JPH04115207A - Motor fitting structure of lens barrel - Google Patents

Abstract

PURPOSE:To eliminate the twist of a rotary shaft and to reduce the overall size and weight by fitting a motor in the floating state while the motor is restrained from rotating. CONSTITUTION:A pin 16 projecting from a collar part 3b is engaged with the engagement hole 21a of a motor main body 21, which is restrained from rotating and fitted in the floating state. Both ends of the shaft 10 are formed hemispherically and one end surface projecting from the side of the motor main body 21 is pressed by an L-shaped leaf spring 18 fixed to the outer peripheral surface of a lens barrel 3 with a screw 17; and the shaft 10 is energized toward the tip of its screw 10a to prevent thrust-directional play and reduce the load. Then a lens frame 13 moves forth and back along shafts 10 and 11 by the rotation of the shaft 10, and consequently a lens 12 moves forth and back and is used for zooming. Further, the motor main body 21 is not fixed with a fitting screw directly unlike conventional one, so the main body is supported rotatably without twist and no unreasonable load is placed.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a motor mounting structure for a lens barrel used in a camera such as a video camera.

[Important of the invention] This invention provides a rotating shaft of a motor that extends parallel to the optical axis within the lens barrel and supports it rotatably via a bearing, and a screw is provided on this rotating shaft to control the rotation of the rotating shaft. In a lens barrel motor mounting structure in which lenses for zooming, focusing, etc. are moved along the optical axis via the screw, both sides of the rotational axis of the motor are mounted on the respective lenses provided on the lens barrel. While each of the motors is rotatably supported by a bearing, a rotation stopper is provided on the motor body side of the motor that engages with a locking part provided on the lens barrel, thereby preventing the rotating shaft of the motor from twisting. By eliminating this, the load on the screw of the rotating shaft can be reduced, and the lens barrel can be made smaller and lighter.

[Prior Art] For example, a video camera uses a lens barrel having a zoom lens, a focus lens, and the like.

The zoom lens and the like are moved in the optical axis direction along two guide shafts by a stepping motor having a rotating shaft directly connected to a lead screw. The motor mounting structure of this lens barrel will be explained in detail with reference to FIG. 60 is a side plate 61 forming a part of the motor body.
It is fixed by fastening the upper and lower parts with respective mounting screws 55. The rotating shaft 62 of this stepping motor 60 extends to the front bearing fixing portion 50, and a screw 62a is formed on the front side thereof. A movable lens frame 56 that holds a zoom variator lens (not shown) having a variable magnification function is screwed onto this screw 62a. As the rotating shaft 62 rotates, the movable lens frame 56 moves along the optical axis direction.

The rotating shaft 62 is connected to a sliding bearing 53 provided on the front bearing fixing portion 50, a sliding bearing 66 provided at the center of the side plate 61 of the stepping motor 60, and a sliding bearing 66 provided at the center of the other side plate 67 of the stepping motor 60. It is rotatably supported via a total of three sliding bearings 53, 66, and 69 of sliding bearings 69 provided in the.

However, in the above lens barrel motor mounting structure,
Since the stepping motor 60 is fastened and fixed to the bearing fixing part 51 on the rear side of the lens barrel with each mounting screw 55,
If the cores of the three sliding bearings 53, 66, and 69 that rotatably support the rotating shaft 62 of the stepping motor 60 do not come out,
Due to the prying of the rotating shaft 62, the screw 6 of the rotating shaft 62
There was a drawback that a large load was placed on 2a.

As a motor mounting structure that reduces the load caused by the prying of the rotating shaft 62, for example, as in another conventional example shown in FIG. The screw 62a of the rotary shaft 62 is integrally formed in a U-shape with a parallel reinforcing portion 52, and both ends of the screw 62a of the rotating shaft 62 are fixed to the sliding bearing 53 of the front bearing fixing portion 50 and the rear bearing. There is a structure in which the rotating shaft 62 is rotatably supported by a sliding bearing 54 of the portion 51, and one end of the rotating shaft 62 on the magnet rotor 65 side is pressed in the thrust direction by a leaf spring-like side plate 68.

[Problems to be Solved by the Invention] However, in the conventional lens barrel motor mounting structure shown in FIG. The part of the lens barrel corresponding to 52 protrudes outward, making the entire lens barrel large and heavy.

Therefore, this invention solves the problem of prying (twisting) of the rotating shaft of the motor.
It is an object of the present invention to provide a lens barrel motor mounting structure that can prevent such problems and also make the lens barrel smaller and lighter.

[Means for solving the problem] A rotating shaft of a motor is provided in the lens barrel in parallel with the optical axis and supported rotatably via a bearing, and a screw is provided on this rotating shaft to control the rotation of the rotating shaft. In a motor mounting structure for a lens barrel in which the lens is moved along the optical axis via the screw, both sides of the rotation axis of the motor are rotatably supported by respective bearings provided on the lens barrel. On the other hand, a rotation stopper is provided on the motor body side of the motor to engage with a locking part provided on the lens barrel.

[Function] A detent part that engages with a locking part provided on the lens barrel is provided on the motor body side of the motor attached to the lens barrel.
The motor body is mounted on the lens barrel in a floating state and restricted from rotating in the direction of rotation of the rotation shaft. This eliminates the twisting of the rotating shaft and reduces the load on the screw due to the twisting of the rotating shaft. In addition, the above motor is small.

In addition to being lighter, the entire lens barrel is also smaller.

Further weight reduction is achieved.

[Example code] Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

In FIG. 1, 1 is a lens barrel used in a video camera. The lens barrel of this lens barrel 1 includes a cylindrical front lens barrel 2, and a cylindrical rear mirror that is fixed to the front lens barrel 2 through a fixed lens frame 4 in the form of an original plate with each mounting screw 5. It is composed of a cylinder 3. A focusing lens 6 as a front lens is fitted onto the inner peripheral surface of the front flange 2a of the front lens barrel 2. The rear flange 2b of this front lens barrel 2
A compensator lens 7 is fitted into the center of the inner circumferential surface of the fixed lens frame 4, which is fixed between the front flange 3a of the rear lens barrel 3 by the mounting screws 5.

In addition, a first reference parallel to the optical axis C is connected between the front flange 2a of the front lens barrel 2 and the rear flange 3b of the rear lens barrel 3 via sliding bearings 8°9. The frame is rotatable around the axis (rotation axis) 10, and the front side of the front lens barrel 2 has a flange ε((
2a and the rear flange 3b of the rear lens barrel 3, a second reference shaft 11 is fitted parallel to the optical axis C and the first reference axis 10,
There is an intervention.

This first reference shaft 10 is connected to a stepping motor 2 which will be described later.
0 is the rotation axis, and the front side is the Nuclue 10a.
It is formed. The screw 10a of the first reference shaft 10 is screwed onto one end side of a first movable lens frame 13 in the form of an original plate holding a zoom variator lens 12 having a variable power function. Second reference axis 11
The other end of the first movable lens frame 13 is slidably supported through the front side of the lens frame 13 .

Further, on the rear side of the first and second reference axes 10.11, there is a second movable lens frame 15 in the form of an original plate, which holds a master lens 14 for focusing, which has focusing, correction, and imaging functions. Both ends are penetrated and supported slidably. Above 1st. The second reference axis 10.11 serves as a reference when assembling the front lens barrel 2 and the rear lens barrel 3, and also serves as a reference when assembling the front lens barrel 2 and rear lens barrel 3. It serves as a guide for reciprocating the second movable lens frame 13.15 along the optical axis C. Furthermore, the second reference axis 1
1 is the above 1. It serves as an axis for regulating rotation of the second movable lens frame 13°15.

In addition, 1st. The fixed lens frame 4 holding the compensator lens 7 is disposed in the middle of the second reference axis 10.11.
It passes through both ends.

The rotating shaft of the stepping motor 20 is also used as the first reference shaft 10 . An engagement hole (rotation prevention part) 21a is formed in the motor body 21 of this stepping motor 20. The rear flange 3b of the rear lens barrel 3 is inserted into this engagement hole 21a.
By engaging the protruding bottle (locking part) 16,
The motor main body 21 is mounted in a floating state so that rotation in the rotational direction is restricted. Further, both ends of the first reference shaft 10, which is a rotating shaft of the stepping motor 20, are each formed into a hemispherical shape, and the motor main body 2
One end surface protruding from the rear lens barrel 3 is pressed by an L-shaped leaf spring 18 fixed to the outer peripheral surface of the rear lens barrel 3 with a screw 17. As a result, the first reference shaft 10 is urged toward the distal end of the screw 10a, thereby preventing rattling in the thrust direction and reducing the load.

The motor main body 21 is composed of left and right side plates 22 and 23, and a stator yoke 24 having a multi-phase drive coil 25 therein. At the center of the left and right sides 222 and 23, there are slide bearings 26 and 27 that rotatably support the first reference shaft 10, which is a 15-rotation shaft. The engagement hole 21a is formed in the left side plate 22 in a vertically long manner. Also, the first reference shaft 10 between the sliding bearings 26 and 27
A magnet rotor 28 is fixedly attached to the magnet rotor 28.

The first reference shaft 1 of the stepping motor 20 is
0 rotation, the first movable lens frame 13 moves to the first position. Second
It moves forward and backward along the reference axis 1.0.11. As a result, the variator lens 12 held by the first movable lens frame 13 moves forward and backward along the optical axis C, and is used as a power zoom.

The second movable lens frame 15 is moved to the first movable lens frame 15 by a linear motor (not shown) provided inside the flange 3b on the rear side of the inner peripheral surface of the rear lens barrel 3. It moves in the longitudinal direction of the optical axis C along the second reference axis 1.0.11. As a result, the second
A master lens 14 held by a movable lens frame 15 moves back and forth along an optical axis C and is used for autofocus.

The rear flange 3b of the rear lens barrel 3 is a mount that is coupled to the CCD (not shown) side of the video camera, and the opening 3C formed by the inner peripheral surface of the flange 3b is connected to the CCD (not shown) side of the video camera. The COD is arranged in the center.

According to the lens barrel 1 of the above embodiment, the zoom variator lens 12. The first lens holds the master lens 14 for focusing. Since the first reference axis 10 along which the second movable lens frame 13, 15 moves is also used as the rotation axis of the stepping motor 20, the number of parts can be reduced accordingly, and costs can be reduced.

Further, the motor main body 21 of the stepping motor 20 is prevented from rotating by a pin 16 on the rear side flange 3b of the rear lens barrel 3, and is fastened and fixed directly to the rear side flange 3b with a screw or the like as in the conventional case. Therefore, the first reference axis lO, which is the rotation axis of the stepping motor 20, is aligned with the front lens barrel 2.
It is rotatably supported without twisting by the sliding bearing 8 of the rear border portion 3 and the sliding bearing 9 of the rear boundary portion 3, and no unreasonable load is applied. Thereby, the load torque on the screw 10a due to the prying of the bearing during rotation of the first reference shaft 10 of the stepping motor 20 can be significantly reduced, and power saving can be achieved. Furthermore, the stepping motor 20
Seal type 1 in which the bolt is not fastened and fixed to the rear lens barrel 3b with mounting screws, etc.
It can be made lighter. Furthermore, as before,
Sliding bearings 8 and 9 rotatably support the first reference shaft 10
Since the flange portions 2a and 3b of the lens barrels 2 and 3 in which the lens barrels 2 and 3 are embedded do not protrude outward, the entire lens barrel 1 can be further downsized.

Further, the front lens barrel 2 and the rear lens barrel 3 constituting the lens barrel of the lens barrel l have a common first lens barrel. Since the second reference axis 10.11 is provided, component accuracy can be easily achieved and cumulative error elements can be reduced.

Furthermore, when assembling the lens barrel 1, the above-mentioned 1. Since each part such as the second movable lens frame 13.15 can be positioned and assembled based on the second reference axis 10.11, it is easy to understand the reference when the lens barrel is in a separate room. In addition, it can be assembled with high precision,
It is possible to improve assembly workability.

In this way, in order to move the first movable lens frame 13 of the variator lens 12, there is no need to provide a guide shaft, screw, etc. in addition to the first reference axis 10 as in the conventional case. It is possible to simplify the overall structure of the lens barrel 1 by reducing the installation space for the parts to be moved, and it is also possible to further reduce the size and weight of the lens barrel 1.

Incidentally, according to the above embodiment, a radial bearing is used as the sliding bearing of the front lens barrel, but the present invention is not limited to this, and a thrust bearing may be used. Further, the motor is not limited to a stepping motor.

Furthermore, a pin as a locking part is provided on the rear barrel, and a locking hole is provided on the motor body as a locking part. A bottle may be provided on the main body as a rotation stopper, and the shape and combination are not limited to these.

Furthermore, although the lens barrel used in a video camera has been described, it goes without saying that the lens barrel can be applied to a still camera.

[Effects of the Invention] As described above, according to the present invention, both sides of the rotating shaft of the motor are rotatably supported by respective bearings provided on the lens barrel, and the lens barrel is attached to the motor main body side of the motor. Since a rotation prevention part is provided that engages with a locking part provided on the rotation axis, the motor body can be mounted on the lens barrel in a floating state and prevented from rotating in the rotation direction of the rotation axis. The load on the screw of the rotating shaft can be reduced by eliminating the strain caused by the bearing. As a result, the motor attached to the lens barrel can be made smaller and lighter, and the entire lens barrel can be made smaller and lighter.

[Brief explanation of the drawing]

Fig. 1 is a sectional view of a lens barrel showing an embodiment of the present invention, Fig. 2 is an enlarged sectional view of the main parts of the same lens barrel, Fig. 3 is a sectional view of a conventional example, and Fig. 4 is a sectional view of a conventional lens barrel. FIG. 3 is a sectional view of another conventional example. 1... Lens barrel, 2, 3... Lens barrel, 8, 9...
Bearing, 10... Reference axis (rotating axis), 10a... Screw 12.14... Lens, 16... Bin (locking part), 20... Motor, 21... Motor body, 21
a...Engagement hole (rotation prevention part), C...optical axis. j Zugo 1P, Ikuri (711#Ii 7 Figure 3 I V's tdff Ri Shun 6 Ri Tomagcho 6bF Ri Figure 4

Claims (1)

[Claims] (1) A rotating shaft of the motor is installed in the lens barrel in parallel with the optical axis, and is rotatably supported via a bearing, and a screw is provided on this rotating shaft, and the rotation of the rotating shaft causes the motor to rotate through the screw. In a motor mounting structure for a lens barrel that moves a lens along an optical axis, both sides of the rotation axis of the motor are rotatably supported by respective bearings provided on the lens barrel, and A motor mounting structure for a lens barrel, characterized in that a rotation stopper that engages with a locking part provided on the lens barrel is provided on the motor main body side.