JP2011128313A - Lens barrel - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent image blur resulting from displacement of a lens holding frame. <P>SOLUTION: The lens barrel includes: the lens holding frame 110 with cam pins 111; a cam cylinder 120 disposed on the outer periphery side of the lens holding frame 110 and having cam grooves 121 engaged with the cam pins 111; and a rectilinear guide member 130 disposed between the lens holding frame 110 and cam cylinder 120 and used for sliding the lens holding frame 110 in the direction of an optical axis. The lens barrel includes an image blur prevention mechanism between the lens holding frame 110 and rectilinear guide member 130 for preventing displacement of the lens holding frame 110 in a direction orthogonal to the optical axis. The image blur prevention mechanism includes: a putting-aside portion for generating a biasing force between the lens holding frame 110 and rectilinear guide member 130 in the direction orthogonal to the optical axis; and a holding-frame-side projection 115 for regulating the position of the lens holding frame 110 in the direction orthogonal to the optical axis by receiving the biasing force from the putting-aside portion. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a lens barrel including a lens holding frame, a cam barrel, and a rectilinear guide member, and more particularly to a lens barrel provided with an image shaking prevention mechanism that prevents image shaking caused by a positional shift of the lens holding frame.

  Conventionally, in a lens barrel including a lens holding frame, a cam barrel, and a rectilinear guide member, a technique for preventing the positional deviation of the lens holding frame has been devised (see, for example, Patent Documents 1 and 2 below). For example, Patent Document 1 below is a technique for preventing the displacement of a lens holding frame caused by a parting line that occurs when a cam member or a guide member is formed of plastic. The cam member is formed so as not to provide a parting line at the end position, or the cam pin is controlled not to stop on the parting line, thereby preventing the lens holding frame from being displaced.

  Patent Document 2 below discloses a guide provided on a moving lens frame located at the intersection of both cam grooves of a cam groove formed in a fixed cylinder and a cam groove formed in a cam cylinder fitted in the fixed cylinder. In the lens moving device comprising a pin, the cam grooves are formed on inclined surfaces having inclination angles opposite to each other, and the guide pins are formed of two coaxial guide pins that respectively engage with the cam grooves. The surfaces abutting on both cam grooves are formed at an inclination angle similar to the inclination angle of the cam grooves, and at the same time with one spring so that the two guide pins abut on the inclination angles of the cam grooves. Energized.

JP-A-5-034558 Japanese Utility Model Publication No. 61-65416

  However, in the conventional technique described in Patent Document 1 described above, there is a problem in that the influence of the parting line cannot be avoided when the position of the cam pin changes even during shooting, for example, during moving image shooting. There is. Since a conventional camera for taking a still image only takes a still image, it is assumed that the position of the cam pin is fixed during the shooting. On the other hand, recently, still cameras for taking a still image have a moving image shooting function. In this case, the position of the cam pin is not necessarily fixed even during photographing, and may move between the telephoto end and the wide-angle end through the parting line.

  In the prior art described in Patent Document 2 described above, the guide pin receives a force directed toward the bottom surface of the cam groove by the biasing force of the spring, and the distance between the guide pin and the bottom surface of the cam groove is reduced. For this reason, when the lens holding frame (moving lens frame) is slid, there is a problem that the image is liable to be affected by a parting line on the bottom surface of the cam groove or a step caused by a foreign substance, and the image is easily shaken.

In order to solve the above-described problems caused by the conventional technology, the present invention can prevent the lens holding frame from being displaced due to the step formed on the bottom surface of the cam groove, and can prevent the image shake of the captured image. An object is to provide a lens barrel.

  In order to solve the above-described problems and achieve the object, a lens barrel according to the present invention includes a sliding member provided with a cam pin, and a cam groove that is disposed on the outer peripheral side of the sliding member and engages with the cam pin. A lens barrel, and a linear guide member that is disposed between the sliding member and the cam barrel and that slides the sliding member in the optical axis direction. Image shake preventing means disposed between the sliding member and the rectilinear guide member and preventing displacement of the sliding member in a direction orthogonal to the optical axis (hereinafter referred to as “optical axis orthogonal direction”). The image shaking prevention means receives an urging portion that generates an urging force in a direction orthogonal to the optical axis between the sliding member and the rectilinear guide member, and an urging force of the urging portion. A restricting portion for restricting the position of the sliding member in the direction orthogonal to the optical axis , Characterized in that it comprises a.

  According to the present invention, the position of the sliding member in the direction orthogonal to the optical axis is regulated by the urging force generated by the urging unit, and the image shake of the photographed image due to the displacement of the sliding member can be prevented. .

  In the lens barrel according to the present invention as set forth in the invention described above, the image shake preventing means is disposed at a position different from a position at which the cam pin is disposed in a circumferential direction around the optical axis. It is characterized by that.

  According to this invention, since the sliding member is regulated at a position different from the cam pin, unlike the case where the sliding member is regulated at the cam pin position, the position of the sliding member due to the step on the bottom surface of the cam groove. Deviation can be prevented.

  Further, the lens barrel according to the present invention is the lens barrel according to the above invention, wherein the urging portion is provided on an outer peripheral portion of the sliding member, and includes a frame that contacts the rectilinear guide member, and an elastic member. The elastic member is held in a compressed state between the outer peripheral portion of the sliding member and the top.

  According to the present invention, the elastic member held in a compressed state exerts an elastic force in the direction orthogonal to the optical axis with respect to the top and the sliding member. With this elastic force, the position of the sliding member can be held in the direction orthogonal to the optical axis between the linearly moving guide member.

  In the lens barrel according to the present invention as set forth in the invention described above, the image shake preventing means includes one urging portion and at least two restricting portions, and the one urging portion and the at least one. The two restricting portions are arranged at equal intervals on a circumference centered on the optical axis.

  According to the present invention, the position of the sliding member is restricted by at least three points of one urging portion and two restricting portions. These three points are arranged at equal intervals on the circumference around the optical axis, and the position of the sliding member can be stably held.

  In the lens barrel according to the present invention as set forth in the invention described above, the rectilinear guide member includes a first convex portion that protrudes toward the sliding member and contacts the biasing portion. .

  In the lens barrel according to the present invention as set forth in the invention described above, the rectilinear guide member includes a second convex portion that protrudes toward the sliding member and contacts the restricting portion.

  According to the present invention, since the straight guide member is provided with the convex portion that comes into contact with the urging portion or the restricting portion, the position of the sliding member can be held more stably.

  In the lens barrel according to the present invention as set forth in the invention described above, the sliding member includes, as the restricting portion, a third protrusion that protrudes toward the rectilinear guide member and contacts the rectilinear guide member. It is characterized by that.

  According to this invention, since the projecting portion that contacts the linear guide member is provided on the sliding member, the position of the sliding member can be held more stably.

  As described above, according to the lens barrel of the present invention, it is possible to prevent the lens holding frame from being displaced due to the step formed on the bottom surface of the cam groove, and to prevent image shake of the photographed image. it can.

1 is a perspective view illustrating an overall configuration of a lens barrel according to an embodiment. It is a perspective view of a lens holding frame. It is the top view which looked at the lens holding frame from the optical axis direction. It is an enlarged view of the one-sided part of an image shaking prevention mechanism. It is sectional drawing which shows the attachment state of the one-sided member to a lens holding frame. It is an enlarged view which shows the structure around a convex part. It is sectional drawing which cut | disconnected the cam cylinder by the surface parallel to an optical axis. It is explanatory drawing which shows the difference in the shape of the cam pin of a some lens holding frame. It is sectional drawing which cut | disconnected the rectilinear guide member by the surface parallel to an optical axis. It is explanatory drawing which shows the assembly state of a lens-barrel. It is sectional drawing which cut | disconnected the periphery of the one-sided member of a lens barrel with the surface parallel to an optical axis direction. It is sectional drawing which cut | disconnected the cam pin periphery of the lens-barrel by the surface parallel to an optical axis direction.

  Exemplary embodiments of a lens barrel according to the present invention will be described below in detail with reference to the accompanying drawings.

(Embodiment)
(Whole structure of lens barrel 100)
FIG. 1 is a perspective view illustrating an overall configuration of a lens barrel according to an embodiment. The lens barrel 100 includes a lens holding frame 110, a cam barrel 120, and a rectilinear guide member 130. A line segment OP in FIG. 1 indicates the optical axis direction. The lens holding frame 110, the cam cylinder 120, and the rectilinear guide member 130 are each substantially cylindrical.

  The lens holding frame 110 holds a lens (not shown). Although only one lens holding frame 110 is shown in FIG. 1, a plurality of lens holding frames 110 can be inserted into the lens barrel 100 as will be described later. A cam pin 111 is formed on the outer peripheral surface of the lens holding frame 110 to engage with a cam groove 121 formed on the inner peripheral surface of the cam cylinder 120. A number of cam grooves 121 corresponding to the number of cam pins 111 of the lens holding frame 110 are formed on the inner peripheral surface of the cam cylinder 120. Further, the straight guide member 130 is formed with a guide hole 131 extending in the optical axis direction.

  In the assembled state of the lens barrel 100, the cam pin 111 of the lens holding frame 110 passes through the guide hole 131 of the rectilinear guide member 130 and engages with the cam groove 121 of the cam barrel 120. That is, in the assembled state of the lens barrel 100, the lens holding frame 110 is disposed inside the cam barrel 120, and the rectilinear guide member 130 is disposed between the cam barrel 120 and the lens holding frame 110. Further, the rectilinear guide member 130 is fixed to the camera body or the like. When the cam cylinder 120 is rotated around the optical axis in this state, the cam pin 111 is driven by the rotation of the cam groove 121 and the lens holding frame 110 moves. Since the cam pin 111 is engaged with the cam groove 121 through the guide hole 131, the lens holding frame 110 is guided and moved in the optical axis direction.

(Configuration of lens holding frame 110)
Next, details of each component of the lens barrel 100 will be described. First, the structure of the lens holding frame 110 will be described with reference to FIGS. 2 is a perspective view of the lens holding frame, and FIG. 3 is a plan view of the lens holding frame viewed from the optical axis direction. As described above, a plurality (three in the illustrated example) of cam pins 111 that engage with the cam grooves 121 of the cam cylinder 120 are formed on the outer periphery of the lens holding frame 110. Each cam pin 111 is formed at equal intervals with respect to the outer periphery of the lens holding frame 110.

  Further, an image shake prevention mechanism is provided on the outer peripheral surface of the lens holding frame 110 so as to prevent the position of the lens holding frame 110 from being shifted and causing image shake. Parts such as the lens holding frame 110 and the cam barrel 120 constituting the lens barrel 100 are made of plastic. Parting lines (steps) are formed on the surfaces of these parts due to the dividing surface of the mold used during plastic processing.

  If there is a parting line on the inner peripheral surface of the cam cylinder 120 (more specifically, the bottom surface of the cam groove 121), when the cam pin 111 passes through this position, the lens holding frame 110 is displaced due to a step, and photographing is performed. Image shaking occurs in the image. In addition, even when there is a foreign object on the bottom surface of the cam groove 121, the lens holding frame 110 is displaced when the cam pin 111 passes through this position, and the captured image is shaken. The image shaking prevention mechanism is such that the cam pin 111 passes through the step on the parting line and the position of foreign matter existing on the inner peripheral surface of the cam cylinder 120, so that the position of the lens holding frame 110 is shifted and image shaking occurs. This is a mechanism for preventing the occurrence.

  The image shaking prevention mechanism is configured by a biasing member 116, which includes a biasing member 112, an elastic member 113, and a biasing member engaging portion 114 formed on the lens holding frame 110, and a holding frame side convex portion 115. In the present embodiment, the image shaking prevention mechanism is configured by a total of three points, that is, one side shift part 116 and two holding frame side convex parts 115. The image shake prevention mechanism is formed on the outer peripheral surface of the lens holding frame 110 where the cam pin 111 is not formed.

  FIG. 4 is an enlarged view of a shift portion of the image shaking prevention mechanism. FIG. 5 is a cross-sectional view showing a state in which the shift member is attached to the lens holding frame. The one-sided member 112 has a substantially U-shape including a flat portion 112b and two engaging portions 112a. The engaging portion 112a protrudes from the end portion of the flat surface portion 112b at a substantially right angle, and has a claw-like portion that engages with the shifting member engaging portion 114 of the lens holding frame 110 at the tip thereof. A positioning boss 112c protruding in the same direction as the engaging portion 112a is formed at the center of the surface on the inner side of the flat portion 112b (the protruding direction side of the engaging portion 112a). The elastic member 113 is fitted to the positioning boss 112c. The elastic member 113 is a spring, for example, and is fitted to the positioning boss 112c of the offset member 112.

  A contact surface 114b with which the hook receiving portion 114a with which the hooking portion 112a of the piece biasing member 112 is hooked and the elastic member 113 is formed is formed in the piece biasing member hooking portion 114. The hook receiving portion 114a is a convex portion on which the claw-like portion of the hook portion 112a of the one-sided member 112 is hooked. The hook receiving portions 114a are formed at two locations in the upper and lower directions in the optical axis direction of the lens holding frame 110, and the one-sided member 112 is hooked on the lens holding frame 110 so that the longitudinal direction thereof coincides with the optical axis direction.

  The width of the parting member engaging portion 114 (the length of the lens holding frame 110 in the circumferential direction) is formed in accordance with the width of the parting member 112. Further, the depth of the hook receiving portion 114a (the length in the longitudinal direction of the lens holding frame 110) is formed smaller than the depth of the hook portion 112a. For this reason, the one-sided member 112 is movable in the longitudinal direction of the lens holding frame 110 within the range of the depth of the hooking portion 112a in the state of being hooked to the lens holding frame 110.

  The elastic member 113 fitted to the positioning boss 112c of the one-sided member 112 is in contact with the contact surface 114b. The length L of the elastic member 113 (the natural length of the spring) is longer than the height of the positioning boss 112c (the length on the protruding direction side from the flat surface portion 112b), and only the elastic member 113 is present on the contact surface 114b. Touch. The length L of the elastic member 113 is longer than the distance between the flat surface portion 112b and the contact surface 114b when the one-sided member 112 is engaged with the one-sided member engaging portion 114. For this reason, when the one-sided member 112 is engaged with the one-sided member engaging part 114, the one-sided member 112 and the one-sided member engaging part 114 are elastic in the longitudinal direction of the lens holding frame 110 as indicated by an arrow P. Is received from the elastic member 113.

  Next, the holding frame side convex portion 115 of the image shaking prevention mechanism will be described. FIG. 6 is an enlarged view showing the structure around the convex portion. Two holding frame side convex portions 115 are formed on the outer periphery of the lens holding frame 110 (see FIG. 3). It is desirable that the three points of the holding frame side convex portions 115 and the one-sided member engaging portions 114 are formed at equal intervals with respect to the outer periphery of the lens holding frame 110.

  The holding frame-side convex portion 115 has a predetermined height with respect to the outer peripheral surface of the lens holding frame 110 (excluding a portion where the cam pin 111 and the one-sided member engaging portion 114 are formed). The flat portion 115a of the holding frame side convex portion 115 is a plane that is perpendicular to the longitudinal direction of the lens holding frame 110 (having no curvature with respect to the circumferential direction of the lens holding frame 110). In the assembled state of the lens barrel 100, the flat portion 115a contacts the guide member side convex portion 132 (see FIG. 9) formed on the inner peripheral surface of the rectilinear guide member 130.

(Configuration of cam cylinder 120)
Next, the configuration of the cam cylinder 120 will be described. FIG. 7 is a cross-sectional view of the cam cylinder cut along a plane parallel to the optical axis. On the inner peripheral surface of the cam cylinder 120, a step (not shown) due to the parting line is formed. Further, cam grooves 121 corresponding to at least the number of cam pins 111 (three in the illustrated example) of the lens holding frame 110 are formed on the inner peripheral surface of the cam cylinder 120. In the cam groove 121, a lens insertion opening 122 is opened at an end portion of the cam cylinder 120 in the optical axis direction, and an optical axis direction moving portion 123 that moves the cam pin 111 in the optical axis direction and a cam pin in the circumferential direction of the cam cylinder 120. A circumferential direction moving part 124 for moving 111 is formed.

  Here, in the cam cylinder 120 shown in FIG. 7, a plurality of (two in the illustrated example) circumferential movement portions 124 (124 a and 124 b) are formed for one lens insertion opening 122. The plurality of circumferentially moving portions 124a and 124b are formed to engage and move different lens holding frames 110, respectively. That is, a plurality of lens holding frames 110 can be inserted and used in the lens barrel 100 according to the present embodiment.

  In general, when a plurality of lens holding frames 110 are inserted into the lens barrel 100 and used, it is necessary to separately generate lens insertion ports 122 corresponding to the lens holding frames 110. For this reason, in a normal lens barrel, the number of cam grooves 121 that can be formed in the cam barrel 120 and the length of the cam barrel 120 in the optical axis direction may be limited.

  On the other hand, in the lens barrel 100 according to the present embodiment, one lens insertion port 122 is commonly used by the plurality of lens holding frames 110 by making the shapes of the cam pins 111 of the respective lens holding frames 110 different. Making it possible.

  FIG. 8 is an explanatory diagram showing the difference in the shape of the cam pins of the plurality of lens holding frames. FIG. 8 shows a first lens holding frame 110a and a second lens holding frame 110b. Comparing the cam pin 111a of the lens holding frame 110a with the cam pin 111b of the lens holding frame 110b, the cam pin 111a has a circular shape with the same height Ha and width Wa, whereas the cam pin 111b has a height higher than the height Hb. Also, the width Wb is longer and substantially oval. Here, the height H of the cam pin 111 is the length in the optical axis direction, and the width W is the length in the optical axis orthogonal direction (circumferential direction). The height Ha of the cam pin 111a is equal to the height Hb of the cam pin 111b (Ha = Hb).

  On the other hand, when the width Wa of the cam pin 111a and the width Wb of the cam pin 111b are compared, the width Wb of the cam pin 111b is longer (Wb> Wa). As shown in FIG. 7, the width of the lens insertion opening 122 of the cam cylinder 120 is formed in accordance with the width Wb. Moreover, the height of the circumferential direction moving parts 124a and 124b is formed according to the heights Ha and Hb. Further, when the intersection between the optical axis direction moving unit 123 and the circumferential direction moving unit 124a is an intersection 125a, and the intersection between the optical axis direction moving unit 123 and the circumferential direction moving unit 124b is an intersection point 125b, the optical axis direction moving unit 123 is used. Is formed in accordance with the width Hb of the cam pin 111b from the lens insertion opening 122 to the intersection point 125a. The width from the intersection point 125a to the intersection point 125b is formed in accordance with the width Wa of the cam pin 111a.

  For this reason, when the lens holding frame 110b is inserted from the lens insertion opening 122, the cam pin 111b can only move to the position of the intersection 125a in the optical axis direction, and is introduced into the circumferential direction moving part 124a. As a result, the lens holding frame 110b moves along the circumferential direction moving part 124a. On the other hand, when the lens holding frame 110a is inserted from the lens insertion port 122, the cam pin 111a passes through the intersection 125a and moves in the optical axis direction to a deeper position. The cam pin 111a is introduced into the circumferential direction moving part 124b at the intersection 125b, and the lens holding frame 110a moves along the circumferential direction moving part 124b.

  Thus, in the lens barrel 100 according to the embodiment, each cam pin 111 can be engaged with a desired cam groove 121 by making the shape of the cam pin 111 of the lens holding frame 110 different. Thereby, compared with the conventional lens barrel, the number of cam grooves 121 that can be formed in the cam barrel 120 of the same length can be increased, and the influence on the length of the cam barrel 120 can be reduced.

(Configuration of the rectilinear guide member 130)
Next, the configuration of the rectilinear guide member 130 will be described. FIG. 9 is a cross-sectional view of the rectilinear guide member cut along a plane parallel to the optical axis. The rectilinear guide member 130 has a guide hole 131 formed in the optical axis direction. The guide holes 131 are formed in the same number (three in the illustrated example) as the cam pins 111 of the lens holding frame 110, and the cam pins 111 of the lens holding frame 110 are penetrated when the lens barrel 100 is assembled.

  In addition, on the inner circumferential surface of the rectilinear guide member 130, two holding frame side convex portions 115 of the lens holding frame 110 and a guide member side convex portion 132 in contact with the offset member 112 are formed. The guide member-side convex portion 132 is a region extending in the optical axis direction and has a predetermined height with respect to the inner peripheral surface of the rectilinear guide member 130. The surface of the guide member-side convex portion 132 is a plane perpendicular to the longitudinal direction of the rectilinear guide member 130 (having no curvature with respect to the circumferential direction of the rectilinear guide member 130).

  The guide member side convex portions 132 are formed in numbers (three in the illustrated example) corresponding to the holding frame side convex portions 115 of the lens holding frame 110 and the shifting members 112. The width of the guide member side convex portion 132 (the length in the circumferential direction) is formed in accordance with the width of the holding frame side convex portion 115 and the width of the offset member 112. Since the surfaces of the guide member-side convex portion 132, the holding frame-side convex portion 115, and the one-sided member 112 are mirror-finished, the frictional force when contacting the holding frame-side convex portion 115 or the one-sided member 112 is reduced, The lens holding frame 110 is easy to move in the optical axis direction.

(Operation of the lens barrel 100)
Next, the operation of the lens barrel 100 in the assembled state will be described. FIG. 10 is an explanatory view showing an assembled state of the lens barrel. FIG. 11 is a cross-sectional view in which the vicinity of the lens barrel side-shift member is cut along a plane parallel to the optical axis direction, and FIG. FIG.

  FIG. 10A is a view of the assembled state of the lens barrel 100 as seen from the circumferential direction. 10B and 10C are cross-sectional views of the lens barrel 100 taken along a plane orthogonal to the optical axis (the XX ′ plane of FIG. 10A), and FIG. An XX ′ plane is taken at a position passing through the center, and (c) is an XX ′ plane taken at a position passing through the upper end of the offset member 112. 10D is an enlarged view of the cam pin 111 portion of FIG. 10B, and FIG. 10E is an enlarged view of the parting member 112 portion of FIG. 10C. is there.

  As shown in FIGS. 10B and 10C, in the assembled state of the lens barrel 100, the lens holding frame 110 is disposed inside the cam barrel 120, and between the cam barrel 120 and the lens holding frame 110. A rectilinear guide member 130 is disposed. Further, the lens holding frame 110 is in contact with the guide member-side convex portion 132 of the rectilinear guide member 130 at three points, that is, the one-sided member 112 and the two holding frame-side convex portions 115. At this time, the elastic member 113 fitted to the one-sided member 112 is sandwiched in a compressed state between the one-sided member engaging portion 114 of the lens holding frame 110 and the one-sided member 112, as shown in FIG. .

  For this reason, the biasing member 112 receives an elastic force directed outward in the longitudinal direction from the elastic member 113 and is pressed against the guide member side convex portion 132 of the rectilinear guide member 130. Further, the one-sided member engaging portion 114 of the lens holding frame 110 receives an elastic force directed inward in the longitudinal direction from the elastic member 113, and the two holding frame side convex portions 115 are changed to the guide member side convex portion 132 by this stress. Abutted. As described above, the lens holding frame 110 is supported at the three points of the side-shifting member 112 and the two holding frame-side convex portions 115 inside the rectilinear guide member 130 and stably holds the posture in the circumferential direction. be able to.

  10B and 10C, the cam pin 111 of the lens holding frame 110 passes through the guide hole 131 of the rectilinear guide member 130 and is formed on the inner peripheral surface of the cam cylinder 120. Engages with the groove 121. Here, as shown in FIGS. 10D and 12, the tip of the cam pin 111 and the bottom surface of the cam groove 121 are formed to have a predetermined clearance.

  With this clearance, the cam pin 111 can be moved without contacting a parting line (step) formed on the bottom surface of the cam groove 121. As described above, the lens holding frame 110 stably holds the circumferential posture inside the rectilinear guide member 130. For this reason, the circumferential position of the cam pin 111 can also be stably held, and the clearance between the tip of the cam pin 111 and the bottom surface of the cam groove 121 can be stably held.

  As described above, according to the lens barrel 100 according to the embodiment, the position of the lens holding frame 110 in the direction orthogonal to the optical axis is regulated by the biasing force generated by the biasing portion 116 of the image shaking prevention mechanism. Further, it is possible to prevent the image shake of the photographed image due to the displacement of the lens holding frame 110. Further, according to the lens barrel 100, the image shake prevention mechanism is formed at a position different from the cam pin 111, and therefore the lens holding frame 110 is restricted to a position different from the cam pin 111. For this reason, unlike the case where the lens holding frame 110 is regulated by the position of the cam pin 111, it is possible to prevent the positional displacement of the lens holding frame 110 due to the step on the bottom surface of the cam groove 121.

  Further, according to the lens barrel 100, the elastic member 113 held in a compressed state exerts an elastic force in the direction perpendicular to the optical axis with respect to the one-sided member 112 and the one-sided member engaging portion 114 of the lens holding frame 110. With this elastic force, the position of the lens holding frame 110 can be held in the direction perpendicular to the optical axis between the lens holding frame 110 and the rectilinear guide member 130.

  Further, according to the lens barrel 100, the position of the lens holding frame 110 is restricted by at least three points of the one side-shift member 112 and the two holding frame side convex portions 115. These three points are arranged at equal intervals on the circumference centered on the optical axis, and the position of the lens holding frame 110 can be stably held. Further, according to the lens barrel 100, since the convex portions (the holding frame side convex portion 115 and the guide member side convex portion 132) are provided at the contact portion between the lens holding frame 110 and the rectilinear guide member 130, the lens holding The position of the frame 110 can be held more stably.

  As described above, the lens barrel according to the present invention includes the lens holding frame, the cam barrel, and the rectilinear guide member. The lens held by the lens holding frame is moved in the optical axis direction so that a predetermined imaging state is obtained. It is effective for a lens barrel to be obtained, and is particularly suitable for a lens barrel of a moving image shooting camera in which the lens position continues to move even during shooting.

DESCRIPTION OF SYMBOLS 100 Lens barrel 110 Lens holding frame 111 Cam pin 112 One-sided member 113 Elastic member 114 One-sided member hooking part 115 Holding frame side convex part 116 One-sided part 120 Cam cylinder 121 Cam groove 130 Straight guide member 131 Guide hole 132 Guide member side Convex

Claims (7)

A sliding member with a cam pin;
A cam cylinder provided on the outer peripheral side of the sliding member and provided with a cam groove engaging with the cam pin;
A linear guide member that is disposed between the sliding member and the cam barrel and that slides the sliding member in the optical axis direction;
Image shake preventing means disposed between the sliding member and the rectilinear guide member and preventing displacement of the sliding member in a direction orthogonal to the optical axis (hereinafter referred to as “optical axis orthogonal direction”). Has
The image shaking prevention means is:
An urging portion that generates an urging force in a direction orthogonal to the optical axis between the sliding member and the linear guide member;
And a restricting portion that restricts the position of the sliding member in the direction perpendicular to the optical axis in response to the urging force of the urging portion.   2. The lens barrel according to claim 1, wherein the image shaking prevention unit is disposed at a position different from a position at which the cam pin is disposed in a circumferential direction around the optical axis. The biasing portion is provided on an outer peripheral portion of the sliding member, and includes a piece that comes into contact with the rectilinear guide member, and an elastic member.
The lens barrel according to claim 1, wherein the elastic member is held in a compressed state between an outer peripheral portion of the sliding member and the top. The image shaking prevention means is composed of one urging portion and at least two restricting portions,
The said one energizing part and the said at least 2 control part are arrange | positioned at equal intervals on the periphery centering on the said optical axis, The any one of Claims 1-3 characterized by the above-mentioned. Lens barrel.   5. The lens barrel according to claim 1, wherein the rectilinear guide member includes a first convex portion that protrudes toward the sliding member and contacts the biasing portion. .   The lens barrel according to claim 1, wherein the rectilinear guide member includes a second convex portion that protrudes toward the sliding member and contacts the restricting portion.   7. The slide member according to claim 1, wherein the sliding member includes a third convex portion that protrudes toward the linear guide member and contacts the linear guide member as the restricting portion. The lens barrel described.

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