JP4909220B2 - Lens barrel, lens barrel manufacturing method, and optical apparatus - Google Patents

Description

  The present invention relates to a lens barrel, a method for manufacturing a lens barrel, and an optical apparatus.

  As a lens barrel attached to a still camera, a video camera, or the like, a lens including a movable frame that holds a predetermined lens and is movable in the optical axis direction, and a cylindrical barrel body in which the movable frame is disposed A lens barrel is known (see, for example, Patent Document 1). In the lens barrel described in Patent Document 1, a photo interrupter (Photo Interrupter, hereinafter referred to as “PI”) for detecting the reference position of the moving frame is directly fixed to the lens barrel body. It is configured to move by a predetermined distance with respect to PI.

JP 2007-193374 A

  However, generally, variations in the outer shape of a sensor such as PI are large. Therefore, when the movement distance of the moving frame is determined based on the sensor fixed to the lens barrel body at the position determined by design, the moving range in which the moving frame actually moves varies. Therefore, the length of the lens barrel in the optical axis direction needs to be increased in order to allow the movement frame to move by a predetermined movement distance even if the movement range of the movement frame varies. As a result, it is difficult to downsize the lens barrel in the optical axis direction.

  Accordingly, an object of the present invention is to provide a lens barrel that can be reduced in size in the optical axis direction, a method for manufacturing a lens barrel that can be reduced in size in the optical axis direction, and the lens. An object of the present invention is to provide an optical apparatus including a lens barrel or a lens barrel manufactured by the method for manufacturing the lens barrel.

  In order to solve the above problems, a lens barrel of the present invention detects a reference position of a lens holding body that holds an optical lens, a barrel body in which the lens holding body is disposed, and a lens holding body. And a sensor holder that holds the sensor and is attached to the barrel main body. The barrel main body is formed with an adjustment portion for adjusting the mounting position of the sensor holder in the optical axis direction of the optical lens. It is characterized by being.

  In the lens barrel of the present invention, an adjustment portion for adjusting the mounting position of the sensor holder in the optical axis direction is formed in the barrel main body. Therefore, even when the outer shape of the sensor varies, the influence of variations in the outer shape of the sensor can be suppressed by adjusting the mounting position of the sensor holding body with the adjustment unit. Therefore, even if the movement distance of the lens holder is determined with reference to the sensor, the variation in the actual movement range of the lens holder can be suppressed. As a result, in the present invention, even if the length of the lens barrel in the optical axis direction is shortened, the lens holder can be moved by a predetermined moving distance, and the lens barrel can be downsized in the optical axis direction. It becomes possible.

  Moreover, in this invention, the attachment position of a sensor holding body is adjusted with the adjustment part of a lens-barrel main body. That is, the mounting position of the sensor holding body formed larger than the sensor is adjusted. Therefore, the adjustment work becomes easier as compared with the case where the sensor is directly adjusted by the adjustment unit.

  In the present invention, the sensor holding body is formed with a first abutting surface that abuts the holding portion and a holding projection that protrudes from the first abutting surface to hold the sensor, and the adjustment portion includes a first abutting surface. A second contact surface that contacts the contact surface and a protrusion insertion hole into which the holding protrusion is inserted are formed, and a gap is formed between the holding protrusion and the protrusion insertion hole in the optical axis direction. Is preferred. If comprised in this way, the attachment position of a sensor holding body can be adjusted, sliding a sensor holding body in an optical axis direction in the state which contact | abutted the 1st contact surface and the 2nd contact surface. . Therefore, it is possible to adjust the mounting position of the sensor holder with an arbitrary adjustment amount. In addition, the attachment position of the sensor holder can be easily adjusted.

  In the present invention, the sensor holder is preferably formed with a sensor insertion hole into which the sensor is inserted, and the sensor is preferably fixed to the sensor insertion hole. If comprised in this way, even if it is a case where the external shape of a sensor varies, the rattling between a sensor and a sensor holding body can be prevented. In this case, the sensor is press-fitted and fixed in the sensor insertion hole, and the sensor insertion hole is deformed when the sensor is press-fitted, and a pressing protrusion for pressing the sensor in a predetermined direction after the press-fitting is formed. It is preferable that With this configuration, it is possible to prevent rattling between the sensor and the sensor holding body with a simple configuration in which the sensor is inserted into the sensor insertion hole.

  In order to solve the above-described problems, the present invention provides a lens holder that includes a lens holder that holds an optical lens, and a lens barrel body in which the lens holder is disposed. An adjustment step for adjusting the mounting position of the sensor holder for holding the sensor for detecting the reference position of the optical lens in the optical axis direction of the optical lens in the optical axis direction, and after the adjustment step, the sensor holder is attached to the barrel main body. And a fixing step of fixing.

  In the manufacturing method of the lens barrel of the present invention, the attachment position of the sensor holder that holds the sensor to the barrel main body in the optical axis direction is adjusted in the adjustment step. For this reason, even if the outer shape of the sensor varies, the effect of variations in the outer shape of the sensor can be suppressed by adjusting the mounting position of the sensor holding member in the adjustment process. Even if the movement distance is determined, variation in the actual movement range of the lens holder can be suppressed. As a result, when the manufacturing method of the present invention is used, the lens barrel can be downsized in the optical axis direction. Further, in the present invention, the adjustment position adjusts the mounting position of the sensor holding body that is formed larger than the sensor, so that the adjustment work becomes easier compared to the case where the sensor is directly adjusted by the adjustment unit. .

  In the present invention, it is preferable that the adjustment step includes a moving step of moving the lens holding body to a position where the lens apparatus is in focus with an optical device to which the lens barrel is attached. If comprised in this way, the attachment position of a sensor holding body can be adjusted based on the position of the lens holding body moved to the focus position in the moving process. Therefore, it is possible to appropriately focus on the optical device to which the lens barrel is attached.

  In the present invention, the adjustment step preferably includes an arrangement step of moving the lens holding body by a predetermined reference distance after the moving step and arranging the sensor holding body in accordance with the position of the lens holding body after the movement. If comprised in this way, it will become possible to focus more reliably with the optical apparatus to which a lens barrel is attached.

  In the present invention, the adjustment step includes a temporary positioning step of temporarily positioning the sensor holding body at a design mounting position, and after the temporary positioning step, the lens holding body is moved by a predetermined reference distance to attach the lens barrel. It is preferable to include a focus confirmation step for confirming whether or not the optical device is in focus. With this configuration, when it is confirmed that the focus is achieved in the focus confirmation process, the sensor holding body can be fixed to the lens barrel body as it is. Therefore, when a sensor having a relatively small variation in outer shape is used, the manufacturing process of the lens barrel can be simplified.

  In the present invention, in the adjustment step, it is preferable to adjust the mounting position of the sensor holder while irradiating the lens holder with laser light and confirming the position of the lens holder in the optical axis direction. If comprised in this way, it will become possible to adjust the attachment position of the sensor holding body according to the position of the confirmed lens holding body, confirming the position of a lens holding body, using a comparatively simple adjustment system.

  The lens barrel of the present invention or the lens barrel manufactured by the manufacturing method of the lens barrel of the present invention can be used for an optical apparatus. In the optical apparatus configured as described above, the lens barrel can be downsized in the optical axis direction.

  As described above, the lens barrel of the present invention can be downsized in the optical axis direction. In addition, when the method for manufacturing a lens barrel of the present invention is used, the lens barrel can be downsized in the optical axis direction. Furthermore, in an optical apparatus including the lens barrel of the present invention or the lens barrel manufactured by the method of manufacturing the lens barrel of the present invention, the lens barrel can be downsized in the optical axis direction.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Schematic configuration of optical equipment)
FIG. 1 is a diagram for explaining a schematic configuration of an optical system of a camera 1 according to an embodiment of the present invention.

  The optical apparatus 1 of this embodiment is a digital camera having an image sensor 2, for example. Therefore, hereinafter, the optical device 1 is referred to as “camera 1”. The camera 1 includes a lens barrel 3 and a main body 4 as shown in FIG.

  The lens barrel 3 includes a first lens group 5, a second lens group 6, and a third lens 7 as optical lenses constituting the optical system of the camera 1. The first lens group 5, the second lens group 6 and the third lens 7 are disposed inside the lens barrel 3. Specifically, the first lens group 5, the second lens group 6, and the third lens 7 are disposed along the optical axis L in this order from the front side to the rear side of the lens barrel 3. In this embodiment, the first lens group 5 is a focusing lens that moves in the lens barrel 3 in the optical axis L direction, and the second lens group 6 is a zooming lens that moves in the lens barrel 3 in the optical axis L direction. is there. The third lens 7 is a fixed lens fixed inside the lens barrel 3. The detailed configuration of the lens barrel 3 will be described later.

  The main body 4 includes an image sensor 2 disposed inside. Further, the main body unit 4 includes a control unit (not shown) that performs various controls of the camera 1 therein. The image sensor 2 is, for example, a CCD (Charge Coupled Device). The image sensor 2 may be a C-MOS (Complementary Metal Oxide Semiconductor), or a photosensitive film may be disposed on the main body 4 instead of the image sensor 2.

(Schematic configuration of lens barrel)
FIG. 2 is a perspective view of the lens barrel 3 shown in FIG. FIG. 3 is a plan view of the lens barrel 3 shown in FIG. 4 is a cross-sectional view showing a part of the EE cross section of FIG. FIG. 5 is an exploded perspective view of the first sensor 12 and the sensor holder 13 shown in FIG. FIG. 6 is a view for explaining the sensor insertion hole 13a shown in FIG.

  FIG. 2 shows a state in which the sensor holder 13 holding the first sensor 12 is disassembled from the lens barrel main body 11. In the following description, as shown in FIG. 2, the optical axis L direction of the lens barrel 3 is the Z direction, the direction orthogonal to the Z direction, and the vertical direction of FIG. 2 is the Y direction, the Z direction, and the Y direction. An orthogonal direction is defined as an X direction. In the following description, the Z1 direction is the front, the Z2 direction is the rear (back), the Y1 direction is the top, the Y2 direction is the bottom, the X1 direction is the left, and the X2 direction is the right. This plane is the ZX plane.

  In addition to the first lens group 5, the second lens group 6, and the third lens 7 described above, the lens barrel 3 serves as a lens holding body that holds the first lens group 5, as shown in FIGS. A first lens holding body 10, a second lens holding body (not shown) that holds the second lens group 6, and a lens barrel body 11 in which the first lens holding body 10 and the second lens holding body are disposed. It has.

  The lens barrel 3 includes a first sensor 12 as a sensor for detecting the reference position of the first lens holding body 10 and a second sensor (not shown) for detecting the reference position of the second lens holding body. ) And a sensor holder (sensor holder) 13 attached to the barrel main body 11 as well as the first sensor 12. The 1st sensor 12 and the 2nd sensor of this form are PI (photo interrupter) provided with a light-emitting part and a light-receiving part.

  The first lens holder 10 is formed in a flat and generally cylindrical shape as a whole, and holds the first lens group 5 at the radial center as shown in FIG. The first lens holder 10 is movable in the direction of the optical axis L inside the barrel main body 11. That is, the first lens holder 10 is connected to a moving mechanism (not shown) that moves the first lens holder 10 in the direction of the optical axis L. This moving mechanism is, for example, a stepping motor, and a first screw is formed by a feed screw formed on the output shaft of the stepping motor and a female screw (not shown) formed on the first lens holder 10 and screwed into the feed screw. The holding body 10 moves in the direction of the optical axis L.

  On the upper end side of the first lens holder 10, a detected portion 10 a that protrudes outward in the radial direction is formed. As shown in FIG. 4, the detected portion 10 a is formed in a substantially rectangular thin plate shape whose longitudinal direction is the optical axis L direction. In this embodiment, when the first lens holding body 10 moves toward the front side and the detected part 10a blocks between the light emitting part and the light receiving part of the first sensor 12, the first sensor 12 is switched from on to off. The first sensor 12 is detected by the first sensor 12. Note that the position where the on / off of the first sensor 12 is just switched becomes the reference position of the first lens holder 10, and the movement distance of the first lens holder 10 (that is, the movement of the first lens group 5) based on this reference position. Distance) is determined.

  The second lens holder is formed in a substantially cylindrical shape as a whole, and holds the second lens group 6 at the center in the radial direction. Similar to the first lens holder 10, the second lens holder is connected to a stepping motor and can move in the direction of the optical axis L inside the barrel body 11. The second lens holder also has a detected portion that protrudes radially outward, and when the detected portion blocks between the light emitting portion and the light receiving portion of the second sensor, the second sensor Thus, the second lens holder is detected. It should be noted that the position at which the second sensor is just turned on and off is the reference position of the second lens holder, and the movement distance of the second lens holder (that is, the movement distance of the second lens group 6) is based on this reference position. Determined.

  The lens barrel body 11 is formed in a substantially cylindrical shape as a whole. As shown in FIG. 2, an adjustment portion 11a for adjusting the mounting position of the sensor holding body 13 in the direction of the optical axis L is formed on the front end side and the upper end side of the barrel body 11. A second abutting surface 11b that abuts on a first abutting surface 13d described later formed on the sensor holding body 13 and a holding projection 13b described later formed on the sensor holding body 13 are inserted into the adjusting portion 11a. The protrusion insertion hole 11c is formed.

  The second contact surface 11b is formed in a planar shape parallel to the ZX plane. The second contact surface 11b is formed in a substantially rectangular shape with the longitudinal direction as the longitudinal direction. Also, wall surfaces 11d, 11e, and 11f that rise slightly upward are formed at the left and right ends and the rear end of the second contact surface 11b, respectively. The protrusion insertion hole 11c is formed at a substantially central position of the second contact surface 11b. The protrusion insertion hole 11c is formed in a substantially rectangular shape so as to penetrate from the upper end side to the inner peripheral side of the lens barrel body 11 and the longitudinal direction is the front-rear direction.

  The sensor holding body 13 is formed in a substantially rectangular plate shape having the longitudinal direction as a longitudinal direction as a whole, and is fixed to the barrel main body 11 with an adhesive. A sensor insertion hole 13 a into which the first sensor 12 is inserted is formed at a substantially central position of the sensor holder 13. Further, a holding projection 13b for holding the first sensor 12 is formed on the lower surface of the sensor holding body 13 so as to protrude downward, and the sensor holding body 13 holds the sensor in the optical axis L direction on the upper surface. An adjustment projection 13c used for adjusting the attachment position of the body 13 is formed. Furthermore, the lower surface of the sensor holder 13 is a first contact surface 13 d that contacts the second contact surface 11 b formed on the lens barrel body 11.

  The sensor insertion hole 13a is a recess formed in a substantially rectangular shape. As shown in FIG. 6, a through hole 13e through which the terminal of the first sensor 12 is inserted is formed in the bottom surface of the sensor insertion hole 13a. The holding protrusion 13b is formed in a rectangular shape along the periphery of the sensor insertion hole 13a. The adjustment protrusions 13 c are formed in a rectangular parallelepiped shape with the left-right direction as the longitudinal direction, and are formed at both ends of the sensor holding body 13 in the front-rear direction.

  A pressing protrusion 13f that contacts the first sensor 12 and presses the first sensor 12 in a predetermined direction is formed from the inner peripheral surface of the sensor insertion hole 13a to the inner peripheral surface of the holding protrusion 13b. Specifically, the pressing protrusion 13f is formed on the inner peripheral surface on the left side and the inner peripheral surface on the rear side of the sensor insertion hole 13a and the holding protrusion 13b. Further, the pressing protrusion 13f is formed in an elongated shape having a longitudinal direction in the vertical direction so that a cross section parallel to the ZX plane is substantially semicircular. In this embodiment, the first sensor 12 is press-fitted into the sensor insertion hole 13a of the sensor holder 13 and fixed. When the first sensor 12 is inserted, the pressing protrusion 13 f is deformed and the pressing protrusion 13 f comes into contact with the first sensor 12. Further, after the press-fitting, the pressing protrusion 13f presses the first sensor 12 toward the inner peripheral surface on the right side and the inner peripheral surface on the front side of the sensor insertion hole 13a and the holding protrusion 13b.

  The width of the holding projection 13b in the front-rear direction is narrower than the width of the projection insertion hole 11c in the front-rear direction, and as shown in FIG. 4, the holding projection 13b and the projection insertion hole 11c in the front-rear direction (optical axis L direction). A gap G is formed between the two. The width of the second contact surface 11b in the front-rear direction is wider than the width of the first contact surface 13d in the front-rear direction. Therefore, as described later, the attachment position of the sensor holding body 13 in the optical axis L direction can be performed in a state where the first contact surface 13d and the second contact surface 11b are in contact with each other. Note that the width in the left-right direction of the first contact surface 13d is slightly narrower than the width in the left-right direction of the second contact surface 11b.

  The second sensor is directly fixed to a predetermined position of the barrel main body 11.

(Lens barrel manufacturing method)
FIG. 7 is a conceptual diagram for explaining the configuration of the adjustment system 20 for adjusting the mounting position of the sensor holder 13 shown in FIG. FIG. 8 is a flowchart for explaining a method for adjusting and fixing a mounting position of the sensor holder 13 shown in FIG. FIG. 9 is a conceptual diagram for explaining a method for adjusting the mounting position of the sensor holder 13 shown in FIG.

  In the manufacturing process of the lens barrel 3 configured as described above, the first lens holding body 10 to which the first lens group 5 is fixed, the second lens holding body to which the second lens group 6 is fixed, and the like are the lens barrel. In the final stage after the moving mechanism or the like that is arranged in the main body 11 and moves the first lens holding body 10 is fixed to the barrel main body 11, the position of the sensor holder 13 attached to the barrel main body 11 is determined. Adjustment and fixing are performed. Below, the adjustment method and fixing method of the attachment position of the sensor holding body 13 to the lens-barrel main body 11 among the manufacturing methods of the lens-barrel 3 are demonstrated.

  In this embodiment, the adjustment system 20 shown in FIG. 7 is used when adjusting the attachment position of the sensor holder 13 to the lens barrel body 11. The adjustment system 20 includes a reflection mirror 21, a focus confirmation mechanism 22, a holder adjustment mechanism 23, and a chuck mechanism (not shown) for fixing the lens barrel 3.

  The reflection mirror 21 is fixed at a position corresponding to the image sensor 2 in the optical axis L direction. That is, the reflection mirror 21 is set so that the distance between the third lens 7 and the reflection mirror 21 in the optical axis L direction is equal to the distance between the third lens 7 and the imaging element 2 in the optical axis L direction in the camera 1. It is fixed.

  The focus confirmation mechanism 22 includes a light emitting unit that emits light toward the reflecting mirror 21, a light receiving unit that receives the light reflected by the reflecting mirror 21, and determines whether the received light is in focus. It has.

  The holder adjusting mechanism 23 includes a holding portion that holds the adjustment protrusion 13c of the sensor holding body 13, a feed screw that is screwed into a female screw formed on the holding portion, and a knob portion that rotates the feed screw. Yes. In this embodiment, when the operator rotates the knob portion, the sensor holding body 13 moves in the direction of the optical axis L, and the attachment position of the sensor holding body 13 is adjusted. In this embodiment, for example, the mounting position of the sensor holder 13 can be adjusted in units of 0.01 mm. That is, in this embodiment, the attachment position of the sensor holder 13 can be finely adjusted.

  Using this adjustment system 20, the attachment position of the sensor holder 13 to the lens barrel body 11 is adjusted as follows, and the sensor holder 13 is fixed to the lens barrel body 11. At this time, the second lens moving body to which the second lens group 6 is fixed is disposed at a predetermined position inside the barrel main body 11.

  Specifically, as shown in the flow of FIG. 8, first, whether or not the light received by the focus confirmation mechanism 22 is in focus at the wide angle shooting (wide) and at the time of telephoto shooting (tele) is determined. While confirming, the first lens holder 10 is moved to a position where each focus is achieved by the moving mechanism connected to the first lens holder 10 (step S1). That is, in step S1, the first lens holder 10 is moved to a position where each camera 1 is estimated to be in focus. For example, the position shown in FIG. 9A is the position (focus value) at which each focus is achieved.

  Thereafter, the first lens holder 10 is moved by the reference distance C to the PI optimum reference position calculated from the wide focus value and the tele focus value (step S2, see FIG. 9B).

  The position of the sensor holding body 13 to which the first sensor 12 is fixed is adjusted so that when the first lens holding body 10 is moved backward from the moved position, the on / off of the first sensor 12 is just switched. Then, temporary positioning of the sensor holder 13 is performed (step S3). That is, the sensor holding body 13 is arranged in accordance with the position of the first lens holding body 10 after the movement. In this step S <b> 3, the sensor holder 13 is temporarily positioned while the holder holder 13 moves the sensor holder 13. Specifically, the sensor holding body 13 is slid while adjusting the mounting position of the sensor holding body 13 while the first contact surface 13d and the second contact surface 11b are in contact with each other. Perform temporary positioning.

  Thereafter, the first lens holder 10 is moved by the reference distance C in the in-focus direction, and it is confirmed whether or not the in-focus position is in focus (step S4). If the subject is in focus, the sensor holder 13 is bonded and fixed to the barrel main body 11 at the temporarily positioned position (step S5), and the attachment position of the sensor holder 13 to the barrel main body 11 is adjusted. And fixing is finished. On the other hand, if the image is not in focus, the process returns to step S1 and adjustment is performed again.

  In this embodiment, Steps S1 to S4 are adjustment steps for adjusting the attachment position of the sensor holder 13 in the direction of the optical axis L to the lens barrel body 11, and Step S5 is a lens barrel after the adjustment step. This is a fixing process for fixing the sensor holder 13 to the main body 11. Step S1 is a moving step of moving the first lens holding body 10 to a position where the camera 1 to which the lens barrel 3 is attached is in focus (more specifically, a position estimated to be in focus). Steps S2 and S3 are arrangement steps in which, after the moving step, the first lens holding body 10 is moved by the reference distance C, and the sensor holding body 13 is arranged in accordance with the position of the first lens holding body 10 after the movement. .

(Main effects of this form)
As described above, in this embodiment, the adjustment unit 11a for adjusting the mounting position of the sensor holding body 13 in the direction of the optical axis L is formed in the lens barrel body 11, and in steps S1 to S4, the sensor holding body is formed. The attachment position to the barrel main body 11 in the direction of the optical axis L of 13 is adjusted. Therefore, even when the outer shape of the first sensor 12 varies, the influence of the variation in the outer shape of the first sensor 12 can be suppressed by adjusting the mounting position of the sensor holder 13. Therefore, even if the movement amount (movement distance) of the first lens holding body 10 is determined with reference to the first sensor 12, variation in the actual movement range of the first lens holding body 10 can be suppressed, and the lens Even if the length of the lens barrel 3 in the optical axis L direction is shortened, the first lens holder 10 can be moved by a predetermined moving distance. As a result, in this embodiment, the lens barrel 3 can be reduced in size in the optical axis L direction.

  In this embodiment, the attachment position of the sensor holding body 13 is adjusted by the adjusting portion 11a of the lens barrel body 11. That is, the mounting position of the sensor holder 13 formed larger than the first sensor 12 is adjusted. Therefore, adjustment work becomes easier as compared with the case where the first sensor 12 is directly adjusted in the adjustment unit 11a.

  In this embodiment, a first contact surface 13d is formed on the sensor holding body 13, and a second contact surface 11b that contacts the first contact surface 13d is formed on the adjustment portion 11a. A gap G is formed between the holding projection 13b and the projection insertion hole 11c. Therefore, the mounting position of the sensor holding body 13 can be adjusted while the sensor holding body 13 is slid in the optical axis L direction in a state where the first contact surface 13d and the second contact surface 11b are in contact with each other. it can. Therefore, the attachment position of the sensor holder 13 can be easily adjusted. Further, by using the holder adjustment mechanism 23, the attachment position of the sensor holder 13 can be finely adjusted.

  In this embodiment, the first sensor 12 is fixed to the sensor insertion hole 13a. Therefore, even if the outer shape of the first sensor 12 varies, it is possible to prevent rattling between the first sensor 12 and the sensor holder 13. In particular, in this embodiment, the first sensor 12 is press-fitted into the sensor insertion hole 13a and fixed. Further, after the press-fitting, the pressing protrusion 13f presses the first sensor 12 in the right direction and the front direction. Therefore, even if the outer shape of the first sensor 12 varies, the rattling between the first sensor 12 and the sensor holding body 13 can be achieved with a simple configuration in which the first sensor 13 is inserted into the sensor insertion hole 13a. Can be reliably prevented. Further, since the pressing protrusion 13f is configured to be deformed when the first sensor 12 is press-fitted into the sensor insertion hole 13a, it is possible to reduce the pressure input at the time of press-fitting.

  In this embodiment, in step S1, the first lens moving body 10 is moved to a position estimated to be in focus by the camera 1 to which the lens barrel 3 is attached, and then in steps S2 and S3, the first lens holding body. 10 is moved by the reference distance C, and the sensor holder 13 is arranged in accordance with the position of the first lens holder 10 after the movement. Therefore, even when the sensor holder 13 is adjusted by the lens barrel 3 alone, the camera 1 to which the lens barrel 3 is attached can be appropriately focused.

(Other embodiments)
The above-described embodiment is an example of a preferred embodiment of the present invention, but is not limited thereto, and various modifications can be made without departing from the scope of the present invention.

  In the embodiment described above, the sensor holding body 13 is fixed to the barrel main body 11 by adjusting the mounting position of the sensor holding body 13 to the barrel main body 11 as in the flow shown in FIG. In addition to this, for example, as shown in the flow of FIG. 10, the sensor holding body 13 may be fixed to the lens barrel body 11 by adjusting the attachment position of the sensor holding body 13 to the lens barrel body 11. Hereinafter, the adjustment method and the fixing method of the attachment position of the sensor holding body 13 to the lens barrel body 11 according to another embodiment will be briefly described with reference to FIGS. 10 and 11.

  First, the sensor holder 13 is temporarily positioned at the designed mounting position (step S11). That is, the first sensor 12 is temporarily positioned at the designed mounting position (see FIG. 11A). Thereafter, the first lens holder 10 is moved in the direction in which the wide focus and the tele focus are in focus by the design reference distance C with reference to the temporarily positioned first sensor 12, and the movement is performed. It is confirmed whether or not each focus is achieved at a later position (step S12, see FIG. 11B).

  If each focus is correct, the sensor holder 13 is bonded and fixed to the lens barrel body 11 at the temporarily positioned position (step S13), and the position of the sensor holder 13 attached to the lens barrel body 11 is determined. Adjustment and fixing are finished.

  On the other hand, when each focus is not in focus, the first lens holding body 10 is moved to the position where each focus is achieved, and the shift amount ΔD of each focus position is obtained (see step S14, FIG. 11C). Thereafter, a deviation amount (that is, a deviation amount of the first sensor 12) D of the sensor holder 13 is calculated from the deviation amount ΔD in accordance with a predetermined calculation formula (step S15). Thereafter, the sensor holding body 13 is moved by the shift amount D (see step S16, FIG. 11D), and the process returns to step S12 again to move the first lens holding body 10 at the position after the movement. It is confirmed whether or not each focus is in focus (see FIG. 11E).

  As described above, when the attachment position of the sensor holder 13 to the lens barrel body 11 is adjusted according to the flow shown in FIG. 10 and the sensor holder 13 is fixed to the lens barrel body 11, the focus is adjusted in step S12. Is confirmed, the sensor holding body 13 can be fixed to the lens barrel body 11 as it is in step S13. Therefore, in the lens barrel 1, when the first sensor 12 having a relatively small outer shape variation is used, the manufacturing process of the lens barrel 3 can be simplified.

  In the case of the flow shown in FIG. 10, steps S11, S12, and S14 to S16 are adjustment steps for adjusting the mounting position of the sensor holder 13 on the lens barrel body 11 in the optical axis L direction. Step S13 is a fixing step of fixing the sensor holder 13 to the lens barrel body 11 after the adjustment step. Step S11 is a temporary positioning step in which the sensor holding body 13 is temporarily positioned at the designed mounting position. Step S12 moves the first lens holding body 10 by a predetermined reference distance C after the temporary positioning step. Thus, the camera 1 to which the lens barrel 3 is attached is used to check whether or not the camera 1 is in focus (more specifically, whether or not the camera 1 to which the lens barrel 3 is attached is estimated to be in focus). It is a confirmation process.

  Further, when calculating the shift amount D of the sensor holder 13, either the wide focus position shift amount ΔD or the telephoto focus position shift amount ΔD is obtained to obtain the shift amount D of the sensor holder 13. May be calculated.

  In the embodiment described above, the second sensor is directly fixed to a predetermined position of the lens barrel body 11. In addition to this, for example, the lens barrel 3 includes a sensor holding body that holds the second sensor, and the mounting position of the sensor holding body that holds the second sensor in the optical axis L direction is adjusted similarly to the sensor holding body 13. It may be configured to be possible. In this case, for example, a sensor holding body that holds the second sensor while irradiating the second lens holding body that holds the second lens group 6 with laser light and confirming the position of the second lens holding body. The mounting position may be adjusted. When adjusting the mounting position of the sensor holder while checking the position of the second lens holder using laser light, the position of the second lens holder is confirmed with a relatively simple adjustment system. However, it is possible to adjust the mounting position of the sensor holding body according to the confirmed position of the second lens holding body.

  In the above-described embodiment, when the imaging device 2 is used as a reference, the third lens 7 (fixed lens), the second lens group 6 (zooming lens), and the first lens group 5 (focusing lens) are provided inside the lens barrel 3. Are arranged along the optical axis L in this order. In addition to this, for example, as shown in FIG. 12, a focusing lens 25, a fixed lens 27, and a zooming lens 26 are arranged along the optical axis L in this order in the lens barrel 23 with respect to the imaging device 2. May be arranged.

  In this case, the lens barrel 23 includes a first sensor for detecting a reference position of a lens holder that holds the focusing lens 25, and a sensor holder to which the first sensor is fixed. Similarly, the mounting position of the sensor holder may be adjusted. Further, the lens barrel 23 includes a second sensor for detecting a reference position of a lens holder that holds the zooming lens 26, and a sensor holder to which the second sensor is fixed. Thus, the mounting position of the sensor holder may be adjusted. Note that a prism 28 and a predetermined optical lens 29 are disposed inside the lens barrel 23.

  In the embodiment described above, the first sensor 12 is PI. However, the first sensor 12 may be a non-contact proximity sensor, a contact limit switch, or a micro switch. In the above-described embodiment, the lens barrel 3 is used in a still camera such as a digital camera. However, the lens barrel 3 is a moving image capturing device such as a video camera, an observation device such as a binocular or a telescope, and the like. It may be used for optical equipment.

  In the above-described embodiment, the adjustment unit 11a for adjusting the attachment position of the sensor holding body 13 in the optical axis L direction is formed in the lens barrel body 11, and the lens barrel of the sensor holding body 13 in the optical axis L direction. Although adjustment of the attachment position to the main body 11 is possible, the adjustment part for adjusting the attachment position of the sensor holding body 13 in the direction orthogonal to the optical axis L direction is formed in the lens barrel main body 11, and the optical axis It may be possible to adjust the attachment position of the sensor holder 13 to the barrel main body 11 in the direction orthogonal to the L direction. In this case, the adjustment portion may be formed in a flat shape, or may be formed in a curved shape along the outer peripheral surface of the lens barrel body 11 formed in a substantially cylindrical shape.

It is a figure for demonstrating schematic structure of the optical system of the camera concerning embodiment of this invention. It is a perspective view of the lens barrel shown in FIG. FIG. 3 is a plan view of the lens barrel shown in FIG. 2. It is sectional drawing which shows a part of EE cross section of FIG. It is a disassembled perspective view of the 1st sensor and sensor holding body which are shown in FIG. It is a figure for demonstrating the sensor insertion hole shown in FIG. It is a conceptual diagram for demonstrating the structure of the adjustment system for adjusting the attachment position of the sensor holding body shown in FIG. It is a flowchart for demonstrating the adjustment method and fixing method of the attachment position of the sensor holding body shown in FIG. It is a conceptual diagram for demonstrating the adjustment method of the attachment position of the sensor holding body shown in FIG. It is a flowchart for demonstrating the adjustment method and fixing method of the attachment position of the sensor holding body concerning other embodiment of this invention. It is a conceptual diagram for demonstrating the adjustment method of the attachment position of the sensor holding body concerning other embodiment of this invention. It is a figure for demonstrating schematic structure of the optical system concerning other embodiment of this invention.

Explanation of symbols

1 Camera (optical equipment)
3, 23 Lens barrel 5 First lens group (optical lens)
6 Second lens group (optical lens)
10 First lens holder (lens holder)
DESCRIPTION OF SYMBOLS 11 Body 11a Adjustment part 11b 2nd contact surface 11c Projection insertion hole 12 1st sensor (sensor)
13 sensor holder 13a sensor insertion hole 13b holding projection 13d first contact surface 13f pressing projection 25 focusing lens (optical lens)
26 Zooming lens (optical lens)
G Gap L Optical axis S1 Movement process, part of adjustment process S2, S3 Arrangement process, part of adjustment process S4, S14 to S16 Part of adjustment process S5, S13 Fixing process S11 Temporary positioning process, part of adjustment process S12 Focus confirmation process, part of adjustment process

Claims (5)

A lens holder for holding an optical lens, a lens barrel body in which the lens holder is disposed, a sensor for detecting a reference position of the lens holder, and holding the sensor and the lens barrel body A sensor holder attached to the
The lens barrel body is formed with an adjustment portion for adjusting the mounting position of the sensor holder in the optical axis direction of the optical lens ,
The sensor holding body and the adjustment unit are in contact with each other at a first contact surface formed on the sensor holding body and a second contact surface formed on the adjustment unit,
The sensor holding body is formed with a holding protrusion that protrudes from the first contact surface to hold the sensor,
The adjustment portion is formed with a protrusion insertion hole into which the holding protrusion is inserted,
A lens barrel, wherein a gap is formed between the holding projection and the projection insertion hole in the optical axis direction .   The lens barrel according to claim 1, wherein the sensor holding body is formed with an adjustment protrusion disposed outside the barrel main body.   3. The lens barrel according to claim 1, wherein a sensor insertion hole into which the sensor is inserted is formed in the sensor holding body, and the sensor is fixed to the sensor insertion hole. The sensor is fixed by being press-fitted into the sensor insertion hole,
4. The lens barrel according to claim 3, wherein the sensor insertion hole is formed with a pressing protrusion that is deformed when the sensor is press-fitted and presses the sensor in a predetermined direction after the press-fitting. An optical apparatus comprising the lens barrel according to claim 1.

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