KR100195312B1 - Lens barrel - Google Patents

Abstract

The present invention relates to a lens barrel used for a camera such as a video camera. The present invention relates to a lens barrel of a camera, in which at least two reference axes are disposed in parallel to an optical axis in each of the reference shafts. Thus, a plurality of lenses such as zooming and focusing are arranged to be movable, and at least one of the reference axes can be used together with the axis of the driving source so that the lens can be moved by driving the driving source, thereby reducing the number of parts and simplifying the structure. In addition, it can be easily assembled with high accuracy on the basis of the reference axis.

Description

Lens barrel

1 is a schematic cross-sectional view of a lens barrel showing an embodiment of the present invention.

2 is a schematic sectional view of a lens barrel of a conventional example.

* Explanation of symbols for main parts of the drawings

1: lens barrel 2, 3: barrel

10, 11: reference axis 12, 14: lens

20: motor (drive source) C: optical axis

The present invention relates to a lens barrel used for a camera such as a video camera.

In the lens barrel of the camera, at least two reference axes are disposed in the barrel in parallel to the optical axis, and a plurality of lenses such as a zoom and a focus can be moved along each reference axis, and at least one of The reference axis is combined with the axis of the drive source to move the lens by driving the drive source, so that the number of parts can be reduced to a simple structure, and the assembly can be easily and accurately assembled on the basis of the reference axis.

For example, a lens barrel having a zoom, a focus lens, etc. is used for a video camera. To explain this concretely with reference to FIG. 2, reference numeral 50 denotes a lens barrel, and the barrel of the lens barrel 50 has a cylindrical front flat barrel 51 and a cylindrical body connected to the full barrel 51. FIG. It is comprised by the rear part barrel 52. A focusing lens group (hereinafter referred to as a focusing lens) 53 as a front lens is fitted in the center of the inner circumferential surface of the collar part 51a on the front side of the all barrel 51, and the collar part on the rear side of the all barrel 51 is placed. A compensator lens group (hereinafter referred to as a compensator lens) 54 is fitted in the center of the inner peripheral surface of 51b.

In addition, a pair of guide shafts 55 and 55 are interposed between the front side of the all barrel 51, the collar portion 51a and the rear collar portion 51b so as to be parallel to the optical axis C. A pair of guide shafts 56 and 56 so as to be parallel to the optical axis C also between the collar part 51b on the rear side of the all barrel 51 and the collar part 52b on the rear side of the rear barrel 52. Is interposed.

The pair of guide shafts 55 and 55 of the all barrel 51 support a group of variator lenses for zoom (hereinafter referred to as variator lenses) 57 having a shifting function. It is supported so as to slide through the circular plate-shaped first moving lens frame 58, and at the same time, a pair of guide shafts 56 and 56 of the rear barrel 52 are in focus. Slide through the circular plate-shaped second movable lens frame 60 supporting the master lens group for focus (hereinafter referred to as master lens) 59 having a combination, correction and imaging function. It is supported.

The first moving lens frame 58 is provided with an engaging pin 61 serving as a cam follower. The engagement pin 61 is fitted into the cam groove hole 62a formed so as to be inclined to the cam cylinder 62 which slides on the inner circumferential surface of the all barrel 51 so as to be able to slide. The cam cylinder 62 is connected to the cylindrical zoom ring 63 rotating around the rear side of the outer circumferential surface of the all-cylinder 51 through pins 64 and the like. The inner circumferential surface of the barrel 51 is rotated clockwise and counterclockwise. Then, by rotating the zoom ring 63, the cam barrel 62 rotates around the inner circumferential surface of the entire barrel 51, so that the first moving lens frame 58 is connected to the pair of guide shafts 55, 55. To go back and forth. For this reason, the variator lens 57 supported by the said 1st moving lens frame 58 is moved to the front-back direction along the optical axis C. As shown in FIG.

In addition, the second moving lens frame 60 is screwed into a screw 66 integrally formed on the front end side of the rotation shaft of the motor 65 passing through the collar portion 52b on the rear side of the rear barrel barrel 52. . Then, by driving the motor 65 to rotate the screw 66, the second moving lens frame 60 moves the optical axis C forward and backward along the pair of guide shafts 56 and 56. FIG. . As a result, the master lens 59 supported by the second moving lens frame 60 moves in the front-rear direction along the optical axis C. FIG. Reference numeral 67 in the second diagram denotes a speed reducer of the motor 65.

However, in the conventional lens barrel 50, the guide shafts 55, 56 for guiding the movement of the variator lens 57 and the master lens 59 are separately provided, and at the same time, the guide shaft 56 In addition, since the screw 66 for moving the master lens 59 is disposed, the number of parts increases, resulting in a cost increase and a complicated and large structure.

Further, the barrel of the lens barrel 50 is composed of a full barrel 51 and a rear barrel 52, and guide shafts 55 and 56 for guiding the variator lens 57 and the master lens 59. Since it is separately provided, it is difficult to position each lens 53, 54, 57, 59 with respect to the optical axis C without making it eccentric or inclining, For example, in the case of assembling the rear barrel 52 after assembling the entire barrel 51, a standard deviation is required, so that the cumulative error of the whole becomes large and the assembly workability is complicated.

Thus, the present invention is to provide a lens barrel that can solve the above problems.

At least two reference axes are disposed in the barrel in parallel with the optical axis, and the plurality of lenses are disposed to be movable along each reference axis, and the at least one reference axis is combined with the axis of the drive source to drive the lens by driving the drive source. You can move it.

Since at least one of the reference axes to which the plurality of lenses such as zoom and focus are moved is used as the axis of the drive source, the number of parts can be reduced by that amount and the cost can be reduced. As a result, the cumulative error element of the whole part is reduced at the time of assembly, and the lens barrel is easily assembled with high accuracy on the basis of the reference axis, thereby improving the assembly workability. In addition, there is no need to provide a drive mechanism made of a guide shaft, a screw, and the like separately from the reference shaft in order to move the lens, so that the overall structure can be simplified and the compact and lightweight can be achieved.

Next, an embodiment of the present invention will be described in detail with the drawings.

In Fig. 1, reference numeral 1 denotes a lens barrel used for a video camera. The barrel of this lens barrel (1) is a cylindrical barrel (2), and a cylindrical rear barrel (3) fixed to the barrel (2) by screws (5) through a plate-shaped fixed lens frame (4). ) A focusing lens 6 as a prot lens is fitted to the inner circumferential surface of the collar part 2a on the front side of the all barrel 2. The center of the inner circumferential surface of the fixed lens frame 4 fixed by the respective screws 5 between the collar part 2b on the rear side of the all barrel 2 and the collar part 3a on the front side of the rear barrel 3. The compensator lens 7 is fitted into the.

Moreover, between the collar part 3b of the rear side of the back barrel 3 of the collar part 2a of the front side of the said full barrel 2, it is made parallel to an optical axis C through each bearing 8 and 9; While the reference axis 10 of 1 spans so that it can rotate, the optical axis C and between the collar part 2a of the front side of this all barrel 2, and the collar part 3b of the rear side of the rear part barrel 3 are carried out. The second reference axis 11 is sandwiched and interposed in parallel with the first reference axis 10.

The first reference shaft 10 is a rotating shaft of the stepping motor 20 (sphere), which will be described later, and the front side thereof is formed on the screw 10a. Then, the first reference shaft 10 is screwed to one end of the annular first movable lens frame 13 which supports the zoom variator lens 12 having the variable displacement function on the screw 10a. At the same time, the front side of the second reference axis 11 is supported so as to slide through the other end side of the first moving lens frame 13. In addition, a rear plate-shaped second movable lens frame 15 supporting the focus master lens 14 having a focus, correction and imaging function is provided on the rear side of the first and second reference axes 10 and 11. It is supported so that it can slide through both ends of the side. The first and second reference shafts 10 and 11 serve as a reference for assembling the entire barrel 2 and the rear barrel 3, and the first and second moving lens frames 13, A guide for reciprocating 15 along the optical axis C is provided. The second reference shaft 11 is a shaft for rotationally regulating the first and second moving lens frames 13 and 15.

In addition, the intermediate portions of the first and second reference axes 10 and 11 penetrate both ends of the fixed lens frame 4 supporting the compensator lens 7.

The rotating shaft of the stepping motor 20 serves as the first reference shaft 10. A locking hole 21a is formed in the motor main body 21 of the stepping motor 20. A locking hole 21a is formed in the motor main body 21 of the stepping motor 20. By engaging the pin 16 protruding to the rear collar portion 3b of the rear barrel tube 3 to the locking hole 21a, the stepping motor 20 is regulated in the rotational direction of rotation and the entire state is floating. It is installed. In addition, both ends of the first reference shaft 10, which is the rotating shaft of the stepping motor 20, are formed in a hemispherical shape, and one end surface protruding from the motor body 21 side is the rear portion. It is pressed by the L-shaped leaf spring 18 fixed to the outer peripheral surface of the barrel 3 by the screw 17. As shown in FIG. For this reason, the 1st reference shaft 10 is applied with the pressing force to the front end side of the screw 10a, and prevents the flow of a thrust direction, and reduces a load.

The first moving lens frame 13 is moved forward and backward along the first and second reference axes 10 and 11 by the rotation of the first reference axis 10 of the stepping motor 20. Go to. For this reason, the variator lens 12 supported by the said 1st moving lens frame 13 moves to the front-back direction along the optical axis C, and is used as a power zoom.

In addition, the second moving lens frame 15 is formed by a linear motor (not shown) disposed inside the collar part 3b on the rear side of the inner circumferential surface of the rear barrel tube 3. , In the forward and backward directions of the optical axis C in accordance with (11). For this reason, the master lens 14 supported by the second moving lens frame 15 moves forward and backward along the optical axis C to be used as an auto focus.

And the collar part 3b of the rear side of the said back barrel 3 is a mount part couple | bonded with the CCD (not shown) side of a video camera, and of the opening part 3c which consists of the inner peripheral surface of this collar part 3b. The CCD is arranged at the center.

According to the lens barrel 1 of the above embodiment, the first and second moving lens frames 13 and 15 for supporting the zooming variator lens 12 and the focusing master lens 14 are moved. Since the first reference shaft 10 is also used as the rotating shaft of the stepping motor 20, the number of parts can be reduced by that amount, and the cost reduction can be achieved. The motor main body 21 of the stepping motor 20 is rotationally stopped by the pin 16 on the collar portion 3b on the rear side of the rear barrel 3 and directly screwed to the collar portion 3b on the rear side. Since the fastening is not fixed, the load torque applied to the first reference shaft 10, which is the rotation shaft of the stepping motor 20, can be greatly reduced.

In addition, since the front barrel 2 and the rear barrel 3 constituting the barrel of the lens barrel 1 have a common first and second reference axes 10, 11, it is easy to produce parts precision. The cumulative error factor can be reduced.

In the case of assembling the lens barrel 1, the first and second moving lens frames 13, 15, and the like may be used based on the first and second reference axes 10 and 11. Since each part can be mounted by positioning, the standard at the time of assembling the lens barrel 1 is easy to understand and can be assembled with high precision. Therefore, it is not necessary to change the reference as in the prior art can improve the assembly workability.

Further, in order to move the first moving lens frame 13 of the variator lens 12, the guide shaft, the screw, etc. do not need to be disposed separately from the first reference shaft 10 as in the related art. The structure of the entire lens barrel 1 can be simplified by reducing the installation space of the components for moving the lens frame, and further miniaturization and weight can be achieved.

In addition, according to the embodiment, a stepping motor is used as a driving source for moving the first moving lens frame supporting the variator lens, but the driving source is not limited to the stepping motor.

In addition, a screw is disposed in a part of the second reference axis for moving the second moving lens frame supporting the master lens to the linear motor, similarly to the first reference axis, and the second reference axis is stepped in the above embodiment. The second moving lens frame may be moved in the front-rear direction along the optical axis by being configured as a rotating shaft of the stepping motor separately provided from the motor, similarly to the first moving lens frame.

In addition, although the lens barrel used for the video camera has been described, it is obvious that the lens barrel can be applied to a still camera.

As described above, according to the lens barrel of the present invention, at least two reference axes are disposed in the barrel in parallel with the optical axis, and a plurality of lenses for zooming, focusing, etc. can be moved along each reference axis, and at least one Since the reference axis is combined with the axis of the drive source so that the lens can be moved by the drive of the drive source, the number of parts can be greatly reduced. Thereby, the lens barrel can be manufactured at low cost.

In addition, since the lens barrel can be assembled on the basis of the reference axis at the time of assembly, the cumulative mounting error of the whole parts can be reduced, and the lens barrel can be easily assembled with high precision, thereby improving the assembly workability.

In addition, it is not necessary to provide a drive mechanism made of a guide shaft, a screw, etc. separately from the reference axis in order to move the lens, thereby simplifying the overall structure of the lens barrel and at the same time miniaturization and weight reduction. have.

Claims (1)

At least two reference axes are disposed in the barrel parallel to the optical axis, and a plurality of lenses are disposed along each reference axis, and at least one of the reference axes is combined with the axis of the drive source to drive the drive source. The lens barrel, characterized in that for moving the lens by.