JP2004347920A - Lens device and linear drive device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To eliminate the failure that a carriage bites a screw thread due to the malfunction of a stepping motor in the conventional clipping type carriage. <P>SOLUTION: The lens device 100 is equipped with: a lens support member, that is, a main lens barrel 120; the screw thread 122 which is rotatable with respect to the lens support member 120; the stepping motor 124 for rotating the screw thread 122; a lens frame 126 which can be moved by the rotation of the screw thread 122; a movable lens frame 126 which is attached to the lens frame 126; and a movement limiting device which limits the moving range of the movimg lens 114. The movement limiting device includes: a screw rotation stopping member which is fixed to the screw thread 122 and stops the rotation of the screw thread 122; and a rotation stopping and resting member for stopping the rotation of the screw thread 122 by being brought into contact with the screw rotation stopping member. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a lens device having a lens system including a moving lens, such as a photographic lens using a linear driving device. In particular, the present invention relates to a lens device provided with a linear driving device for moving a part or all of a lens system in an optical axis direction using a stepping motor.
[0002]
In addition, the present invention relates to a linear drive device that can be widely applied to a photographic lens, a machine tool, an assembly device, a printing device, a distribution device, a transport device, a measurement device, a display device, and the like.
[0003]
[Prior art]
2. Description of the Related Art Conventionally, in a video camera or a digital still camera, when a sliding type of a focus lens is a pole type, a method of driving a lens moving frame via a carriage by a stepping motor having a screw screw has been widely used. As a carriage for driving such a lens moving frame, a so-called sandwich type carriage and a so-called nut type carriage are known.
[0004]
In a conventional pinch type carriage, a screw screw of a stepping motor is pinched by a U-shaped carriage having plastic threads. The rotation of the stepping motor rotates the screw screw, and the carriage moves along the thread of the screw screw. The carriage sandwiches the screw screw due to the elasticity of the plastic. Thus, the thread between the carriage and the screw thread is absorbed. The pinching pressure at which the carriage pinches the screw is about 10 to 20 g. In this sandwiching type carriage, when the carriage passes beyond the mechanical end, the carriage is deformed and tooth skipping occurs. Therefore, it is possible to prevent the carriage from biting by the screw screw due to such tooth skipping.
[0005]
In a conventional nut-type carriage, the screw is rotated by the rotation of the stepping motor, and the carriage moves along the thread of the screw. Once the carriage has passed the mechanical end, the carriage is tightened to a screw screw. Therefore, the carriage bites into the screw screw, and the carriage becomes inoperable. In such a nut type carriage, the software for driving the stepping motor stops driving of the stepping motor before the carriage passes the mechanical end, thereby preventing the carriage from biting into the screw screw.
[0006]
Further, the conventional lens driving device disclosed in Patent Document 1 has a screw having a screw portion on the outer periphery and rotatably supported by a support member, a stepping motor for driving the screw to rotate, and a screw for the screw. A movable body that engages with the section and moves on the screw by rotation of the screw; and a lens frame that engages with the movable body and moves in the optical axis direction of the lens. The screw located ahead of the position of the moving body when the lens frame comes into contact with the stopper and comes to the mechanical stop position is provided with a small diameter portion smaller in diameter than the screw portion. The lens driving device further includes an urging member that urges the moving body from the idle position on the small-diameter portion of the screw in a direction engaging with the screw portion.
[0007]
[Patent Document 1]
Japanese Utility Model Laid-Open No. 5-55116 (pages 4 to 6, FIG. 1)
[0008]
[Problems to be solved by the invention]
However, it has been difficult to improve the positional accuracy of the carriage in the conventional sandwiching type carriage.
Further, in a conventional nut type carriage, the carriage sometimes bites into the screw screw due to a malfunction of the stepping motor.
Furthermore, in the conventional lens driving device disclosed in Patent Document 1, the screw structure is complicated, and an urging member is required.
[0009]
[Object of the invention]
An object of the present invention is to provide a lens device configured such that a carriage for moving a lens frame does not bite into a screw screw. Another object of the present invention is to provide a linear drive device configured such that a carriage for moving a moving member does not bite into a screw screw.
Another object of the present invention is to provide a lens device that can guarantee the position of a lens frame with high accuracy. Another object of the present invention is to provide a linear drive device that can guarantee the position of the moving member with high accuracy.
Still another object of the present invention is to provide a lens device and a linear drive device that can be easily manufactured with a simple shape.
[0010]
[Means for Solving the Problems]
The present invention is a lens device having a lens system including a moving lens, which has a lens support member for supporting the lens system, a screw portion on an outer peripheral portion, and is rotatable with respect to the lens support member. A configured screw screw, a driving unit for rotating the screw screw, a lens frame configured to be movable in the optical axis direction of the lens system by rotating the screw screw, and attached to the lens frame. And a movement restricting device for restricting a moving range of the moving lens. In the lens device of the present invention, the movement restricting device is fixed to the screw screw and stops the rotation of the screw screw by contacting the screw rotation stop member for stopping the rotation of the screw screw. And a non-rotating stationary member.
[0011]
In the lens device of the present invention, the movement limiting device includes a first movement limiting device for limiting a range in which the moving lens moves toward the subject, and a range in which the moving lens moves in the direction of the imaging position. And a second movement restriction device for restricting the movement. The first movement restricting device includes a first screw rotation stop member fixed to the screw screw and stopping rotation of the screw screw, and a first screw rotation stop member for stopping rotation of the screw screw by contacting the first screw rotation stop member. It can be configured to include a first rotation stop stationary member. The second movement limiting device is fixed to the screw screw and stops rotation of the screw screw by stopping the rotation of the screw screw by contacting the second screw rotation stop member. It can be configured to include a second rotation stop stationary member.
With this configuration, it is possible to effectively prevent the carriage for moving the lens frame from biting into the screw screw. Further, with this configuration, the position of the lens frame can be secured with high accuracy.
[0012]
In the lens device of the present invention, the screw rotation stop member is constituted by a stopper protrusion provided on a stopper fixed to the screw screw, and the rotation stop stationary member is constituted by a lens frame protrusion provided on the lens frame. It is preferable that the rotation of the screw screw can be stopped by the projection coming into contact with the lens frame projection.
[0013]
In the lens device of the present invention, the first screw rotation stop member is constituted by a first stopper protrusion provided on a first stopper fixed to the screw screw, and the first rotation stop stationary member is provided on the lens frame. It is preferable that the first lens frame projection is provided so that the rotation of the screw screw can be stopped by the first stopper projection contacting the first lens frame projection. With this configuration, the range in which the moving lens moves toward the subject can be limited.
[0014]
In the lens device of the present invention, the second screw rotation stop member is constituted by a second stopper projection provided on a second stopper fixed to the screw screw, and the second rotation stop stationary member is provided on the lens frame. It is preferable that the second screw is provided with a second lens frame projection, and the second stopper projection is brought into contact with the second lens frame projection to stop the rotation of the screw screw. With this configuration, the range in which the moving lens moves in the direction of the imaging position can be limited.
With this configuration, it is possible to realize a lens device with a small number of parts, a simple shape of the parts, and easy manufacture and assembly of the parts.
[0015]
Further, the present invention provides a linear drive device, comprising: a screw screw having a screw portion on an outer peripheral portion and configured to be rotatable with respect to a support member; a drive unit for rotating the screw screw; Is configured to include a moving member configured to be movable with respect to the support member by rotating the moving member, and a movement restricting device for restricting a moving range of the moving member. In the linear drive device of the present invention, the movement limiting device is fixed to the screw screw and stops the rotation of the screw screw by contacting the screw rotation stop member for stopping the rotation of the screw screw. And a stationary member for stopping rotation.
[0016]
In the linear drive device of the present invention, the movement restricting device includes a first movement restricting device for restricting a range in which the moving member moves in the first direction, and a second movement restricting device configured to move the moving member in a second direction opposite to the first direction. And a second movement restricting device for restricting the range of movement in the direction of. The first movement restriction device is fixed to the screw screw and stops the rotation of the screw screw by contacting the first screw rotation stop member and the first screw rotation stop member for stopping the rotation of the screw screw. And the first rotation stop stationary member. The second movement restricting device is fixed to the screw screw and stops the rotation of the screw screw by contacting the second screw rotation stop member and the second screw rotation stop member for stopping the rotation of the screw screw. And the second rotation stop stationary member. With this configuration, the position of the moving member can be guaranteed with high accuracy.
[0017]
【The invention's effect】
In the lens device of the present invention, there is no possibility that the carriage for moving the lens frame will bite into the screw screw. Further, in the linear drive device of the present invention, there is no possibility that the carriage for moving the moving member will bite into the screw screw.
Further, in the lens device of the present invention, the position of the lens frame can be guaranteed with high accuracy. Further, in the linear drive device of the present invention, the position of the moving member can be guaranteed with high accuracy.
Furthermore, since the lens device and the linear drive device of the present invention have a small number of components and simple component shapes, component production and assembly are easy.
[0018]
BEST MODE FOR CARRYING OUT THE INVENTION
(1) Configuration of lens device
Hereinafter, embodiments of a lens device and a linear drive device of the present invention will be described with reference to the drawings. The embodiment of the present invention described below shows a structure in which the lens device is a photographic lens used for a camera such as a still camera, a digital camera, a video camera, and a TV camera. The lens device of the present invention can be widely applied to not only cameras but also optical devices such as binoculars, telescopes, microscopes, OHP projectors, liquid crystal projectors, projectors, light projectors, and distance measuring devices.
[0019]
Referring to FIGS. 1 and 2, in an embodiment of the lens device of the present invention, the lens device 100 has a lens system 110. The lens system 110 includes a fixed lens 112 including four lenses 112a to 112d and a moving lens 114 including three lenses 114a to 114c. The lens system 110 has an optical axis 110A. The fixed lens 112 is supported so as not to move with respect to the main lens barrel 120. The moving lens 114 is supported so as to be movable with respect to the main lens barrel 120. The main lens barrel 120 forms a lens supporting member for supporting the lens system 110. In the embodiment shown in FIG. 1, the lens system 110 is configured to include a fixed lens and a moving lens, but in the lens apparatus 100 of the present invention, the lens system 110 is configured to include only a moving lens. You can also.
[0020]
If the lens device 100 is a variable focal length zoom lens or varifocal lens, the moving lens can be configured to move to change the focal length of the lens system 110, or to focus the lens system 110. It can also be configured to move to. When the lens device 100 is a fixed focal length lens having a fixed focal length, the moving lens is configured to move to focus the lens system 110. A screw screw 122 is disposed so as to be rotatable with respect to the main lens barrel 120. The screw screw 122 has a male screw part 122b at a part of the outer peripheral part. The screw 122 is preferably formed of a metal such as carbon steel or stainless steel.
[0021]
A stepping motor 124 constituting a driving unit is provided to rotate the screw 122. The rotation axis of the stepping motor 124 is configured to be integral with the screw screw 122. An electronic circuit (not shown) for driving the stepping motor 124 can be arranged in the lens device 100 or in the camera body. A power supply (not shown) for driving the stepping motor 124 can be provided in the lens device 100 or in the camera body. A switch (not shown) for controlling the operation of the stepping motor 124 can be disposed on the lens device 100 or on the camera body.
[0022]
The lens frame 126 is arranged so as to be movable along the guide pole 128. The moving lens 114 is attached to the lens frame 126. A steady rest pole 130 is provided for movably guiding the lens frame 126. It is preferable that the center axis of the guide pole 128 and the center axis of the steady rest pole 130 are disposed at positions substantially opposite to each other with respect to the optical axis 110A. The lens frame 126 is guided by the guide pole 128 and the steady rest pole 130 and can move along the optical axis 110A. The bias spring 132 is arranged to bias the lens frame 126 toward the subject. The bias spring 132 is preferably formed by a coil spring. In FIG. 1, the direction of the subject is referred to as “outside”, and the direction opposite to the subject, that is, the direction of the imaging position is referred to as “inside”.
[0023]
The carriage 136 is arranged to move along the axis of the screw screw 122 by the rotation of the screw screw 122. The carriage 136 has a female screw portion 136c. The female screw portion 136c of the carriage 136 is configured to mesh with the male screw portion 122b of the screw screw 122.
The lens frame 126 has a first outer receiving portion 126a, a second outer receiving portion 126b, a first inner receiving portion 126c, and a second inner receiving portion 126d. The lens frame 126 can be formed of a plastic such as polycarbonate. The first outer receiving portion 126a and the second outer receiving portion 126b are formed on the subject side (ie, the outer side) with respect to the first inner receiving portion 126c and the second inner receiving portion 126d. The first inner receiving portion 126c and the second inner receiving portion 126d are preferably formed in deformable shapes.
[0024]
The carriage 136 is disposed between the first outer receiving portion 126a and the second outer receiving portion 126b and the first inner receiving portion 126c and the second inner receiving portion 126d. That is, the carriage 136 is located inside the first outside receiving portion 126a and the second outside receiving portion 126b and outside the first inside receiving portion 126c and the second inside receiving portion 126d. The first inner receiving portion 126c and the second inner receiving portion 126d are pressed against the carriage 136 by the spring force of the biasing spring 132. The carriage 136 is positioned with respect to the lens frame 126 so as not to rotate about the central axis of the screw 122. In order to prevent rotation of the carriage 136 with respect to the screw screw 122, a rotation stop groove 136g is provided on the carriage 136, and a rotation stop rib 126f is provided on the lens frame 126. The rotation of the carriage 136 can be prevented by fitting the rotation stop rib 126f into the rotation stop groove 136g.
[0025]
By actuating the stepping motor 124 to rotate the screw screw 122, the carriage 136 moves along the central axis of the screw screw 122, and the lens frame 126 can move along the optical axis 110A of the lens system 110. . As the lens frame 126 moves along the optical axis 110A, the moving lens 114 moves along the optical axis 110A.
The lens device 100 further includes a movement restricting device for restricting a range in which the moving lens 114 moves along the optical axis 110A. The movement limiting device is fixed to the screw screw 122, and a screw rotation stop member for stopping rotation of the screw screw 122, and a rotation stop stationary for stopping rotation of the screw screw by contacting the screw rotation stop member. And a member.
[0026]
In the lens device 100, the movement limiting device includes a first movement limiting device for limiting a range in which the moving lens 114 moves toward the subject, and a range in which the moving lens 114 moves in the direction of the imaging position. And a second movement restriction device for restricting the movement. The first movement restricting device is fixed to the screw screw 122, and stops the rotation of the screw screw 122 by contacting the first screw rotation stopping member for stopping the rotation of the screw screw 122 and the first screw rotation stopping member. And a first rotation stop stationary member for causing the rotation to stop. The second movement restricting device is fixed to the screw screw 122, and stops the rotation of the screw screw 122 by contacting the second screw rotation stop member for stopping the rotation of the screw screw 122 and the second screw rotation stop member. And a second rotation stop stationary member for causing the rotation to stop.
[0027]
Referring to FIG. 3, the first stopper 140 has a first base portion 140a, a second base portion 140b, a connecting portion 140c, a fitting portion 140d, and a receiving portion 140e. The first base portion 140a is provided with a first circular portion 140h for attaching the first stopper 140 to the male screw portion 122b of the screw screw 122. The second base portion 140b is also provided with a second circular portion 140j for attaching the first stopper 140 to the male screw portion 122b of the screw screw 122. The first protrusion 140m is provided on the first base portion 140a. The second protrusion 140n is provided on the second base portion 140b.
[0028]
Referring to FIGS. 1, 2, 4, and 6 to 9, the first screw rotation stop member includes a first protrusion 140 m and a second protrusion 140 n. The first stopper 140 is attached to the male screw portion 122b of the screw screw 122 such that the first protrusion 140m and the second protrusion 140n are arranged inside the first stopper 140. When the first circular portion 140h and the second circular portion 140j of the first stopper 140 are fitted into the male screw portion 122b of the screw screw 122, and the fitted portion 140d is fitted into the receiving portion 140e, the first stopper 140 is fixed to the screw screw 122. It is fixed to the male screw part 122b.
[0029]
The first rotation stop stationary member includes a first lens frame protrusion 126j provided on the lens frame 126 and a second lens frame protrusion 126k. The first lens frame protrusion 126j is formed outside the first outer receiving portion 126a of the lens frame 126. The second lens frame protrusion 126k is formed outside the second outer receiving portion 126b of the lens frame 126. The first outer receiving portion 126a and the second outer receiving portion 126b are preferably formed in deformable shapes. The first stopper 140 is disposed at a position corresponding to a mechanical end outside the lens frame 126. The first stopper 140 is fixed to the screw screw 122 so as to sandwich the screw portion 122b of the screw screw 122.
[0030]
Due to the rotation of the screw 122, the lens frame 126 moves outward, the first protrusion 140m of the first stopper 140 contacts the first lens frame protrusion 126j, and / or the second protrusion of the first stopper 140. The rotation of the screw screw 122 can be stopped by the 140n contacting the second lens frame protrusion 126k. When the rotation of the screw 122 stops, the rotation of the stepping motor 124 stops.
[0031]
In the embodiment of the present invention, it is preferable that the first stopper 140 and the second stopper 144 have the same size and shape. However, the direction in which the first stopper 140 is fixed to the screw screw 122 is opposite to the direction in which the second stopper 144 is fixed to the screw screw 122. That is, the first stopper 140 is fixed to the screw 122 with the two protrusions (the first protrusion 140m and the second protrusion 140n) facing inward. On the other hand, the second stopper 144 is fixed to the screw 122 with the two protrusions facing outward. The first stopper 140 and the second stopper 144 can be formed of a plastic such as polyacetal or polypropylene. In the embodiment described above, the first stopper 140 and the second stopper 144 are each provided with two projections, but the number of projections may be three or more.
[0032]
It is preferable to provide a slope on the back surface of each projection. By providing a slope on the back surface of each projection, the rotation of the screw screw 122 can be locked when the screw screw 122 rotates in one direction, and when the screw screw 122 rotates in the opposite direction. The configuration can be such that the rotation of the screw 122 is not locked.
[0033]
Referring to FIGS. 1, 2, 5 to 9, the second screw rotation stop member includes a third protrusion 144 m and a fourth protrusion 144 n. The third protrusion 144m and the fourth protrusion 144n are arranged outside the second stopper 144. The second rotation stop stationary member includes a third lens frame protrusion 126m provided on the lens frame 126 and a fourth lens frame protrusion 126n. The third lens frame protrusion 126m is formed inside the first inner receiving portion 126c of the lens frame 126. The fourth lens frame protrusion 126n is formed inside the second inner receiving portion 126d of the lens frame 126. The second stopper 144 is arranged at a position corresponding to a mechanical end inside the lens frame 126. The second stopper 144 is fixed to the screw screw 122 so as to sandwich the screw portion 122b of the screw screw 122.
[0034]
Due to the rotation of the screw 122, the lens frame 126 moves inward, the third protrusion 144m of the second stopper 144 contacts the third lens frame protrusion 126m, and / or the fourth protrusion of the second stopper 144. The rotation of the screw screw 122 can be stopped by the contact of the 144n with the fourth lens frame protrusion 126n. When the rotation of the screw 122 stops, the rotation of the stepping motor 124 stops.
In the embodiment described above, although the first stopper 140 and the second stopper 144 are configured to sandwich the screw portion 122b of the screw screw 122, a hole, a D cut, a groove, and the like for attaching the stopper to the screw screw 122 are provided. The first stopper 140 and the second stopper 144 may be fixed to these holes, D-cuts, and grooves.
[0035]
(2) Function of lens device
Next, the operation of the lens apparatus of the present invention in the case where the moving lens is configured to move to change the focal length of the lens system 110 will be described.
Referring to FIGS. 1 and 4, when a switch (not shown) for controlling the operation of the stepping motor 124 is operated, a drive signal is output from the electronic circuit (not shown) to the stepping motor 124. The drive signal causes the stepping motor 124 to operate, for example, to rotate the screw 122 in a counterclockwise direction (counterclockwise, that is, a first direction) when viewed from the stepping motor 124 side. When the screw screw 122 rotates in the first direction, the carriage 136 moves along the central axis of the screw screw 122 toward a position corresponding to the outer mechanical end. When the carriage 136 moves, the lens frame 126 moves toward the subject (outside) along the optical axis 110A of the lens system 110. As the lens frame 126 moves, the moving lens 114 moves toward the subject (outside) along the optical axis 110A, and the focal length of the lens system 110 changes.
[0036]
As described above, the first stopper 140 constituting the movement restricting device is arranged at a position corresponding to the mechanical end outside the lens frame 126. When the screw 122 rotates in the first direction and the lens frame 126 approaches the position corresponding to the outer mechanical end, the first protrusion 140m of the first stopper 140 contacts the first lens frame protrusion 126j, and And / or the rotation of the screw screw 122 is stopped by the second protrusion 140n of the first stopper 140 contacting the second lens frame protrusion 126k. When the rotation of the screw 122 stops, the rotation of the stepping motor 124 stops.
[0037]
Referring to FIGS. 1, 4 and 5, a switch (not shown) for controlling the operation of the stepping motor 124 is operated, and a drive signal is output from the electronic circuit (not shown) to the stepping motor 124. Then, the screw 122 is rotated clockwise as viewed from the stepping motor 124 side (clockwise direction, that is, a second direction opposite to the first direction). When the screw 122 rotates in the second direction, the carriage 136 moves along the central axis of the screw 122 toward a position corresponding to the inner mechanical end. In this state, since a slope is provided on the back surface of each projection, when the screw screw 122 rotates in the second direction, the first outer receiving portion 126a and the second outer receiving portion 126b of the lens frame 126 The first stopper 140 can be deformed inward by contacting the protrusion.
[0038]
When the carriage 136 moves toward the image formation position (inside), the lens frame 126 moves along the optical axis 110A of the lens system 110 toward the image formation position (inside). When the lens frame 126 moves, the moving lens 114 moves along the optical axis 110A toward the image forming position (inside), and the focal length of the lens system 110 changes.
[0039]
As described above, the second stopper 144 constituting the movement restriction device is disposed at a position corresponding to the mechanical end inside the lens frame 126. When the screw frame 122 approaches the position corresponding to the inner mechanical end by rotating the screw screw 122 in the second direction, the third protrusion 144m of the second stopper 144 contacts the third lens frame protrusion 126m, and And / or the rotation of the screw screw 122 is stopped by the fourth protrusion 144n of the second stopper 144 coming into contact with the fourth lens frame protrusion 126n. When the rotation of the screw 122 stops, the rotation of the stepping motor 124 stops. In this state, since a slope is provided on the back surface of each projection, when the screw screw 122 rotates in the first direction, the first inner receiving portion 126c and the second inner receiving portion 126d of the lens frame 126 The second stopper 144 can be deformed outward by contacting the protrusion.
[0040]
Since the lens device of the present invention is configured as described above, there is no possibility that the carriage for moving the lens frame will bite into the screw screw. Further, in the lens device of the present invention, the position of the lens frame can be guaranteed with high accuracy. Further, the lens device of the present invention has a small number of components, has a simple component shape, and is easy to manufacture and assemble.
[0041]
(3) Linear drive
In the embodiment of the present invention described above, the lens device to which the linear driving device is applied has been described. Further, another embodiment of the linear drive device of the present invention will be described below. The embodiment of the linear drive device of the present invention described below shows a structure in which the linear drive device is a machine tool provided with a tool that moves linearly. Note that the following description mainly describes differences between the linear drive device according to the embodiment of the present invention and the linear drive device according to the above-described embodiment of the lens device according to the present invention. Therefore, the description of the embodiment of the lens apparatus of the present invention described above applies mutatis mutandis to places not described below.
Further, the linear drive device of the present invention can be widely applied to not only a lens device and a machine tool but also an assembly device, a printing device, a distribution device, a transport device, a measuring device, a display device, and the like.
[0042]
Referring to FIG. 10, in the embodiment of the linear driving device of the present invention, the linear driving device 200 has a tool, for example, a cutting tool 210. A screw 222 is rotatably disposed with respect to the support member 220. The screw screw 222 has a male screw part 222b at a part of its outer peripheral part.
A stepping motor 224 is provided for rotating the screw 222. The tool holding member 226 is arranged so as to be movable along the guide pole 228. The cutting tool 210 is attached to the tool holding member 226. A steady rest pole 230 is provided for movably guiding the tool holding member 226. The center axis of the guide pole 228 and the center axis of the steady rest pole 230 are preferably arranged in parallel. The tool holding member 226 can be guided and moved by the guide pole 228 and the steady rest pole 230. A bias spring 232 is arranged to urge the tool holding member 226 in a first direction away from the stepping motor 224. In FIG. 1, a direction toward the left is referred to as a “first direction”, and a direction opposite to the first direction is referred to as a “second direction”.
[0043]
The carriage 236 is arranged so as to move along the axis of the screw 222 by the rotation of the screw 222. The female screw portion of the carriage 236 is configured to mesh with the male screw portion 222b of the screw screw 222.
The tool holding member 226 has a first outer receiving portion 226a, a second outer receiving portion 226b, a first inner receiving portion 226c, and a second inner receiving portion 226d. The carriage 236 is disposed between the first outer receiving portion 226a and the second outer receiving portion 226b, and the first inner receiving portion 226c and the second inner receiving portion 226d. That is, the carriage 236 is located inside the first outside receiving portion 226a and the second outside receiving portion 226b and outside the first inside receiving portion 226c and the second inside receiving portion 226d. The first inner receiving portion 226 c and the second inner receiving portion 226 d are pressed against the carriage 236 by the spring force of the biasing spring 232.
[0044]
The carriage 236 is positioned with respect to the tool holding member 226 so as not to rotate about the central axis of the screw 222. In order to prevent rotation of the carriage 236 with respect to the screw 222, a rotation stop groove (not shown) is provided on the carriage 236, and a rotation stop rib (not shown) is provided on the tool holding member 226. The rotation of the carriage 236 can be prevented by fitting the detent rib into the detent groove.
By actuating the stepping motor 224 to rotate the screw screw 222, the carriage 236 moves along the central axis of the screw screw 222, and the tool holding member 226 can move parallel to the central axis of the screw screw 222. . As the tool holding member 226 moves, the cutting tool 210 moves parallel to the central axis of the screw 222.
[0045]
The linear drive device 200 further includes a movement restricting device for restricting a range in which the tool holding member 226 moves. The movement restricting device is fixed to the screw screw 222 and has a screw rotation stop member for stopping rotation of the screw screw 222 and a rotation stop stationary for stopping rotation of the screw screw by contacting the screw rotation stop member. And a member.
In the linear drive device 200, the movement restriction device includes a first movement restriction device for restricting a range in which the tool holding member 226 moves in the first direction, and the tool holding member 226 moves in the second direction. A second movement restriction device for restricting the range. The first movement restricting device is fixed to the screw screw 222, and stops the rotation of the screw screw 222 by contacting the first screw rotation stopping member for stopping the rotation of the screw screw 222 and the first screw rotation stopping member. And a first rotation stop stationary member for causing the rotation to stop. The second movement restricting device is fixed to the screw screw 222, and stops the rotation of the screw screw 222 by contacting the second screw rotation stopping member for stopping the rotation of the screw screw 222 and the second screw rotation member. And a second rotation stop stationary member for causing the rotation to stop.
[0046]
The first stopper 240 is disposed at a position corresponding to a mechanical end of the tool holding member 226 in the first direction. The first stopper 240 is fixed to the screw screw 222 so as to sandwich the screw portion 222b of the screw screw 222. The second stopper 244 is disposed at a position corresponding to a mechanical end of the tool holding member 226 in the second direction. The second stopper 244 is fixed to the screw screw 222 so as to sandwich the screw portion 222b of the screw screw 222.
The configuration and operation of the first movement restriction device and the second movement restriction device of the linear driving device 200 are the same as the configuration and operation of the first movement restriction device and the second movement restriction device of the lens device 100 described above.
[0047]
Since the linear drive device of the present invention is configured as described above, the position of the moving member such as the tool holding member can be guaranteed with high accuracy. Further, the linear drive device of the present invention has a small number of components, has a simple component shape, and is easy to manufacture and assemble.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing an overall structure of a lens device in an embodiment of the lens device of the present invention.
FIG. 2 is a cross-sectional view showing a structure of a carriage portion in the embodiment of the lens device of the present invention.
FIG. 3 is a diagram showing a stopper in the embodiment of the lens device of the present invention. 3A is a left side view of the stopper, FIG. 3B is a front view of the stopper, and FIG. 3C is a right side view of the stopper.
FIG. 4 is an enlarged partial sectional view showing a portion 4A in FIG. 1 in the embodiment of the lens device of the present invention.
FIG. 5 is an enlarged partial sectional view showing a portion 5A of FIG. 1 in the embodiment of the lens device of the present invention.
FIG. 6 is an enlarged partial sectional view showing a portion 6A of FIG. 2 in the embodiment of the lens device of the present invention.
FIG. 7 is a perspective view showing a lens frame, a guide pole, a steady rest pole, a stepping motor, and the like as viewed from an upper front diagonal direction in the embodiment of the lens apparatus of the present invention.
FIG. 8 is a perspective view showing a lens frame viewed from a front upper oblique direction in the embodiment of the lens device of the present invention.
FIG. 9 is a perspective view showing a lens frame viewed from an upper rear oblique direction in the embodiment of the lens device of the present invention.
FIG. 10 is a longitudinal sectional view showing the overall structure of the linear drive device in the embodiment of the linear drive device of the present invention.
[Explanation of symbols]
100 lens device
110 lens system
112 Fixed lens
114 Moving lens
120 Primary lens barrel
122 screw screw
124 stepper motor (drive unit)
126 lens frame
128 guide pole
130 steady rest pole
132 One-sided spring
136 carriage
140 1st stopper
144 second stopper
200 linear drive
210 bytes
220 support member
222 screw screw
224 stepping motor
226 Tool holding member
228 Guide pole
230 steady rest pole
232 One-sided spring
236 carriage

Claims (6)

A lens device having a lens system including a moving lens,
A lens support member for supporting the lens system,
A screw screw having a screw portion on the outer periphery and configured to be rotatable with respect to the lens support member,
A driving unit for rotating the screw screw,
By rotating the screw screw, a lens frame configured to be movable in the optical axis direction of the lens system,
A moving lens attached to the lens frame,
A movement limiting device for limiting a range in which the moving lens moves,
The movement restriction device,
A screw rotation stop member fixed to the screw screw and for stopping rotation of the screw screw,
A rotation stop stationary member for stopping rotation of the screw screw by contacting the screw rotation stop member,
A lens device characterized by the above-mentioned. The movement limiting device includes a first movement limiting device for limiting a range in which the moving lens moves toward the subject, and a second movement limiting device for limiting a range in which the moving lens moves toward the image forming position. Movement restriction device,
The first movement restricting device is fixed to the screw screw and stops the rotation of the screw screw. The first screw rotation stop member, and the rotation of the screw screw by contacting the first screw rotation stop member. A first rotation stop stationary member for stopping the
The second movement restricting device is fixed to the screw screw, and a second screw rotation stop member for stopping rotation of the screw screw, and rotating the screw screw by contacting the second screw rotation stop member. A second rotation stop stationary member for stopping the
The lens device according to claim 1, wherein: The screw rotation stop member is configured by a stopper protrusion provided on a stopper fixed to the screw screw, and the rotation stop stationary member is configured by a lens frame protrusion provided on the lens frame, and the stopper protrusion is provided. The lens device according to claim 1, wherein the lens device is configured to stop rotation of the screw screw by contacting the lens frame protrusion. The first screw rotation stop member includes a first stopper protrusion provided on a first stopper fixed to the screw screw, and the first rotation stop stationary member includes a first lens provided on the lens frame. The first stopper projection is configured to stop the rotation of the screw screw by contacting the first lens frame projection, whereby the moving lens moves in the direction of the subject. You can limit the range of movement toward
The second screw rotation stop member includes a second stopper protrusion provided on a second stopper fixed to the screw screw, and the second rotation stop stationary member includes a second lens provided on the lens frame. The second stopper projection is configured to stop rotation of the screw screw by coming into contact with the second lens frame projection, whereby the movable lens is positioned at an imaging position. Configured to be able to limit the range of movement in the direction,
The lens device according to claim 2, wherein: A screw screw having a screw portion on the outer periphery and configured to be rotatable with respect to the support member,
A driving unit for rotating the screw screw,
A moving member configured to be movable with respect to the support member by the rotation of the screw screw,
A movement limiting device for limiting a range in which the moving member moves,
The movement restriction device,
A screw rotation stop member fixed to the screw screw and for stopping rotation of the screw screw,
A rotation stop stationary member for stopping rotation of the screw screw by contacting the screw rotation stop member,
A linear drive device characterized by the above-mentioned. The movement restricting device includes a first movement restricting device for restricting a range in which the moving member moves in the first direction, and a range in which the moving member moves in a second direction opposite to the first direction. And a second movement restriction device for restricting
The first movement restricting device is fixed to the screw screw, a first screw rotation stop member for stopping rotation of the screw screw, and a rotation of the screw screw by contacting the first screw rotation stop member. A first rotation stop stationary member for stopping the
The second movement restricting device is fixed to the screw screw, a second screw rotation stop member for stopping rotation of the screw screw, and a rotation of the screw screw by contacting the second screw rotation stop member. A second rotation stop stationary member for stopping the
The linear drive device according to claim 5, wherein:

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