JP5824658B2 - Optical equipment - Google Patents

Description

  The technology disclosed herein relates to an optical device used for a camera or the like.

  Conventionally, an optical device used for a camera or the like includes a lens frame that holds an optical element in a lens barrel. The focal length can be changed by driving the lens frame with a zoom motor. The lens frame and the zoom motor are engaged by inserting a feed screw provided in the zoom motor into a rack provided in the lens frame (see, for example, Patent Document 1).

JP 2009-139516 A

  However, when the feed screw is inserted into the rack, the rack teeth and the thread of the feed screw do not mesh with each other, and the feed screw sometimes runs on the rack. In this case, since the lens frame cannot be driven by the zoom motor, a reassembly process has to be performed again.

  Therefore, the technique disclosed herein aims to provide an optical apparatus with improved assembly accuracy in order to solve the above-described problems.

  In order to achieve the above object, an optical apparatus according to the technique disclosed herein includes at least one optical element, a holding member, a rack member, and a feed screw. The holding member holds the optical element. The rack member has at least one rack. Furthermore, the rack member is attached to the holding member. The rack member is inserted into the feed screw in a direction substantially parallel to the rack teeth (extension direction). The feed screw meshes with the rack and rotates to drive the holding member. The rack has a smaller tooth width as it goes to the end face in the rack insertion direction.

  According to said structure, the optical apparatus which improved the assembly precision can be provided.

1 is an exploded perspective view of a lens barrel according to a first embodiment. 2 is a perspective view of a second group lens frame according to the first embodiment. FIG. The perspective view of the rack member concerning Embodiment 1. FIG. The top view of the meshing part concerning Embodiment 1. 1 is a perspective view of a zoom motor according to a first embodiment. The figure which shows the engagement relationship between the rack and feed screw concerning Embodiment 1. FIG. The top view of the meshing part of the rack member concerning a comparative example

(Embodiment 1)
In the first embodiment, a lens barrel 100 that is an example of an optical apparatus will be described.

1. Configuration of Lens Barrel 100 FIG. 1 is an exploded perspective view of a lens barrel 100 according to the first embodiment. Here, for convenience of explanation, the subject side and the front side, and the imaging element side are defined as the rear side.
The lens barrel 100 includes a first group lens frame 10, a second group lens frame 20, a rack member 30, a main body frame 40, and a zoom motor 50. The optical axis X of the lens barrel 100 is set by an optical system including a plurality of lenses (an example of optical elements) provided in the lens barrel 100. The light passing through the optical system in the lens barrel 100 is imaged on the image sensor.
The first group lens frame 10 includes at least one lens. The first group lens frame 10 includes a lens arranged closest to the subject among the lenses provided in the lens barrel 100. The first group lens frame 10 is fixed to the end surface of the main body frame 40 on the subject side.
The second group lens frame 20 includes at least one lens 21 (see FIG. 2). The second group lens frame 20 is disposed closer to the image sensor than the first group lens frame 10. The second group lens frame 20 is held by two guide poles (not shown) in the main body frame 40. The second group lens frame 20 includes a rack member 30.
The rack member 30 is supported by the second group lens frame 20. The rack member 30 is engaged with the zoom motor 50. The rack member 30 is driven in the optical axis X direction by the zoom motor 50. Therefore, the driving force of the zoom motor 50 is transmitted to the second group lens frame 20, and the second group lens frame 20 is driven in the optical axis X direction. As a result, the focal length of the lens barrel 100 is changed.
The main body frame 40 has a rectangular shape having openings on the front end face and the rear end face. The first group lens frame 10 is fixed to the front end surface with screws. A sheet metal provided with an image sensor is attached to the rear end face. The main body frame 40 has a plurality of lenses inside. The main body frame 40 includes an aperture mechanism and an image blur correction mechanism inside. As a result, light is imaged on the image sensor.

2.2 Configuration of Group Lens Frame and Rack Member FIG. 2 is a perspective view of the second group lens frame 20 according to the first embodiment. The second group lens frame 20 includes a flat portion 22 that holds at least one lens 21 and a bearing portion 23 that is engaged with a guide pole. The plane portion 22 is a plane that is substantially perpendicular to the optical axis X. The bearing portion 23 is formed substantially parallel to the optical axis X on the outer peripheral side of the flat portion 22. The bearing 23 has a hole that penetrates in the direction of the optical axis X, and a guide pole is inserted into the hole. The bearing portion 23 is formed with a holding portion 24. The holding unit 24 holds the rack member 30 at two places arranged in the optical axis X direction. A spring 25 is provided between the two locations. The spring 25 biases the rack member 30 toward the holding portion 24 in the optical axis X direction. Further, the spring 25 biases the rack member 30 to the feed screw 52 (see FIG. 5) in the direction perpendicular to the optical axis X.

3. Configuration of Rack Member FIG. 3 is a perspective view of the rack member 30 according to the first embodiment. The rack member 30 includes an engaging portion 31, a meshing portion 32, and a stopper 35.
The engaging portion 31 is two columnar protrusions having the optical axis X direction as a central axis. The engaging part 31 protrudes to the front side and the rear side. The engaging portion 31 is engaged with the holding portion 24 by being inserted into two holes formed in the holding portion 24. A spring 25 is provided between the two engaging portions 31 (see FIG. 2). The meshing portion 32 has a planar shape parallel to the optical axis X. A plurality of racks 33 that mesh with a feed screw 52 (see FIG. 5), which will be described later, are formed at at least one location of the meshing portion 32. The rack 33 according to the first embodiment is formed in the meshing portion 32. The rack 33 includes a plurality of teeth 34 protruding from the meshing portion 32. The plurality of teeth 34 of the rack 33 are formed in parallel. The stopper 35 is provided at a position facing the rack 33. The stopper 35 is provided so that the feed screw 52 (see FIG. 5) is positioned between the stopper 35 and the rack 33. Thereby, the stopper 35 can suppress the phase shift between the rack 33 and the feed screw 52.

  FIG. 4 is a top view of the meshing portion 32 according to the first embodiment. The teeth 34 of the rack 33 have a shape in which the tooth width W becomes narrower toward the end surface of the rack 33 in the extending direction. The tooth width W is formed with a width that meshes with a thread of a feed screw 52 (see FIG. 5) described later. The end surface in the extending direction of the teeth 34 of the rack 33 is cut at an angle of approximately 45 degrees with respect to the extending direction of the rack 33 in the plane of the meshing portion 32. Further, the end face in the extending direction of the teeth 34 of the rack 33 is cut at an angle of about 45 degrees with respect to the height direction.

4). Configuration of Zoom Motor FIG. 5 is a perspective view of the zoom motor 50 according to the first embodiment. The zoom motor 50 includes a main body 51, a feed screw 52, and an attachment 53. The main body 51 is a motor that rotationally drives the feed screw 52. The feed screw 52 has a thread that meshes with the rack 33 on an axis extending substantially parallel to the optical axis X. When the thread of the feed screw 52 and the teeth 34 of the rack 33 are engaged, the feed screw 52 and the rack 33 are engaged. The drive shaft of the main body 51 and the rotation shaft of the feed screw 52 coincide. One end of the feed screw 52 is directly connected to the main body 51. One end of the attachment portion 53 is fixed to the main body portion 51, and the other end of the feed screw 52 is held at the other end. The attachment portion 53 is attached to the side surface of the main body frame 40 with screws.

5. FIG. 6 is a diagram illustrating an engagement relationship between the rack 33 and the feed screw 52 according to the first embodiment. The zoom motor 50 is attached to the side surface of the main body frame 40 so that the rotation axis of the feed screw 52 is parallel to the optical axis X (see FIG. 1). An opening through which the feed screw 52 of the zoom motor 50 can enter is formed on the side surface of the main body frame 40. The zoom motor 50 is engaged with the rack member 30 inside the main body frame 40 so that the feed screw 52 meshes with the rack 33. The zoom motor 50 is attached to the main body frame 40 so that the main body 51 is on the image sensor side and the feed screw 52 is on the subject side.
Next, the assembly of the rack member 30 and the zoom motor 50 will be described in detail. The rack member 30 is assembled to the feed screw 52 in a direction substantially parallel to the extending direction of the rack 33. In the first embodiment, the feed screw 52 is inserted into the rack member 30 in the extending direction of the rack 33. The insertion direction of the feed screw 52 is indicated by a direction Y in FIG. At this time, the feed screw 52 is inserted between the meshing portion 32 and the stopper 35.
After the second group lens frame 20 engaged with the rack member 30 is held inside the main body frame 40, the rack motor 30 and the feed screw 52 are engaged by attaching the zoom motor 50 to the side surface of the main body frame 40.
Here, the engagement relationship between the rack member 60 and the feed screw 52 according to the comparative example will be described. FIG. 7 is a top view of the meshing portion 62 of the rack member 60 according to the comparative example. As shown in FIG. 7, in the conventional rack member 60, the tooth width W of the rack 63 is constant with respect to the extending direction of the rack 63. In other words, the tooth width W of the rack 63 is not narrowed toward the end face in the insertion direction Y of the rack member 60. For this reason, when the rack member 60 and the zoom motor 50 are assembled, if the rack 63 and the feed screw 52 are assembled at a position where they do not mesh with each other, an assembly failure occurs in which the teeth 64 of the rack 63 ride on the thread of the feed screw 52. There are things to do.
On the other hand, the rack 33 according to the first embodiment has a tooth width W that becomes narrower toward the end face in the insertion direction Y of the rack member 30. Therefore, the rack 33 follows the thread of the feed screw 52 when the rack member 30 and the feed screw 52 are engaged. That is, the position of meshing between the rack 33 and the feed screw 52 is adjusted by moving the second group lens frame 20 engaged with the rack member 30 in the optical axis X direction. Thereby, the lens barrel 100 can suppress the teeth 34 of the rack 33 from riding on the thread of the feed screw 52 during assembly.
Therefore, the lens barrel 100 can provide an optical apparatus with improved assembly accuracy.
Then, when the main body 51 is driven, the feed screw 52 rotates. By rotating the feed screw 52, the driving force of the main body 51 is transmitted to the rack 33. Thus, the zoom motor 50 drives the second group lens frame 20 in the optical axis X direction via the rack member 30. In this way, the focal length of the lens barrel 100 is changed.
5. Summary The lens barrel 100 (an example of an optical apparatus) according to the first embodiment includes at least one lens 21, a second group lens frame 20 (an example of a holding member), a rack member 30, and a feed screw 52. The second group lens frame 20 holds the lens 21. The rack member 30 has at least one rack 33. Further, the rack member 30 is attached to the second group lens frame 20. The rack member 30 is inserted into the feed screw 52 in a direction Y that is substantially parallel to the tooth trace (extending direction) of the rack 33. The feed screw 52 meshes with the rack 33 and rotates to drive the second group lens frame 20. The rack 33 has a smaller tooth width W as it goes to the end face in the insertion direction Y of the rack 33.
According to this configuration, the lens barrel 100 can provide an optical apparatus with improved assembly accuracy.

(Other embodiments)
Embodiment 1 was illustrated as embodiment concerning the technique disclosed here. However, the technique disclosed here is not limited to this. Therefore, another embodiment of the technology disclosed herein will be described below. Note that the technology disclosed herein is not limited to these, and can be applied to embodiments that are appropriately modified.
In the first embodiment, the rack 33 is formed at one place of the rack member 30, but is not limited thereto. The rack 33 may be formed in at least one place of the rack member 30. The rack 33 may be formed, for example, on a stopper 35 provided at a position facing the meshing portion 32.
In the first embodiment, the rack 33 includes a plurality of protruding teeth 34, but is not limited thereto. There may be at least one tooth 34 of the rack 33. However, a plurality of teeth 34 of the rack 33 are preferably formed. Further, the end surface in the extending direction of the teeth 34 of the rack 33 in the first embodiment is cut at an angle of approximately 45 degrees with respect to the extending direction of the rack 33 in the plane of the meshing portion 32, but is not limited thereto. Absent. However, the end surface in the extending direction of the teeth 34 of the rack 33 is preferably cut at 60 degrees or less with respect to the extending direction of the rack 33 in the plane of the meshing portion 32. Moreover, although the end surface of the extending | stretching direction in the tooth | gear 34 of the rack 33 is cut at the angle of about 45 degree | times with respect to the height direction, it is not restricted to this. However, the end surface in the extending direction of the teeth 34 of the rack 33 is preferably cut at 60 degrees or less with respect to the height direction.
In the first embodiment, the rack member 30 is provided with the stopper 35, but the stopper 35 may not be formed. However, it is preferable that the stopper 35 is formed because the phase shift between the rack 33 and the feed screw 52 can be suppressed by providing the stopper 35.
In the first embodiment, the rack member 30 and the feed screw 52 are assembled by inserting the feed screw 52 in the extending direction of the rack 33 with respect to the rack member 30, but is not limited thereto. The rack member 30 may be inserted into the feed screw 52 in a direction substantially parallel to the tooth trace (extending direction) of the rack 33.

  The technology disclosed herein can be applied to a digital still camera, a digital video camera, a camera-equipped terminal, and the like.

10 1st group lens frame 20 2nd group lens frame (an example of a holding member)
21 Lens (an example of an optical element)
22 Plane part 23 Bearing part 24 Holding part 25 Spring
DESCRIPTION OF SYMBOLS 30 Rack member 31 Engagement part 32 Engagement part 33 Rack 34 Tooth 35 Stopper 40 Main body frame 50 Zoom motor 51 Main part 52 Feed screw 53 Mounting part 60 Rack member 62 Engagement part 63 Rack 64 Teeth 100 Lens barrel (an example of optical apparatus) )

Claims (3)

At least one optical element, a holding member, a rack member, and a feed screw;
The holding member holds the optical element;
The rack member has at least one rack, and the rack member is attached to the holding member;
The rack member is inserted into the feed screw in a direction substantially parallel to the tooth traces of the rack;
The feed screw engages with the rack and rotates to drive the holding member,
An optical apparatus characterized in that the rack has a constant tooth width from the end surface opposite to the rack insertion direction to the end surface in the rack insertion direction, and the tooth width is narrowed from the middle . A spring is provided between the rack member and the holding member,
The optical apparatus according to claim 1, wherein the spring biases the rack of the rack member in a direction in which the rack is pressed against the feed screw.   The optical device according to claim 1, wherein the rack member includes a stopper at a position facing the rack.