JPH07159830A - Collapsible mount type zoom camera - Google Patents

Abstract

PURPOSE:To miniaturize a collapsible mount type zoom camera capable of changing a finder magnification in accordance with variations in a photographing magnification as well. CONSTITUTION:The collapsible mount type zoom camera is provided with a retractive cam barrel 50 rotated around an optical axis to move lens groups 15, 23,... up to just the front of a minimum magnification position from a collapsed position, a zooming cam barrel 60 rotated similarily to move the lens groups from the minimum magnification position to a maximum magnification position, a cam barrel rotating mechanism 70 rotating the collapsible cam barrel 50 in a range where the lens groups can be moved up to the minimum magnification position from the collapsed position and simultaneously, the zooming cam barrel 60 in the range where the lens groups can be moved up to the maximum magnification position from the minimum magnification position, a power varying mechanism 110 allowing a finder 120 to take a power varying action in according with only the rotation of the zooming cam barrel 60. The second lens 23 is moved from the collapsed position to the minimum magnification position by the movement of a lifting frame 80 moved in a direction parallel with the optical axis by the rotation of the collapsible cam barrel 50.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zoom camera capable of changing the photographing magnification and also changing the finder magnification in accordance with the change of the photographing magnification.
The retracted position in which the lens closest to the subject is housed in the main body, the minimum magnification position at which the subject side can shoot images from the collapsed position, and the maximum magnification position at which the subject side can shoot further than the minimum magnification position. The present invention relates to a retractable zoom camera that can be moved to and from.

[0002]

2. Description of the Related Art As a conventional retractable zoom camera, for example, there is one shown in FIG. This collapsible zoom camera can change the shooting magnification and the viewfinder magnification and strobe irradiation angle according to the change of the shooting magnification, and the first lens closest to the subject is housed in the main body. The retractable position, the lowest magnification position at which the subject can take a picture with respect to the retracted position, and the highest magnification position at which the subject can take a picture further than the lowest magnification position. This retractable zoom camera has a lens support tube (not shown in the figure) provided so as to be relatively movable with respect to the camera body in a direction parallel to the optical axis, and an optical system for the camera body. A cam barrel 2 that is relatively rotatable around an axis, a drive motor 1 that rotates the cam barrel 2, and a finder 12 that rotates as the cam barrel 2 rotates.
A variable magnification / variable angle mechanism 5 is provided for causing the strobe 130 to perform the variable magnification operation to 0 and the strobe 130 to perform the irradiation angle changing operation.

The cam barrel 2 is provided with a cam 3 for moving the lens support barrel from the retracted position to the maximum magnification position through the minimum magnification position as the cam barrel 2 rotates, and on the outer periphery thereof. A gear 4 extending in the circumferential direction is formed. The variable power and variable angle mechanism 5 includes a gear group 6 that engages with the gear 4 of the cam barrel 2, a variable power and variable angle cam body 7 that swings due to the operation of the gear group 6, and a moving lens of the finder 120. 121, 122 and guide shafts 116, 117 for guiding the strobe main body 131 to move in a direction parallel to the optical axis. The zooming / changing cam body 7 has finder zooming cams 7a and 7b with which the lens support shafts 126 and 127 that support the moving lenses 121 and 122 of the finder 120 are engaged, and the support shaft 1 of the strobe body 131.
A strobe irradiation angle changing cam 7c with which 34 is engaged is formed.

In this prior art, when changing from the retracted position to the image-capable state (between the lowest magnification position and the highest magnification position), the drive motor 1 is driven and the cam barrel 2 is rotated. With the rotation of the cam barrel 2, the lens support barrel moves from the retracted position to the minimum magnification position, while the zooming / changing cam body 7 swings, and the viewfinder 1 moves.
20 moving lenses 121, 122 and strobe body 13
1 moves in a direction parallel to the optical axis. Further, when the drive motor 1 is driven to rotate the cam barrel 2 in a state capable of photographing, the lens support barrel moves between the minimum magnification position and the maximum magnification position, while the zooming / changing cam is moved. Body 7 swings,
The moving lenses 121 and 122 of the finder 120 and the strobe main body 131 move in a direction parallel to the optical axis, and the finder magnification corresponding to the photographing magnification and the strobe irradiation angle corresponding to the photographing magnification are obtained.

[0005]

However, in such a conventional technique, a finder or a strobe which is sufficient to perform a magnification change / angle change operation in a photographable state can be moved from the retracted position to the minimum magnification position. Even if it does, it will change the magnification and change the angle. Specifically, even when the lens support barrel moves from the retracted position to the minimum magnification position, the zooming / changing cam body 7 swings to move the moving lenses 121 and 122 of the finder 120 and the strobe light. The main body 131 will move. As described above, even in a state in which shooting is not possible, the viewfinder 120 and the strobe 130 perform variable power and variable angle operations.
There is a problem that the range of movement of 21, 122 and the range of movement of the strobe main body 131 are increased, and the zooming / changing angle cam body 7 that secures these movements is also increased, which enlarges the entire camera.

The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a retractable zoom camera capable of downsizing the entire camera.

[0007]

A retractable zoom camera for achieving the above object is a zoom camera capable of changing a photographing magnification and also changing a finder magnification according to a change of the photographing magnification. , In the lens barrel,
The first lens is housed closest to the subject side, the second lens is housed closer to the film than the first lens, and the first lens and the second lens are such that both lenses are located closest to the film and It is possible to move to a retracted position in which one lens is housed in the main body, a minimum magnification position at which the subject side can shoot with respect to the collapsed position, and a maximum magnification position at which the subject side can shoot further than the minimum magnification position. In a retractable zoom camera, the lens barrel includes a first lens support barrel that supports the first lens and is movable relative to the main body in a direction parallel to an optical axis, and the second lens. A second lens support cylinder supported and provided so as to be relatively movable in a direction parallel to the optical axis with respect to the main body, and the first lens support cylinder and the second lens support cylinder not relatively movable with respect to the main body. Fixed on the outer periphery of A retractable cam barrel provided on the outer side of the fixed barrel so as to be rotatable relative to the main body around the optical axis; and an outer side of the fixed barrel rotatable relative to the main body around the optical axis. A zoom cam barrel provided closer to the subject than the retractable cam barrel, and a movable piece provided between the fixed barrel and the retractable cam barrel so as to be movable in a direction parallel to the optical axis, A piece driven protrusion that protrudes in the radial direction with respect to the optical axis is formed on the movable piece, and a first driven protrusion that protrudes in the radial direction with respect to the optical axis is formed in the first lens support cylinder. Then, the second lens supporting cylinder is projected in the radial direction with respect to the optical axis, and is moved in a direction parallel to the optical axis from the retracted position to immediately before the minimum magnification position. Second contacting the moving piece
A driven protrusion is formed, and the first driven protrusion is engageable with the fixed barrel during the movement of the first lens from the retracted position to the maximum magnification position. The first driven guide portion that guides in a direction parallel to the optical axis and the second driven protrusion that can be engaged while the second lens is moved from the retracted position to the maximum magnification position and the second driven portion. A second rectilinear guide portion that guides the protrusion in a direction parallel to the optical axis is formed, and the retractable cam barrel is provided between the retracted position and immediately before reaching the minimum magnification position. A first cam portion, which is engageable with the first driven protrusion portion and spiral with respect to the optical axis, is engaged with the piece driven protrusion portion, and the second lens is moved from the collapsed position to the lowest magnification position. Spiral against the optical axis until just before In a similar manner, an annular piece cam portion is formed in a direction perpendicular to the optical axis except during a period from immediately before reaching the minimum magnification position of the second lens to the minimum magnification position. Is a first cam portion that is engageable with the first driven protrusion and that is spiral with respect to the optical axis while the first lens is moved from the minimum magnification position to the maximum magnification position, and While the second lens is moved from the minimum magnification position to the maximum magnification position, the second driven protrusion is engageable and a second cam portion spirally formed with respect to the optical axis is formed, The retractable cam barrel is rotated within a range in which the lens can be moved from the retracted position to at least just before the minimum magnification position, and the first lens is moved from at least the minimum magnification position to the maximum magnification position. In a range in which the zoom cam barrel can be rotated, a cam barrel rotating mechanism and a scaling mechanism for scaling the viewfinder with only rotation of the zoom cam barrel are provided. Is.

[0008]

In the retracted position, the first driven protrusion formed on the first lens support barrel engages with the first straight guide portion of the fixed barrel and the first cam portion of the retractable cam barrel. . Further, the piece driven protrusion formed on the moving piece is engaged with the piece cam portion of the spiral portion of the piece cam portion of the collapsible cam barrel. Further, the second driven protrusion formed on the second lens support cylinder is in contact with the moving piece and is also engaged with the second linear guide portion of the fixed cylinder. When the cam barrel rotating mechanism is operated in this retracted position, the retractable cam barrel rotates. When the retractable cam barrel rotates,
Since the positions of the cams formed on the cams also change, the first driven protrusions and the piece driven protrusions engaged with these cams move in a direction including a direction component parallel to the optical axis. When the piece driven protrusion moves in the direction including the directional component parallel to the optical axis, the second driven protrusion contacting the piece also moves in the direction including the directional component parallel to the optical axis. At this time, since the first driven protrusion and the second driven protrusion are also engaged with the first straight guide portion and the second straight guide portion of the fixed cylinder, respectively, they are guided by these straight guide portions. , Move in the direction parallel to the optical axis. Thus, as a result of the first driven protrusion and the second driven protrusion moving in the direction parallel to the optical axis, the first lens and the second lens
The lens also moves in a direction parallel to the optical axis.

When the collapsing cam barrel rotates and the first lens and the second lens reach just before the minimum magnification position, the first driven protrusion engaged with the first cam portion of the collapsing cam barrel becomes the zoom cam barrel. Transfer to the first cam part of. In addition, the second driven protrusion that was in contact with the moving piece separates from the moving piece and engages with the second cam portion of the zoom cam barrel. Then, when the minimum magnification position is reached, the cam barrel rotating mechanism starts rotating the zoom cam barrel. By this rotation of the zoom cam cylinder, the first driven protrusion and the second driven protrusion are guided by the corresponding cams and straight guide portions, respectively, as described above, and the first lens and the second lens reach the maximum magnification position. It moves in the direction parallel to the optical axis.

By the way, the variable power mechanism causes the finder to perform a variable power operation only in accordance with the rotation of the zoom cam barrel. Therefore, the zooming mechanism of the viewfinder causes the viewfinder to perform zooming operation from the state of the minimum magnification position where the zoom cam barrel rotates to the state of the maximum magnification position. In other words, the viewfinder zooming mechanism that operates only by rotating the zoom cam barrel, and the viewfinder that zooms using this zooming mechanism operates from the retracted position where shooting is impossible to the state immediately before the minimum magnification position. do not do. Therefore, it is possible to shorten the operation stroke of the movable portion of the finder itself and the operation stroke of the movable portion of the variable power mechanism of the finder, and it is possible to reduce the size of the entire camera.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a retractable zoom camera according to the present invention will be described below with reference to FIGS. As shown in FIG. 1, the retractable zoom camera according to the present embodiment is configured to include a camera body and a retractable lens barrel device in the camera body.

In the lens barrel device, the first lens group 15, the second lens group 23, the second lens group 27, and the third lens group 27, 3 in this order from the object side.
The group lens 36 is stored. The lens barrel device includes a diaphragm ring 85 arranged in front of the first group lens 15 and the first group lens 1
5, a first lens group supporting cylinder 10 supporting the lens 5, and a shutter film 21.
A shutter block 20 for supporting the second lens group front lens 23, a vibration isolation unit 25 for supporting the second lens group rear lens 27 via a lens support ring 26, a helicoid ring 34 for supporting the third lens group 36, and a helicoid A focusing unit 30 that moves the ring 34 in the direction parallel to the optical axis C while rotating the ring about the optical axis, a fixed barrel 40 that is fixed to the main body base 102, and a vibration isolation unit 25 that supports the second lens group rear lens 27. On the other hand, a light blocking tube 87 for blocking a gap when the first group lens tube 10 relatively moves in a direction parallel to the optical axis C, and a fixed tube 40 are provided on the outer periphery of the light blocking tube 87 so as to be rotatable around the optical axis. The zoom cam barrel 60 and the retractable cam barrel 50, the cam barrel rotating mechanism 70 for rotating the zoom cam barrel 60 and the retractable cam barrel 50, the inner peripheral side of the zoom cam barrel 60 and the outer peripheral side of the fixed barrel 40. Between the zoom cam barrel 60 and the collapsing cam barrel 50, the other one of the lift barrels 80, which is provided between the zoom barrel and the retractable cam barrel 50, is rotatable in parallel with the optical axis C. In order to prevent the other cam barrel from rotating, the cam barrel rotation restraining mechanism 90 is provided.

The diaphragm ring 85 is fixed to the first lens group support cylinder 10 so that the light incident on the first lens group 15 can be narrowed to some extent. The shutter block 20 is fixed to the vibration isolation unit 25 with screws 22. Anti-vibration unit 2
5 is a lens support ring 26 to prevent so-called camera shake.
The second lens group 27 has a mechanism (not shown) for moving the rear lens group 27 in the direction perpendicular to the optical axis C. A male helicoid 35 is formed on the outer circumference of the helicoid ring 34 that supports the third group lens 36, and a female helicoid 31 that is screwed into the male helicoid 35 is formed on the inner circumference of the focus unit 30. The focus unit 30 is
It has a mechanism for moving the third lens group 36 together with the helicoid ring 34 in the direction parallel to the optical axis C while rotating the third lens group 36 around the optical axis.

The first-group lens support cylinder 10 has a first-group follower pin 11 projecting in the radial direction (the direction away from the optical axis C) on the most film side. Further, the anti-vibration unit 25 is also formed with a follower pin 28 for the second group, which projects in the radial direction, on the most film side thereof.
Further, the focus unit 30 also has a third group follower pin 32 protruding in the radial direction on the most object side. Each follower pin 11, 28, 32 has a cylindrical portion 12a, 29a, 33a formed on the base side thereof and tapered portions 12b, 29b, 33b formed on the tip end side thereof.

As shown in FIGS. 1 and 4, the fixed barrel 40 has a follower pin 11 for the first group and a follower pin 2 for the second group.
Straight guide holes 41, 42, 43 for guiding the movement of the follower pins 32 for the eighth and third groups in the directions parallel to the optical axis C are formed. Each straight guide hole 41, 42, 43 is long in the direction parallel to the optical axis C and has the longest movement distance.
The long hole has a length corresponding to the moving distance of the group lens 15. Corresponding follower pins 11, 28, 32 are inserted into the respective straight-ahead guide holes 41, 42, 43. Each follower pin 11, 28, 32 has a cylindrical portion 12 a, 29.
a and 33a are in sliding contact with the inner surfaces of the straight guide holes 41, 42 and 43, and the taper portions 12b, 29b and 33b thereof project from the straight guide holes 41, 42 and 43 to the outer peripheral side of the fixed cylinder 40. The fixed barrel 40 includes a fixed barrel 40 for restricting movement of the zoom cam barrel 60 and the collapsible cam barrel 50 in a direction parallel to the optical axis C.
A flange 44 protruding in the outer peripheral direction is formed at the end portion on the film side, and a ring 46 is provided at the end portion on the subject side.

The film thickness of the zoom cam barrel 60 is thin on the film side. Further, the retractable cam barrel 50 has a thin plate on the subject side. The zoom cam barrel 60 and the collapsible cam barrel 50 overlap each other where the plate thicknesses of the two are thin. As shown in FIGS. 1 and 4, the zoom cam barrel 60 and the collapsing cam barrel 50 have tapered portions 12b, 29b, 33 of the follower pins 11, 28, 32, respectively.
Cams 51, 61, 62, 63 with which b is engaged are formed. Each of the cams 51, 61, 62, 63 basically has a spiral shape with respect to the optical axis C.

Cams 61, 62, 63 of the zoom cam barrel 60
As for the inner cams (cams formed on the inner peripheral side of the cylinder and having groove bottoms) 61a, 62 formed in the thick portions (the subject side portion = the inner cam portion 64).
a, 63a and through-cams (cams penetrating from the inner peripheral side to the outer peripheral side of the cylinder) formed in thin portions (film-side portion = through-cam portion 65) 61b, 62
b and 63b. This inner cam 61a, 62
a, 63a and the through cams 61b, 62b, 63b are
So that one follower pin 11, 28, 32 is engaged,
Connected at the ends of both, one cam 61, 62, 63
Is formed. Follower pin 11 for the first group engages 1
The group cam 61 is formed so as to be spiral with respect to the optical axis C from one end to the other. Further, the third group cam 63 with which the third group follower pin 32 is engaged extends completely in the spiral direction with respect to the optical axis C in the inner cam portion 64, and in the through cam portion 65, the subject side is aligned with the optical axis C. On the other hand, it extends in the spiral direction and extends in the direction perpendicular to the optical axis C on the film side. The portion of the cam 63 extending in the direction perpendicular to the optical axis C is referred to as the vertical portion 6
3c. The second group cam 62 engaged with the second group follower pin 28 includes an inner cam portion 64 and a through cam portion 6.
5 extends in the spiral direction with respect to the optical axis C. However, the second-group cam 62 is formed only on a part of the through-cam portion 65 on the subject side. The lift cam 80 is attached to the through-cam portion 65 of the zoom cam barrel 60.
Is formed, and a lift piece storage portion 66 for moving this in a direction parallel to the optical axis C is formed. The lift piece storage section 66 is connected to the film side end of the second group cam 62. A follower pin 81 is formed on the lift piece 80 so as to project in the radial direction with respect to the optical axis C.

The retractable cam barrel 50 is formed with an inner cam 52 with which the follower pin 81 of the lift piece 80 is engaged, and a first-group cam 51 with which the first-group follower pin 11 is engaged. The inner cam 52 has a vertical portion 52b extending in a direction perpendicular to the optical axis C and an oblique portion 52a extending obliquely to the optical axis C. A claw 53 protruding toward the subject is formed at the end of the retractable cam barrel 50 on the subject side. On the other hand, the claw 53 of the retractable cam barrel 50 is provided on the step 67a where the thickness of the zoom cam barrel 60 changes.
A notch 67 is formed in which is inserted. This notch 6
The 7 and the claw 53 are for ensuring the relative rotation of the collapsible cam barrel 50 and the zoom cam barrel 60, while ensuring the integral rotation of the collapsible cam barrel 50 and the zoom cam barrel 60. A sector gear 68 extending in the circumferential direction is formed on the outer peripheral side of the zoom cam barrel 60 and at a step 67a. Further, the retractable cam barrel 50 also has a sector gear 54 extending in the circumferential direction on the outer peripheral side thereof and at the subject side end portion. The positional relationship between the two sector gears 54 and 68 in the circumferential direction will be described when the operation of this embodiment is described.

On the outer peripheral side of the zoom cam barrel 60 and the collapsible cam barrel 50, a cam barrel drive gear 71 that engages with the sector gears 54 and 68 in order to rotate these barrels 50 and 60 around the optical axis, and this cam barrel. Another gear 72 that engages with the drive gear 71, and a drive motor 7 that rotates this gear 72
3 is provided. The cam barrel rotation mechanism 70 is composed of these sector gears 54 and 68, gears 71 and 72, and a cam barrel drive motor 73. As shown in FIG. 3, a slit disc 161 is attached to the drive shaft of the cam barrel drive motor 73, and a photo interrupter 162 is provided so as to face the slit disc 161. The photo interrupter 162 has a light emitting portion on one side of the slit disc 161 and a light receiving portion on the other side of the slit disc 161.
The drive amount of the cam barrel drive motor 73 can be detected by the number of times the light is received by the light receiving portion through the slit 61. That is, the slit plate 161 and the photo interrupter 162 form a drive amount detection sensor 160 that detects the drive amount of the cam barrel drive motor 73.

On the outer peripheral sides of the zoom cam barrel 60 and the collapsible cam barrel 50, the claws 53 of the collapsible cam barrel 50 do not come into contact with the ends of the notches 67 of the zoom cam barrel 60, and both cam barrels 5 are
A rotation restraint mechanism 90 is provided to prevent the other cam barrel from rotating in response to the rotation of one cam barrel when the 0 and 60 are relatively rotatable.

The rotation restraint mechanism 90 includes a zoom cam barrel 90b for restraining the rotation of the zoom cam barrel 60 and a retractable cam barrel 90a for restraining the retractable cam barrel 50 from rotating. The rotation restraint mechanisms 90a and 90b are substantially U-shaped, and have rotation restraint levers 91a and 91b formed with locking ends 92a and 92b at one end and cam follower ends 93a and 93b at the other ends. The locked portions 55a and 69b to which the locking ends 92a and 92b of the rotation restraining levers 91a and 91b are locked, and the rotation restraining levers 91a and 91b.
rotation restricting cams 69a, 55b with which the cam follower ends 93a, 93b of b contact, and rotation restricting levers 91a, 91.
swinging shafts 94a and 94b that swingably support b, and cam follower ends 93a and 9 of the rotation restraining levers 91a and 91b.
3b has a spring 95a, 95b for urging the rotation restraining levers 91a, 91b in a direction in which the rotation restraining cams 69a, 55b abut and the locking ends 92a, 92b move away from the locked portions 55a, 69b. Is configured. In the zoom cam barrel 90b, the rotation restraining cam 55b is formed on the outer peripheral surface of the collapsible cam barrel 50, and the locked portion 69b thereof is provided.
Is formed on the outer periphery of the zoom cam barrel 60. In the retractable cam barrel 90a, the rotation restraining cam 69a is formed on the outer peripheral surface of the zoom cam barrel 60, and the locked portion 55a thereof is provided.
Is formed on the outer peripheral surface of the retractable cam barrel 50. Note that, in FIG. 4, a schematic drawing is provided to facilitate understanding of the operation of the rotation restricting mechanism 90, but in reality, as shown in FIGS. 1 and 8, the rotation restricting lever 91 is provided on both cams. Tube 5
It extends in the direction parallel to the optical axis C so as to extend over 0 and 60, and the swing axis 95 also extends in the direction parallel to the optical axis C. However, in these drawings, only one of the zoom cam barrel 90b and the retractable cam barrel 90a is drawn.

A reset switch 1 for detecting the rotation reference position of the retractable cam barrel 50 and resetting the drive amount of the cam barrel drive motor 73 on the outer peripheral side of the retractable cam barrel 50.
65 is provided. Further, on the outer periphery of the retractable cam barrel 50, a reference position detecting projection 59 for indicating the rotation reference position is provided.
Are formed.

In the above-mentioned lens barrel device, the lift piece 80, the lift piece storage portion 66, the lenses 15, 23,
Each follower pin 11, 28 of the member supporting 36,
32, cam 5 with which these pins 11, 28, 32 engage
Although only one of 1, 61, 62, and 63 is drawn in the figure, in order to ensure a backlash-free operation, three are provided in reality. Further, the first group linear guide holes 41 of the fixed barrel 40, the second group linear guide holes 42, and the third group linear guide holes 43 are also formed in threes corresponding to the numbers of the follower pins 11, 28, 32. ing.

As shown in FIG. 1, the main body includes a control circuit 150 for controlling each driving portion, a main body base 102 provided at the rear portion of the main body, a main body cover 101 for covering the main body base 102 and the lens barrel device, A back cover 103 for loading the film 105, a pressure plate 104 that presses the film 105 against the main body base 102, a viewfinder 120 that can change the magnification, and a strobe 13 that can change the irradiation angle, as shown in FIG.
0, a variable magnification / variable angle mechanism 110 that performs a variable magnification operation of the finder 120 and an irradiation angle change operation of the strobe 130 in accordance with the operation of the lens barrel device, and a film winding mechanism and a film winding mechanism (not shown). It has a return mechanism and the like.

As shown in FIG. 3, the control circuit 150 includes a counter 151 for counting the drive amount of the cam barrel drive motor 73, and a cam barrel so that the drive amount of the cam barrel drive motor 73 becomes a predetermined amount. It has a cam barrel drive control unit 152 that controls the drive motor 73 and a focus control unit 153 that controls the drive amount of the focus unit 30. The cam barrel drive control unit 152 receives a signal from the main switch 154 for activating various functions of the camera of the present embodiment to enable shooting, and a zoom switch 155 for the operator to set a shooting magnification. And the signal of is input. The camera of the present embodiment is a so-called autofocus camera, and the signal from the distance detection unit 159 that detects the distance to the subject is the focus control unit 153.
It is designed to be input into.

As shown in FIG. 8, the finder 120 is a movable lens 1 which is movable with respect to the main body cover 101.
21, 122, a fixed lens 123 fixed to the main body cover 101, a field frame 124, and an eyepiece lens 125. Also, strobe 13
Reference numeral 0 includes a strobe body 131 and a Brinell lens (not shown) arranged closer to the subject than the strobe body 131. Strobe body 1
31 is a light emitting body 132 and a strobe cover 1 covering the light emitting body 132.
And 33. A cam follower shaft 134 is provided on the strobe cover 133. Finder 12
The moving lenses 121 and 122 of 0 are the cam follower shaft 12
It is supported by 6,127.

The variable magnification / angle changing mechanism 110 is used for the zoom cam barrel 6.
0 sector gear 68, variable magnification / variable angle gear groups 111, 112, 113 engaged with this sector gear 68, and variable magnification / variable angle cam bodies swinging by the operation of these gear groups 111, 112, 113. 114, the swing shaft 115 of the zooming / changing cam body 114, and the viewfinder moving lenses 121 and 122.
And the guide shafts 116 and 117 for guiding the strobe body 131 to move in a direction parallel to the optical axis C. The variable-magnification / angle-changing cam body 114 has a fan shape,
A swing shaft 115 is provided at a main portion thereof. A gear 114d that engages with one gear 113 of the gear groups 111, 112, 113 is formed at a portion corresponding to the arc of the fan-shaped zooming / changing cam body 114. Further, the fan-shaped variable-magnification / angle-change cam body 114 has cams 114a, 1 for moving the movable lenses 121, 122 and the strobe body 131 as the cam body 114 swings.
14b and 114c are formed. As the cam, the cam follower shaft 12 of the moving lenses 121 and 122 is used.
Finder variable magnification cam 1 into which the ends of 6, 127 are inserted
14a and 114b, and a strobe irradiation angle changing cam 114c into which the end of the cam follower shaft 134 of the strobe main body 131 is inserted. Finder variable magnification guide shaft 1
16 and the strobe irradiation angle changing guide shaft 117 are both fixed to the main body cover 101 in parallel with the optical axis C. The viewfinder variable magnification guide shaft 116 includes movable lenses 121, 12
The second cam follower shafts 126 and 127 are penetrated, and the stroboscope irradiation angle changing guide shaft 117 is provided in the strobe cover 1
It penetrates through 33.

Next, the operation of the retractable zoom camera according to this embodiment will be described. As shown in FIGS. 1 and 4, in the retracted position, the entire lens barrel device is housed inside the main body cover 101. At this time, the follower pins 11 for the first group, the follower pins 28 for the second group, and the follower pins 32 for the third group are located closest to the film. Specifically, as shown in FIG. 4, the first group follower pin 11 is located on the most film side of the first group cam 51 formed in the collapsible cam barrel 50, and the second group follower pin 28 is the zoom cam barrel. The follower pin 32 for the third lens group is located in the lift frame storage portion 66 formed in the lens 60, and is located in the vertical portion 63c of the cam 63 for the third lens group formed in the zoom cam barrel 60. The lift piece 80 is also located closest to the film in the lift piece storage portion 66 of the zoom cam barrel 60. This lift piece 80 has two end faces, one on the subject side and the other on the subject side.
The taper portion 29a of the group follower pin 28 is in contact. The cam barrel drive gear 71 engages only with the sector gear 54 formed on the outer periphery of the retractable cam barrel 50, and does not engage with the sector gear 68 formed on the outer periphery of the zoom cam barrel 60.

Further, the locking end 92a of the collapsing cam barrel rotation restraining lever 91a is not locked to the locked portion 55a of the collapsing cam barrel 50, and the locking end 92b of the zoom cam barrel rotation restraining lever 91b is It is locked to the locked portion 69b of the zoom cam barrel 60. Furthermore, the claw 53 of the retractable cam barrel 50 is
The end of the notch 67 of the zoom cam barrel 60 is not reached. Therefore, the zoom cam barrel 60 cannot rotate with respect to the main body,
The retractable cam barrel 50 is rotatable with respect to the main body.

When the operator presses the main switch 154 in this retracted position, a signal is output from the cam barrel drive control section 152 to the drive motor 73, and the drive motor 73 is driven. Here, for the sake of simplicity of explanation, the signal from the cam barrel drive control unit 152 is supposed to be output to the drive motor 73, but in reality, the drive motor 73 is used.
Is output to a switching element (not shown) provided between the power supply and the power supply (not shown). Then, as shown in FIG. 4, the cam barrel drive motor 73
The cam cylinder drive gear 71 that rotates by the drive of the retractable cam cylinder 5
Since only the 0 sector gear 54 is engaged, only the retractable cam barrel 50 rotates about the optical axis (direction A in the figure).
By the rotation of the collapsible cam barrel 50, the positions of the lift frame cam 52 and the first group cam 51 formed on the collapsible cam barrel 50 also move relative to the main body. This first group cam 5
By the movement of 1, the first-group follower pin 11 engaged with the first-group cam 51 tries to move in a direction having a directional component parallel to the optical axis C. At this time, the first-group follower pin 11 moves in a direction parallel to the optical axis C because the cylindrical portion 12a is engaged with the first-group straight-ahead guide hole 41 of the fixed barrel 40. Therefore, the first-group lens support cylinder 10 starts moving in the direction parallel to the optical axis C. Also, the cam 52 for the lift piece
The follower pin 81 of the lift piece 80 engaged with the slanted portion 52a of the cam 52 tends to move in the direction including the directional component parallel to the optical axis C by the movement of. By the way, the lift piece 80 can be moved to the optical axis C by the lift piece storage section 66.
Since the lift piece 80 is regulated to move in a direction parallel to, the lift piece 80 moves in a direction parallel to the optical axis C. Due to the movement of the lift piece 80, the follower pin 28 for the second group, which is in contact with the lift piece 80, also tries to move in a direction including a direction component parallel to the optical axis C. At this time, in the follower pin 28 for the second group, the cylindrical portion 29 a of the second group follower pin 28 is fixed to the fixed barrel 40.
Since it is engaged with the group-advancing guide hole 42, it moves in a direction parallel to the optical axis C. Therefore, the shutter block 20 supporting the second group lenses 23 and 27 and the image stabilization unit 2
5 also starts moving in a direction parallel to the optical axis C.

That is, when the drive motor 73 starts to drive in the retracted position, only the retractable cam barrel 50 rotates and the first lens group 15 and the second lens groups 23 and 27 move in the direction parallel to the optical axis C. Moving. The third lens group 36
Is a retractable cam barrel 50 in which the follower pin 32 for the third group rotates.
It does not move at all because it is not engaged with the cam.

When the drive motor 73 is further driven from this state, as shown in FIG.
Comes into contact with the end of the notch 67 of the zoom cam barrel 60, and the zoom cam barrel 60 also starts to rotate together with the retractable cam barrel 50. At this time, the positions of the subject side end of the first group cam 51 of the retractable cam barrel 50 and the film side end of the first group cam 61 of the zoom cam barrel 60 are aligned, and the follower pin 11 for the first group is attached to the retractable cam barrel. It becomes possible to transfer from the first group cam 51 of 50 to the first group cam 61 of the zoom cam barrel 60. Incidentally, the locking end 92b of the rotation restricting lever 91b for the zoom cam cylinder, which has restricted the rotation of the zoom cam cylinder 60, is disengaged from the locked portion 69b of the retractable cam cylinder 50 immediately before this, and the zoom cam cylinder 60 is locked.
Is also rotatable with respect to the main body. This is because the cam follower end 93b of the rotation restraining lever 91b is formed on the retractable cam barrel 50, and the cam 55 for restraining rotation of the zoom cam barrel is shown.
Since it comes to contact the lower part of the step of b,
This is because the locking end 92b, which is located symmetrically with respect to the cam follower end 93b about the swing shaft 94b, moves in the direction away from the zoom cam barrel 60.

Further, the claws 5 of the retractable cam barrel 50 from the retracted state.
The limit switch 165 contacts the reference position detecting convex portion 59 formed on the outer periphery of the retractable cam barrel 50 until the contact point 3 of the zoom cam barrel 60 contacts the end of the notch 67 of the zoom cam barrel 60. The ON state is set, and the counter 151 of the control circuit 150 is reset to "0". Counter 1
After that, 51 counts up the number of pulses from the drive amount detection sensor 160 that detects the drive amount of the cam barrel drive motor 73.

The claw 53 of the retractable cam barrel 50 is the zoom cam barrel 6
When the zoom cam barrel 60 starts to rotate together with the collapsible cam barrel 50 by coming into contact with the end of the notch 67 of 0, the cam barrel drive gear 7
1 also engages with the sector gear 68 of the zoom cam barrel 60. At this time, the lift piece 80 is positioned closest to the subject in the lift piece storage portion 66, and the follower pin 28 for the second group (which has been located in the lift piece storage portion 66 until now) was in contact with the lift piece 80. , To the second group cam 62b of the zoom cam barrel 60. Further, as the zoom cam barrel 60 starts to rotate, the position of the third group cam 63 formed on the zoom cam barrel 60 also starts to move relative to the main body. By the way, since the third group follower pin 32 is located in the vertical portion 63c of the third group cam 63, it does not move at all even when the zoom cam barrel 60 starts to rotate. In addition, the first-group follower pin 11 further moves along with the movement of the third-group cam 63 of the collapsible cam barrel 50, and further the optical axis C.
It advances in a direction parallel to and approaches the zoom cam barrel 60.

When the drive motor 73 is further driven to rotate the zoom cam barrel 60 and the collapsing cam barrel 50, as shown in FIGS. 6 and 2, the follower pin 1 for the first group 1
1 moves from the first group cam 51 of the retractable cam barrel 50 to the first group cam 61 of the zoom cam barrel 60. Further, the follower pin 28 for the second group is provided with the through cam portion 65 of the zoom cam barrel 60.
The second group cam 62b moves to the second group cam 62a of the inner cam portion 64. Furthermore, the follower pin 32 for the third group is
The third group cam 63 moves from the vertical portion 63c to the diagonal portion thereof.
Further, the cam barrel drive gear 71 is disengaged from the sector gear 54 of the retractable cam barrel 50, and the sector gear 68 of the zoom cam barrel 60 is removed.
Will be engaged only. In this state, the control circuit 1
The number 50 recognizes from the count number of the counter 151 that the state is the minimum magnification position. Then, the control circuit 15
The cam cylinder drive motor 73 is stopped by an instruction from the cam cylinder drive control unit 152 of 0. Immediately before reaching the state of the minimum magnification position, the locking end 92a of the collapsing cam barrel rotation restraining lever 91a is locked to the locked portion 55a of the collapsing cam barrel 50, and the collapsing cam barrel 50 is attached to the main body. On the other hand, it becomes unable to rotate.

By the way, since the claw 53 of the collapsible cam barrel 50 contacts the end of the notch 67 of the zoom cam barrel 60 and both the zoom cam barrel 60 and the collapsible cam barrel 50 start to rotate, the state of the minimum magnification position is reached. Until then, many operations are performed and the rotation angles of the cam barrels 50 and 60 seem to be large.
Actually, the rotation angle of the cam barrels 50 and 60 during this period is small, and the above-described many operations are performed immediately before reaching the state of the minimum magnification position.

When the photographer desires another magnification in the state of the minimum magnification position and operates the zoom switch 155, the drive motor 73 is driven again by an instruction from the cam barrel drive control section 152 of the control circuit 150. start. Cam cylinder drive gear 7
Since No. 1 is engaged only with the sector gear 68 of the zoom cam cylinder 60, the zoom motor cylinder 60 is driven by the drive motor 73.
Only the chimney begins to rotate. By rotating the zoom cam barrel 60,
First group cams 61, 2 formed on the zoom cam barrel 60
The positions of the group cam 62 and the third group cam 63 move relative to the main body, and the follower pins 11, 28, 32 engaged with these cams 61, 62, 63 are aligned with the optical axis C. Move in parallel direction. These follower pins 11, 28, 3
By the movement of 2, the first-group lens support cylinder 10 supporting the first-group lens 15 and the shutter block 20 supporting the second-group lenses 23 and 27, the image stabilizing unit 25, and the third-group lens 36 are supported. Focus unit 30 is optical axis C
By moving in a direction parallel to, it becomes possible to obtain the magnification desired by the photographer. The control circuit 150 uses the counter 1
When the photographer recognizes indirectly that the magnification desired by the photographer can be obtained from the count number of 51, the drive of the drive motor 73 is stopped by the instruction from the cam barrel drive control unit 152, and the focus is adjusted. The focus unit 30 is driven according to an instruction from the control unit 153. When the focus unit 30 is driven, the helicoid ring 34 rotates, and the third group lens 36 slightly moves in the direction parallel to the optical axis C while rotating around the optical axis, and focus adjustment is performed.

In order to obtain the maximum magnification, the follower pin 11 for the first group and the follower pin 2 for the second group, as shown in FIG.
The follower pins 32 for the eighth and third groups are provided for the respective cams 61, 62, 6
3 is the most object side, and each lens 1
5, 23, 27 and 36 are also located closest to the subject. However, even if the follower pin 32 for the third group is located on the most object side of the third group cam 63, the third group lens 36 is not located on the most object side by driving the focus unit 30 for focus adjustment. Needless to say, there are cases.

Next, the operation of retracting the state from the minimum magnification position to the retracted position will be described. This transfer operation is
The operation is basically the same as the reverse operation of the above-mentioned feeding operation. However, there is an operation that differs by one point. Follower pin 2 for 2 groups
8 can be moved to the subject side by the movement of the lift piece 80 during the feeding operation, but cannot be moved to the film side even when the lift piece 80 is moved during the feeding operation. Therefore, in this case, as shown in FIG. 1, at the film side end portion 14 of the first lens group supporting cylinder 10, the anti-vibration unit 25 having the second lens group follower pin 28 is pushed to the film side to push the second lens group follower pin. 28 is moved to the film side.

Next, the zooming operation of the finder 120 and the irradiation angle changing operation of the strobe 130 will be described with reference to FIG. When the zoom cam barrel 60 rotates, the variable magnification / angle changing gear groups 111, 112, 113 engaged with the sector gear 68 of the zoom cam barrel 60 rotate. This gear group 1
The rotation of 11, 112 and 113 causes the zooming / changing cam body 114 to swing about the swing shaft 115. By the swinging of the zooming / changing cam body 114, the zooming / changing cam body 1
A finder zooming cam 114a formed on the lens 14,
The positions of 114b and the irradiation angle changing cam 114c move relative to the main body, and these cams 114a, 114b, 1
Finder moving lens 121,1 engaged with 14c
22 cam follower shafts 126 and 127 and strobe 13
The cam follower axis 134 of 0 tends to move in a direction including a direction component parallel to the optical axis. At this time, the cam follower shafts 1269, 12 of the viewfinder moving lenses 121, 122
7 is guided by the finder magnification changing guide shaft 116 and the strobe main body 131 is guided by the strobe irradiation angle changing guide shaft 117, so that the finder moving lenses 121, 122 are moved.
And the strobe body 131 moves in a direction parallel to the optical axis,
The viewfinder magnification and strobe irradiation angle correspond to the shooting magnification.

Here, the rotation of the cam barrels 50 and 60 will be briefly summarized. The sector gear 54 of the retractable cam barrel 50 is
It is formed between the retracted position and the state immediately before the minimum magnification position. The sector gear 68 of the zoom cam barrel 60 is formed between the state immediately before the minimum magnification position and the state at the maximum magnification position. Therefore, the cam cylinder drive gear 71 that engages with these sector gears 54 and 68
When the state of the retracted position is changed to the state of the minimum magnification position with respect to the rotation of, only the retractable cam barrel 50 initially rotates,
When the state immediately before the minimum magnification position is reached, the retractable cam barrel 50 and the zoom cam barrel 60 rotate. Further, when the state of the minimum magnification position changes to the state of the maximum magnification position, only the zoom cam barrel 60 rotates. That is, the zoom cam barrel 60
Rotates from the state immediately before the minimum magnification position to the state at the maximum magnification position.

By the way, the variable magnification / angle changing mechanism 110 is operated by the rotation of the zoom cam barrel 60. For this reason, the viewfinder moving lenses 121 and 122 and the strobe body 131 do not move from the retracted position incapable of photographing to the state immediately before the minimum magnification position, but from the state immediately before the minimum magnification position to the maximum magnification position. Move between states. Therefore,
In this embodiment, the moving distance between the finder moving lenses 121 and 122 and the strobe main body 131 and the swing range of the zooming / changing cam body 114 are reduced, and each cam of the zooming / changing cam body 114 is reduced. The length of the camera can be shortened, and the overall size of the camera can be reduced.

Generally, when the two cylinders 50 and 60 are to be rotated separately, it is customary to provide an independent drive source for each. However, in the present embodiment, the sector gears 54,
Since the forming regions of the sector gears 54 and 68 are defined in accordance with the state in which the cylinders 68 are formed and the cylinders 50 and 60 are to be rotated, one gear 71 that engages with the sector gears 54 and 68 is defined. The two cylinders 50 and 60 can be rotated separately by rotating the drive cylinder 73 with one drive source 73. Therefore, by dividing the cam barrel into two, it is not necessary to provide two drive sources, and the circumference of the cam barrel rotating mechanism 70 does not become large. Further, in this embodiment, since the two divided cam cylinders partially overlap each other,
It is possible to completely shield the two cam barrels 50, 60 from each other. In the case of the present embodiment, it is inevitable that the lift frame 80 is moved by the position of the moving range of each lens and the relative rotation between the zoom cam barrel 60 and the collapsing cam barrel 50.
Although the two cam barrels 50 and 60 partially overlap each other, the two cam barrels 5 need to be completely shielded from light even if such restrictions are not imposed on the optical design.
It is preferable to partially overlap 0, 60 with each other.

Further, in the present embodiment, in the inner cam portion 63 of the zoom cam barrel 60, the cams formed here are formed as inner cams 61a, 62a, 63a having groove bottoms, so that the zoom cam barrel 60 of the zoom cam barrel 60 has The rigidity of the cam follower pins 11, 18, 32 does not decrease so much.
The inner cams 61a, 62a, 63a are hardly deformed even when they come into contact with the cam follower pins 11, 18, 32.
Can be guided to the correct position. On the other hand, in the through-cam portion 64 of the zoom cam barrel 60, although the cam formed here is formed as a through-cam due to the thickness of this portion, the through-cam portion 64 is the retractable cam barrel 50 from the outside thereof. Since it is pressed down, its rigidity does not decrease so much, and the through cams 61b, 62b, 63b formed on the through cam portion 64 do not deform so much. Further, since the cam of the collapsible cam barrel 50 is also formed as the inner cam 51, the follower pin 11 engaged therewith can be guided to an accurate position.

Further, in this embodiment, since the cam barrel rotation restraining mechanism 90 is provided, in the state where one cam barrel is rotated and the other cam barrel is stopped, the rotation of one cam barrel causes the other The cam cylinders do not rotate, and it is possible to prevent the rotational angle phase shift between the cam cylinders when the follower pin 11 moves from one cam cylinder to the other cam cylinder. Further, in general, it is customary to provide a drive amount detecting sensor and a reset switch for the rotation of the two cam barrels 50 and 60, respectively. However, in the present embodiment, the cam barrel rotation restraint mechanism 90 can reliably ensure the phase relationship of the rotation angles of both cam barrels, so that for each of the two separately rotating cam barrels 50, 60, One drive amount detection sensor 160 and one reset switch 165 can be used.

In this embodiment, the reference position detecting convex portion 59 is formed at a specific position on the outer circumference of the collapsible cam barrel 50, and the limit switch 165 is arranged there. However, these are only drive amount detecting sensors 165. Cam cylinder 5 to be grasped more
Since it is for recognizing the reference positions of the rotation amounts of 0 and 60, it goes without saying that they may be provided on the zoom cam barrel 60 side.

[0047]

According to the present invention, the lens is moved by the rotation of the collapsing cam barrel from the retracted position to the state immediately before the minimum magnification position, and from the minimum magnification position to the maximum magnification position. The lens is moved only by rotating the zoom cam barrel. For this reason, the viewfinder zooming mechanism that operates only by rotating the zoom cam barrel, and the viewfinder that zooms using this zooming mechanism, operates from the retracted position where shooting is impossible to the state immediately before the minimum magnification position. do not do. Therefore,
According to the present invention, the operation stroke of the movable portion of the finder itself and the operation stroke of the movable portion of the variable power mechanism of the finder can be shortened, and the overall size of the camera can be reduced.

[Brief description of drawings]

FIG. 1 is a sectional view of a retractable zoom camera according to an exemplary embodiment of the present invention (in a retracted position).

FIG. 2 is a cross-sectional view (state at a minimum magnification position) of a lens barrel portion of a retractable zoom camera according to an embodiment of the present invention.

FIG. 3 is a functional block diagram of a control circuit according to an embodiment of the present invention.

FIG. 4 is a development view of a retractable cam barrel and a zoom cam barrel (in a retracted position) according to an embodiment of the present invention.

FIG. 5 is a development view of a retractable cam barrel and a zoom cam barrel according to an embodiment of the present invention (a state at an intermediate position between the retracted position and the minimum magnification position).

FIG. 6 is a development view of a retractable cam barrel and a zoom cam barrel according to an embodiment of the present invention (state at a minimum magnification position).

FIG. 7 is a development view of a retractable cam barrel and a zoom cam barrel (in a state of maximum magnification position) according to an embodiment of the present invention.

FIG. 8 is an exploded perspective view of essential parts of a retractable zoom camera according to an embodiment of the present invention.

FIG. 9 is an exploded perspective view of a main part of a conventional retractable zoom camera.

[Explanation of symbols]

10 ... 1 group lens support cylinder, 11 ... 1 group follower pin,
15 ... 1-group lens, 20 ... Shutter block, 23 ... 2
Front lens of group, 25 ... Anti-vibration unit, 27 ... Rear lens of 2nd group, 28 ... Follower pin for 2nd group, 30 ... Focus unit, 32 ... Follower pin for 3rd group, 36 ... 3rd group lens,
40 ... Fixed tube, 41 ... Straight group guide hole for 1st group, 42 ... Straight group guide hole for 2nd group, 43 ... Straight group guide hole for 3rd group, 50 ... Retractable cam barrel, 51 ... 1st group inner (of retractable cam barrel) Cam, 52
... Lifting cams, 53 ... Claws, 54 ... Sector gears (of retractable cam barrel), 55a ... Locked parts (of retractable cam barrel),
55b ... Zoom cam barrel rotation restraining cam, 59 ... Reference position detecting convex portion, 60 ... Zoom cam barrel, 61 ... First group cam (of zoom cam barrel), 61a ... First group inner cam, 61
b ... 1st group through cam, 62 ... 2nd group cam, 62a ... 2
Inner cam for group, 62b ... Through cam for group 2, 63 ...
3rd group cam, 63a ... 3rd group inner cam, 63b ... 3
Group through-cam, 64 ... Inner cam part, 65 ... Through-cam part, 66 ... Lift top storage part, 67 ... Notch, 68
... (zoom cam barrel) sector gear, 69a ... collapsing cam barrel rotation restraining cam, 69b ... (zoom cam barrel) locked portion, 70 ... cam barrel rotating mechanism, 71 ... cam barrel driving gear, 7
3 ... Drive motor, 80 ... Lift coma, 81 ... Lift coma follower pin, 90 ... Cam barrel rotation restraint mechanism, 90a ... Collapsing cam barrel rotation restraint mechanism, 90b ... Zoom cam barrel rotation restraint mechanism, 91a, 91b ... Rotation restraint lever, 92a , 92
b ... locking end, 93a, 93b ... cam follower end, 101
... main body cover, 102 ... main body base, 103 ... back cover, 1
Reference numeral 05 ... Film, 110 ... Variable magnification / angle changing mechanism, 114 ... Variable magnification / angle changing cam body, 114a, 114b ... Viewfinder variable magnification cam, 114c ... Strobe irradiation angle changing cam, 12
0 ... Finder, 121, 122 ... Moving lens, 125
... Eyepiece, 130 ... Strobe, 131 ... Strobe body, 132 ... Light emitter, 133 ... Strobe cover, 150
... Control circuit, 151 ... Counter, 152 ... Cam barrel drive amount control unit, 153 ... Focus control unit, 154 ... Main switch, 155 ... Zoom switch, 160 ... Drive amount detection sensor, 161 ... Slit disk, 162 ... Photo interrupter , 165 ... Limit switch.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Sone Isao Marunouchi 3-chome 3-3, Chiyoda-ku, Tokyo Incorporated Nikon (72) Inventor Junichi Omi 3-chome 2-3, Marunouchi, Chiyoda-ku, Tokyo Ceremony Company Nikon

Claims (2)

[Claims] 1. A zoom camera capable of changing a photographing magnification and also changing a finder magnification according to a change of the photographing magnification, wherein a first lens is housed in a lens barrel closest to a subject, A retracted position in which a second lens is housed on the film side of the first lens, both the first lens and the second lens are located closest to the film side, and the first lens is housed in the main body. In the retractable zoom camera, which is movable to a minimum magnification position at which the subject can be photographed with respect to the retracted position and a maximum magnification position at which the subject can be photographed further than the minimum magnification position, the lens barrel is A first lens which supports the first lens and is movable relative to the main body in a direction parallel to the optical axis;
A lens support tube, a second lens support tube that supports the second lens and is movable relative to the main body in a direction parallel to the optical axis, and a second lens support tube that cannot move relative to the main body. A fixed barrel provided on the outer circumference of the first lens support barrel and the second lens support barrel; and a retractable cam barrel provided on the outer side of the fixed barrel so as to be rotatable relative to the main body about the optical axis.
Between the fixed cam and the collapsible cam barrel, a zoom cam barrel provided outside the fixed barrel and closer to the subject than the retractable cam barrel is rotatable relative to the main body about the optical axis. A movable piece provided so as to be movable in a direction parallel to the axis, and the movable piece is formed with a piece driven protrusion protruding in the radial direction with respect to the optical axis, and the first lens support cylinder A first driven protrusion protruding radially with respect to the optical axis, and the second lens support cylinder protruding radially with respect to the optical axis to move the second lens from the retracted position to the second position. A second driven protrusion that is in contact with the moving piece that moves in a direction parallel to the optical axis is formed immediately before reaching the minimum magnification position, and the first lens is attached to the fixed barrel. The first driven protrusion is moved from the retracted position to the maximum magnification position. And a second linear guide portion that is engageable with the first driven projection portion in a direction parallel to the optical axis and the second lens is moved from the retracted position to the maximum magnification position. A second rectilinear guide portion is formed which is engageable with the driven protrusion and guides the second driven protrusion in a direction parallel to the optical axis. The retractable cam cylinder is provided with the first lens and the retracted position. To just before reaching the minimum magnification position, the first driven protrusion is engageable, and the spiral first cam portion with respect to the optical axis is engaged with the piece driven protrusion. Between the retracted position and immediately before reaching the minimum magnification position until just before reaching the minimum magnification position of the second lens in a spiral shape with respect to the optical axis until just before reaching the minimum magnification position from the collapsed position. Between the other than the annular in the direction perpendicular to the optical axis A frame cam portion is formed, and the first driven projection portion is engageable with the zoom cam barrel while the first lens is moved from the minimum magnification position to the maximum magnification position and with respect to the optical axis. The spiral-shaped first cam portion and the second lens are moved from the minimum magnification position to the maximum magnification position, the second driven protrusion portion is engageable and is spiral with respect to the optical axis. A second cam portion is formed, and the retractable cam barrel is rotated within a range in which the first lens can be moved from the retracted position to at least immediately before the minimum magnification position, and at least the first lens is disposed. A cam barrel rotating mechanism that rotates the zoom cam barrel within a range in which it can be moved from the minimum magnification position to the maximum magnification position, and the finder that rotates only with the zoom cam barrel. Retractable zoom camera, characterized in that it comprises a variable power mechanism for zooming operation, a. 2. A strobe capable of changing an irradiation angle is provided, and the zooming mechanism is configured so that the strobe can also be actuated in accordance with the rotation of the zoom cam barrel. The retractable zoom camera according to claim 1.