The present application relates to a precision mechanical device, particularly to a three-dimensional adjustment and locking mechanism for precise adjustment of an optical element.
With improving performance of an optical imaging system, further requirements are demanded on adjustment of optical elements: not only adjustment precision of the optical element is required to be micron or even sub-micron level; but also higher requirement is put forward for dynamic response time of an adjustment mechanism; and space arrangement of the adjustment mechanism is required to be compact.
In an embodiment, three elastic adjustment springs Z1, Z2, Z3 are evenly distributed at a bottom of an optical element to be adjusted, and the elastic adjustment springs are connected to the optical element by a central boss 10 as shown in
In the optical imaging system, a typical method of adjusting position of the optical element involves a displacement adjustment in a Z direction along an optical axis thereof and a tilt adjustment with respect to an X/Y direction. In order to correspondingly adjust the optical element, in a known mechanism, a linear guide is used to perform the displacement adjustment in the Z direction and a three-point wedge member is used to conduct the tilt adjustments of the optical element with respect to the X/Y direction. A combination of the linear guide with the three-point wedge member is used to adjust the position of the optical element.
In a high-resolution imaging optical system, there are some technical difficulties upon adjusting the position of the optical element by means of a combined adjustment mechanism including the combination of the linear guide with the wedge member: on the one hand, the combined adjustment mechanism would occupy a larger installation space, which is not consistent with the size requirements on compactness for the adjustment mechanism in the high-resolution imaging system; on the other hand, adjustment error in the combined adjustment mechanism does not meet the high-precision adjustment requirement of the optical element.
In order to solve the above described problems and achieve the precise adjustment of the optical element in the high-resolution imaging system, the present disclosure provides a three-dimensional adjustment mechanism, which performs a high-precision position adjustment of the optical element while only occupying a small space.
In an embodiment, a lever mechanism 20, as shown in
A technical solution of the present disclosure is a three-dimensional adjustment mechanism which includes three elastic adjustment springs, and configured to perform a displacement adjustment in a Z direction and a tilt adjustment with respect to an X/Y direction on basis of deformations of the elastic adjustment springs. When adjusting the position in the Z direction along an optical axis thereof, the three elastic adjustment springs have same deformation amounts of h, and thus the combined adjustment mechanism has a Z-direction adjustment parameter being
Z=(Z1+Z2+Z3)/3=h;
when performing tilt adjustment with respect to an X direction, Z3 remains unchanged, and both Z1 and Z2 have equal deformation amounts but in opposite directions, that is, Z1=h, Z2=−h, and an X-direction tilt adjustment parameter is:
when performing tilt adjustment with respect to the Y direction, Z1 and Z2 have the same deformation amounts and in the same direction, that is, Z1=Z2=h1; and Z3 has a deformation amount of Z3=h2, and an Y-direction tilt adjustment parameter is:
where R is a radius of a circle where the three elastic adjustment members are uniformly distributed.
The adjustment mechanism according to the present disclosure will be further described with reference to the drawings.
In an embodiment, three elastic adjustment springs are evenly distributed at a bottom of an optical element to be adjusted, and the elastic adjustment springs are connected to the optical element by a central boss as shown in
In an embodiment, when adjusting the optical element in the Z direction along the optical axis thereof, the three elastic adjustment members are adjusted so that driving forces at the three elastic adjustment members are the same, and the deformation amounts at the three elastic adjustment members are all equivalent to h. Thus, a Z-direction adjustment parameter of the adjustment mechanism is:
Z=(Z1+Z2+Z3)/3=h;
When performing tilt adjustment with respect to the X direction, Z3 remains unchanged, and Z1 and Z2 have equal deformation amounts but in opposite directions, that is, Z1=h, Z2=−h. Thus, an X-direction tilt adjustment parameter is
When performing tilt adjustment with respect to the Y direction, Z1 and Z2 have the same deformation amounts with the same direction, that is, Z1=Z2=h1; and Z3 has a deformation amount of Z3=h2. Thus, a Y-direction tilt adjustment parameter is:
where R is a radius of a circle where the three elastic adjustment members are uniformly distributed.
In an embodiment, a lever mechanism, as shown in
Number | Date | Country | Kind |
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201810262320.2 | Mar 2018 | CN | national |
This application is a U.S. National Phase application under 35 U.S.C. § 371 of International Patent Application No. PCT/CN2018/125479, filed Dec. 29, 2018, which claims priority to Chinese Application No. 201810262320.2, filed on Mar. 28, 2018. The entire contents of the parent applications are hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/CN2018/125479 | 12/29/2018 | WO | 00 |