KR830000320Y1 - Close-up ZOOM type interchangeable lens - Google Patents

Abstract

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Description

Close-up ZOOM type interchangeable lens

1 is a longitudinal cross-sectional view of a straight-angle interchangeable lens showing an embodiment of the present invention.

2 is an exploded view of the present invention cam box.

The present invention is directed to an improvement of a close-up straight-angle interchangeable lens.

A straight-angle interchangeable lens that performs "pinning" by sliding the operating ring in the direction of the optical axis, and a "pint" adjustment by rotating around the optical axis, is a rotatable exchange in which the pinching and the pin adjustment are performed by the rotation of the separate members, respectively. Compared to the lens, it is becoming the mainstream of the interchangeable lens because of its advantages such as simple and quick operation.

By way of example, in the four-group linear interchangeable lens, the cam barrel is rotated by sliding in the optical axis direction of the operating ring, the cam lens is moved linearly in the optical axis direction by the cam hole, and the correction lens group is moved with respect to its movement. By moving non-linearly, the lens is moved, but from the shortest focal length (wide end) state in which the variable lens group is most exposed, only the correction lens group is moved to retreat in the optical axis direction, thereby enabling close-up (macro) photography. Known.

However, such a conventional close-up straight-angle interchangeable lens is equipped with a mechanical close-up switching mechanism, and after the switching operation, only the correction lens group is moved by operating the operating ring or a separate ring. Therefore, not only the mechanism is complicated, but also the operation cannot be performed by the operation ring, which is why the direct exchange type lens has the advantage.

The present invention has been devised in view of the above point, and it is not necessary to install a lower switching mechanism, and thus, no switching operation is required, and only by sliding the operating ring in the optical axis direction, switching from telephoto to wide shooting and close-up photography. And a close-up photographic linear interchangeable lens capable of adjusting the proximity in one operation (one-touch).

Next, embodiments of the present invention will be described with reference to the accompanying drawings.

1 is a longitudinal cross-sectional view of a straight-angle interchangeable lens according to the present invention, but for convenience of explanation, a portion not necessarily in the same cross-section is also shown.

The lens agent is used for correcting the light beams passing through the first lens group L ₁ for the focusing adjustment, the second lens group L _{2 for} the variable shift of the focal length, and the first and second lens groups L ₁ and L ₂ . The third lens group L ₃ and the fourth lens group L ₄ for forming an image. The fourth lens group L ₄ is integrally fixed to the fixed barrel 1 in which the fitting portion to be attached to the chimeric body is formed. In addition to the fixed barrel 1, the barrel 2 and the straight guide cylinder 3 are integrally fixed, and the helicon drum 4 is again fixed to the tip of the barrel 2.

The lens frames 5 and 6 of the second and third lens groups L ₂ and L ₃ are freely mounted on the inner circumferential surface of the bottom barrel 2. Longitudinal grooves 2a and 2b are formed in the cross cylinder 2 along the optical axis direction, and a cam cylinder 7 is mounted on the outer circumferential surface by rotating a ball bearing 8.

Although the cam cylinder 7 is described later with reference to FIG. 2, first, second, and third cam grooves 7a, 7b, and 7c are laid out, and the first cam groove 7a has a lens hood. The pins 9 implanted on the outer periphery of (5) and the pins 10 implanted on the outer periphery of the lens frame 6 are placed on the second cam groove 7b, respectively. Infiltrated via 2b).

The first lens group L ₁ is fixed to the movable frame 11 which is rotatably joined to the helicoid frame 4.

12 is an operation ring for both chucking and focusing, wherein sliding and rotation are freely mounted on the outer circumferential surface of the fixed barrel 1, and a longitudinal groove 12a is formed on the inner circumferential surface thereof and movable in the longitudinal groove 12a. When the projection 11a formed at the rear end of the barrel 11 is engaged and the operation ring 12 slides in the optical axis direction, the movable barrel 11 does not move together, and the operation ring 12 rotates around the optical axis. At one time, the movable barrel 11 is moved and rotated as it is, and the first lens group L ₁ is moved in the optical axis direction by the helicoide frame 4 so that the focus can be adjusted. The straight cylinder 13 is integrally fixed to the operation ring 12 so as to sandwich the movable barrel 11, and the straight golem 14 is integrally screwed to the distal end thereof.

The pin 15 is implanted in the straight golem 14, and the pin 15 is inserted into the third cam groove 7c of the cam barrel 7 through the straight guide groove 3a installed in the straight guide tube 3 along the direction of the lightworm. It is.

Next, the expanded view of the cam barrel 7 is shown in FIG. 2, and the formation of the 1st-3rd cam groove 7a, 7b, 7c is demonstrated.

In Fig. 2, the arrow A indicates the radial direction, the upper side is forward (subject side) and the lower side is rear (pint side), and the arrow B indicates the circumferential direction.

The first cam groove 7a is a linear cam cam groove 7a ₁ inclined in a constant gradient with respect to the optical axis direction (arrow display A) and a close cam groove bent in the circumferential direction (arrow display B) from the front end thereof. 7a ₂ ). The second cam groove 7b is composed of a curved cam groove 7b ₁ curved rearward with respect to the circumferential direction and a close cam groove 7b ₂ bent at an angle in the rear of the optical axis direction from the wide side end thereof. .

Further, the third cam groove 7c for cam groove rotation is a linear cam groove inclined more than the shift cam groove 7a ₁ with respect to the optical axis direction. The length 1 ' _{2 in} the circumferential direction, the length 1 _{3 in the} optical axis direction, and the length 1 ₃ in the optical axis direction of the third cam groove 7c are the first cam groove 7a (the cam cam groove 7a _{1 for the} displacement and the close cam groove). (7a ₂ )) is equal to the length 1 _{2 in} the circumferential direction and the length 1 _{3 in the} optical axis direction.

And the side length ₁₁ of the circumferential direction of the cam groove baeyong (7a _1), the second is a circumferential length of ₁₂ "Short than ₁₁ 'of the cam groove (7c) of the three. That is as follows. 1 ₁ '= 1 ₁ , 1 ₂ = 1 ₂ , 1 ₃ ' = 1 ₃

In addition, the third cam groove 7c is formed in two parallel as shown in FIG. 2 in order to facilitate the movement of the cam barrel 7, and the pins 15 fitted therein also have the circumferential direction of the cam barrel 7c. There are two planted at intervals.

Next, the operation of the present embodiment having the above-described configuration will be described.

When the tissue ring 12 is pulled completely to the rear (pint side), the pin 15 is in the position indicated by T in Fig. 2, and the cam barrel 7 is in the leftmost position, and the pins 9 and 10 are also removed. The position is indicated by 2 degrees T.

At this time, the second lens group L ₂ is in the retracted telephoto position. In this state, when the operating ring 12 slides forward in the optical axis direction (the subject side), the straight halem 14, which is coincided with it, also moves forward (the subject side), and the pin 15 moves in the straight guide cylinder 3 Is guided by the straight guide groove (3a) of the movement in the optical axis direction.

Accordingly, the cam barrel 7 is first rotated, and the pins 9 and 10 are moved along the first and second cam grooves 7a and 7b to extract the second lens group L ₂ to shorten the focal length gradually. The shift is made to the wide axis and correction by the third lens group L ₃ is performed. And when the pin 15 comes to the position indicated by W in the third cam groove by the second figure, the pins 9 and 10 also reach the position indicated by W and are in the wide end position.

FIG. 1 shows the state of each part in this wide end position.

The creek groove 18 is formed in the inner surface of the rear end of the cam barrel 7, and in this state, the creek ball 17 installed in the prism cylinder 2 projected by the leaf spring 16 is inserted into the cam barrel. When the operation ring 12 is moved forward again from this state in which the rotation of (7) is creek-locked, the cam barrel 7 rotates out of the creek lock and again preferentially rotates so that the pin 15 moves forward again.

Accordingly, the pins 9 and 10 move relatively in the close cam grooves 7a ₂ and 7b ₂ of the first and second cam grooves 7a and 7b, but the close cam grooves 7a ₂ are circumferentially directed. The pin 9 stays at the same position even when the cam barrel 7 rotates, and the second lens group L ₂ remains at the maximum feeding position.

On the other hand, since the pin 10 moves rearward in the optical axis direction along the proximity cam arc 7b ₂ , the third lens group L ₃ retreats to be in a close-up photographing state. The positions of the pins 15, 9, and 10 indicated by N in FIG. 2 are the most recent end positions.

On the contrary, when the operating ring 12 is retracted from the foremost position, the cam barrel 7 is rotated and the second and third lens groups L ₂ and L _{3, which} are connected to the pins 9 and 10, respectively, are telephoto in a close-up state. Can be moved and operated.

As described above, according to the present invention, switching between the telephoto end and the wide end between the telephoto end and the wide end within the rotating stroke of the cam barrel 7 by simply sliding the operating ring 12 in the optical axis direction and It is possible to provide an interchangeable lens which can adjust the proximity with one touch, which is extremely operable and allows the close-up photography to be fully utilized by utilizing the characteristics of the straight-angle interchangeable lens.

In addition, there is no need for a special switching mechanism and the like, and simply by changing the cam shape of the cam can be advantageously described.

Claims (1)

The first cam groove 7a fitting the pin 9 implanted in the frame holding the shift lens group L _2, and the _second pin fitting the pin 10 implanted in the frame holding the correction lens group L ₃ . The cam groove 7b and the third cam groove 7c are fitted to the pin 15 moving together with the sliding motion in the optical axis direction of the operation ring 12, and the optical axis is moved around the optical axis direction by sliding in the optical axis direction of the operation ring 12. In the linearism exchange leg provided with the rotating cam barrel 7, the pin 9 mounted on the shift lens group L ₂ is slidably inserted into the first cam groove 7a and the third lens group L ₃ for focus correction. The second cam groove 7b in which the mounted pin 10 is squeezed in a sliding manner is constituted, and the electrical first cam groove 7a is a straight cam shift cam groove inclined with a constant gradient with respect to the optical axis direction A of the cam barrel 7 ( 7a ₁₎ and has a close-up cam (7a ₂₎ for bending to the circumferential direction B from its front end portion, an electric second cam groove (7b) is rearward with respect to the circumferential direction of the cam sleeve (7) Correction cam groove on the gokdoen curve (7b ₁₎ and having an inclined bent-up cam for (7b ₂₎ rearward in the optical axis direction in yihohyeong portion ends, electrical first side of Figure 1, the cam groove (7a) (7b) baeyong cam groove (7a ₁ ) length ₁₁ and near the cam groove as possible (7a ₂₎ length ₁₂ are respectively second correction cam groove of the cam groove (7b) (7b ₁₎ and near the close-up to be equal to the length of the cam groove (7b ₂₎ taken for the straight for the Interchangeable lens.