JPH06313829A - Lens-barrel - Google Patents

Abstract

PURPOSE:To realize a lens barrel, large in the angle of rotation with the barrel retracting quantity taken large, thin in lens-barrel diameter with no fear of light leakage while dispensing with an expensive metal die for the forming of a movable barrel, with simple constitution. CONSTITUTION:A lens-barrel is provided with a fixed barrel 1 fixed to a body and provided with a linear guide part; a movable barrel 2 moving in the optical axis direction while rotating being helicoidally screwed with the fixed barrel 1 and provided at the rear end with a gear having an addendum circle smaller than the root diameter of a male helicoid; a lens frame 4 helicoidally screwed with the lens-barrel and provided with a linear guide part so as to hold at least one group of photographic lenses; a guide member assembled rotatably and integrally to the rear end of the movable barrel 2 so as to be engaged with the fixed barrel 1 and the linear guide part 21 of the lens frame 4; a first driving gear meshed with the gear of the movable barrel 2 and rotatably journalled to the guide member; and a second driving gear meshed with the first driving gear and provided with tooth width larger than the moving quantity of the movable barrel 2 in the optical axis direction.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens barrel of a camera.

[0002]

2. Description of the Related Art A mechanism for retracting a lens barrel has been conventionally used so that it can be carried as small as possible without using a camera. In recent years, a mechanism for double-fitting a lens barrel has been widely used in compact cameras. That is, the fixed barrel fixed to the camera body, the movable barrel that moves in the optical axis direction while rotating inside the fixed barrel, the lens barrel that holds the lens inside the movable barrel, and the rotation of the lens barrel is blocked. And a guide member for rotating the movable barrel in the optical axis direction to move the lens barrel in the optical axis direction. With respect to such a lens barrel, various mechanisms have been proposed and put to practical use in the past, but all of the lens barrels have advantages and disadvantages, and they are not satisfactory for downsizing while maintaining predetermined performance. .

FIG. 4 is a schematic view of the first conventional example, in which the movable barrel 111 is helicoid-threaded with the fixed barrel 112,
No helicoid is screwed in the middle of the male helicoid 111a, and a spiral gear 111b having a tip circle substantially the same as the outer diameter of the male helicoid is provided. The spiral gear 111b is rotated by the drive gear 113 provided on the mountain portion of the fixed body 112,
A lens frame (not shown) on the inner circumference of the movable barrel 111 is moved straight by known means. However, in such a first conventional example, there is a restriction that the gear 111b should not appear in the external appearance of the camera, and since a sufficient rotation angle of the movable barrel 111 cannot be obtained, the retractable amount is small. Further, the fixed barrel 112 has a portion in which a female helicoid is not screwed so as not to hit the gear 111b, and the hole 112a for the drive gear 113 is provided.
Therefore, outside light enters from here toward the optical axis,
There is a risk of light leakage. Further, in order to mold and process the movable barrel 111 with a spiral gear, a very expensive and highly accurate mold is required.

FIG. 5 is a schematic view of a second conventional example, in which the movable barrel 121 and the fixed barrel 122 are helicoidally screwed to each other.
The front part of 1 has a gear 12 with a root circle larger than the outer diameter of the fixed barrel 122.
1b is provided integrally with the movable barrel 121, and the drive gear is long in the optical axis direction.
It meshes with 123. Therefore, the movable gear 121 is rotated by the drive gear 123, and the lens frame (not shown) on the inner circumference of the movable barrel 121 is linearly moved by known means. However, in such a first conventional example, a sufficient amount of collapsing cannot be obtained to accommodate the drive gear 123, which is long in the optical axis direction, inside the camera, and the outer diameter of the lens barrel 121b causes a large outer diameter of the lens barrel. turn into.

FIG. 6 shows a third conventional example which is an improvement of the first and second conventional examples. The movable barrel 131 is engaged with the fixed barrel 132 by helicoid, and the male helicoid 131a of the movable barrel 131 is attached to the movable barrel 131. A helicoid is not screwed, but a plurality of spiral gears 131b having a root circle larger than the mountain diameter of the male helicoid are provided. A helical gear 1 by a drive gear 133 that is long in the optical axis direction.
By rotating 31b, a lens frame (not shown) on the inner circumference of the movable barrel 131 is moved straight by known means. However, in the third conventional example as described above, the outer diameter of the lens barrel is larger than that of the first conventional example, and the movable barrel 131 with the spiral gear is formed in the same manner as in the second conventional example. Requires a very expensive and highly accurate mold.

[0006]

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems of the prior art. The rotation angle is large, the amount of collapsing is sufficient, the lens barrel diameter is thin, and there is a possibility of light leakage. In addition, the present invention realizes a lens barrel having a simple structure, which is expensive and does not require a highly accurate mold for molding the movable barrel.

[0007]

SUMMARY OF THE INVENTION According to the present invention, there are provided a fixed barrel fixed to a camera body and having a female helicoid and a linear guide portion on the inner periphery, and a male helicoid screwed to the fixed barrel on the outer periphery. Provided with a female helicoid on the inner periphery and integrally provided with a gear having a tip circle smaller than the root diameter of the male helicoid on the rear end, and a movable barrel that moves in the optical axis direction while rotating; At least one of the photographing lenses is provided with a male helicoid to be screwed and a linear guide portion.
A lens barrel carrying a group, a guide member that is rotatably and integrally assembled with the rear end of the movable barrel and that engages with the fixed barrel and the linear guide portion of the lens barrel; A first drive gear that meshes with a gear and is rotatably supported by the guide member; and a tooth width that meshes with the first drive gear and is larger than the amount of movement of the movable barrel in the optical axis direction. And a second driving gear, wherein the first driving gear and the movable barrel are rotated by the second driving gear to move the lens frame in a straight line.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to FIGS.

FIG. 1 is an exploded perspective view of a zoom lens barrel according to the present invention, and FIG. 2 is a cross-sectional view of the zoom lens barrel. The upper half of the barrel has a wide focal length, and the lower half of the barrel has a focal length. FIG. 3 is a view showing the assembling of the fixing plate, and FIG.

Reference numeral 1 denotes a fixed barrel integrally fixed to the camera body, and a female helicoid 1a is screwed on the inner periphery of the fixed barrel.
Straight guides to be described later are provided on the left and right sides of the female helicoid 1a.
A guide groove 1b for 21 is provided across the female helicoid 1a. Reference numeral 2 denotes a movable barrel, which has a male helicoid 2a and a large gear 2b screwed onto the outer periphery of the female helicoid 1a.
Are integrally formed, and a female helicoid 2c and a cam groove 2d (inner cam) are provided on the inner circumference, and a rib 2e is provided on the rear end portion inwardly. The tooth circle of the large gear 2b is formed smaller than the root diameter of the male helicoid 2a. When the movable body 2 and the large gear 2b are integrally molded with resin, the large gear 2b is arranged on the rear end surface of the movable body 2. By doing so, the molding die can be molded in one piece in the die cutting direction instead of dividing the molding die, so that highly accurate parts can be manufactured with a simple die structure. 3 is an FC sliding frame, FC with a synthetic focal length of (+)
The FC lens frame 4 that holds the lens group 5 is attached from the front with screws. On the outer circumference of the FC sliding frame 3, a male helicoid 3a screwed with a female helicoid 2c and a guide groove 3b for a straight guide 21 described later are provided, and a hole 3c for a guide shaft 11 described later is formed. There is. Reference numeral 6 is an RC sliding frame, which has a combined focal length of (-) on the inner circumference.
The lens group 7 is held, a guide groove 6a for a linear guide 21 which will be described later is provided on the outer periphery, an RC cam pin 8 that engages with the cam groove 2d is embedded, and a guide shaft 11 is projected forward. Reference numeral 13 is a shaft spring inserted into the guide shaft 11, and 12 is an E-shaped retaining ring for preventing the shaft spring 13 from coming off. Reference numeral 21 denotes a straight-moving guide, which is slidably engaged with the guide groove 1b of the fixed body 1 at the left and right protruding portions 21a, and the other protruding portion 21a.
A drive gear 44, which will be described later, is rotatably supported by b, and the guide groove 3b and the guide groove 6 are supported by the arm portion 21c bent forward.
Sliding with a. Reference numeral 22 is a guide fixing plate that connects the movable barrel 2 and the straight guide 21. 23 is a guide fixed shaft that connects the straight guide 21 and the guide fixing plate 22 and holds the movable barrel 2 with the ribs 2e. 24 is a straight guide. A set screw for holding 21 on the fixed guide shaft 23. 31 is a lens barrel drive motor, the shaft of which
A propeller 33 for LDP1 is attached to 32, and LDP1
The signal LDP1 is generated by the photo interrupter 34 for use. Reference numeral 35 is a pinion directly connected to the motor, and rotation of the motor 31 is performed by the first gear 36, the second gear 37, the third gear 38, and the fourth gear.
By 42, it is transmitted to the fifth gear 43 having a gear long in the optical axis direction, and further transmitted to the drive gear 44. The drive gear 44 meshes with the large gear 2b of the movable barrel 2. The propeller 40 for LDP2 is attached to the shaft 39 of the third gear 38
The signal LDP2 is generated by the P2 photo interrupter 41. The signals LDP1 and LDP2 are signals for controlling the lens barrel drive motor.

Reference numeral 52 is a shutter, and 53 is a shutter driving motor, which is mounted on the FC sliding frame 3. Reference numeral 51 denotes an FPC board, which connects a shutter drive motor 53 and a printed board 54 on which electrical components on the main body side are mounted. After the FPC board 51 is connected to the shutter driving motor 53, the FPC board 51 passes through the gap between the arm portion 21c of the straight guide 21 and the inner circumference of the movable barrel 2 toward the rear of the camera, and is folded back at the rear end 2f of the movable barrel 2. It passes through the gap between the outer periphery of the movable barrel 2 and the fixed barrel 1 in the forward direction. A hole 1c is provided in front of the camera from the rear end 2f of the movable body 2 when the movable body 2 is most extended to the fixed body 1.
The PC board 51 passes through the hole 1c and is pulled out to the outer periphery of the fixed body 1 to be connected to the printed board 54 on the main body side. In addition,
51a is the FPC board 51 at the position where the lens barrel is most retracted.
Is shown. Reference numeral 61 is the external appearance of the camera, the decorative ring 62 is attached to the movable barrel 2, and the front cylinder 63 is attached to the FC sliding frame 3.

Next, the basic operation of the zoom lens barrel will be described.

First, when the drive motor 31 rotates, its driving force is transmitted to the fifth gear 43 through the gear trains 36, 37, 38, 42, and the fifth gear 43 is attached to the drive gear 44 attached to the linear guide 21. , Transmit the driving force. Drive gear 44 is large gear 2b
And the movable barrel 2 is rotated to move the fixed barrel 1 and the movable barrel 2 screwed with the helicoid in the optical axis direction. At this time, the movable barrel 2 moves forward or backward in the optical axis direction according to the rotation direction of the drive motor 31, and the drive gear 44 also moves forward or backward, so that the teeth in the optical axis direction with the fifth gear 43 meshed with each other. Although the engagement position changes, the fifth gear 43 has a long tooth width in the optical axis direction, so that the engagement does not deviate. Movable torso 2
The rectilinear guide 21 is integrally attached to the rib 2e by a guide fixing plate 22, a guide fixing shaft 23, and a set screw 24. The rectilinear guide 21 includes the left and right protruding portions 21a and the guide groove 1b of the fixed body 1. The rotation is blocked by and only moves in the optical axis direction. Similarly, the FC slide frame 3 is prevented from rotating in the guide groove 3b by the straight guide 21. Also, R
The guide shaft 11 projecting from the C sliding frame 6 has the FC sliding frame 3
The RC sliding frame 6 is also prevented from rotating together with the FC sliding frame 3 since it penetrates through. Therefore, when the movable barrel 2 is rotationally moved, the FC sliding frame 3 helicoidally coupled to the movable barrel 2 and the RC sliding frame 6 cam-coupled to the movable barrel 2 only advance or retract in the optical axis direction. . FC sliding frame 3
Moves about twice as much as the movable barrel 2. This ratio is determined by the leads of the inner helicoid and the outer helicoid of the movable barrel. Since the leads are set to be almost the same in the embodiment, the ratio is as described above. Although the meshing position of the fifth gear 43 and the drive gear 44 changes in the optical axis direction as the movable barrel 2 moves, the fifth gear 43 is a gear having long teeth in the optical axis direction. The meshing is always maintained regardless of the movement of the movable barrel 2. The rib 2e of the movable barrel 2 has a bearing surface for receiving the rotation of the movable barrel 2 in addition to the thrust slip-out prevention of the straight guide 21, so that the movable barrel 2 is prevented from being deformed when the driving force is transmitted. There is.

The RC sliding frame 6 for holding the RC lens is driven by the cam groove 2d as described above, and its cam shape is made to be a focusing area so that focusing and focal length switching can be driven by the same driving source. , Focal length switching area.

Guide shaft 11 projecting from RC sliding frame 6
Penetrates the FC sliding frame 3 and holds the shaft spring 13 in a compressed state by the E-shaped retaining ring 12 at the tip thereof, so that the RC sliding frame 6 constantly keeps the spring force of the FC sliding frame 3. Attracted in the direction. Therefore, the cam groove 2d of the movable barrel 2
Is using only one side of the cam. Therefore, the cam groove width is larger than the cam pin width, and the groove width has a margin. The standing angle of the cam groove 2d is as high as possible on the side to which the force of the shaft spring 13 is applied in order to increase the operating efficiency of the cam, and the standing angle of the cam groove is asymmetric in the front and rear so that plastic molding can be performed. Further, during focusing, the spring force moves in the direction of increasing spring force, and during zooming up, the spring force moves in the direction of decreasing spring force. Since the cam groove 2d is open in the front direction of the optical axis, RC
When incorporating the sliding frame 6 into the movable barrel 2, the sliding frame 6 is incorporated from the front of the movable barrel 2. This RC sliding frame 6 is an FC sliding frame 3
Since it is connected to the guide shaft 11 (including the shutter 52, etc.), the movable barrel 2 serves as an FC / RC sliding frame unit.
However, if the RC sliding frame 6 is pulled toward the FC sliding frame 3 side at that time, the workability of assembly is good. Moreover, by making the RC sliding frame 6 cover the RC sliding frame 6, it is possible to prevent the RC lens group 7 of the RC sliding frame 6 from being damaged.

Normally, lens performance such as projection resolving power is inspected at the stage of the movable barrel unit including the FC / RC sliding frame unit. However, if the movable barrel on the outer surface of the current unit is rotated, the focal length is increased. Since you can select and adjust the focus,
The inspection efficiency is very high and does not require extensive electrical jigs. If the lens performance such as the projection resolution can be inspected in this state, defects and the like can be detected quickly, and the time and cost for disassembly repair can be saved. This unit has a shutter drive, F
It is easy to replace the FC lens due to defects caused by the FC lens because the PC, lens cover, etc. do not have to be built in, and there is no focusing mechanism. The straight guide 21 is incorporated, and two guide fixing plates 22 for retaining rotation receivers of the straight guide 21 are incorporated. Figure 3
This will be described with reference to (A) and FIG. In FIG. 3 (A), in order to improve the assembly workability, the two fixing plates 22 are
Each set is temporarily fixed to the linear guide 21 by a set screw 24, the straight guide 21 is incorporated into the movable barrel 2 from the back of the camera, and then the set screw 24 is rotated clockwise, as shown in FIG.
As shown in (B), the straight guide 21 is screwed and coupled at a total of 6 positions of the set screw 24 and the set screw 25. In this way, since the straight guide 21 can guide the fixed barrel 1 and the FC sliding frame 3 in a straight line with a single component, the FC sliding frame 3 has a high straight moving accuracy and is a drive for performing a straight running operation. Power efficiency is high.

The movable barrel 2 moves in synchronization with the linear guide 21 in the optical axis direction. A drive gear 44 is attached to the linear guide 21. Therefore, even if the movable barrel 2 moves in the optical axis direction, the position of the drive gear in the optical axis direction does not change.
The large gear 2b shown in 1 has a simple shape having a tooth width only a predetermined length from the rear end surface. This is to reduce the size of the large gear 2b in the optical axis direction as much as possible.

[0018]

As described above, according to the present invention, since a normal gear having no twist is provided on the movable barrel, the rotation angle is large, a sufficient amount of collapsing can be obtained, and the lens barrel diameter can be made small. Since there is no escape of the helicoid in the fixed barrel, there is no worry of light leakage, and it is possible to realize a lens barrel with a simple structure that does not require an expensive mold for molding the movable barrel. Produce an effect.

Further, by providing a rib on the inner circumference of the rear end of the movable barrel, a sufficient bottom thickness can be obtained and the strength of the movable barrel is increased.

[Brief description of drawings]

FIG. 1 is an exploded perspective view of a lens barrel of the present invention.

FIG. 2 is a cross-sectional view of a lens barrel.

FIG. 3 is a view showing an assembling of a fixing plate.

FIG. 4 is a schematic diagram of a first prior art.

FIG. 5 is a schematic diagram of a second prior art.

FIG. 6 is a schematic diagram of a third prior art.

[Explanation of symbols]

 1 Fixed barrel 2 Movable barrel 2b Large gear 3 FC sliding frame 4 FC lens mirror frame 5 FC lens 6 RC sliding frame 7 RC lens 8 RC cam pin 11 Guide shaft 21 Straight guide 22 Guide fixing plate 31 Lens barrel drive motor 43 No. 5 gears 44 drive gears

Claims (2)

[Claims] 1. A fixed barrel fixed to a camera body and having a female helicoid and a linear guide portion on its inner circumference, and a male helicoid screwed to the fixed barrel on its outer circumference, and a female helicoid on the inner circumference and a rear end. A gear having a tip circle smaller than the root diameter of the male helicoid is integrally provided with the movable barrel that moves in the optical axis direction while rotating, a male helicoid that is screwed with the movable barrel, and a linear guide portion. A lens frame that carries at least one group of provided photographing lenses, and a guide member that is rotatably and integrally assembled with the rear end of the movable barrel and that engages with the fixed barrel and the linear guide portion of the lens frame. A first drive gear that meshes with the gear of the movable barrel and is rotatably supported by the guide member; and a moving amount of the movable barrel that meshes with the first drive gear in the optical axis direction. A second drive gear having a large tooth width, A lens barrel, wherein the first drive gear and the movable barrel are rotated by a second drive gear to move the lens frame in a straight line. 2. The lens barrel according to claim 1, wherein a rib is provided on an inner circumference of a rear end of the movable barrel.