JP2003287669A - Lens barrel of camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens barrel of a camera, which can be made small-sized and prevents damage due reflection of stray light, etc., without requiring an increase in man-hour, an increase in material cost, etc. <P>SOLUTION: One of a plurality of lens groups is moved along an optical axis 30 by a driving motor 62 arranged in a barrel body and a lens frame 40 of one of the plurality of lens groups is provided with a cover member 70 which can cover a part of the flank of the driving motor. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens barrel for a camera, and more particularly to a lens barrel for a camera which is suitable for a small-sized and high-pixel digital camera.

[0002]

2. Description of the Related Art In recent years, digital cameras are increasingly constructed so that the lens barrel can be housed in the camera body when not in use due to the demand for compactness. That is, each lens group that constitutes the taking lens is movably supported along the optical axis, and only when taking a picture, the lens is extended to a predetermined position for taking a picture, and when not in use, it can be retracted and stored in the camera body. The number of configured items is increasing.

By the way, in recent years, the lens barrel of a digital camera is required to have high zoom performance and high performance of the optical system itself, and the number of lenses and the number of groups of lenses are increasing. There is. On the other hand, in order to make the lens barrel more compact, a drive device such as a motor is increasingly housed in the lens barrel. For example, Japanese Patent Laid-Open No. 2000-89079,
Japanese Patent Laying-Open No. 2000-275499 discloses such a configuration example.

[0004]

However, in the above-mentioned conventional lens barrel, incident light is reflected on the glossy surface of the motor housed in the lens barrel, and the reflected light is a CCD which is a light receiving element.
There is a concern that the light beam may be incident on the image plane and, as a result, may cause a defect in photographing. This tendency was particularly strong when shooting on the telephoto side.

As measures against this, a structure in which an antireflection member is separately attached to the glossy surface of the motor, a structure in which a black matte coating is applied to the surface of the motor, and the like are considered. That is, most commercially available stepping motors and the like have metallic luster on their surfaces, and such measures were necessary.

However, if such measures are taken, it is not preferable because the number of man-hours for painting or the like increases and the material cost for special specifications of the motor increases.

The present invention has been made in view of the above circumstances, and it is possible to reduce the size of the lens barrel and to reduce the damage of incident light without increasing man-hours and material costs. An object is to provide a lens barrel of a camera that can be prevented.

[0008]

In order to achieve the above object, the present invention provides a lens barrel in which a plurality of lens groups are movably held along an optical axis in a cylindrical body. At least one lens group among the plurality of lens groups is moved along the optical axis by a drive motor disposed in the cylinder, and the drive motor is attached to a lens frame of any one of the plurality of lens groups. A lens barrel for a camera is provided, in which a cover member that can cover a part of the side surface of the camera is extended.

According to the present invention, the lens frame of one lens group is provided with the cover member that can cover a part of the side surface of the drive motor, so that the lens barrel can be downsized. At the same time, it is possible to prevent the damage due to the reflection of the incident light without increasing the man-hour and the material cost.

Further, the member constituting the lens frame is usually black and can effectively prevent incident light, and in combination with this, it is possible to prevent harm due to reflection of incident light.

Further, the cover member extended to the lens frame is often easily mass-produced by injection molding, and the man-hour and material cost can be reduced.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT A preferred embodiment of a lens barrel of a camera according to the present invention will be described in detail below with reference to the accompanying drawings. FIG. 1 is a perspective view showing an external configuration of a digital camera to which a lens barrel of a camera according to the present invention is applied.

As shown in the figure, the digital camera 1 has a camera body formed in a rectangular box shape, and a lens barrel 2, a finder window 3, and a strobe light adjusting sensor 4 are provided on the front surface thereof. , A self-timer lamp 5 and the like are provided. A pop-up strobe 6, a release switch 7 and the like are provided on the upper surface thereof, and a finder eyepiece, a liquid crystal display panel, operation keys and the like (not shown) are provided on the rear surface thereof. The digital camera 1 is a collapsible type, and the lens barrel 2 is extended from the camera body only when it is used, and projects from the front part of the camera body.

2 to 4 are side sectional views of the lens barrel 2 applied to the digital camera 1 described above. 2 shows the lens barrel 2 in the wide position, and FIGS. 3 and 4 show the lens barrel 2 in the tele position and the retracted position, respectively. Shows.

As shown in FIGS. 2 to 4, the lens barrel 2 includes a first zoom lens group 12, a second zoom lens group 14, a focus lens 16, and a first zoom lens barrel 1.
8, the second zoom lens barrel (corresponding to the second lens frame) 20,
The cam cylinder 22, the fixed cylinder 24, the drive cylinder 26, the aperture shutter unit 28, and the like are included.

A gear portion 26a is formed on the outer periphery of the drive cylinder 26, and the driving force of a zoom motor (not shown) is transmitted to the gear portion 26a. The driving force of the motor causes the drive barrel 26 to rotate around the optical axis 30 as the center of rotation while contacting the outer periphery of the fixed barrel 24.

Further, the lens barrel 2 is moved from the retracted position to the tele position by rotating the drive barrel 26 in the "storage rotation range" from the "initial position" to the "intermediate position".
Further, the drive barrel 26 is moved from the tele position to the wide position by rotating in the "variable rotation range" from the "intermediate position" to the "end position".

A straight advance groove 26b for moving the cam barrel 22 along the optical axis 30 is formed on the inner peripheral surface of the drive barrel 26. The rectilinear groove 26b transmits the rotational force of the drive cylinder 26 to the cam cylinder 22 via the cam follower 32.

The fixed barrel 24 includes a second zoom lens barrel 20.
A straight groove 24a for moving the cam barrel 22 along the optical axis 30 and a cam groove 24b for moving the cam barrel 22 along the optical axis 30 are formed.

A cam follower 32 is provided on the outer peripheral surface of the cam barrel 22.
Is provided. This cam follower 32 has a cam groove 24.
It is fitted in the groove b, penetrates the cam groove 24b, and is fitted in the rectilinear groove 26b. Therefore, the cam cylinder 22
Moves in the optical axis 30 direction with respect to the fixed barrel 24 while rotating in association with the rotation of the drive barrel 26. A first cam groove 22a is formed on the inner peripheral surface of the cam barrel 22. The cam groove 24b, the rectilinear groove 26b, and the cam follower 32 are provided at three divided positions around the optical axis 30, respectively.

Inside the first zoom lens barrel 18, the first
The zoom lens group 12 is held. Further, a straight groove 34 is formed on the inner peripheral surface of the first zoom lens barrel 18,
Further, a cam follower 36 that fits in the first cam groove 22a is provided on the outer peripheral surface of the first zoom lens barrel 18.
Therefore, the first zoom lens barrel 18 is moved to the cam barrel 22 by the linear movement guide action (described later) by the second zoom lens barrel 20 as the cam barrel 22 rotates and the feeding action of the first cam groove 22a of the cam barrel 22. On the other hand, it moves back and forth in the direction of the optical axis 30. The cam follower 36 and the first cam groove 22a are provided at three divided positions around the optical axis 30, respectively.

Inside the second zoom lens barrel 20, there is a second
The zoom lens group 14 is held. The second cam groove 22 b of the cam barrel 22 is formed on the outer peripheral surface of the second zoom lens barrel 20.
There is provided a cam follower 38 that fits in the. A tip arm portion 50 is formed at the front end of the second zoom lens barrel 20, and a straight advance guide protrusion 52 is formed on the outer peripheral surface side of the tip of each tip arm portion 50. The straight-line guide projections 52 are fitted into the straight-line grooves 34 of the first zoom lens barrel 18, so that the straight-line guide function described above is produced. The cam follower 38, the second cam groove 22b,
The straight-movement guide protrusion 52 and the straight-movement groove 34 are respectively provided at three divided positions around the optical axis 30.

A rear end arm portion 51 is formed at the rear end of the second zoom lens barrel 20, and each rear end arm portion 51 is formed.
A straight guide projection 53 is formed on the outer peripheral surface side of the rear end. Since these straight-movement guide protrusions 53 are fitted in the straight-movement grooves 24a of the fixed cylinder 24, a straight-movement guide action is generated.

That is, the driving force of the second zoom lens barrel 20 is changed by the rotation of the driving barrel 26 so that the cam barrel 22 and the first
It is transmitted via the zoom lens barrel 18 and moves back and forth with respect to the fixed barrel 24 in the optical axis 30 direction. The straight-movement guide protrusion 53 and the straight-movement groove 24a are provided at three divided positions around the optical axis 30, respectively.

According to the above construction, the first zoom lens barrel 18, the second zoom lens barrel 20, the cam barrel 22, and the fixed barrel 2 are provided.
Of the drive barrel 26 and the drive barrel 26, the fixed barrel 24 has its rear end fixed to the base B and is immovable, and the first zoom lens barrel 18 and the second zoom lens barrel 20 are constrained from moving in the rotational direction. It moves back and forth only in the direction of the axis 30. The drive barrel 26 is constrained from moving in the direction of the optical axis 30 with respect to the fixed barrel 24, and only rotates. The cam barrel 22 is rotated by the drive barrel 26 and moves back and forth in the direction of the optical axis 30.

In each figure, reference numeral 10a indicates the image plane of the lens barrel 2, and the image plane of the CCD (not shown) is arranged at this position.

The focus lens 16 is arranged at the rear stage position of the second zoom lens group 14, and is held by the focus lens frame 40. The focus lens frame 40 is
It is supported by the focus lens drive unit 60. Here, the focus lens frame 40 is movably supported in the fixed barrel 24 along the optical axis.

The lens barrel 2 has a focus lens frame 40.
The focus lens frame 40 is driven by a focus lens drive unit 60 described below. The focus lens frame 40 is driven by moving the focus lens frame 40 along the optical axis 30.

The focus lens drive unit 60 comprises a ball screw unit 64 which is a combination of a drive motor 62, a screw shaft 64a and a nut 64b, and a bracket 66 having a substantially U-shape.

One end of the bracket 66 is fixed to the base B, and the drive motor 62 is fixed to the other end of the bracket 66. Ball screw unit 64 screw shaft 64
Both ends of a are rotatably supported by brackets 66. Also, at the other end of the bracket 66,
The screw shaft 64 a is connected to the shaft of the drive motor 62.
The nut 64b of the ball screw unit 64 is slidably supported so as to prevent the nut 64b from rotating with respect to the screw shaft 64a. Therefore, drive the drive motor 62,
When the screw shaft 64a is rotated, the nut 64b moves back and forth according to the rotation amount of the screw shaft 64a.

The focus lens frame 40 is supported by a connecting member 68 fixed to the nut 64b. Therefore, when the drive motor 62 is operated and the screw shaft 64a is rotated, the focus lens 16 supported by the focus lens frame 40 moves back and forth according to the rotation amount of the screw shaft 64a.

Further, the focus lens frame 40 is provided with a cover member 70 which can cover a part of the side surface of the drive motor 62. The cover member 70 is not limited in shape and material as long as it has a function of preventing incident light from being reflected on the drive motor 62 and preventing the reflected light from entering the CCD which is a light receiving element. .

However, as shown in FIG. 5, a circle which is arranged on the optical axis 30 side of the drive motor 62 and in the vicinity of the drive motor 62 and whose side surface shape follows the outer peripheral shape of the drive motor 62. The arc shape is preferable because the lens barrel can be downsized and the damage due to reflection of incident light can be effectively prevented.

As the material of the cover member 70, various resin materials are preferable in terms of molding accuracy, manufacturing cost, weight, corrosion resistance and the like. Further, if the cover member 70 is black and has a matte surface, there is little concern that light will be reflected by the cover member 70, which is preferable.

The cover member 70 of the focus lens frame 40
A light-blocking blade 74 is fixed on the opposite side of
A light blocking cover 76 is provided on the subject side (left side in FIGS. 2 to 4) of the light blocking blade 74. A photointerrupter 72 having a substantially π shape is fixed to the base B so as to sandwich the light shielding cover 76. A of the above configuration in FIG.
-A line arrow view is shown in FIG.

The photo interrupter 72 is used for detecting the origin position of the focus lens 16 and the like, and is used in combination with the light shielding blade 74. That is, the light is emitted from the side wall on one side of the groove portion 72a of the photo interrupter 72 shown in FIG. 6 and is received by the side wall on the opposite side of the groove portion 72a. The origin position of the focus lens 16 can be detected by blocking this light by the light blocking blade 74.

However, if the incident light entering the lens barrel enters the groove 72a of the photo interrupter 72, it may cause a malfunction. Therefore, the light shielding cover 76 is provided at the position described above.
Is provided to prevent such malfunction.

In the example of the present embodiment, the focus lens 16 has a single element unlike the other lens groups.
Of course, it may be a lens group including two or more lenses.

Although the example of the embodiment of the lens barrel of the camera according to the present invention has been described above, the present invention is not limited to the example of the above embodiment, and various modes can be adopted. For example, in the present embodiment, one lens group that is moved along the optical axis 30 by the drive motor 62 and one lens group in which the cover member 70 extends in the lens frame are the same focus lens. However, the same can be applied to other combinations.

For example, the drive motor 62 drives the optical axis 30.
It is also possible to apply a configuration in which one lens group that is moved along is the focus lens 16 and one lens group in which the cover member 70 is extended in the lens frame is the second zoom lens group 14.

In the above embodiment, the zoom lens has a three-group structure, but the present invention is not limited to this, and the zoom lens is not limited to this.
It may have a configuration of more than one group.

For example, in a zoom lens having a four-group structure, the first and second lens groups are supported by three suspensions, and the third and fourth lens groups are supported by guide rods. You may comprise. In this case, depending on the diameter of the lens group, it is preferable to select whether to support by hanging three or by supporting with a guide rod. That is, two lens groups each having a large diameter are supported by three suspensions, and the remaining lens groups are supported by a guide rod. Thereby, each lens group can be stably operated.

The present invention can be applied not only to the zoom lens camera, but also to a bifocal camera that switches between a tele position, a wide position, and a retracted position.

Further, in the above embodiment, the tele position is set between the retracted position and the wide position, but it is also possible to set the wide position between the retracted position and the tele position. In this case, the boundary between the variable power guide portion and the storage guide portion is the wide position.

In the above embodiment, the straight groove 34
And the straight-movement guide protrusions 52 and the like are provided at three divided positions around the optical axis.
They may be provided at two positions around the optical axis, respectively.

[0046]

As described above, according to the lens barrel of the present invention, the lens frame of one lens group is provided with the cover member that can cover a part of the side surface of the drive motor. Therefore, the lens barrel can be downsized, and the damage due to the reflection of the incident light can be prevented without increasing the number of steps and the material cost.

[Brief description of drawings]

FIG. 1 is a perspective view of a digital camera to which a lens barrel according to the present invention is applied.

FIG. 2 is a side sectional view showing a configuration of a lens barrel (extended state (wide end)).

FIG. 3 is a side sectional view showing a configuration of a lens barrel (extended state (tele end)).

FIG. 4 is a side sectional view showing a configuration of a lens barrel (in a collapsed state).

FIG. 5 is a sectional view showing the first zoom lens barrel cut in a direction intersecting the optical axis.

FIG. 6 is a view of A- of FIG.
A line arrow view

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Digital camera, 2 ... Lens barrel, 12 ... 1st zoom lens group, 14 ... 2nd zoom lens group, 16 ... Focus lens, 18 ... 1st zoom lens barrel, 20 ... 2nd zoom lens barrel, 22 ... Cam barrel, 24 ... Fixed barrel, 26 ... Driving barrel, 30 ... Optical axis, 40 ... Focus lens frame, 62 ...
Drive motor, 70 ... Cover member

Claims (3)

[Claims] 1. A lens barrel having a plurality of lens groups movably held along an optical axis in a cylinder, wherein at least one lens group of the plurality of lens groups is arranged in the cylinder. A cover member that can be moved along the optical axis by the drive motor and that covers a part of the side surface of the drive motor is provided in the lens frame of any one of the plurality of lens groups. The lens barrel of the camera. 2. The at least one lens group that is moved along the optical axis by the drive motor is the same as any lens group in which a cover member is extended to the lens frame. Lens barrel of the listed camera. 3. The lens barrel of a camera according to claim 1, wherein the lens group in which the cover member is extended to the lens frame is a focus lens group.