rotation transmission groove 58 Pin 59 Leaf spring 60 Pin 61 Pin 62 Linear groove 65 Cam upper part

Claims (9)

A lens frame that houses at least one lens, a cam member provided on the outer periphery of the lens frame, a cam member provided on the outer peripheral position of the lens frame, and a continuous member provided on the cam member A first cam portion on the imaging side and a second cam portion on the subject side,
The cam member includes an introduction portion of the cam member to be connected to the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. A lens driving device characterized in that the lens driving device is provided. A lens frame that houses at least one lens, a cammed member provided on the outer periphery of the lens frame, and a lens frame storage member provided substantially concentrically with the lens frame at the outer peripheral position of the lens frame A cam member provided between the lens frame housing member and the lens frame, a continuous first cam portion on the imaging side and a second cam portion on the subject side provided on the cam member, A guide portion for guiding the cam member provided in the lens frame housing member, and a biasing means for biasing the cam member;
The cam member includes an introduction portion of the cam member to be connected to the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. A lens driving device characterized in that the lens driving device is provided. A lens frame that houses at least one lens, a cammed member provided on the outer periphery of the lens frame, and a lens frame storage member provided substantially concentrically with the lens frame at the outer peripheral position of the lens frame A cam member provided between the lens frame housing member and the lens frame, a continuous first cam portion on the imaging side and a second cam portion on the subject side provided on the cam member, A guide portion for guiding the cam member provided in the lens frame housing member, and a biasing means for biasing the cam member;
The cam member includes an introduction portion of the cam member to be continuous with the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. Provided,
The lens frame is movable in a substantially optical axis direction by being driven by the first cam portion or the second cam portion while the cam member is guided by the guide portion.
The lens driving device according to claim 1, wherein the urging unit abuts and urges the cam member within a driving range in which the cam member is driven by the second cam portion.   The lens driving device according to claim 2, wherein the urging unit is disposed outside the lens frame housing member.   5. The lens driving device according to claim 2, wherein the biasing unit is disposed on an outer periphery of the lens frame housing member.   6. The lens driving device according to claim 2, wherein the urging means is a leaf spring.   The lens driving device according to claim 1, wherein a gradient of the first cam portion with respect to the optical axis is steeper than a gradient of the second cam portion.   The lens driving device according to claim 1, wherein the first cam portion is a lens frame extension region, and the second cam portion is an autofocus region. An imaging device comprising a lens, an imaging device, and a lens driving device,
The lens driving device includes a lens frame that houses at least one lens, a cammed member provided on an outer periphery of the lens frame, an outer peripheral position of the lens frame, and substantially concentric with the lens frame. A lens frame storage member, a cam member provided between the lens frame storage member and the lens frame, a first cam portion on the imaging side provided on the cam member, and a first cam portion on the subject side. Two cam portions, a guide portion that guides the cam member provided in the lens frame housing member, and a biasing means that biases the cam member,
The cam member includes an introduction portion of the cam member to be continuous with the second cam portion at an end portion on the subject side, and the cam member can be inserted into the first cam portion and the second cam portion. Provided,
The lens frame is movable in a substantially optical axis direction by being driven by the first cam portion or the second cam portion while the cam member is guided by the guide portion.
The imaging device according to claim 1, wherein the biasing means abuts and biases the cam member within a range in which the cam member is driven by the second cam portion.

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