JP2005242377A - Lens barrel and optical equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lens barrel realizing the shortening of entire length at the maximum withdrawing time. <P>SOLUTION: The lens barrel has a lens holding member driven to be extended and withdrawn in an optical axis direction, a position detection means for detecting that the lens holding member is located at a prescribed position and a control means for setting the maximum withdrawing position of the lens holding member according to moving amount from the prescribed position. In the lens barrel, the moving amount from the prescribed position can be changed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a lens barrel used in an optical apparatus such as a digital still camera, a video camera, and a silver salt camera having a lens movable in the optical axis direction.

  In the lens barrel as described above, the movable lens is often driven in the optical axis direction by engaging the rack with the feed screw of the stepping motor. Conventionally, the rack is rotatable with respect to the movable lens and is integrally provided in the optical axis direction. The maximum retracted position of the movable lens in which the movable lens is retracted at the time of non-photographing is set to a position retracted by a certain amount from this position detection position with reference to the position detected by the position detector.

  However, in the above conventional example, the error of the detection position by the position detector of the movable lens is about plus or minus 0.5 mm due to the detection position error of the detector itself or the mounting error of the detector to the lens barrel. Normally, the movable lens is controlled so that the group does not hit the fixed portion of the lens barrel. However, in consideration of this detection error, the movable lens must be set to stop at a position extended by the detection error from the fixed portion. For this reason, the movable lens is extended from the fixed portion by the maximum detection error width, and there is a problem in that the entire length of the lens barrel when not photographing is increased.

  Therefore, an object of the present invention is to shorten the overall length of the lens barrel in the maximum retracted state.

  In order to achieve the above object, the present invention provides a lens holding member that is extended and driven in the optical axis direction, a position detection unit that detects that the lens holding member is positioned at a predetermined position, and a lens holding member. In a lens barrel having a control means for setting a maximum retracting position by a movement amount from a predetermined position, the movement amount from the predetermined position can be changed.

  Specifically, the amount of movement from a predetermined position is determined based on the position where the lens holding member hits the fixed member.

  According to the present invention, it is possible to set the gap in the optical axis direction between the lens holding member and the fixed member at the time of non-photographing to be minimum, and to shorten the total length of the lens barrel at the maximum retracting time. Can do.

  Examples of the present invention will be described below.

  FIG. 1 shows a lens barrel that is a first embodiment (Embodiment 1) of the present invention, and represents the position of a lens or the like in the optical axis direction. FIG. 2 shows a cross section of the lens barrel of FIG. 1 taken along a plane perpendicular to the optical axis. FIG. 3 shows a state where the movable lens of the lens barrel in FIG. 1 is slid in the optical axis direction.

  In these drawings, reference numeral 1 denotes a fixed lens frame (fixing member), which is attached to an optical device main body (not shown) or formed integrally with the optical device main body.

  2 is a front frame attached to the lens frame 1, 3 is a sleeve bar supported by being sandwiched between the lens frame 1 and the front frame 2, and 4 is supported by being sandwiched between the lens frame 1 and the front frame 2. Rotation restriction bar.

  Reference numeral 5 denotes a movable lens a, 6 a movable lens b, and 8 a movable lens frame (lens holding member) that holds the movable lens a5 and the movable lens b6. The movable lens frame 8 is slidable in the optical axis direction with respect to the sleeve bar 3, and the rotation of the movable lens frame 8 is restricted with respect to the sleeve bar 3 by the rotation restriction bar 4. A diaphragm unit 9 is attached to the movable lens frame 8.

  10 is a stepping motor attached to the lens frame 1, 11 is meshed with a feed screw 10 a of the stepping motor 10, and both ends are inserted into holes 8 a and 8 b formed in the movable lens frame 8. The rack is movably mounted in the optical axis direction.

  12 is a rack spring that biases the rack 11 toward the wall portion where the hole 8a is formed in the movable lens frame 8, and 13 is a position where the movable lens frame 8 is at a predetermined position (the rear end of the driveable range). This is a position detector composed of a photo sensor or the like that detects the occurrence.

  Reference numeral 14 denotes a CCD unit attached to the lens frame 1, and 15 denotes a low-pass infrared cut filter attached to the lens frame 1. Reference numeral 16 denotes a flexible printed circuit board for energizing the aperture unit 9 and has a U-shaped portion 16a. The repulsive force of the U-shaped portion 16a of the flexible printed circuit board 16 is directed toward the sleeve bar 3, and even if the repulsive force changes, the force applied to the rotation restricting bar 4 is hardly changed.

  In the above configuration, when the stepping motor 10 is driven by a control circuit (not shown) and the feed screw 10a rotates, the movable lens frame 8 moves in the optical axis direction by the meshing action of the feed screw 10a and the rack 11. By changing the rotation direction of the stepping motor 10, the moving direction of the movable lens frame 8 can also be changed.

  In addition, the aperture diameter can be changed by driving the aperture unit 9 by a control circuit (not shown).

  When an external force F is applied to the movable lens frame 8 in the pushing direction, the movable lens frame 8 moves in the optical axis direction (pushing direction) as shown in FIG. 3, but the movable lens frame 8 is racked by elastic deformation of the rack spring 12. By shifting in the optical axis direction with respect to 11, the meshing state of the rack 11 with the feed screw 10a is maintained.

  In addition, the movable lens frame 8 that has moved in the push-in direction is further moved by the optical axis direction stopper 8d provided on the movable lens frame 8 against the movable lens frame stopper 1a provided on the lens frame 1. Does not move in the optical axis direction.

  Here, the shiftable amount in the optical axis direction of the rack 11 with respect to the movable lens frame 8 is the movable amount of the movable lens frame 8 relative to the lens frame 1 (not the amount that can be driven by the stepping motor 10, but the lens on the sleeve bar 3. It is set to be larger than the movable amount to the position where it hits the frame 1. For this reason, the movable lens frame 8 that has shifted from the rack 11 regardless of the position of the movable lens frame 8 in the optical axis direction finally comes into contact with the lens frame 1, and the displacement of the movable lens frame 8 causes light to reach the rack 11. It moves in the axial direction, that is, the rack 11 does not come off the feed screw 10a.

  When the external force F disappears, the movable lens frame 8 returns to the original position by the urging force of the rack spring 12, and focus adjustment and the like are possible.

  Further, in this embodiment, the movable range of the movable lens frame 8 can be changed by a control circuit (not shown), and the maximum retraction position for retracting the movable lens frame 8 beyond the photographing position at the time of non-photographing is set as the movable lens frame 8. The gap between the optical axis direction stopper 8d and the movable lens stopper 1a of the lens frame 1 is set to be minimum. For example, during assembly, the movable lens frame 8 is retracted while measuring the movement of the movable lens frame 8 in the optical axis direction with a laser length measuring device, a photonic sensor, etc. The position at which the movable lens frame 8 abuts against the lens frame 1 is defined as a position where the movable lens frame 8 has stopped. The position immediately before the abutting is set as the maximum retraction position of the movable lens frame 8, and the driving amount from the position (predetermined position) where the position detector 13 detects the movable lens frame 8 to the position just before the abutting is a control circuit (not shown). And the maximum retraction control of the movable lens frame 8 is performed.

  Alternatively, the stepping motor 10 is driven in the opposite direction from the position where the movable lens frame 8 stops moving in the retracting direction (optical axis direction), and the position where the movable lens frame 8 starts moving in the optical axis direction (measurement value changes). The position at which the movable lens frame 8 and the lens frame 1 are separated from each other is defined as a position where the movable lens frame 8 and the lens frame 1 are separated. Then, the stepping motor 10 is driven from that position to a position where the movable lens frame 8 is detected by the position detector 13, and the position where the movable lens frame 8 starts to move in the optical axis direction and the position detector 13 are moved to the movable lens frame 8. Is stored in a control circuit (not shown), and maximum retraction control of the movable lens frame 8 is performed. As a result, the overall length of the photographing lens when not photographing can be shortened.

  FIG. 4 shows a lens barrel that is Embodiment 2 of the present invention, and represents the position of the lens or the like in the optical axis direction. In this figure, reference numeral 21 denotes a fixed lens frame (fixing member), which is attached to an optical device main body (not shown) or formed integrally with the optical device main body.

  22 is a front frame attached to the lens frame 21, 23 is a sleeve bar supported by being sandwiched between the lens frame 21 and the front frame 22, and 24 is supported by being sandwiched between the lens frame 21 and the front frame 22. Rotation restriction bar.

  Reference numeral 25 denotes a movable lens a, 26 denotes a movable lens b, and 28 denotes a movable lens frame that holds the movable lens a25 and the movable lens b26. The movable lens frame 28 is slidable in the optical axis direction with respect to the sleeve bar 23, and is held by the rotation restriction bar 24 so that the rotation is restricted with respect to the sleeve bar 23.

  29 is a diaphragm unit attached to the movable lens frame 28, 30 is a stepping motor attached to the lens frame 21, 31 is engaged with a feed screw 30a of the stepping motor 30, and is fitted to a bar 37 attached to the stepping motor 30. A rack 32 that is movable in the optical axis direction is a rack spring that biases the rack 31 toward the flange 28 a of the movable lens frame 28.

  Reference numeral 33 denotes a position detection device comprising a photosensor or the like for detecting that the movable lens frame 28 is located at a predetermined position (the rear end of the drive movable range), 34 a CCD unit attached to the lens frame 21, and 35 a lens frame 21. A low-pass infrared cut filter 36 attached to is a flexible printed circuit board for energizing the aperture unit 29.

  In the above configuration, when the stepping motor 30 is driven by a control circuit (not shown) and the feed screw 30a is rotated, the movable lens frame 28 moves in the optical axis direction by the meshing action of the feed screw 30a and the rack 31. By changing the rotation direction of the stepping motor 30, the moving direction of the movable lens frame 28 also changes.

  In addition, the aperture diameter can be changed by driving the aperture unit 29 by a control circuit (not shown).

  When an external force F in the pushing direction is applied to the movable lens frame 28, the movable lens frame 28 moves in the optical axis direction, but the movable lens frame 28 is displaced in the optical axis direction with respect to the rack 31 by elastic deformation of the rack spring 32. Thus, the meshing state of the rack 31 with the feed screw 30a is maintained.

  In addition, the movable lens frame 28 that has moved in the push-in direction has an optical axis direction stopper 28d that is provided on the movable lens frame 28 abuts on the movable lens frame stopper 21a that is provided on the lens frame 21. Does not move in the optical axis direction.

  Here, the shiftable amount of the rack 31 relative to the movable lens frame 28 in the optical axis direction is the movable amount of the movable lens frame 28 relative to the lens frame 21 (not the amount that can be driven by the stepping motor 30 but the lens on the sleeve bar 23. It is set to be larger than the movable amount to the position where it hits the frame 21). For this reason, the movable lens frame 8 that is displaced relative to the rack 31 at any position in the optical axis direction finally hits the lens frame 21 and the rack 31 does not come off the feed screw 30a. .

  When the external force F disappears, the movable lens frame 28 returns to the original position by the biasing force of the rack spring 32, and focus adjustment and the like are possible.

  Note that the maximum retraction control of the movable lens frame 28 in the present embodiment is performed in the same manner as in the first embodiment.

  Further, the shape of the rack and the biasing means for shifting the rack to the movable lens frame in the present invention are not limited to those described in the above embodiments. For example, the urging means may be integrally formed on the movable lens frame.

  In each of the above embodiments, the case where the present invention is applied to a focus lens has been described. However, the present invention can also be applied to a zoom lens.

1 is a cross-sectional view of a lens barrel that is Embodiment 1 of the present invention. FIG. 3 is a front sectional view of the lens barrel. Explanatory drawing which shows the state by which the movable lens frame was pushed in the optical axis direction in the said lens barrel. Sectional drawing of the lens barrel which is Example 2 of this invention.

Explanation of symbols

1, 21 ... Lens frame 2, 22 ... Front frame 3, 23 ... Sleeve bar 4, 24 ... Rotation restriction bar 5, 25 ... Movable lens a
6, 26 ... movable lens b
8, 28 ... movable lens frame 9, 29 ... aperture unit 10, 30 ... stepping motor 10a, 30a ... feed screw 11, 31 ... rack 12, 32 ... rack spring 13, 33 ... position detector 14, 34 ... CCD unit 15 , 35 ... low-pass infrared cut filter 16, 36 ... flexible printed circuit board

Claims (3)

A lens holding member that is extended and driven in the optical axis direction, a position detection unit that detects that the lens holding member is located at a predetermined position, and a movement amount of the maximum holding position of the lens holding member from the predetermined position In a lens barrel having a control means to set by
A lens barrel characterized in that the amount of movement from the predetermined position can be changed.   The lens barrel according to claim 1, wherein the amount of movement from the predetermined position is determined based on a position where the lens holding member abuts against a fixed member. An optical apparatus comprising the lens barrel according to claim 1.

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