JP2022125472A - camera device - Google Patents

Abstract

To provide a camera device with which it is possible to realize two photographing states by a simple and compact structure.SOLUTION: A lens barrel 10 of a camera device 1 includes a rear barrel unit 31 capable of moving forward to a barrel part 22 and a front barrel unit 32 capable of moving from a first position accommodated in the radially inside of the rear barrel unit 31 to a second position stretched forward from the rear barrel unit 31. The front barrel unit 32 has a protrusion 41 that projects to the radially outside. The lens barrel 10 includes a switching spring 60 bridged between a spring axis part 55 formed in the rear barrel unit 31 and the protrusion 41 of the front barrel unit 32. The rear barrel unit 31 has elastic pieces 52A, 52B having salient 53A, 53B for engaging with the protrusion 41 and holding the front barrel unit 32 at a first position, and deformation suppress means for suppressing the elastic deformation of the elastic piece 52B. The switching spring 60 is constituted so that the direction of urging changes depending on the position of the protrusion 41 of the front barrel unit 32.SELECTED DRAWING: Figure 9

Description

The present invention relates to a camera device, and more particularly to a camera device that allows a lens barrel to extend forward along the optical axis direction.

2. Description of the Related Art Conventionally, a camera having a lens barrel extension mechanism that extends a lens barrel forward along the optical axis direction is known (see, for example, Japanese Unexamined Patent Application Publication No. 2002-100002). In such a camera, in order to perform short-distance photography (macro photography) in addition to normal photography, it is necessary to extend the lens barrel further forward than during normal photography. However, the mechanism for extending the lens barrel forward in multiple steps tends to be complicated and requires a large storage space. For this reason, there is a demand for a simple and compact structure for a mechanism for extending the lens barrel further forward than during normal photography.

JP 2014-56009 A

SUMMARY OF THE INVENTION It is an object of the present invention to provide a camera apparatus capable of realizing two photographing states with a simple and compact structure.

According to a first aspect of the present invention, there is provided a camera device capable of realizing two photographing states with a simple and compact structure. This camera device includes a barrel portion and a lens barrel that is movable in an extended direction along the optical axis from a collapsed state housed inside the barrel portion. The lens barrel includes: a first lens barrel unit that can move forward with respect to the barrel portion from a state housed inside the barrel portion in the radial direction; a second lens barrel unit movable from a first position housed to a second position extended forward from the first lens barrel unit. The second lens barrel unit has a protrusion that protrudes radially outward. The lens barrel includes a switching spring bridged between a spring shaft portion formed in the first lens barrel unit and the projection portion of the second lens barrel unit. When the projection of the second lens barrel unit is positioned on the side of the retraction direction opposite to the extending direction from the reference position, the switching spring moves the projection of the second lens barrel unit. When the projecting portion of the second lens barrel unit is biased in the retracting direction and the projecting portion of the second lens barrel unit is located on the extension direction side of the reference position, the projecting portion of the second lens barrel unit is extended. It can rotate about the spring shaft so as to bias it in the direction. The first lens barrel unit includes a first base portion, a first elastic piece extending from the first base portion in the retraction direction, a second base portion, and the first elastic piece. and a second elastic piece extending from the second base portion in the retraction direction at a position away from the spring shaft portion. The first elastic piece projects onto a path of the projection of the second lens barrel unit moving in the extension direction, thereby forming a first projection that restricts movement of the projection in the extension direction. have. The second elastic piece has a second projecting portion that projects onto the path of the projecting portion of the second lens barrel unit and restricts movement of the projecting portion in the extending direction. The first lens barrel unit is configured such that when the protrusion of the second lens barrel unit moves over the second protrusion of the second elastic piece in the extending direction, the second elastic spring is applied. It has deformation suppressing means for suppressing elastic deformation of the piece.

FIG. 1 is a perspective view showing a camera device according to one embodiment of the invention. 2 is an exploded perspective view showing a part of components housed in an internal space formed by the front cover, rear cover, and top cover of the camera device shown in FIG. 1. FIG. FIG. 3 is a perspective view showing a state in which the lens barrel shown in FIG. 2 is maximally extended in the +X direction. 4 is a perspective view showing a normal photographing state of the camera device shown in FIG. 1. FIG. 5 is a perspective view showing a macro shooting state of the camera device shown in FIG. 1. FIG. 6 is a perspective view showing part of the lens barrel in the normal shooting state of FIG. 4. FIG. 7 is a side view of part of the lens barrel of FIG. 6. FIG. 8 is an exploded perspective view of part of the lens barrel of FIG. 6. FIG. FIG. 9 is a side view of part of the lens barrel in the macro photography state of FIG. FIG. 10 is a schematic diagram showing an enlarged part of FIG. FIG. 11 is a schematic diagram showing a modification of the lens barrel shown in FIG.

An embodiment of a camera device according to the present invention will be described in detail below with reference to FIGS. 1 to 11. FIG. 1 to 11, the same or corresponding components are denoted by the same reference numerals, and redundant explanations are omitted. In addition, in FIGS. 1 to 11, the scale and dimensions of each component may be exaggerated, and some components may be omitted. In the following description, unless otherwise specified, terms such as "first" and "second" are used only to distinguish components from each other and indicate a particular rank or order. not a thing

FIG. 1 is a perspective view showing a camera device 1 according to one embodiment of the invention. The camera device 1 in the present embodiment is a camera (instant camera) that uses photographic film that is automatically developed after photographing, but the present invention can of course be applied to other than such an instant camera. In this embodiment, the +X direction in FIG. 1 is referred to as "forward" or "forward", and the -X direction is referred to as "backward" or "rearward" for convenience.

As shown in FIG. 1 , the camera device 1 includes a front cover 2 , a rear cover 3 attached behind the front cover 2 , and a top cover 4 sandwiched between the front cover 2 and the rear cover 3 . A finder window 5 is formed in the front cover 2, and a flash window 6 is arranged adjacent to the finder window 5. - 特許庁A release button 7 is arranged on the -Z direction side of the finder window 5 . A discharge slit 4A extending in the Y direction is formed in the top cover 4, and the developed photographic film is discharged from the discharge slit 4A after photographing.

FIG. 2 is an exploded perspective view showing some of the components housed in the internal space formed by the front cover 2, rear cover 3, and top cover 4. FIG. As shown in FIG. 2, the camera device 1 has a lens barrel 10 housed inside the cylindrical portion 2A (see FIG. 1) of the front cover 2, and a frame 20 to which the lens barrel 10 is attached. ing. The frame 20 includes a substantially rectangular parallelepiped base portion 21 and a cylindrical barrel portion 22 extending forward from the base portion 21 and holding the lens barrel 10 .

The lens barrel 10 in this embodiment has a structure that can be extended in the +X direction. FIG. 3 is a perspective view showing the lens barrel 10 in a state of maximum extension in the +X direction. As shown in FIG. 3 , the lens barrel 10 includes a first barrel portion 11 , a second barrel portion 12 and a third barrel portion 13 . The first tubular portion 11 is movable in the X direction with respect to the barrel portion 22 of the frame 20 , and the second tubular portion 12 is movable in the X direction with respect to the first tubular portion 11 . Also, the third cylindrical portion 13 is movable in the X direction with respect to the second cylindrical portion 12 . In this embodiment, the first barrel portion 11 and the second barrel portion 12 constitute a rear barrel unit 31 (first barrel unit), and the third barrel portion 13 constitutes a front barrel unit 32. (Second barrel unit). A lens (not shown) is housed inside the third cylindrical portion 13 .

As shown in FIG. 3, two engaging projections 14 projecting radially outward are formed at the rear end portion of the first cylindrical portion 11 of the lens barrel 10 . Two guide grooves 24 extending along the direction of the optical axis P (X direction) are formed in the barrel portion 22 of the frame 20 corresponding to the respective engaging projections 14, as shown in FIG. . Each engagement projection 14 of the lens barrel 10 is accommodated inside the guide groove 24 of the barrel portion 22 and engages with the guide groove 24 . The width of the guide groove 24 in the Z direction is slightly larger than the width of the engagement projection 14 in the Z direction. Therefore, the engaging projection 14 is guided by the guide groove 24 and moves in the direction of the optical axis P (X direction) inside the guide groove 24 .

As shown in FIG. 2, near the barrel portion 22 of the frame 20, the operation button 8 is provided while being biased in the +X direction by a coil spring 8A. As shown in FIG. 1, the operation button 8 projects in the +X direction from the front cover 2 in the vicinity of the cylindrical portion 2A of the front cover 2 so that the user can push the operation button 8 in the -X direction. there is When the user pushes the operation button 8 in the -X direction, the engagement projection 14 of the lens barrel 10 is pushed out in the +X direction by the lens barrel extension mechanism 9 attached to the barrel portion 22, and as shown in FIG. The lens barrel 10 is extended in the +X direction (extending direction). When the lens barrel 10 protrudes from the barrel portion 22 in the +X direction in this manner, the power of the camera device 1 is turned on by a switch mechanism (not shown).

The lens barrel extension mechanism 9 includes a lever 9A that pushes the engagement projection 14 in the +X direction in conjunction with the operation button 8, and a torsion coil spring (Fig. not shown). This torsion coil spring biases the engaging projection 14 in the +X direction when the engaging projection 14 moves beyond the predetermined position in the +X direction. It is configured to bias the engaging projection 14 in the -X direction when it moves in the direction. Note that the lens barrel extension mechanism 9 is not limited to a specific one, and may have any structure as long as it can extend the lens barrel 10 in the +X direction.

In this embodiment, when the first cylindrical portion 11 moves in the +X direction with respect to the barrel portion 22, the second cylindrical portion 12 is moved in the +X direction with respect to the first cylindrical portion 11 by a moving mechanism (not shown). It is designed to move. Therefore, as shown in FIG. 4, the second tubular portion 12 is extended from the first tubular portion 11 in the +X direction. The position of the third tubular portion 13 with respect to the second tubular portion 12 in this state will be referred to as the "first position". In this state, the user can perform normal photography (normal photography state). In this normal photographing state, the third barrel portion 13 of the front barrel unit 32 is accommodated radially inside the second barrel portion 12 of the rear barrel unit 31 .

Further, in the present embodiment, the user can manually pull out the third tubular portion 13 further in the +X direction from the second tubular portion 12 in the state shown in FIG. When the third cylindrical portion 13 is pulled out further in the +X direction from the second cylindrical portion 12, as shown in FIG. 5, the second cylindrical portion extends from the first cylindrical portion 11 in the +X direction, The tubular portion 13 is extended in the +X direction from the second tubular portion 12 . The position of the third tubular portion 13 with respect to the second tubular portion 12 at this time is referred to as the "second position". In this state, the user can, for example, perform close-range macro photography (macro photography state).

On the other hand, FIG. 1 shows a state in which the lens barrel 10 is accommodated in the barrel portion 22 of the frame 20, and in this state the lens barrel 10 is the shortest in the X direction. Hereinafter, this state will be referred to as a "collapsed state".

6 is a perspective view showing part of the lens barrel 10 in the normal shooting state of FIG. 4, FIG. 7 is a side view of part of the lens barrel 10 shown in FIG. 6, and FIG. 8 is an exploded perspective view. It is a diagram. As shown in FIGS. 6 to 8, the third barrel portion 13 of the front barrel unit 32 has two cylindrical protrusions 41 and two guide claws 42 protruding radially outward. (Only one of each is shown in FIGS. 6-8).

As shown in FIG. 8, a guide groove 51 extending in the X direction is formed on the inner peripheral surface of the second cylindrical portion 12 of the rear lens barrel unit 31 so as to correspond to the guide claw 42 of the third cylindrical portion 13. It is The guide claws 42 of the third cylindrical portion 13 are engaged with the guide grooves 51 of the second cylindrical portion 12 , and the third cylindrical portion 13 is guided by the guide grooves 51 while moving toward the second cylindrical portion 12 . can be moved in the X direction with respect to

The second cylindrical portion 12 has a first base portion 54A and a second base portion 54B that extend behind the guide groove 51 so as to face each other in a direction perpendicular to the X-axis. A first elastic piece 52A extends like a cantilever in the -X direction from the first base 54A, and a second elastic piece 52B cantilevers in the -X direction from the second base 54B. extended. Therefore, the free end sides (-X direction sides) of these elastic pieces 52A and 52B are elastically deformable. Between these elastic pieces 52A and 52B, a movement space S is formed in which the protrusion 41 of the third cylindrical portion 13 moves. It extends to the outside of the second cylindrical portion 12 through this movement space S.

The first elastic piece 52A and the second elastic piece 52B each have a first projecting portion 53A and a second projecting portion 53B projecting toward the inside of the movement space S near the end on the -X direction side. is doing. These two protrusions 53A and 53B are positioned on the path of the protrusion 41 moving in the X direction, and the width of the movement space S is narrowed by the protrusions 53A and 53B.

The second tubular portion 12 has a contact portion 56 that can contact the second elastic piece 52B on the opposite side of the second projecting portion 53B of the second elastic piece 52B. An extending portion 57 extending toward the side opposite to the second protruding portion 53B is formed at a location where the contact portion 56 of the second elastic piece 52B abuts.

A pin-shaped spring shaft portion 55 protruding radially outward is formed in the vicinity of the first elastic piece 52A of the second tubular portion 12. Around this spring shaft portion 55, for example, a torsion coil spring is formed. One arm portion 61 of the switching spring 60 is wound, and the arm portion 61 of the switching spring 60 and the spring shaft portion 55 are engaged with each other. The end of the other arm portion 62 of the switching spring 60 is wound around the projection 41 of the third cylindrical portion 13 extending to the outside of the second cylindrical portion 12 through the movement space S, Arm 62 of 60 and projection 41 are engaged. That is, between the spring shaft portion 55 of the second cylindrical portion 12 and the projecting portion 41 of the third cylindrical portion 13, the switching spring 60 is bridged so as to be rotatable about the spring shaft portion 55. there is The switching spring 60 is mounted so that the opening angle between the arms 61 and 62 is smaller than the free angle of the switching spring 60 . In the illustrated example, the switching spring 60 is composed of a torsion coil spring, but it can also be composed of another type of spring (for example, a plate spring). In addition, as shown in FIG. 8 , an overhanging portion 43 extends from the tip of the protrusion 41 of the third cylindrical portion 13 , and the switching spring 60 is engaged with the protrusion 41 by the overhanging portion 43 . is prevented from being detached from the protrusion 41.例文帳に追加

Here, in the state shown in FIG. 7, since the arm portion 62 of the switching spring 60 that engages with the projection portion 41 of the third cylindrical portion 13 is located on the -X direction side of the arm portion 61, the third The −X direction component of the biasing force of the switching spring 60 acts on the projecting portion 41 of the cylindrical portion 13 of FIG. Therefore, unless a force exceeding the -X direction component of the biasing force of the switching spring 60 acts on the third cylindrical portion 13, the third cylindrical portion 13 does not move in the +X direction. In addition, in the state shown in FIG. 7, the protrusion 41 of the third cylindrical portion 13 is located in the -X direction relative to the protrusions 53A and 53B of the elastic pieces 52A and 52B of the second cylindrical portion 12, so that the switching spring Even if a force exceeding the -X direction component of the urging force of 60 acts on the third cylindrical portion 13, the projecting portions 53A and 53B of the elastic pieces 52A and 52B do not move the projecting portion 41 of the third cylindrical portion 13 In order for the protrusion 41 of the third cylindrical portion 13 to move in the +X direction beyond the protrusions 53A and 53B of the elastic pieces 52A and 52B, the protrusion of the third cylindrical portion 13 A force is required to elastically deform the elastic pieces 52A and 52B to such an extent that the elastic pieces 52A and 52B can be overcome by the protrusions 53A and 53B of the elastic pieces 52A and 52B. Thus, a certain amount of force is required to move the third cylindrical portion 13 in the +X direction from the state shown in FIG. Therefore, even if some force is applied to the third cylindrical portion 13 when the lens barrel 10 is extended in the +X direction (extending direction) from the collapsed state by the lens barrel extending mechanism 9, the third cylindrical portion 13 can maintain the first position shown in FIG.

As described above, when switching from the normal shooting state to the macro shooting state, the user manually holds the third cylindrical portion 13 (for example, the flange portion 13A) and pulls it out in the +X direction. At this time, the user presses the third tubular portion 13 with a force larger than the force for elastically deforming the elastic pieces 52A and 52B to such an extent that the protrusion 41 of the third cylindrical portion 13 rides over the protrusions 53A and 53B of the elastic pieces 52A and 52B. When the cylindrical portion 13 is pulled out, the projecting portion 41 of the third cylindrical portion 13 moves over the projecting portions 53A and 53B of the elastic pieces 52A and 52B and moves in the +X direction. 9 (the position of the protrusion 41 when the positions of the arm 61 and the arm 62 of the switching spring 60 in the X direction match) , the biasing direction of the switching spring 60 is reversed, and a force in the +X direction is applied from the switching spring 60 to the projecting portion 41 of the third cylindrical portion 13 . Therefore, even if the user does not pull out the third tubular portion 13 in the +X direction, the third tubular portion 13 can move toward the second tubular portion 12 in the +X direction ( direction). Finally, the third cylinder portion 13 moves in the +X direction to a second position where it abuts against a stopper (not shown) of the second cylinder portion 12, and the macro photographing state shown in FIGS. becomes.

As described above, the switching spring 60 in this embodiment moves the projection 41 to the -X direction when the projection 41 of the third cylindrical portion 13 is positioned on the -X direction (collapse direction) side of the reference position R. direction, and when the projecting portion 41 of the third cylindrical portion 13 is located on the +X direction (extension direction) side of the reference position R described above, the projecting portion 41 is biased in the +X direction. It is configured. In addition, in order to urge the protrusion 41 of the third cylindrical portion 13 in the +X direction after the protrusion 41 has passed over the protrusions 53A and 53B of the elastic pieces 52A and 52B, the elastic pieces 52A and 52B It is preferable to set the reference position R on the +X direction (delivery direction) side of the tops of the projections 53A and 53B of 52B.

When changing from the macro shooting state to the normal shooting state or the collapsed state, the user must press the biasing force of the switching spring 60 to be greater than the +X direction component, and furthermore, the protrusion 41 of the third cylindrical portion 13 will be pushed by the elastic pieces 52A and 52B. The third cylindrical portion 13 (for example, the flange portion 13A) is pushed in the -X direction with a force larger than the force that elastically deforms the elastic pieces 52A and 52B to the extent that the projecting portions 53A and 53B are overcome. As a result, the projecting portion 41 of the third cylindrical portion 13 moves over the projecting portions 53A and 53B of the elastic pieces 52A and 52B in the -X direction. At this time, since the projection 41 of the third cylindrical portion 13 is located on the -X direction side of the reference position R shown in FIG. A force in the -X direction acts, and the protrusion 41 of the third cylindrical portion 13 moves to the above-described first position.

Further, in the present embodiment, since the projection 41 of the third cylindrical portion 13 is cylindrical, the friction between the projection 41 of the third cylindrical portion 13 and the projections 53A, 53B of the elastic pieces 52A, 52B is Since it becomes smaller, the movement of the third cylindrical portion 13 in the X direction becomes smoother, and the durability of the projecting portion 41 and the projecting portions 53A and 53B is improved. In addition, the user's operational feeling with respect to the third tubular portion 13 is also improved.

In this embodiment, since the projections 53A and 53B of the two elastic pieces 52A and 52B are arranged to face each other, the projections 53A and 53B of the two elastic pieces 52A and 52B facing each other form the third The projecting portion 41 of the tubular portion 13 can be more reliably held at the first position.

Here, the third tubular portion 13 is attached to the second tubular portion 12 with a slight play in the circumferential direction. In the state shown in FIG. 7 , the protrusion 41 of the third cylindrical portion 13 is biased away from the spring shaft portion 55 by the switching spring 60 . Therefore, when a force acts on the protrusion 41 of the third cylindrical portion 13 in the drawing-out direction, the protrusion 41 moves to the first position near the spring shaft portion 55 due to the play in the circumferential direction described above. The second projecting portion 53B of the second elastic piece 52B, which is farther from the spring shaft portion 55 than the first projecting portion 53A of the elastic piece 52A, comes into contact with the second projecting portion 53B. At this time, if the second elastic piece 52B elastically deforms earlier than the first elastic piece 52A due to contact with the projection 41, the force from the first projection 53A of the first elastic piece 52A and the force from the second projecting portion 53B of the second elastic piece 52B cannot be applied to the projecting portion 41 at the same time. It is conceivable that the holding force of the protrusion 41 by the second protrusion 53B of the elastic piece 52B is reduced.

From this point of view, in the present embodiment, the deformation of the second elastic piece 52B is suppressed by a deformation suppressing means described below, and the first projecting portion 53A of the first elastic piece 52A and the second elastic piece 52B are deformed. The second protrusion 53B of the elastic piece 52B suppresses a decrease in the holding force of the protrusion 41. As shown in FIG.

FIG. 10 is a schematic diagram showing an enlarged part of FIG. As shown in FIG. 10, the width T _B along the optical axis direction (X direction) of the second base portion 54B at the root of the second elastic piece 52B is the width of the first base portion 54B at the root of the first elastic piece 52A. is larger than the width T _A along the optical axis direction of the base portion 54A. With such a configuration, elastic deformation of the second elastic piece 52B is less likely to occur than that of the first elastic piece 52A. Therefore, the second elasticity is maintained until the projection 41 of the third tubular portion 13 contacts both the first projection 53A of the first elastic piece 52A and the second projection 53B of the second elastic piece 52B. Elastic deformation of the piece 52B can be suppressed, and the projecting portion 41 is firmly held by both the first projecting portion 53A of the first elastic piece 52A and the second projecting portion 53B of the second elastic piece 52B. becomes possible. Thus, by making the width of the second base portion 54B along the optical axis direction larger than the width of the first base portion 54A along the optical axis direction, elastic deformation of the second elastic piece 52B is suppressed. A part of the deformation suppressing means can be realized.

Further, in the present embodiment, the length L along the optical axis direction (X direction) from the second base portion 54B to the second projecting portion 53B (the portion in contact with the projecting portion 41) of the second elastic piece 52B _B is shorter than the length L _A along the optical axis direction from the first base portion 54A to the first projecting portion 53A (the portion in contact with the projecting portion 41) of the first elastic piece 52A. With such a configuration, elastic deformation of the second elastic piece 52B is less likely to occur than that of the first elastic piece 52A. That is, as shown in FIG. 11, even when the width of the second base portion 54B is the same as the width T _A of the first base portion 54A, the second base portion 54B extends from the second base portion 54B to the second elastic piece 52B. The length L _B along the optical axis direction to the protruding portion 53B is shorter than the length L _A along the optical axis direction from the first base portion 54A to the first protruding portion 53A of the first elastic piece 52A. By doing so, it is possible to make elastic deformation of the second elastic piece 52B less likely to occur than that of the first elastic piece 52A. Thus, the length L _B along the optical axis direction from the second base portion 54B to the second projecting portion 53B of the second elastic piece 52B is set to the first base portion 54A to the first elastic piece 52A. A part of the deformation suppressing means for suppressing elastic deformation of the second elastic piece 52B can also be realized by making it shorter than the length L _A along the optical axis direction up to the first projecting portion 53A.

Further, as described above, in the present embodiment, the contact portion 56 capable of contacting the second elastic piece 52B is provided on the opposite side of the second projecting portion 53B of the second elastic piece 52B. This abutting portion 56 is formed when the protrusion 41 of the third cylindrical portion 13 contacts the second protrusion 53B of the second elastic piece 52B to elastically deform the second elastic piece 52B. It functions to contact the second elastic piece 52B and suppress the elastic deformation of the second elastic piece 52B. Such abutting portion 56 also constitutes a part of deformation suppressing means for suppressing elastic deformation of the second elastic piece 52B. In this case, in order to more effectively suppress the elastic deformation of the second elastic piece 52B, as in the illustrated example, a second elastic piece 52B is provided at a location where the contact portion 56 of the second elastic piece 52B abuts. It is preferable to form an extension portion 57 that extends toward the opposite side of the projecting portion 53B.

In addition, the terms "front", "forward", "back", "backward", "upper", "upper", "lower", "lower" and other terms indicating positional relationships used in this specification are It is used in relation to the illustrated embodiment and will vary with the relative positioning of the devices.

As described above, according to one aspect of the present invention, there is provided a camera device capable of realizing two photographing states with a simple and compact structure. This camera device includes a barrel portion and a lens barrel that is movable in an extended direction along the optical axis from a collapsed state housed inside the barrel portion. The lens barrel includes: a first lens barrel unit that can move forward with respect to the barrel portion from a state housed inside the barrel portion in the radial direction; a second lens barrel unit movable from a first position housed to a second position extended forward from the first lens barrel unit. The second lens barrel unit has a protrusion that protrudes radially outward. The lens barrel includes a switching spring bridged between a spring shaft portion formed in the first lens barrel unit and the projection portion of the second lens barrel unit. When the projection of the second lens barrel unit is positioned on the side of the retraction direction opposite to the extending direction from the reference position, the switching spring moves the projection of the second lens barrel unit. When the projecting portion of the second lens barrel unit is biased in the retracting direction and the projecting portion of the second lens barrel unit is located on the extension direction side of the reference position, the projecting portion of the second lens barrel unit is extended. It can rotate about the spring shaft so as to bias it in the direction. The first lens barrel unit includes a first base portion, a first elastic piece extending from the first base portion in the retraction direction, a second base portion, and the first elastic piece. and a second elastic piece extending from the second base portion in the retraction direction at a position away from the spring shaft portion. The first elastic piece projects onto a path of the projection of the second lens barrel unit moving in the extension direction, thereby forming a first projection that restricts movement of the projection in the extension direction. have. The second elastic piece has a second projecting portion that projects onto the path of the projecting portion of the second lens barrel unit and restricts movement of the projecting portion in the extending direction. The first lens barrel unit is configured such that when the protrusion of the second lens barrel unit moves over the second protrusion of the second elastic piece in the extending direction, the second elastic spring is applied. It has deformation suppressing means for suppressing elastic deformation of the piece.

With such a configuration, if the protrusion of the second lens barrel unit is positioned on the retraction direction side of the reference position in the retracted state, the switching spring is applied when the lens barrel extends forward from the retracted state. The second lens barrel unit does not move in the extension direction unless a force exceeding the component of the biasing force in the retracting direction acts on the second lens barrel unit, and a force exceeding the component of the biasing force of the switching spring in the retracting direction. is applied to the second lens barrel unit, the holding portion of the extending piece engages the protrusion of the second lens barrel unit, so that the second lens barrel unit is moved in the extending direction. A certain amount of force is required for this. Therefore, even if some force acts on the second lens barrel unit, the second lens barrel unit can maintain the first position, and the first photographing state can be realized.

Further, when the extension piece is elastically deformed to such an extent that the protrusion of the second lens barrel unit rides over the holding portion of the extension piece and the second lens barrel unit is pulled forward, the biasing direction of the switching spring is reversed. Then, a force is applied from the switching spring to the protruding portion of the second lens barrel unit in the extension direction, and the second lens barrel unit can be moved to the second position. can be realized.

Thus, according to the present invention, there are two photographing states, namely, the first photographing state in which the second lens barrel unit is at the first position with respect to the first lens barrel unit, and the second lens barrel unit. The second photographing state in which the barrel unit is at the second position with respect to the first lens barrel unit can be realized with a simple and compact structure.

Further, when the protrusion of the second lens barrel unit moves in the extending direction beyond the second protrusion of the second elastic piece, the elastic deformation of the second elastic piece is suppressed by the deformation suppressing means. Therefore, the second elastic piece is elastically deformed until the projection of the second lens barrel unit contacts both the first projection of the first elastic piece and the second projection of the second elastic piece. can be suppressed. Therefore, it is possible to firmly hold the projection by both the first projection of the first elastic piece and the second projection of the second elastic piece.

At least part of the deformation suppressing means may be realized by making the width of the second base along the optical axis direction larger than the width of the first base along the optical axis direction. , the length along the optical axis direction from the second base to the second projection of the second elastic piece is the first projection of the first elastic piece from the first base It may be realized by making the length shorter than the length along the optical axis direction up to the portion.

At least a part of the deformation suppressing means may be realized by a contact portion capable of coming into contact with the second elastic piece on the opposite side of the second projecting piece portion of the second elastic piece. . In this case, in order to more effectively suppress elastic deformation of the second elastic piece, the second elastic piece may further have an extension portion extending toward the contact portion. good.

In order to urge the protrusion of the second lens barrel unit in the extending direction after the protrusion has passed over the protrusion of the elastic piece, the reference position is set to the first position of the first elastic piece. It is preferable that the top portion of the first protrusion portion and the top portion of the second protrusion portion of the second elastic piece are located on the delivery direction side.

Moreover, it is preferable that the protrusion of the second lens barrel unit is cylindrical. By forming the projection into a cylindrical shape, the friction between the projection of the second lens barrel unit and the projection of the elastic piece is reduced, so that the movement of the second lens barrel unit in the direction of the optical axis is smooth. As a result, the durability of the projecting portion and the projecting portion of the elastic piece is improved. In addition, the user's operational feeling for the second lens barrel unit is also improved.

Although the preferred embodiments of the present invention have been described so far, it goes without saying that the present invention is not limited to the above-described embodiments and may be embodied in various forms within the scope of its technical concept.

1 Camera Device 2 Front Cover 3 Rear Cover 4 Top Cover 5 Viewfinder Window 6 Flash Window 7 Release Button 8 Operation Button 9 Lens Barrel Extension Mechanism 10 Lens Barrel 11 First Cylinder Part 12 Second Cylinder Part 13 Third Cylinder Part 14 engagement protrusion 20 frame 21 base portion 22 barrel portion 24 guide groove 31 rear lens barrel unit (first lens barrel unit)
32 front barrel unit (second barrel unit)
41 projection 42 guide claw 51 guide groove 52A first elastic piece 52B second elastic piece 53A first projection 53B second projection 54A first base 54B second base 55 spring shaft 56 contact Part 57 Extension 60 Switching spring 61, 62 Arm

Claims (7)

a barrel section;
a lens barrel that is movable in an extending direction along the optical axis from a collapsed state housed inside the barrel,
The lens barrel is
a first lens barrel unit that can move forward with respect to the barrel portion from a state housed inside the barrel portion in the radial direction;
A second lens barrel unit movable from a first position accommodated radially inside the first lens barrel unit to a second position extended forward from the first lens barrel unit, a second lens barrel unit having a protrusion projecting radially outward;
A switching spring bridged between a spring shaft formed in the first lens barrel unit and the protrusion of the second lens barrel unit, wherein the protrusion of the second lens barrel unit is positioned on the side of the retraction direction opposite to the extending direction from the reference position, the protrusion of the second lens barrel unit is biased in the retraction direction, and the second lens barrel unit When the projection is located on the extension direction side of the reference position, the projection of the second lens barrel unit is rotatable about the spring shaft so as to bias the projection in the extension direction. a switching spring and
The first lens barrel unit is
a first base;
A first elastic piece extending from the first base portion in the retraction direction, the first elastic piece projecting onto a path of the protrusion of the second lens barrel unit moving in the extension direction to a first elastic piece having a first protrusion that restricts movement in the delivery direction;
a second base;
A second elastic piece extending in the retraction direction from the second base at a position further from the spring shaft than the first elastic piece, the projecting portion of the second lens barrel unit a second elastic piece having a second projecting portion that projects onto the path of the projecting portion and restricts movement of the projecting portion in the delivery direction;
deformation suppression for suppressing elastic deformation of the second elastic piece when the projection of the second lens barrel unit moves in the extension direction beyond the second projection of the second elastic piece having a means
camera equipment. At least part of the deformation suppressing means is realized by making the width of the second base portion along the optical axis direction larger than the width of the first base portion along the optical axis direction. Item 1. The camera device according to item 1. At least a portion of the deformation suppressing means extends the length along the optical axis direction from the second base to the second projecting portion of the second elastic piece from the first base to the first projection. 3. The camera device according to claim 1, which is realized by making the length of said elastic piece shorter than the length of said elastic piece along said optical axis direction to said first projecting portion. The first lens barrel unit further has a contact portion that can contact the second elastic piece on the opposite side of the second projecting portion of the second elastic piece,
At least part of the deformation suppressing means is realized by the contact portion,
A camera device according to any one of claims 1 to 3. 5. The camera device according to claim 4, wherein said second elastic piece further has an extension portion extending toward said contact portion. 6. The reference position is on the delivery direction side of the top of the first protrusion of the first elastic piece and the top of the second protrusion of the second elastic piece. A camera device according to any one of Claims 1 to 3. 7. The camera device according to any one of claims 1 to 6, wherein said protrusion of said second lens barrel unit is cylindrical.

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