JPH06160690A - Lens barrel - Google Patents

Abstract

PURPOSE:To realize the coarse and fine two-step adjustment of manual focusing as for a lens barrel which uses an ultrasonic motor as a driving source and by which the full-time manual focusing can be executed. CONSTITUTION:A first-step differential mechanism obtained by setting a first roller ring 16 provided with a first roller 17, a connecting ring 15 to which the rotation of the rotor 13 of the ultrasonic motor is transmitted and a first manual ring 19 as an input member and a second-step differential mechanism consisting of a second roller ring 23 which is provided with a second roller 24 and to which a focus key 7 is fixed are juxtaposed along an optical axis direction. When a second manual ring 22 integrally rotated with the ring 16 is set as the input member of the second-step differential mechanism and a manual ring 25 is coupled to the ring 19, the ring 23 is rotated at 1/4 speed of the rotor 13 in the case of AF and at 1/2 speed of the ring 25 in the case of the manual focusing.

Description

Detailed Description of the Invention

[0001]

[Industrial field of use] An ultrasonic motor is used as a drive motor for auto focus and the like, and relates to a lens barrel capable of full-time manual drive, more specifically, a lens mirror capable of switching the lens moving speed in a plurality of stages. Regarding the cylinder.

[0002]

2. Description of the Related Art Conventionally, an autofocus lens barrel having a built-in ultrasonic motor has a structure as described in JP-B-2-253214. The structure is shown in FIG. In the figure, 1 is a mount for attaching / detaching the lens barrel to / from the camera body, 27 is a back cover attached to the inner diameter side of the mount, 30 is attached to the mount 1 and supports the lens 5. The fixed barrel 3, which is a structural component connected to the guide barrel 3 and also serves as an external appearance of the present lens barrel, is fixed to the fixed barrel and the motor unit main body 31 with a screw or the like, and has a focus lens on the inner peripheral side. A guide tube slidably held on the outer peripheral portion of the focus lens barrel 4 for holding 5, and has a cam 3a for feeding the focus lens, and is mounted in a radial direction from the outer peripheral surface of the focus lens barrel. Outer peripheral surfaces of several rollers 6 and the cam 3a
Is held slidably with the end face of the. Reference numeral 31 is a motor unit main body, which is fixed to the fixed cylinder 30 and the guide cylinder 3 with screws or the like. 9 to 19 are components of the motor unit.

Reference numeral 12 denotes a ring-shaped stator which is a vibrator, and 13 denotes a rotor which comes into pressure contact with the stator 12, and rotates around the optical axis due to the vibration of the stator. 11
Is a vibration absorbing material that does not transmit the vibration of the stator 12 to the outside, 1
0 is Sarabane, 9 is a pressure adjusting ring, 14 is a rotor 13
It is a vibration absorbing material that absorbs the vibration of. Reference numeral 15 denotes a connecting ring, which supports the rotor 13 and the vibration absorbing material 14, but is in contact with the outer peripheral surfaces of at least three rollers 17 on the opposite end surface. The roller 17 is a roller ring 16 on a plane perpendicular to the optical axis,
It is rotatably supported around the axis passing through the intersection with the optical axis, and is restricted from moving in the rotation axis direction by the washer 18. The roller ring 16 is fitted to the motor unit body 31 on the inner peripheral side. Reference numeral 19 denotes a manual input ring, which is rotatably supported by the motor unit main body 31 about the optical axis and is in contact with the outer peripheral surfaces of the plurality of rollers 17.

Further, a concavo-convex portion 19a is formed on the outer peripheral portion of the manual input ring 19, engages with the concavo-convex portion 32a on the inner peripheral side of the manual ring 32, and rotates integrally. The manual ring 32 engages with the fixed barrel 30 and the motor unit body 31, and is rotatably supported around the optical axis.
Reference numeral 7 denotes a focus key, one end of which is fixed to the roller ring 16 and passes through the opening 31a of the motor unit main body 31 to regulate the rotation direction of the roller 6 around the optical axis. Reference numeral 28 denotes an electric circuit board of the present lens barrel, which also controls a motor and the like.

Next, the operation will be described. Since the operating principle of the motor and the like are known, the description of the operation will be omitted and only the rough operation will be described. First, when the stator 12 is supplied with electric power and vibrates, the rotor 13, the vibration absorbing material 14,
The connecting ring 15 integrally rotates about the optical axis. Then, a force acts to rotate the roller 17 in contact with the connecting ring 15 around the mounting shaft. Since the manual input ring 19 is held by the frictional force with the end surface of the motor unit main body 31, the roller 17 moves by rolling contact on the end surface of the manual input ring 19, and the roller ring 16 axially supporting the roller 17 has an optical axis. Rotate to the center. The rotation amount is 1/2 times the rotation amount of the rotor. The rotation amount of the roller ring 16 is transmitted to the focus lens 5 and the focus lens barrel 4 via the roller 6 by the focus key 7. A cam 3a is provided on the guide tube 3 and a roller 6 is engaged therewith. With the rotation of the focus key 7, the roller 6, the focus lens barrel 4 and the focus lens 5 rotate about the optical axis and the optical axis direction. Move to and focus.

Further, when the manual ring 32 is rotated, since the inner diameter irregularity 32a and the outer peripheral irregularity 19a of the manual input ring 19 are engaged with each other, the manual input ring 19 is rotated about the optical axis, and this rotational force is generated by the roller 17. The force acts to rotate the center of the shaft, and at that time, the connecting ring 15, the rotor 13 and the like are held by the frictional force acting between the rotor 13 and the stator 12, so that they do not rotate. The manual ring 32 rotates by half the amount of rotation and is transmitted to the focus lens 5 via the focus key 7 to perform manual focusing.

[0007]

However, in the above-mentioned conventional example, the output of the ultrasonic motor and the rotational force of the manual focus ring are taken out by the one-stage roller and the differential mechanism by the roller ring. There was such a drawback.

(1) Because of the one-stage differential mechanism, the rotation amounts of the ultrasonic motor and the manual focus ring are both halved and output, and no other reduction ratio can be configured.

(2) If the manual focus ring is inadvertently rotated during autofocusing, it is necessary to newly perform autofocusing, and the time required for autofocusing becomes long.

(3) When finely adjusting the focus during manual focus, the reduction ratio from the manual focus ring to the output is small, and it may be difficult to focus. An object of the present invention is to provide a lens barrel that solves such problems.

[0011]

The structure for achieving the object of the present invention is as set forth in the appended claims. Specifically, at least two stages of differential members including the above-mentioned conventional rollers and roller rings are used. By connecting the above, the speed reduction ratio of the motor output and the output with respect to the rotation amount of the manual focus ring is increased and fine adjustment is possible.

Further, by moving the manual focus ring in the axial direction of the lens, the manual ring can be fixed, the AF operation can be prohibited, and the reduction ratio to the output of the manual focus ring can be changed. It has a mechanism and aims to improve the operability of the lens barrel.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a first embodiment of the lens barrel according to the present invention, and FIGS. FIG. 5 shows an exploded perspective view of FIG.

In the figure, 1 is a mount for attaching and detaching the present lens barrel and the camera body, 2 is a fixed tube that connects the mount 1 and the guide tube 3, and 3 is the fixed tube, the motor unit body and screws. It is a guide tube that is fixedly supported and fits and supports a focus lens barrel 4 that holds the focus lens 5 on the inner diameter side, and that has a focus cam 3a, and the end surface of this focus cam and the focus barrel. It engages with the outer peripheral surface of the roller 6 that is mounted radially. The output from the motor section is output by the rotation of the focus key 7 around the optical axis. However, since the roller 6 is supported by the focus key 7 so as to be movable in the optical axis direction, the rotation of the focus key 7 is prevented. By the focus cam 3a, it is converted into an optical rotation direction movement, and the focus lens 5 and the focus lens barrel 4 move in the optical axis direction while rotating around the optical axis,
It is configured to perform focusing.

Next, the inside of the motor unit will be described. Reference numeral 9 denotes a motor unit main body, which will be described later.
The parts 23 and 33 are supported and fixed to the guide tube 3 and the fixed tube 2 with screws or the like. 9 to 19 are the same as in the conventional example, and the description thereof is omitted.

As shown in FIG. 5, a fixing ring 20 has a plurality of protrusions 20a on the inner peripheral side, engages with corresponding grooves 8a on the focus unit body, and is restricted from rotating. There is. Further, at the outer peripheral end of the fixing ring 20,
The manual input ring 19 (hereinafter referred to as the first manual input ring) has an uneven portion 20c similar to that of the manual input ring 19 and can be engaged with the uneven portion 25a of the inner diameter portion of the manual ring 25.

Reference numeral 21 denotes a connecting key, which is a roller ring 16
It is fixed to (hereinafter referred to as the first roller ring), and three claw portions 21a extend in the optical axis direction. A second manual input ring 22 is in contact with the fixed ring 20 in the optical axis direction and is rotatably supported about the optical axis. The second manual input ring 22 has an uneven portion 22b similar to the fixed ring 20 on the outer peripheral portion, a concave portion 22a on the inner peripheral portion, and the claw portion 21a of the coupling key 21 is formed on the inner peripheral portion of the fixed ring 20. It engages with the recess 22a through the groove 20b, so that the first roller ring 16, the connecting key 21 and the second manual input ring 22 are integrally supported rotatably about the optical axis.

The second manual input ring 22 has a roller 2
4 are in contact with each other on the outer peripheral surface, and the roller 24 is rotated around the axis of the roller 24 axially supported by the second roller ring 23. The second roller ring 23 is radially fitted to the motor unit body 8 and is rotatable around the optical axis. Also,
A focus key 7 is fixed to the second roller ring 23 and is used as a motor output for feeding the focus lens 5. A spacer 33 is fixed to the motor unit body 8 and abuts on the outer peripheral surface of the roller 24.

With the above configuration, the connecting ring 15 and the roller 17, the roller 17 and the first manual input ring 19, the first manual input ring 19 and the fixed ring 20, the fixed ring 20 and the second manual input ring 22, and the second manual. Input ring 22 and second roller 24, second roller 24 and spacer 3
The contact surfaces of 3 and 3 are held with an appropriate frictional force by the pressurization of the flat spring 10.

Reference numeral 25 denotes a manual ring, which is rotatable about the optical axis, is supported by the fixed barrel 2 and the motor unit main body 8 and is movable stepwise in the optical axis direction. It is supported by 6 etc. Reference numeral 27 is a back cover, and 28 is an electric circuit for supplying power to and controlling the motor.

Next, the operation will be described with reference to FIGS. First, FIG. 1 shows a case of driving a motor,
3 rotates, and at the same time, the vibration absorbing material 14 and the connecting ring 15 rotate. The first roller 17 contacting the connecting ring 15 rotates about the mounting shaft, and the first roller ring 16 rotates at a speed half that of the rotor 13 due to the principle of the differential mechanism. The rotational force of the first roller ring 16 becomes the optical axis center rotational force of the second manual input ring 22 by the connecting key 21, and the second roller ring and the second roller ring 23 are brought into contact with each other by the differential mechanism. The focus key 7 fixed to 23 can obtain the output of 1/2 rotation of the first roller ring 16, that is, 1/4 rotation of the rotor 13.

On the other hand, the manual ring 25 is the inner peripheral uneven portion 25a and the first manual input ring 19 shown in FIG.
When the manual ring 25 is rotated to perform the manual focus with the uneven portion 19a engaged with each other,
The first manual ring 25 and the first manual input ring 19 rotate integrally, and the differential mechanism of the first roller 17 and the first roller ring 16 causes the first roller ring 16 to move.
Since the manual ring 25 rotates at 1/2 of the rotation, the focus key 7 rotates at 1/4 of the rotation of the manual ring 25 (hereinafter, this state is referred to as state 1).

Next, as shown in FIG. 2, the manual ring 25 is moved from the state 1 in FIG. 1 by one click in the forward direction of the optical axis (hereinafter, this state is referred to as state 2). The concave and convex portions 25a on the inner peripheral portion of the first mesh with the concave and convex portions 19a and 20c on the outer peripheral portions of the first manual input ring 19 and the fixed ring 20, respectively, and are integrated. When the motor is driven in this state, the same state as in FIG. 1 is obtained and an output of 1/4 rotation is obtained, but the manual focus is integrated with the fixed ring 20 in which the rotation is fixed in the manual ring 25. Therefore, it cannot rotate and only the motor drive is in motion.

Next, FIG. 3 shows a state in which the manual ring is moved forward of the optical axis one more than the state 2 shown in FIG. 2 (hereinafter referred to as state 3). And the outer peripheral irregularities 20c of the fixing ring 20 and the outer peripheral irregularities 22a of the second manual input ring 22 are intermeshed and integrated. Manual focusing is impossible because the rotation of the manual ring 25 is fixed as in the case of the state 2. Since the second manual input ring 22 cannot be rotated by the motor drive, the output is the second roller 24 and the second roller ring 23. Therefore, the motor cannot be driven.

Next, FIG. 4 is one more than the state 3 shown in FIG.
In the state where the manual ring 25 is moved forward of the optical axis (hereinafter referred to as state 4), the inner peripheral unevenness 25a of the manual ring 25 meshes with the outer peripheral unevenness portion 20b of the second manual input ring 22. Therefore, in the motor drive, a 1/4 rotation can be obtained as an output as in the state 1, but the manual ring 25 rotates at a 1/2 rotation of the motor. When the manual ring 25 is rotated, the meshed second manual input ring 22 is simultaneously rotated, and the focus mechanism 7, which is the output, is rotated around the optical axis by the differential mechanism of the roller 24 and the second roller ring 23.
It can be rotated by 1/2 the rotation of the manual ring 25.

Table 1 summarizes the operations in the above states 1 to 4, and the usage method in each state will be described below.

State 1 ... Motor can be driven by auto focus. Since the reduction ratio is larger than in the past, the lens can be driven even if the lens weight is heavier. Further, manual focus after autofocus is possible without switching, the reduction ratio is doubled as compared with the conventional one, and fine adjustment is easier.

State 2 ... Motor can be driven by auto focus. The manual ring is fixed so that it cannot be touched carelessly to move the focus.

State 3 ... Neither auto focus nor manual focus is possible. Since the focus lens does not move, it is effective for "placement pin shooting".

State 4 ... The motor can be driven by auto focus, but the manual ring also rotates, so it is not used much. Rather, in manual focus, the focus lens moves twice as fast as in state 1, so quick manual focusing is possible.

Further, in the present embodiment, the two-stage differential mechanism is used, but it goes without saying that it is also possible to connect three or four stages.

[0032]

[Table 1]

FIG. 6 shows a second embodiment. In this embodiment, the rollers 17 and 24 of the first embodiment shown in FIG.
The difference is that the contact surfaces of the connecting ring 15, the first manual input ring 19, the second manual input ring 22, and the spacer 33 which are adjacent to each other are formed in different diameter portions of the stepped rollers.
When the diameter of the large diameter portion of the stepped roller is R ₁ and the diameter of the small diameter portion is R ₂ , if there is an input from the motor to the large diameter portion R ₁ , the roller ring 16 supporting the stepped roller is The relationship between the rotation amount and the rotation amount of the motor is expressed as follows.

Rolling rotation amount / motor rotation amount = R ₂ /
(R ₁ + R ₂ ) Rolling ring rotation amount / manual ring rotation amount = R ₂ /
(R ₁ + R ₂ ) Therefore, depending on the shape of the stepped roller and the contact state of peripheral parts,
Since various reduction ratios can be obtained, the degree of freedom in design is increased. Further, the rollers 17 and 24 may have different shapes, further increasing the degree of freedom and designing an optimum reduction gear ratio.

[0035]

As described above, according to the present invention,
For example, by connecting at least two stages of differential mechanisms including rollers and roller rings, the speed reduction ratio of the rotation amount of the drive lens driving member such as the focus key to the motor output and the rotation amount of the manual focus ring that is the manual operation member. Can be changed, and the reduction ratio can be made larger than in the past to enable fine adjustment.

Further, various states can be set by gradually moving the manual focus ring in the direction of the optical axis, and the manual ring is not inadvertently touched and the focus is not shifted. It is possible to perform operations such as prohibiting focus and switching to change the ratio of the amount of lens extension with respect to rotation of the manual focus ring. did.

Further, by using the stepped roller as the roller in the differential mechanism, it becomes possible to arbitrarily select and design the output rotation amount of the focus key with respect to the motor output and the input by the manual focus ring.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a first embodiment of a lens barrel according to the present invention, showing a state 1.

FIG. 2 is a cross-sectional view showing a first embodiment of the lens barrel according to the present invention, showing a state 2.

FIG. 3 is a cross-sectional view showing a first embodiment of the lens barrel according to the present invention, showing a state 3.

FIG. 4 is a cross-sectional view showing a first embodiment of the lens barrel according to the present invention, showing a state 4.

FIG. 5 is an exploded perspective view of the lens barrel of the first embodiment.

FIG. 6 is a transverse sectional view showing a second embodiment of the lens barrel according to the present invention.

FIG. 7 is a cross-sectional view of a conventional lens barrel.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Mount 2 ... Fixed tube 3 ... Guide tube 4 ... Focus lens barrel 5 ... Focus lens 6 ... Roll 7 ... Focus key 8 ... Motor unit body 9 ... Pressurization adjustment ring 10 ... Sara spring 11 ... Vibration absorbing material 12 ... Stator 13 … Rotor 14… Vibration absorber 15… Contact ring 16… Roller ring 17… Roller 18… Washer 19… Manual input ring 20… Fixing ring 21… Linking key 22… Manual input ring 23… Roller ring 24… Roller 25… Manual focus ring 26… Click ball 27 ... Back cover 28 ... Electrical circuit board 30 ... Fixed cylinder 31 ... Motor unit body 32 ... Manual focus ring 33 ... Spacer

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification code Office reference number FI Technical display location G03B 13/34 H02N 2/00 C 8525-5H 7316-2K G03B 3/10

Claims (7)

[Claims] 1. A differential mechanism having an output member rotatable about an optical axis is provided in parallel in a plurality of stages along the optical axis direction, and the first stage differential mechanism drives an ultrasonic motor with the output member interposed therebetween. Arranging a motor input member that transmits force and a manual input member that can transmit power from a manual operation member, decelerating the rotation input of the motor input member and the manual input member, and transmitting the rotation input to the output member. , The differential mechanism at the final stage is to have the driving member of the moving lens connected to its output member,
The latter-stage differential mechanism and the former-stage differential mechanism are connected to an output member of the former-stage differential mechanism, can transmit power from the manually operated member, and are an intermediate input member rotatable about an optical axis. Is an input member for the output member of the latter-stage differential mechanism. 2. The method according to claim 1, wherein by moving the manual operation member in the optical axis direction, two or more kinds of movement amounts of the movable lens with respect to a rotation angle of the manual operation member can be switched or the operation can be fixed. A lens barrel having a switching means capable of performing the switching. 3. The switching means according to claim 2, wherein the manual operation member is moved stepwise in the optical axis direction so that the manual operation member, the intermediate input member, and the fixed member that cannot rotate about the optical axis. A lens barrel characterized in that it can be selectively and selectively connected to each other, and that it can be independently or selectively connected to the fixing means. 4. The method according to claim 1, 2 or 3, wherein two or more kinds of movement amounts of the moving lens with respect to the rotation angle of the rotor of the ultrasonic motor are switched by gradually moving the manual operation member in the optical axis direction. Or a lens barrel having a switching means capable of fixing the operation. 5. The lens barrel according to claim 4, wherein the switching means is also used as the switching means of claim 3. 6. The method according to claim 1, 2, 3, 4, or 5,
The differential mechanism is arranged at least at three or more places on a circumference centered on the optical axis, and carries a roller rotatable about a radial axis orthogonal to the optical axis and the roller. A lens barrel comprising: a roller carrier that forms an output member that can rotate around the optical axis together with the roller; and an input member that comes into pressure contact with the plurality of rollers on both sides in the optical axis direction. 7. The roller according to claim 6, wherein the roller is formed in a stepped shape including a small diameter portion and a large diameter portion, and one input member that comes into pressure contact with both sides in the optical axis direction abuts the small diameter portion and the other. The lens barrel characterized in that the input member of (1) comes into contact with the large diameter portion.