JP5391950B2 - Lens barrel position adjustment mechanism - Google Patents

Description

  The present invention relates to a lens barrel position adjustment mechanism, and more particularly to a flange back adjustment mechanism for adjusting the position in the optical axis direction with respect to an imaging surface.

  For lens barrels for CCTV (Closed-circuit Television) cameras, a type that allows adjustment of the angle of the lens barrel in the rotation direction around the optical axis is often used while attached to the camera body. . This angle adjustment mechanism supports a base member that supports an imaging optical system so that it can rotate relative to a mount ring that is fixed to the camera body, and in a normal use state, it is biased in the direction of the optical axis. In many cases, friction (friction engagement) is applied between the two to restrict relative rotation. When adjusting the angle of the lens barrel, a force in the rotational direction is applied against this friction.

JP 2000-69347 A

  In the lens barrel in which the angle can be adjusted by the mount part as described above, if the position of the entire optical system relative to the imaging surface is adjusted in the optical axis direction, that is, the flange back adjustment is performed, the load of the biasing member described above fluctuates. The torque at the time of angle adjustment may change, and the operational feeling may be impaired. Specifically, this problem has occurred under the following structure. First, a biasing member such as a washer spring inserted between the base member supporting the imaging optical system and the mount ring is biased in the optical axis direction (either front or rear). A mount fixing ring is fastened to the base member, and the mount fixing ring engages with the mount ring to define a moving end of the biasing member in the biasing direction. Between the mount fixing ring and the base member, a spacer such as an adjustment washer that determines the distance between the optical axis directions is sandwiched. By replacing this spacer with a different thickness, the position of the base member in the optical axis direction can be changed. Changed (adjusted). When the position of the base member in the optical axis direction changes, the distance between the contact surfaces of the biasing member on the base member and the mount ring changes, and as a result, the load on the biasing member fluctuates.

  The present invention has been made to solve the above-described problems, and has a simple structure, but does not cause torque fluctuation during angle adjustment due to position adjustment in the optical axis direction and has excellent adjustment operability. An object of the present invention is to provide a lens barrel position adjustment mechanism.

The lens barrel position adjusting mechanism according to the present invention includes a mount ring fixed to a camera body; a base member that supports an imaging optical system, is relatively rotatable with respect to the mount ring, and is movable in the optical axis direction. A pressing member that forms a pair of opposing portions spaced apart from each other in the optical axis direction with the base member, and that positions the optical axis direction position reference portion provided on the mount ring between the opposing portions; a base member and the pressing member A variable coupling means for coupling the pair of opposing portions in the optical axis direction in an adjustable manner; and a space in the optical axis direction between the pressing member and the mount ring so as to be elastically deformable in the optical axis direction, The combination of the holding member and the base member is urged in the optical axis direction so that either one of the opposing portions that are paired with the position reference portion in the optical axis direction of the mount ring is approached, and the base member and the mount ring are An urging member for imparting friction that restricts relative rotation of the image pickup optical system. When adjusting the position of the imaging optical system in the optical axis direction, the position of the pressing member in the optical axis direction is changed with respect to the mount ring by the variable coupling means. Instead, only the position of the base member in the optical axis direction is changed while maintaining the size of the space in the optical axis direction in which the biasing member is inserted .

  As a specific configuration of the variable coupling means, a spacer that is sandwiched between a base member and a pressing member and defines a distance in the optical axis direction of the opposing portion forming the pair, and a base member and a pressing member by relative rotation about the optical axis. When the position of the imaging optical system in the optical axis direction is adjusted by changing to a spacer with a different plate thickness or changing the number of spacers It is preferable to change the screwing amount of the screwing portion in accordance with the change in the optical axis direction width of the spacer. In order to prevent tilting with respect to the optical axis and achieve highly accurate positioning, it is preferable that each of the spacer and the biasing member is made of an annular body centered on the optical axis.

  More specifically, the following configuration is possible as the first embodiment. First, the optical axis direction position reference portion of the mount ring includes a first flange portion having front and rear optical axis orthogonal planes, and the base member is positioned facing the front of the first flange portion in the optical axis direction. A second flange portion; The holding member is composed of two parts, a mount fixing ring and a mount space ring. The mount fixing ring has a third flange portion that abuts against the rear surface in the optical axis direction of the first flange portion of the mount ring. On the other hand, it is supported via a screw threaded portion. On the other hand, the mount space ring has a fourth flange portion located between the first flange portion of the mount ring and the second flange portion of the base member, and abuts against the third flange portion of the mount fixing ring. Thus, the relative position of the mount fixing ring in the optical axis direction is kept constant. A spacer is sandwiched between the second flange portion of the base member and the fourth flange portion of the mount space ring. An urging member is sandwiched between the first flange portion of the mount ring and the fourth flange portion of the mount space ring, and the base member, the mount space ring, and the mount fixing ring are urged by the urging force of the urging member. Is urged toward the front in the optical axis direction with respect to the mount ring.

  Moreover, it can also be set as the following structures as a 2nd form. The first flange portion of the mount ring and the second flange portion of the base member are configured in the same manner as in the first embodiment. The point that the holding member is composed of two parts, a mount fixing ring and a mount space ring, is also common to the first embodiment, but the third flange portion provided on the mount fixing ring is directly with respect to the first flange portion of the mount ring. The urging member is sandwiched between the first mount portion and the third flange portion, and is positioned rearward in the optical axis direction without contact. The mount space ring has a fourth flange portion positioned between the first flange portion of the mount ring and the second flange portion of the base member, and this fourth flange portion abuts on the first flange portion. Thus, movement backward in the optical axis direction is restricted. Further, the mount space ring abuts on the third flange portion of the mount fixing ring, and the relative position in the optical axis direction with the mount fixing ring is kept constant. A spacer is sandwiched between the second flange portion of the base member and the fourth flange portion of the mount space ring. Due to the urging force of the urging member, the base member, the mount space ring, and the mount fixing ring are urged toward the rear in the optical axis direction with respect to the mount ring.

  Further, the following configuration can also be adopted as the third mode. First, the optical axis direction position reference portion of the mount ring includes a first flange portion having front and rear optical axis orthogonal planes, and the base member is positioned facing the front of the first flange portion in the optical axis direction. A second flange portion; The holding member includes a mount fixing ring supported by a screw threaded portion with respect to the base member, a third flange portion facing the rear surface in the optical axis direction of the second flange portion of the base member, and the mount ring The first flange portion has a fourth flange portion facing the rear surface in the optical axis direction. A spacer is sandwiched between the second flange portion of the base member, the first flange portion of the mount ring, and the third flange portion of the mount fixing ring. A biasing member is sandwiched between the first flange portion of the mount ring and the fourth flange portion of the mount fixing ring, and the base member and the mount fixing ring are attached to the mount ring by the biasing force of the biasing member. It is biased toward the front in the optical axis direction.

  The lens barrel position adjusting mechanism according to the present invention includes a mount ring fixed to the camera body; supports the imaging optical system, and is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction. Base member; a mount fixing ring that is coupled to the base member via a screw threaded portion so that the position can be adjusted in the optical axis direction, and abuts against the optical axis position reference portion provided on the mount ring from the rear in the optical axis direction A mount space ring that is in contact with the mount fixing ring and whose relative movement in the rearward direction of the optical axis with respect to the mount fixing ring is restricted; light of the mount space ring sandwiched between the mount space ring and the base member Spacer that restricts relative forward movement in the axial direction; elastically deformable in the optical axis direction between the mount space ring and the mount ring And a biasing member that biases the mount space ring, the base member, and the mount fixing ring forward in the optical axis direction with respect to the mount ring, and applies a friction that restricts relative rotation between the base member and the mount ring. And when adjusting the position of the imaging optical system in the optical axis direction, the optical axis direction width occupied by the spacer is changed, and the screwing amount of the screw threaded portion according to the change in the optical axis direction width of the spacer And changing only the position in the optical axis direction of the base member without changing the position in the optical axis direction of the mount fixing ring and the mount space ring with respect to the mount ring.

  The lens barrel position adjusting mechanism according to the present invention includes a mount ring fixed to the camera body; supports the imaging optical system, and is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction. A base member; a mount fixing ring coupled to the base member via a screw threaded portion so that the position of the base member can be adjusted in the optical axis direction; against the optical axis position reference portion provided on the mount ring from the front in the optical axis direction A mount space ring that is in contact with and abuts against the mount fixing ring and whose relative movement in the rearward direction in the optical axis with respect to the mount fixing ring is restricted; the mount space ring that is sandwiched between the mount space ring and the base member, That regulates the relative movement forward of the lens in the optical axis direction; elastically deformable in the optical axis direction between the mount ring and the mount fixing ring The urging force is applied to the mount ring to urge the mount space ring, the base member, and the mount fixing ring rearward in the optical axis direction, and to apply friction that restricts the relative rotation between the base member and the mount ring. And adjusting the position in the optical axis direction of the imaging optical system, the width of the optical axis direction occupied by the spacer is changed, and the screwed portion is screwed according to the change in the optical axis direction width of the spacer. The amount is changed, and only the position of the base member in the optical axis direction is changed without changing the position of the mount fixing ring and the mount space ring in the optical axis direction.

  The lens barrel position adjusting mechanism according to the present invention includes a mount ring fixed to the camera body, a spacer that comes into contact with the optical axis position reference portion provided on the mount ring from the front in the optical axis direction, and an imaging optical system. A base member that is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction, and abuts against the spacer from the front in the optical axis direction; Mount fixing ring that is axially adjustable and abuts against the spacer from the rear in the optical axis direction; inserted between the mount fixing ring and the mount ring so as to be elastically deformable in the optical axis direction. By urging the mount fixing ring and the base member rearward in the optical axis direction, a friction is applied to restrict relative rotation between the base member and the mount ring. A biasing member, and when adjusting the position of the imaging optical system in the optical axis direction, the optical axis direction width occupied by the spacer is changed, and the screw threaded portion of the screw threaded portion is changed according to the change in the optical axis direction width of the spacer. The screwing amount is changed, and only the position of the base member in the optical axis direction is changed without changing the position of the mount fixing ring relative to the mount ring.

  According to the present invention described above, even if the position in the optical axis direction of the base member that supports the imaging optical system is changed, the position in the optical axis direction of the two members that hold the biasing member for applying friction is not changed. Thus, there is no torque fluctuation during angle adjustment due to position adjustment in the optical axis direction, and a lens barrel position adjustment mechanism with excellent adjustment operability can be obtained. In addition, this position adjusting mechanism can be configured with almost the same number of parts as the angle-adjustable mount structure in the conventional lens barrel, and the structure is simple.

It is a side view which made the upper half of the lens barrel which concerns on the 1st Embodiment of this invention the cross section. It is sectional drawing to which the mount part vicinity of the lens barrel was expanded. It is a front perspective view of the rear decorative ring constituting the lens barrel. It is a back perspective view of the rear cosmetic ring which comprises the lens barrel. It is a front perspective view of the mount fixing ring which comprises the lens barrel. It is a back perspective view of the mount fixing ring which comprises the lens barrel. It is a front perspective view of the mount ring which comprises the lens barrel. It is a back perspective view of the mount ring which comprises the lens barrel. It is a front perspective view of the mount space ring which comprises the lens barrel. It is a back perspective view of the mount space ring which comprises the lens barrel. It is the side view which made the upper half of the lens barrel which concerns on the 2nd Embodiment of this invention a cross section. It is sectional drawing to which the mount part vicinity of the lens barrel was expanded. It is sectional drawing to which the mount part vicinity of the lens-barrel which concerns on the 3rd Embodiment of this invention was expanded.

  FIG. 1 shows the overall structure of a lens barrel 10 to which a position adjusting mechanism according to the present invention is applied. The lens barrel 10 is a variable magnification lens barrel for a CCTV camera, and includes a front group lens L1, an aperture blade S, and a rear group lens L2 as optical elements of the imaging optical system. In the following description, the direction along the optical axis O of the imaging optical system is referred to as the optical axis direction, the subject side is referred to as the front, and the image plane side is referred to as the rear.

  The lens barrel 10 includes a fixed frame 11 that is a base member that supports the entire imaging optical system. The fixed frame 11 is formed with rectilinear guide grooves for linearly guiding the front group holding frame 12 for holding the front group lens L1 and the rear group holding frame 13 for holding the rear group lens L2 in the optical axis direction. The fixed frame 11 includes a large-diameter cylindrical portion 11a positioned in front of the optical axis direction, and a small-diameter cylindrical portion 11b that is smaller in diameter than the large-diameter cylindrical portion 11a and positioned rearward in the optical axis direction. The front cam ring 14 formed with a cam groove for controlling the movement of the front group holding frame 12 (front group lens L1) in the optical axis direction is rotatably supported, and the rear group holding is provided outside the small-diameter cylindrical portion 11b. A rear cam ring 15 formed with a cam groove for controlling the movement of the frame 13 (rear group lens L2) in the optical axis direction is rotatably supported. The front cam ring 14 and the rear cam ring 15 are integrally rotated by a rotation operation of a magnification change ring 16 that supports a magnification change operation lever 17, and the front group holding frame 12 (front group lens L1) and the rear group are rotated by the rotation. The holding frame 13 (rear group lens L2) is moved in the optical axis direction along a predetermined locus by the respective cam grooves, whereby the focal length is changed. Further, the front cam ring 14 is relatively rotatable and integrated in the optical axis direction with respect to the focus ring 20 supported on the outside of the large-diameter cylindrical portion 11a via a focus screw 19. When the focus ring 20 is rotated via the focus lever 21, the focus ring 20 and the front cam ring 14 are moved in the optical axis direction according to the focus screw 19, and together with the front cam ring 14, the front group holding frame 12 (front group lens L1). ) Is also moved in the optical axis direction. Thereby, focusing is performed. The automatic diaphragm meter 22 including the diaphragm blades S is inserted and supported in a slit portion 11c formed between the large diameter cylindrical portion 11a and the small diameter cylindrical portion 11b of the fixed frame 11. Therefore, all of the optical elements constituting the imaging optical system of the lens barrel 10 and the members related to the support and driving of these optical elements are finally supported by the fixed frame 11.

  A relay fixing ring 26 is fixed to the fixing frame 11 via fixing screws 25. The relay fixing ring 26 has an annular shape surrounding the rear cam ring 15, and a rear decorative ring 28 is fixed to the rear portion of the relay fixing ring 26 via a fixing screw 27. That is, the fixed frame 11, the relay fixing ring 26, and the rear decorative ring 28 are integrated, and the relay fixing ring 26 and the rear decorative ring 28 in addition to the fixed frame 11 also support the entire imaging optical system. Is configured. A mount ring 30 that can be screwed and fixed to a body mount of a camera body (not shown) is provided at the rear end of the lens barrel 10, and a lens for the mount ring 30 is interposed between the mount ring 30 and the rear decorative ring 28. A support structure that allows position adjustment of the entire lens barrel 10 in the optical axis direction and angle adjustment in the rotation direction of the optical axis center is provided. The support structure will be described mainly with reference to FIG.

  As shown in FIGS. 3 and 4, the rear decorative ring 28 has an annular front flange portion (a base member side facing portion, a second flange portion) 28a having three screw insertion holes 28f through which the fixing screw 27 is inserted. An outer cylindrical portion 28b that protrudes rearward from the outer diameter portion of the front flange portion 28a, an inner cylindrical portion 28c that protrudes rearward from the inner diameter portion of the front flange portion 28a and surrounds the outer side of the rear cam ring 15, and an inner cylindrical portion. 28c has an annular rear flange portion 28d that projects from the rear end portion 28c toward the inner diameter direction. By supporting the inner peripheral portion of the rear flange portion 28 d on the outer peripheral surface of the small diameter cylindrical portion 11 b of the fixed frame 11, the rear decorative ring 28 is positioned concentrically with respect to the fixed frame 11.

  An adjustment screw (variable coupling means, screw threaded portion) 28e is formed on the outer peripheral portion of the outer cylindrical portion 28b of the rear decorative ring 28. As shown in FIG. 2, a mount fixing ring (presser) is attached to the adjustment screw 28e. An adjustment screw (variable coupling means, screw threaded portion) 29c formed on the member 29 is threaded. As shown in FIGS. 5 and 6, the mount fixing ring 29 includes a cylindrical portion 29 a having an adjustment screw 29 c formed on the inner peripheral surface, and an annular shape protruding from the rear end portion of the cylindrical portion 29 a toward the inner diameter direction. The rear flange portion (opposing portion on the pressing member side, third flange portion) 29b is provided.

  As shown in FIG. 2, the mount ring 30 is supported on the outer peripheral surface of the inner cylindrical portion 28 c of the rear decorative ring 28. The mount ring 30 includes an adjustment washer (variable coupling means, spacer) 31, a mount space ring (pressing member) 32, and a mount spring (biasing member) 33, as well as the front flange portion 28a of the rear decorative ring 28 and the mount fixing ring 29. It is sandwiched and held between the rear flange portions 29b.

  Specifically, as shown in FIGS. 7 and 8, the front end portion of the mount ring 30 has an annular front flange portion (optical axis direction position reference portion, first flange portion) 30 a protruding in the outer diameter direction. The rear surface of the front flange portion 30 a is in contact with the front surface of the rear flange portion 29 b of the mount fixing ring 29. The contact surfaces of the front flange portion 30a and the rear flange portion 29b are both planes orthogonal to the optical axis O. Further, the cylindrical portion 30b protrudes rearward from the inner diameter portion of the front flange portion 30a, and the inner peripheral surface of the cylindrical portion 30b is supported on the outer peripheral surface of the inner cylindrical portion 28c of the rear decorative ring 28 ( Figure 2). As far as the relationship between the rear decorative ring 28 and the mount ring 30 is concerned, the relative movement in the optical axis direction and the relative movement about the optical axis O are between the outer peripheral surface of the inner cylindrical portion 28c and the inner peripheral surface of the cylindrical portion 30b. Although it has a sliding contact relationship that allows rotation, in the normal use state of the lens barrel 10 by the structure described below, the relative movement and relative rotation of the rear decorative ring 28 and the mount ring 30 in the optical axis direction. Is regulated. The mount ring 30 has a mount screw 30c formed on the outer peripheral surface of the cylindrical portion 30b. The mount screw 30c is screwed into a body-side mount screw (not shown) provided in the camera body. , Fixed to the camera body.

  As shown in FIGS. 9 and 10, the mount space ring 32 includes an annular front flange portion (fourth flange portion) 32a and a cylindrical portion 32b protruding rearward from the outer diameter portion of the front flange portion 32a. Have As shown in FIG. 2, the front flange portion 32 of the mount space ring 32 is located between the rear surface of the front flange portion 28a of the rear decorative ring 28 and the front surface of the front flange portion 30a of the mount ring 30 in the optical axis direction. ing. Further, the rear end portion of the cylindrical portion 32 b can contact the rear flange portion 29 b of the mount fixing ring 29. The cylindrical portion 32 b is further positioned between the outer cylindrical portion 28 b of the rear decorative ring 28 and the outer peripheral portion of the front flange portion 30 a of the mount ring 30 in the radial direction of the lens barrel.

  The adjustment washer 31 is formed of an annular body having the optical axis O as the center, and is sandwiched between the rear surface of the front flange portion 28 a of the rear decorative ring 28 and the front surface of the front flange portion 32 a of the mount space ring 32. The clamping surfaces of the adjustment washers 31 in the front flange portions 28a and 32a are both planes orthogonal to the optical axis O. Similar to the adjustment washer 31, the mount spring 33 has an annular shape with the optical axis O as the center, and is inserted between the rear surface of the front flange portion 32 of the mount space ring 32 and the front surface of the front flange portion 30 a of the mount ring 30. The The contact surfaces of the mount springs 33 in the front flange portions 32a and 30a are both planes orthogonal to the optical axis O. The mount spring 33 is composed of a wave washer or the like that can be elastically deformed in the optical axis direction, and applies a biasing force in a direction that separates the mount ring 30 and the mount space ring 32 from each other in the optical axis direction. That is, the mount space ring 32 is pressed forward (leftward in FIG. 2) against the mount ring 30 fixed to the camera body, and the rear decorative ring 28 is also moved forward via the adjustment washer 31. A biasing force acts. Here, the mount fixing ring 29 coupled to the rear decorative ring 28 via the adjusting screws 28e and 29c is restricted from moving forward relative to the mount ring 30 when the rear flange portion 29b abuts against the front flange portion 30a. That is, the rear decorative ring 28, the mount fixing ring 29, the adjustment washer 31 and the mount space ring 32 are each held at the optical axis direction position shown in FIG. 2 with respect to the mount ring 30 by the urging force of the mount spring 33. The support structure in which relative rotation is allowed between the rear decorative ring 28 and the mount ring 30 as described above is obtained by the pressing force of the mount spring 33 in a state where no special external force is applied. The angular position of the rear decorative ring 28 and the mount fixing ring 29 with respect to the mount ring 30 is kept constant by friction (friction engagement). That is, the portion from the mount ring 30 to the mount fixing ring 29, the rear decorative ring 28, the relay fixing ring 26, and the fixing frame 11 is fixedly supported with respect to the camera body in the normal use state of the lens barrel 10. It becomes.

  In the lens barrel 10 having the above configuration, when angle adjustment in the rotation direction around the optical axis O is performed, the entire lens barrel is pushed rearward in the optical axis direction (camera main body side) with respect to the camera main body. This pushing force acts as a force for displacing the rear decorative ring 28 and the mount fixing ring 29 coupled to the rear portion of the fixed frame 11 to the right in FIG. The mount fixing ring 29 is restricted to move to the left (front in the optical axis direction) in FIG. 2 by the front flange portion 30a of the mount ring 30, but is not restricted to move to the right. The entire lens barrel 10 excluding the mount ring 30 is moved rearward against the urging force of the mount spring 33 (while compressing the mount spring 33). Then, since the frictional coupling between the rear decorative ring 28 and the mount fixing ring 29 and the mount ring 30 is eliminated, the force of the rotation direction is applied while maintaining the backward pushing, so that the base of the lens barrel 10 can be obtained. The angle of the rear decorative ring 28 and the fixed frame 11 constituting the member can be adjusted. When the angle adjustment is completed, the backward pushing of the lens barrel 10 in the optical axis direction is released. Then, the urging force of the mount spring 33 returns to the angle fixed state in which the rear decorative ring 28 and the mount fixing ring 29 are friction-coupled to the mount ring 30.

  In the lens barrel 10, so-called flange back adjustment that changes the position of the entire imaging optical system relative to the imaging surface in the optical axis direction is also possible. When adjusting the flange back, the width (thickness) in the optical axis direction occupied by the adjustment washer 31 inserted between the rear decorative ring 28 and the mount space ring 32 is changed. For example, when the imaging optical system is displaced forward (subject side) from the state of FIG. 2, the adjustment washer 31 is replaced with a thicker (plate thickness) thicker than that of FIG. 2. Alternatively, the number of adjustment washers 31 to be inserted may be increased. In other words, regardless of the number of sheets to be inserted, the width in the optical axis direction occupied by the entire adjustment washer 31 to be inserted is increased. The rear decorative ring 28 is restricted from moving forward by the engagement of the rear flange portion 29b of the mount fixing ring 29 and the front flange portion 30a of the mount ring 30, and can simply replace the adjustment washer 31 or increase the number of the washers. Since the rear decorative ring 28 cannot be displaced forward simply by changing the screwing amount of the adjusting screws 28e and 29c according to the change in the width (thickness) in the optical axis direction occupied by the adjusting washer 31, The rear decorative ring 28 is moved forward relative to the mount fixing ring 29. As a specific work, until the inserted thick washer (or the increased number) adjustment washer 31 is securely clamped by the rear decorative ring 28 and the front flange portions 28a, 32a of the mount space ring 32 without play. The adjustment screws 28e and 29c are tightened. With the above operation, the position of the rear decorative ring 28 and the fixing frame 11 fixed to the front portion thereof with respect to the mount fixing ring 29 changes forward. That is, the flange back adjustment in the direction (front) in which the rear end of the imaging optical system is separated from the imaging surface is performed. Conversely, in the flange back adjustment in the direction in which the imaging optical system approaches the imaging surface (backward), the adjustment washers 31 to be inserted are thinned or the number of adjustment washers 31 to be inserted is reduced. The width in the optical axis direction occupied by 31 is reduced. Then, when the adjustment screws 28e and 29c are tightened to a position where the adjustment washer 31 is securely clamped by the rear decorative ring 28 and the mount space ring 32 front flange portions 28a and 32a without play, the mount fixing ring 29 is The position of the rear decorative ring 28 and the fixed frame 11 fixed to the front part thereof in the optical axis direction changes backward.

  When adjusting the flange back of the lens barrel 10 as described above, the positions of the fixing frame 11 and the rear decorative ring 28 in the optical axis direction change, but the position of the mount fixing ring 29 in the optical axis direction does not change as described above. The mount space ring 32 abuts against the rear flange portion 29b of the mount fixing ring 29, and the rearward movement is restricted, and the forward movement is restricted by being applied to the adjustment washer 31 (adjustment washer). Even if the thickness of 31 is changed, the position on the rear surface side does not change). Therefore, the position of the mount space ring 32 in the optical axis direction does not change. Since the mount spring 33 is supported between the mount space ring 32 and the mount ring 30 whose position in the optical axis direction does not change, the load due to the mount spring 33 does not change even when the flange back adjustment is performed. Kept. Therefore, the operation torque at the time of angle adjustment in the lens barrel 10 does not change due to the influence of the flange back adjustment, and excellent adjustment workability can be obtained. Since the lens barrel 10 of this embodiment is an operation mode in which the lens barrel 10 is rotated while being pushed into the camera main body when adjusting the angle, it is easy to apply a force, and this is excellent in adjustment workability.

  11 and 12 show a lens barrel 110 according to the second embodiment of the present invention. Parts that are not particularly mentioned in the lens barrel 110 are assumed to have the same structure as the lens barrel 10 of the first embodiment described above, and the description of the overlapping parts is omitted. In the first embodiment, the mount spring 33 is sandwiched between the front flange portion 32a of the mount space ring 32 and the front flange portion 30a of the mount ring 30, whereas in the second embodiment, the mount ring Mount spring between 30 front flange part (optical axis position reference part, first flange part) 130a and rear end flange part (opposing part on the pressing member side, third flange part) 129b of mount fixing ring 29 The point that 133 is clamped is different. The rear surface of the front flange portion (fourth flange portion) 132a of the mount space ring 32 abuts against the front surface of the front flange portion 130a of the mount ring 30, so that the mount space ring 32 is moved rearward with respect to the mount ring 30. Movement is restricted. Both the front surface of the front flange portion 130a and the rear surface of the front flange portion 132a are planes orthogonal to the optical axis O. The adjustment washer 31 is sandwiched between the front surface of the front flange portion 132a of the mount space ring 32 and the rear surface of the front flange portion (opposite portion on the base member side, second flange portion) 128a of the rear decorative ring 28. Further, the rear end portion of the cylindrical portion 32 b of the mount space ring 32 abuts against the front surface of the rear end flange portion 129 b of the mount fixing ring 29. In the above configuration, the rearward movement of the mount space ring 32 is restricted by the front flange portion 130a of the mount ring 30, so that the rear decorative ring 28 positioned in front of the mount space ring 32 with the adjustment washer 31 interposed therebetween, Backward movement of the mount fixing ring 29 screwed with the rear decorative ring 28 is also restricted.

  The rear surface of the front flange portion 130a and the front surface of the rear end flange portion 129b sandwiching the mount spring 133 are also planes orthogonal to the optical axis O, and receive a biasing force in a direction away from each other by the mount spring 133. That is, the mount spring 133 presses the mount fixing ring 29 toward the rear (right side in FIG. 12) against the mount ring 30 fixed to the camera body, and the mount spring 133 is mounted via the adjusting screws 28e and 29c. A rearward biasing force also acts on the rear decorative ring 28 that is screwed to the fixing ring 29. Then, the mount space ring 32 is pressed rearward via the adjustment washer 31, and the front flange portion 132a abuts against the front flange portion 130a. As described above, the front space portion 130a is moved backward by the front flange portion 130a. Be regulated. That is, the rear decorative ring 28, the mount fixing ring 29, the adjustment washer 31, and the mount space ring 32 are each held at the optical axis direction position shown in FIG. 12 with respect to the mount ring 30 by the urging force of the mount spring 133. In a state where no special external force is applied, the angular positions of the rear decorative ring 28 and the mount fixing ring 29 with respect to the mount ring 30 are kept constant by the friction (friction engagement) obtained by the pressing force of the mount spring 133.

  In the lens barrel 110, when angle adjustment in the rotation direction about the optical axis O is performed, the entire barrel is pulled forward in the optical axis direction with respect to the camera body. This pulling force acts as a force for displacing the rear decorative ring 28 and the mount fixing ring 29 coupled to the rear portion of the fixing frame 11 to the left in FIG. The mount fixing ring 29 is restricted to move to the right (backward in the optical axis direction) of the figure by the front flange portion 130a of the mount ring 30 with the adjustment washer 31 and the mount space ring 32 interposed therebetween. Since the movement to the left (front in the optical axis direction) with respect to the lens is allowed, the lens mirror excluding the mount ring 30 against the urging force of the mount spring 133 (while compressing the mount spring 133) by the pulling force The entire cylinder 110 is moved forward. Then, since the friction coupling between the mount space ring 32 (and the rear decorative ring 28 and the mount fixing ring 29) and the mount ring 30 is eliminated, a force in the rotational direction is applied while maintaining the forward pull. The angle of the rear decorative ring 28 and the fixed frame 11 constituting the base member of the lens barrel 110 can be adjusted. When the angle adjustment is completed, the forward pulling of the lens barrel 110 in the optical axis direction is released. Then, the biasing force of the mount spring 133 returns to the angle fixed state in which the rear decorative ring 28, the mount fixing ring 29, and the mount space ring 32 are friction-coupled to the mount ring 30.

  In the lens barrel 110, similarly to the lens barrel 10 described above, the width (thickness) in the optical axis direction occupied by the adjustment washer 31 is changed, and the screwing amounts of the adjustment screws 28e and 29c are changed accordingly. It is possible to adjust the flange back. The mount space ring 32 is restricted from moving backward by applying the front flange portion 132 a to the front flange portion 130 a of the mount ring 30, and is restricted from applying forward movement to the adjustment washer 31. Therefore, even if the flange back adjustment is performed, the position of the mount space ring 32 in the optical axis direction does not change. In addition, the mount fixing ring 29 is similarly maintained at a constant position in the optical axis direction by bringing the rear end flange portion 129b into contact with the cylindrical portion 32b of the mount space ring 32. Since the mount spring 133 is supported between the mount fixing ring 29 and the mount ring 30 whose position in the optical axis direction does not change, the load due to the mount spring 133 does not change even when the flange back adjustment is performed.

  FIG. 13 shows the vicinity of the mount portion of the lens barrel 40 according to the third embodiment of the present invention. The imaging optical system of the lens barrel 40 has a rear group lens L2 ′ appearing in FIG. 13 and a front group lens (not shown) positioned in front of the rear group lens L2 ′. The fixed frame 41 is a base member corresponding to the fixed frame 11 and the rear decorative ring 28 of the first and second embodiments, and all the components of the imaging optical system including the front group lens and the rear group lens L2 ′ are Finally, it is supported by the fixed frame 41. Specifically, the fixed frame 41 includes a cylindrical portion 41a that surrounds the optical axis O of the imaging optical system, and an annular outer diameter flange portion that protrudes from the cylindrical portion 41a in the outer diameter direction (an opposing portion on the base member side, a first portion). A helicoid portion 41c that is screwed into the rear group holding frame 42 is formed on the inner peripheral surface of the cylindrical portion 41a. The rear group holding frame 42 is given a rotational force about the optical axis O by a rotation transmission member (not shown), and when rotated, the rear group holding frame 42 is moved in the optical axis direction according to the helicoid portion 41c.

  An adjustment screw (variable coupling means, screw threaded portion) 41d is formed on the outer peripheral portion of the outer diameter flange portion 41b of the fixed frame 41, and the adjustment formed on the mount fixing ring (pressing member) 44 with respect to the adjustment screw 41d. A screw (variable coupling means, screw threaded portion) 44d is threaded. The mount fixing ring 44 includes a cylindrical portion 44a having an adjustment screw 44d formed on the inner peripheral surface, and an intermediate flange portion (third flange portion) located at the rear portion of the cylindrical portion 44a and projecting in the inner diameter direction from the cylindrical portion 44a. ) 44b and a rear flange portion (opposing portion on the pressing member side, fourth flange portion) 44c which is located behind the intermediate flange portion 44b and protrudes further in the inner diameter direction than the intermediate flange portion 44b.

  A mount ring 45 is supported on the outer peripheral surface near the rear end of the cylindrical portion 41 a of the fixed frame 41. The front end portion of the mount ring 45 is provided with an annular front flange portion (optical axis direction position reference portion, first flange portion) 45a protruding in the outer diameter direction, and the rear surface of the front flange portion 45a is a mount fixing ring. The front flange 44 faces the front surface of the rear flange portion 44c. Further, a cylindrical portion 45 b protrudes rearward from the inner diameter portion of the front flange portion 45 a, and the inner peripheral surface of the cylindrical portion 45 b is supported on the outer peripheral surface of the cylindrical portion 41 a of the fixed frame 41. As long as the relationship between the fixed frame 41 and the mount ring 45 is limited, relative movement in the optical axis direction and relative rotation about the optical axis O are performed between the outer peripheral surface of the cylindrical portion 41a and the inner peripheral surface of the cylindrical portion 45b. Although it has an allowed sliding contact relationship, as will be described below, in the normal use state of the lens barrel 40, the relative movement and relative rotation of the fixed frame 41 and the mount ring 45 in the optical axis direction are restricted. The In the mount ring 45, a mount screw 45c is formed on the outer peripheral surface of the cylindrical portion 45b, and this mount screw 45c is screwed into a screw (not shown) of a body side mount provided on the main body of the camera. , Fixed to the camera body.

  An adjustment washer (variable coupling means, spacer) 46 is sandwiched between the front surface of the front flange portion 45a of the mount ring 45 and the intermediate flange portion 44b of the mount fixing ring 44 and the rear surface of the outer diameter flange portion 41b of the fixing frame 41. Is done. These clamping surfaces for the adjustment washer 46 are all planes orthogonal to the optical axis O, and the front surface of the front flange portion 45a of the mount ring 45 and the front surface of the intermediate flange portion 44b of the mount fixing ring 44 are in the optical axis direction. Are located on the same plane. The adjustment washer 46 is formed of an annular body having the optical axis O as the center, and the outer periphery from the inner periphery thereof so that the front flange portion 45a of the mount ring 45 and the intermediate flange portion 44b of the mount fixing ring 44 abut simultaneously. The radial size to the part is set.

  Also, a mount spring (biasing member) 47 having an annular shape with the optical axis O as the center is provided between the rear surface of the front flange portion 45 a of the mount ring 45 and the front surface of the rear flange portion 44 c of the mount fixing ring 44. Has been inserted. The contact surfaces of the mount springs 47 in the front flange portion 45a and the rear flange portion 44c are both planes orthogonal to the optical axis O. The mount spring 47 is constituted by a wave washer or the like that can be expanded and contracted in the optical axis direction, and applies a biasing force in a direction in which the mount fixing ring 44 and the mount ring 47 are separated from each other in the optical axis direction. That is, the mount fixing ring 44 is pressed rearward (rightward in FIG. 11) against the mount ring 45 fixed to the camera body, and is fixed to the fixed frame 41 coupled via the adjustment screws 41d and 44d. Also, a rearward biasing force acts. Here, the rearward movement of the mount fixing ring 44 is restricted via an adjustment washer 46 that is in contact with the front flange portion 45 a of the mount ring 45. That is, the fixed frame 41 and the mount fixing ring 44 are each held at the optical axis direction position shown in FIG. 11 with respect to the mount ring 45 by the urging force of the mount spring 47. As described above, the fixed frame 41 and the mount ring 45 have a support structure in which relative rotation is permitted. However, in a state where no special external force is applied, the friction (friction) obtained by the pressing force of the mount spring 47 is obtained. By engaging), the angular positions of the fixing frame 41 and the mount fixing ring 44 with respect to the mount ring 45 are kept constant. That is, the portion from the mount ring 45 to the mount fixing ring 44 and the fixing frame 41 is a portion that is fixedly supported with respect to the camera body in the normal use state of the lens barrel 40.

  In the lens barrel 40 having the above configuration, when angle adjustment in the rotation direction around the optical axis O is performed, the entire barrel is pulled forward in the optical axis direction with respect to the camera body. This pulling force acts as a force that displaces the fixed frame 41 and the mount fixing ring 44 to the left in FIG. The movement of the fixed frame 41 to the right side (back in the optical axis direction) of FIG. 11 is restricted by the front flange portion 45a of the mount ring 45, but the movement to the left side is not restricted. The entire lens barrel 40 excluding the mount ring 45 is moved rearward against the urging force of the mount spring 47 (while compressing the mount spring 47). Then, since the frictional coupling between the fixed frame 41 and the mount fixing ring 44 and the mount ring 45 is eliminated, the base of the lens barrel 40 is applied by applying a force in the rotational direction while maintaining the forward pulling state. The angle of the fixed frame 41 constituting the part can be adjusted. When the angle adjustment is completed, the forward pulling of the lens barrel 40 in the optical axis direction is released. Then, the urging force of the mount spring 47 returns to an angle fixed state in which the mount ring 45 and the fixed frame 41 are friction-coupled with the adjustment washer 46 interposed therebetween.

  When performing the flange back adjustment that changes the optical axis direction position of the entire imaging optical system with respect to the imaging surface in the lens barrel 40, the width in the optical axis direction occupied by the adjustment washer 46 as a whole is increased. For example, when the imaging optical system is displaced forward (subject side) from the state of FIG. 11, thicker adjustment washers 46 than those in FIG. 11 are inserted, or the number of adjustment washers 46 to be inserted is increased. As a result, the position of the fixing frame 41 with respect to the mount ring 45 is displaced forward, but the forward displacement of the mount fixing ring 44 is restricted when the intermediate flange portion 44 b abuts against the adjustment washer 46. At this time, only the fixed frame 41 can be moved forward without changing the position of the mount fixing ring 44 in the optical axis direction by changing the screwing amount of the adjusting screws 41d and 44d. Thereby, the flange back adjustment in the direction (front) in which the rear end of the imaging optical system is separated from the imaging surface is performed. Conversely, in the flange back adjustment in the direction in which the imaging optical system approaches the imaging surface (backward), the adjustment washer 46 is replaced with a thin one or the number of adjustment washers 46 to be inserted is reduced, so that the adjustment washer 46 as a whole The width in the optical axis direction is reduced. Then, the outer diameter flange portion 41 b of the fixed frame 41 approaches the front end flange portion 45 a of the mount ring 45. At that time, the screwing amounts of the adjustment screws 41d and 44d are changed, and the position of the mount fixing ring 44 in the optical axis direction is not changed, and only the fixing frame 41 is relatively moved rearward.

  When adjusting the flange back of the lens barrel 40 described above, the position of the fixing frame 41 in the optical axis direction changes, but the position of the mount fixing ring 44 in the optical axis direction does not change as described above. Since the mount spring 47 is supported between the mount fixing ring 44 and the mount ring 45 whose position in the optical axis direction does not change, the load due to the mount spring 47 is not changed even when the flange back adjustment is performed. Can keep. Therefore, the operation torque at the time of angle adjustment in the lens barrel 40 does not change due to the influence of the flange back adjustment, and excellent adjustment workability can be obtained. Further, the lens barrel 40 of this embodiment does not include a member corresponding to the mount space ring 32 of the lens barrels 10 and 110 of the first and second embodiments, so that it is excellent in that the number of parts is small. ing.

The lens barrel 10 according to the first embodiment, the lens barrel 110 according to the second embodiment, and the lens barrel 40 according to the third embodiment described above are different in detail, but have the following common elements. ing.
1: Biasing members (33, 133, 47) for friction coupling the base members (11 + 26 + 28, 41) supporting the imaging optical system to the mount rings (30, 45) are used as the base members. The pressing member (29 + 32, 44), which is not directly brought into contact but is coupled to the base member so that the position in the optical axis direction can be adjusted, is inserted between the mount ring.
2: At the time of flange back adjustment, the position of only the base member is changed in the optical axis direction without changing the position of the pressing member in the optical axis direction with respect to the mount ring.
By providing a configuration satisfying these common elements, a position adjusting mechanism with excellent operability can be obtained in which the load of the biasing member, that is, the operating torque for angle adjustment does not change even when flange back adjustment is performed.

  In each of the above embodiments, when adjusting the angle of the lens barrel, the mount springs 33, 133, and 47 are mounted by pushing the lens barrel backward in the optical axis direction or pulling the lens barrel forward in the optical axis direction. The lens barrel is held at an angle by these mount springs, but not by mechanical engagement, but by frictional resistance, so the lens barrel is not pushed or pulled in the optical axis direction. It is also possible to adjust the angle by applying only the force in the rotation direction (a force larger than the frictional resistance).

  As mentioned above, although demonstrated based on illustration embodiment, this invention is not limited to this embodiment. For example, the lens barrels 10, 110, and 40 of the embodiment are variable magnification lens barrels with variable focal lengths, but the present invention can also be applied to single focus lenses. In the case of a variable magnification lens barrel, both types of zoom lenses that continuously change the focal length without changing the image plane position and varifocal lenses that change the image plane position according to the change in focal length are used. Applicable. The embodiment is an example applied to a lens barrel for a CCTV camera, but the present invention can also be applied to a lens barrel of a different type of imaging apparatus.

10 Lens barrel 11 Fixed frame (base member)
12 Front group holding frame 13 Rear group holding frame 14 Front cam ring 15 Rear cam ring 16 Scaling ring 20 Focus ring 26 Relay fixing ring (base member)
28 Rear decorative ring (base member)
28a Front flange part (opposite part on the base member side, second flange part)
28b Outer cylindrical part 28c Inner cylindrical part 28d Rear flange part 28e Adjustment screw (variable coupling means, screw threaded part)
29 Mount fixing ring (holding member)
29a Cylindrical portion 29b Rear flange portion (opposing portion on the pressing member side, third flange portion)
29c Adjustment screw (variable coupling means, screw threaded part)
30 Mount ring 30a Front flange part (optical axis direction position reference part, first flange part)
30b Cylindrical part 30c Mount screw 31 Adjustment washer (variable coupling means, spacer)
32 Mount space ring (holding member)
32a Front flange (fourth flange)
32b Cylindrical portion 33 Mount spring (biasing member)
40 Lens barrel 41 Fixed frame (base member)
41a Cylindrical part 41b Outer diameter flange part (opposite part on the base member side, second flange part)
41c Helicoid part 41d Adjustment screw (variable coupling means, screw threaded part)
42 Rear group holding frame 44 Mount fixing ring (pressing member)
44a Cylindrical portion 44b Intermediate flange portion (third flange portion)
44c Rear flange part (opposing part on the pressing member side, fourth flange part)
44d Adjustment screw (variable coupling means, screw threaded portion)
45 Mount ring 45a Front flange part (optical axis direction position reference part, first flange part)
45b Cylindrical part 45c Mount screw 46 Adjustment washer (variable coupling means, spacer)
47 Mount spring (biasing member)
110 Lens barrel 128a Front flange part (opposite part on the base member side, second flange part)
129b Rear end flange portion (opposing portion on the pressing member side, third flange portion)
130a Front flange part (optical axis direction position reference part, first flange part)
132a Front flange (fourth flange)
133 mount spring (biasing member)
L1 Front lens group L2 L2 'Rear lens group O Optical axis S Aperture blade

Claims (9)

Mount ring fixed to the camera body;
A base member that supports the imaging optical system and is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction;
A pressing member that forms a pair of opposing portions spaced apart in the optical axis direction with the base member, and that positions the optical axis position reference portion provided on the mount ring between the opposing portions;
Variable coupling means for coupling the base member and the pressing member to adjust the distance in the optical axis direction of the pair of opposing portions; and an optical axis space between the pressing member and the mount ring; The deformable member is inserted and urged in the direction of the optical axis so that either one of the opposed portions that are paired with the reference position portion of the mount ring in the direction of the optical axis approaches each other. And a biasing member that imparts friction that restricts the relative rotation between the base member and the mount ring;
With
When adjusting the position of the imaging optical system in the optical axis direction, the variable coupling means inserts the light into which the biasing member is inserted without changing the position of the pressing member in the optical axis direction with respect to the mount ring. A position adjusting mechanism for a lens barrel, wherein only the position of the base member in the optical axis direction is changed while maintaining the size of the space in the axial direction. In the position adjustment of the lens barrel according to claim 1, the variable coupling means includes:
A spacer that is sandwiched between the base member and the pressing member and defines a distance in the optical axis direction between the opposing portions forming the pair;
A screw threaded portion that is formed between the base member and the pressing member and causes a relative position change in the optical axis direction between the base member and the pressing member by relative rotation about the optical axis;
When the position of the imaging optical system in the optical axis direction is adjusted, the optical axis direction width occupied by the spacer is changed, and the screw threaded portion is screwed in accordance with the change in the optical axis direction width of the spacer. A lens barrel position adjusting mechanism characterized by changing a total amount. 3. The lens barrel position adjusting mechanism according to claim 2, wherein the spacer and the urging member are each formed of an annular body centering on the optical axis. In the lens barrel position adjusting mechanism according to claim 2 or 3,
The optical axis direction position reference portion of the mount ring is composed of a first flange portion having front and rear optical axis orthogonal planes,
The base member has a second flange portion positioned facing the front side in the optical axis direction of the first flange portion,
The holding member is
A mount fixing ring having a third flange portion that contacts the rear surface in the optical axis direction of the first flange portion of the mount ring, and supported by the base member via the screw threaded portion;
A fourth flange portion located between the first flange portion of the mount ring and the second flange portion of the base member; and abutment with the third flange portion of the mount fixing ring to fix the mount A mount space ring in which the relative position in the optical axis direction with the ring is kept constant;
Consists of
The spacer is sandwiched between the second flange portion of the base member and the fourth flange portion of the mount space ring, and between the first flange portion of the mount ring and the fourth flange portion of the mount space ring. The biasing member is sandwiched between
A lens barrel position adjusting mechanism, wherein the biasing force of the biasing member biases the base member, the mount space ring, and the mount fixing ring forward in the optical axis direction with respect to the mount ring. In the lens barrel position adjusting mechanism according to claim 2 or 3,
The optical axis direction position reference portion of the mount ring is composed of a first flange portion having front and rear optical axis orthogonal planes,
The base member has a second flange portion positioned facing the front side in the optical axis direction of the first flange portion,
The holding member is
A mount fixing ring having a third flange portion positioned rearward in the optical axis direction of the first flange portion of the mount ring and supported by the base member via the screw thread portion;
A fourth flange portion located between the first flange portion of the mount ring and the second flange portion of the base member, and in contact with the first flange portion of the mount ring in the optical axis direction; A mount space ring whose rearward movement is restricted and which is in contact with the third flange portion of the mount fixing ring and whose relative position in the optical axis direction with the mount fixing ring is kept constant;
Consists of
The spacer is sandwiched between the second flange portion of the base member and the fourth flange portion of the mount space ring, and between the first flange portion of the mount ring and the third flange portion of the mount fixing ring. The biasing member is sandwiched between
A lens barrel position adjusting mechanism, wherein the biasing force of the biasing member biases the base member, the mount space ring, and the mount fixing ring toward the rear in the optical axis direction with respect to the mount ring. In the lens barrel position adjusting mechanism according to claim 2 or 3,
The optical axis direction position reference portion of the mount ring is composed of a first flange portion having front and rear optical axis orthogonal planes,
The base member has a second flange portion positioned facing the front side in the optical axis direction of the first flange portion,
The pressing member includes a third flange portion facing the rear surface in the optical axis direction of the second flange portion of the base member, and a fourth flange facing the rear surface in the optical axis direction of the first flange portion of the mount ring. Comprising a mount fixing ring that is supported by the base member via the screw threaded portion,
The spacer is sandwiched between the second flange portion of the base member, the first flange portion of the mount ring, and the third flange portion of the mount fixing ring,
The biasing member is sandwiched between the first flange portion of the mount ring and the fourth flange portion of the mount fixing ring,
A lens barrel position adjustment mechanism, wherein the biasing force of the biasing member biases the base member and the mount fixing ring forward in the optical axis direction with respect to the mount ring. Mount ring fixed to the camera body;
A base member that supports the imaging optical system and is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction;
A mount fixing ring that is coupled to the base member via a screwed portion so as to be positionally adjustable in the optical axis direction, and that comes into contact with the optical axis position reference portion provided on the mount ring from the rear in the optical axis direction;
A mount space ring that is in contact with the mount fixing ring and whose relative movement relative to the mount fixing ring in the optical axis direction is restricted;
A spacer that is sandwiched between the mount space ring and the base member and restricts relative movement of the mount space ring in the optical axis direction relative to the base member;
Inserted between the mount space ring and the mount ring so as to be elastically deformable in the optical axis direction. The mount space ring, the base member, and the mount fixing ring are urged forward in the optical axis direction with respect to the mount ring. A biasing member that imparts friction that restricts the relative rotation between the member and the mount ring;
With
When adjusting the position in the optical axis direction of the imaging optical system, the optical axis direction width occupied by the spacer is changed, and the screwing amount of the screw screw portion is changed according to the change in the optical axis direction width of the spacer. A position adjusting mechanism for a lens barrel, wherein only the position of the base member in the optical axis direction is changed without changing the position in the optical axis direction of the mount fixing ring and the mount space ring with respect to the mount ring. Mount ring fixed to the camera body;
A base member that supports the imaging optical system and is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction;
A mount fixing ring coupled to the base member via a screwed portion so as to be positionally adjustable in the optical axis direction;
A mount that abuts against the optical axis position reference portion provided on the mount ring from the front in the optical axis direction and abuts against the mount fixing ring to restrict relative movement in the optical axis rearward direction with respect to the mount fixing ring. Space ring;
A spacer that is sandwiched between the mount space ring and the base member and restricts relative movement of the mount space ring in the optical axis direction relative to the base member;
The base ring is inserted between the mount ring and the mount fixing ring so as to be elastically deformable in the optical axis direction. The mount space ring, the base member, and the mount fixing ring are urged rearward in the optical axis direction with respect to the mount ring. A biasing member that imparts friction that restricts the relative rotation between the member and the mount ring;
With
When adjusting the position in the optical axis direction of the imaging optical system, the optical axis direction width occupied by the spacer is changed, and the screwing amount of the screw screw portion is changed according to the change in the optical axis direction width of the spacer. A position adjusting mechanism for a lens barrel, wherein only the position of the base member in the optical axis direction is changed without changing the position in the optical axis direction of the mount fixing ring and the mount space ring with respect to the mount ring. Mount ring fixed to the camera body;
A spacer that comes into contact with the optical axis position reference portion provided on the mount ring from the front in the optical axis direction;
A base member that supports the imaging optical system, is supported so as to be rotatable relative to the mount ring and movable in the optical axis direction, and contacts the spacer from the front in the optical axis direction;
A mount fixing ring that is coupled to the base member via a screwed portion so as to be positionally adjustable in the optical axis direction, and abuts against the spacer from the rear in the optical axis direction;
The base fixing member and the mounting ring are inserted between the mounting fixing ring and the mounting ring so as to be elastically deformable in the optical axis direction, and the mounting fixing ring and the base member are urged rearward in the optical axis direction with respect to the mounting ring. An urging member for imparting friction that restricts the relative rotation between the two;
With
When adjusting the position in the optical axis direction of the imaging optical system, the optical axis direction width occupied by the spacer is changed, and the screwing amount of the screw screw portion is changed according to the change in the optical axis direction width of the spacer. A position adjusting mechanism for a lens barrel, wherein only the position of the base member in the optical axis direction is changed without changing the position of the mount fixing ring in the optical axis direction relative to the mount ring.

Images