KR200317550Y1 - Binoculars with optical axis adjustment mechanism - Google Patents

Abstract

It has a pair of barrels having an objective lens, an eyepiece, and a prism inward, and these barrels are connected to the collapsible by a connecting member in which the adjusting knob is located, so as to adjust the optical axis in order to adjust the optical axis. An optical axis adjustment mechanism using a ball member as a hinge means is provided between the necking members.

The optical axis adjustment mechanism includes two sets of adjustment cone members supported by a member fixed to the barrel side, and a ball member positioned between the adjustment cone member and the connecting member, and these members provide a ball member. Has a notch for positioning.

Description

Binoculars with optical axis adjustment mechanism

The present invention relates to a binocular having an optical axis adjustment structure, and more particularly to a binocular to move the left, right barrels while minimizing the space for optical axis adjustment.

In general, binoculars are classified into a captive type and a rope type according to the shape of a prism installed inside the barrel.

The rope-type binoculars have barrels arranged in parallel, and a focus adjusting means for focusing according to the distance of the subject is provided between the barrels.

Therefore, in such binoculars, it is necessary to adjust the optical axis virtually present in the two barrels.

Such optical axis adjustment is performed in the process of assembling binoculars. The optical axis adjustment methods known to date include a prism flow method, an objective lens flow method, and an eyepiece flow method.

Among the above methods, the prism flow method is to drill a screw hole in the binocular body in three directions and insert the adjustment screw into this hole to adjust the optical axis. The objective lens flow method gives an eccentricity toward the objective lens so that it is within the range of the eccentricity. The optical axis is adjusted, and the eyepiece flow method is a method of adjusting the optical axis by giving a flow with an eccentric ring or an adjusting screw.

However, among the above methods, the prism flow method requires a space for the prism to flow, and the objective lens flow method and the eyepiece flow method must increase the size of the body by the amount of eccentricity, so a certain amount of space must be secured in the optical axis adjustment. This is also a condition that is constrained by design.

The present invention has been made to solve the problems of the prior art as described above, the object of the present invention is to provide a binocular with an optical axis adjustment mechanism that can further increase the degree of freedom of design by minimizing the space in the body for optical axis adjustment To provide.

In order to achieve the object of the present invention as described above, the left and right barrels, which hold the objective lens and the contact lens, the connecting member is provided so that the barrel is foldable, and the adjustment knob is provided, and the connecting member and the barrel. It provides a binocular with an optical axis adjusting mechanism provided between the optical axis adjusting mechanism including an optical axis adjusting means for flowing the barrel.

The optical axis adjustment means includes a member fixed to the barrel side, a member fixed to the connecting member side, two adjustment cone members interposed between these members, and a posture facing an inner member of the adjustment cone members. Provided is a binocular having a sheet fixed to the connecting member side and an optical axis adjusting mechanism including a ball member positioned between the sheet and the adjusting cone member and hinged.

1 is a view of a part of the binoculars according to the present invention cut.

Figure 2 is an enlarged view of the main part of the binoculars according to the present invention.

Figure 3 is a view showing the outer side of the adjustment cone member according to the present invention.

4 is a view showing an inner member of the adjustment cone member according to the present invention.

5 is a view for explaining the optical axis adjustment according to the present invention.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail.

1 is a partially cutaway plan view of a binocular according to the present invention, and FIG. 2 is an enlarged view of a main part of the present invention, and reference numerals 2 and 4 represent barrels, respectively.

Although not shown in the barrels 2 and 4, the eyepiece, the objective lens, the prism, and the like have a conventional structure in which they are arranged at a constant distance, and these barrels are connected to which the adjusting knob 6 is located. It has a structure that can be folded by the member 8. Since this configuration is also generally the same as or similar to the configuration used for this type of binoculars, further detailed description thereof will be omitted.

The present invention provides an optical axis adjusting means between the barrels 2 and 4 and the connecting member 8 in the binocular as described above.

The optical axis adjusting means provided in this embodiment is capable of adjusting the optical axis by moving two barrels, and fixing the sheets 10 and 12 to the connecting member 8 side to the left and right of the eyepiece side and the objective lens side, respectively. The adjustment cone members 14 and 16 are positioned in a position opposite to the sheet 12 on the objective lens side, and the ball member 18 is provided between the sheet and the adjustment cone member.

The adjusting cone members 14 and 16 are constituted by two sets. In this embodiment, the adjusting cone members 16 are positioned inside the adjusting cone members 14 so as to have a combination structure.

The adjustment cone member 14 is made of a hollow member having a larger diameter on one side than the other side as shown in Fig. 3 (a) and (b), and the hollow portion 19 is eccentrically biased from the center line L. Take the structure

And on the side with a small diameter, the adjustment groove 20 which can rotate this member with a driver etc. is provided.

Another adjustment cone member 16 inserted into the hollow portion 19 is the same as the member of Figure 3 as shown in Figure 4 has a larger diameter than one side than the other side, this member is a hollow member Notch 22 is formed on the side having a large diameter. This notch 22 is also formed in a state biased to one side from the center line L. FIG.

And this member is also formed with a groove 24 for using a driver or the like on the side of the small diameter, the outer surface 26 of the member is a structure that can be in surface contact with the inner surface of the hollow portion 19 of the member Has

The adjusting cone members 14 and 16 are formed integrally with the barrels 2 and 4 or are fixed to a bracket 28 fixed to the barrels.

The sheet 12 is formed with a notch 30 having the same structure as the notch 22 formed in the adjusting cone member 16, wherein the ball member 18 is located between these notches.

On the other hand, the notch 32 is formed in the sheet 10 on the eyepiece side, and the ball member 34 is located in this notch, and means for pressurizing the ball member are provided on the barrels 2 and 4 side.

Such means for pressing the ball member is composed of a press member 38, which is located on the barrel side, with a screw member 36 screwed into the screw tube. A notch 40 in contact is formed.

Although the above configuration is shown in only one side in the drawings, the same configuration is provided in a corresponding position.

In the binocular according to the present invention made in this way, when the pressing member 38 is not completely tightened in the assembly process, and the adjusting cone members 14 and 16 are turned by a driver or the like, the optical axis is adjusted as follows.

That is, when the adjusting cone member 14 located on the outer side is turned by a driver or the like, the hollow portion 19 of the cone member is eccentrically formed from the center line L. The position of the hollow part is changed to the same state as b).

By the way, since another adjustment cone member 16 is located in this hollow part 19, this member also changes attitude | position.

Therefore, the position of the ball member 18 located in the notch 22 of the adjusting cone member 16 may change as the position of the notch is changed, and the ball member is fixedly seated on the connecting member 8. Since the brackets 28 provided with the adjustment cone members 14 and 16 are moved because they are partially located in the notch 30 of (12), the barrels 2 and 4 with the brackets move left and right. Becomes

Therefore, the optical axis can be changed by flowing the barrel. In this embodiment, since two adjusting cone members are used, fine adjustment can be realized.

That is, by adjusting the optical axis through the outer adjustment cone member 14 as described above, turning the other adjustment cone member 16 can realize the optical axis adjustment by the above-described action.

After the optical axis adjustment is completed, when the pressing member 38 located on the eyepiece side is rotated, the member presses the ball member 80 so that the seat 10 installed on the connecting member 8 is fixed. Will be set. Thus, the adjusted optical axis does not change.

As described above, the binocular according to the present invention uses the ball member as a hinge means to adjust the optical axis by flowing the barrel, so that the conventional prism flow method, the objective lens flow method, or the eyepiece flow method located inside the barrel as in the prior art. It is possible to increase the degree of freedom in design because it does not have to secure a space for optical axis adjustment.

Claims (5)

Left and right barrels with objective and eyepieces; A connecting member to which the barrel is foldable and provided with an adjustment knob; A binocular having an optical axis adjusting mechanism provided between the connecting member and the barrel and including an optical axis adjusting means for flowing the barrel. The optical axis adjusting means may include: an adjusting cone member provided in pairs between a member fixed to the barrel side and another member fixed to the connecting member side; A sheet fixed to the connecting member side in a posture facing an inner member of the adjusting cone member; A ball member positioned between the sheet and the adjustment cone member to hinge; And an outer adjustment cone member of the pair of adjustment cone members, the hollow portion being eccentric, and the hollow portion having an optical axis adjusting mechanism into which another adjustment cone member having an eccentric notch is inserted. The binocular according to claim 1, wherein the sheet and the adjusting cone member are provided with an optical axis adjusting mechanism formed with a notch. The binocular according to claim 1, wherein the optical axis adjusting means is provided with an optical axis adjusting mechanism arranged on the objective lens side. The binocular with an optical axis adjusting mechanism according to claim 1, wherein the eyepiece side is provided with pressing means for setting a state in which the optical axis adjusting is completed. The optical axis adjustment mechanism according to claim 4, wherein the pressing means includes a screw tube fixed to the barrel side and a pressing member coupled to the screw tube, wherein the pressing member contacts the ball member and transmits a fixing force to the connecting member side. Binoculars equipped with.