The invention relates to an optical magnification system, and more particularly to an optical magnification system with the directional stability of a lens seat improved.
A conventional sight is generally provided with an optical magnification system 1 which, as shown in
During operation of the optical magnification system 1, the outer lens barrel 20 is rotated to slide the first bush 35 and the second bush 45 respectively within the first curved slot 21 and the second curved slot 22. Since the first bush 35 and the second bush 45 are simultaneously slid within the straight slot 11, the first lens seat 30 and the second lens seat 40 are moved along the straight slot 11 relative to the inner lens barrel 10, thereby adjusting the magnification of the optical magnification system 1.
If a clearance between the lens seat and the inner lens barrel is undue, user's view through the lens unit may irregularly jitter relative to the reticle of the sight. To address the problem, reducing the dimensional tolerance between the lens seat and the inner lens barrel may be a solution. However, that requires higher manufacturing accuracy and therefore increases the manufacturing cost.
The invention provides an optical magnification system. The lens seat of the optical magnification system is constrained within the inner lens barrel to avoid uncontrolled rotation, shaking or jittering of the lens seat relative to the inner lens barrel. As a result, the lens seat can be moved stably in an axial direction of the inner lens barrel relative to the inner lens barrel.
The optical magnification system in accordance with an embodiment of the invention includes a first lens barrel, a first lens seat, a first lens unit, a first bush and a first fixing element. The first lens barrel, with a slot formed thereon, includes inner circumferential surfaces and first outer circumferential surfaces. The first lens seat includes a first seat body and a first sliding portion, wherein the first seat body is movably disposed within the first lens barrel, and the first sliding portion is disposed on the first seat body, extends into the slot and is configured to slide within the slot. The first lens unit is disposed within the first lens seat. The first bush is movably disposed on the first lens barrel. The first fixing element extends through the first bush and the first sliding portion and is fixed to the first seat body. The first lens seat is configured to move relative to the first lens barrel and along the slot via the first sliding portion. The first lens seat and the first bush are respectively forced against the inner circumferential surfaces and the first outer circumferential surfaces of the first lens barrel by the first fixing element.
In another embodiment, the first seat body and the first sliding portion are integrally formed as a continuous-unity piece.
In yet another embodiment, the first seat body includes a first recessed portion, and the first sliding portion is disposed in the first recessed portion and extends into the slot.
In another embodiment, the first seat body further includes second outer circumferential surfaces, and the first recessed portion is disposed on the second outer circumferential surfaces.
In yet another embodiment, the optical magnification system further includes a first compression ring configured to fix the first lens unit within the first lens seat.
In another embodiment, the optical magnification system further includes a second lens barrel movably disposed around the first lens barrel, wherein a first slot is formed on the second lens barrel, the first slot is a curved slot, and the first bush is configured to slide within the first slot.
In yet another embodiment, the optical magnification system further includes a second lens seat, a second lens unit, a second bush and a second fixing element. The second lens seat includes a second seat body and a second sliding portion, wherein the second seat body is movably disposed within the first lens barrel, and the second sliding portion is disposed on the second seat body, extends into the slot and is configured to slide within the slot. The second lens unit is disposed within the second lens seat. The second bush is movably disposed on the first lens barrel. The second fixing element extends through the second bush and the second sliding portion and is fixed to the second seat body. The second lens seat is configured to move relative to the first lens barrel and along the slot via the second sliding portion. The second lens seat and the second bush are respectively forced against the inner circumferential surfaces and the first outer circumferential surfaces of the first lens barrel by the second fixing element.
In another embodiment, the second seat body and the second sliding portion are integrally formed as a continuous-unity piece.
In yet another embodiment, the first seat body and the first sliding portion are integrally formed as a continuous-unity piece.
In another embodiment, the second seat body includes a second recessed portion, and the second sliding portion is disposed in the second recessed portion and extends into the slot.
In yet another embodiment, the second seat body further includes third outer circumferential surfaces, and the second recessed portion is disposed on the third outer circumferential surfaces.
In another embodiment, the optical magnification system further includes a second compression ring configured to fix the second lens unit within the second lens seat.
In yet another embodiment, the optical magnification system further includes a second lens barrel movably disposed around the first lens barrel, wherein a first slot and a second slot are respectively formed on the second lens barrel, the first slot and the second slot are curved with different curvatures, the first bush is configured to slide within the first slot, and the second bush is configured to slide within the second slot.
A detailed description is given in the following embodiments with reference to the accompanying drawings.
The invention can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein:
Referring to
As shown in
The first lens unit and the second lens unit are respectively disposed within the first lens seat 195 and the second lens seat 205. In the first embodiment, the first lens unit and the second lens unit are assembled to be an erecting lens unit, and the first lens unit and the second lens unit are respectively fixed within the first lens seat 195 and the second lens seat 205 by adhesive. In another embodiment, the first lens unit is fixed within the first lens seat 195 by a first compression ring (not shown), and the second lens unit is fixed within the second lens seat 205 by a second compression ring (not shown).
Referring to
The optical magnification system 100 further includes a first bush 135, a second bush 145, a first fixing element 115 and a second fixing element 125. The first bush 135 and the second bush 145 are movably disposed on first outer circumferential surfaces of the first lens barrel 110, and more particularly on the first outer circumferential surfaces having the slot 111. The first fixing element 115 extends through the first bush 135 and the first sliding portion 155 and is threaded into the first seat body 130, so that the first lens seat 195 and the first bush 135 are respectively forced against inner circumferential surfaces and first outer circumferential surfaces of the first lens barrel 110. Similarly, the second fixing element 125 extends through the second bush 145 and the second sliding portion 165 and is threaded into the second seat body 140, so that the second lens seat 205 and the second bush 145 are respectively forced against inner circumferential surfaces and first outer circumferential surfaces of the first lens barrel 110. In such arrangement, the first lens seat 195 and the second lens seat 205 are constrained from shaking or uttering in a radial direction of the first lens barrel 110 relative to the first lens barrel 110. In addition, when the second lens barrel 120 is disposed around the first lens barrel 110, the first bush 135 is configured to slide within the first slot 121, and the second bush 145 is configured to slide within the second slot 122.
During adjustment of magnification, the second lens barrel 120 is rotated to slide the first bush 135 and the second bush 145 respectively within the first slot 121 and the second slot 122. Since the first sliding portion 155 and the second sliding portion 165 are simultaneously slid within the slot 111, the first lens seat 195 and the second lens seat 205 are moved along the slot 111 relative to the first lens barrel 110. Moreover, since the first slot 121 and the second slot 122 are with different curvatures, the first lens seat 195 and the second lens seat 205 are moved different distances relative to the first lens barrel 110 and along the slot 111, thereby adjusting the magnification of the optical magnification system 100.
Referring to
In the optical magnification system of the invention, a sliding portion of a lens seat extends into the slot 111 of the first lens barrel 110, and the lens seat and a bush are respectively forced against the inner circumferential surfaces and the first outer circumferential surfaces of the first lens barrel 110 by a fixing element. By such arrangement, the lens seat is constrained from rotating, shaking or jittering relative to the first lens barrel 110, so that the lens seat can be moved stably in an axial direction of the first lens barrel 110. Therefore, when the optical magnification system is applied to a sight, the problems of uncontrolled rotation, shaking or jittering of the lens seat relative to the inner lens barrel can be eliminated, thereby avoiding the requirements of higher manufacturing accuracy and increased manufacturing cost, and even reducing the product defect rate.
Number | Date | Country | Kind |
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201710043495.X | Jan 2017 | CN | national |