SU1339472A1 - Aligning device - Google Patents

Abstract

The invention relates to precision instrument making and makes it possible to dilute the operational capabilities of the device by increasing its kinematic rigidity and loading capacity. In the housing 1 are mounted coaxially rings 2 and 5 with the elastic element 7 between them. Adjusting - g (/) 00 oo from 4 N3

Description

screws 6 move the rings 5 and 2 with the mandrel of the optical element 4. The connection of the ring 2 through the elastic ring 3 with the body 1 increases its resistance to movement, which leads to

one

The invention relates to precision rib-building and can be used in optical-mechanical devices, where it is necessary to center the optical element with high accuracy and sensitivity in the order of fractions of a micrometer with the scarlet axial dimensions of the device.

The purpose of the invention is to show the accuracy of HDCT and centering sensitivity.

FIG. 1 shows a schematic diagram of the device, a section; in fig. 2 shows section A-A in FIG. one.

The device consists of a body 1, a main ring 2 installed inside the body 1 and an elastic ring 3 connected to it. On the ring 2 there is a frame for the optical element 4 (mesh, light guide). In addition, the device contains an additional ring 5 5 located inside the main ring 2 and coaxially with it. The additional ring 5 is connected with the adjusting screws 6 arranged through 90 and connected to the main 4 ring 2 by means of an elastic element 7. Rings 3 and 7 can be made of an elastic material, for example, vacuum rubber.

The device works as follows.

When the adjustment screws 6 rotate in pairs, the additional α-ring 5 moves radially perpendicular to the axis of the device, while the elastic ring 7 is deformed and transmits the movement of ring 2 with the frame for the optical element 4. Since ring 2 is also connected by elastic ring 3 to housing 1, its resistance to movement is significantly greater than the resistance to movement of ring 5, and ring 2 with the rim for the optical element will move

the gear ratio between the rings 2 and 5. As a result, the movement of the optical element 4 will be carried out with a gear ratio much greater than one. .2 il.

perpendicular to the device. by an amount smaller than the additional ring 5j t, e „the movement (centering) of the optical element is made with a gear ratio much greater than one.

The gear ratio (i) between the additional 5 and main 2 rings is determined by the ratio of the moments

 resistance to movement of elastic rings 3 and 7. The gear ratio depends on the ratio of the sizes of elastic rings 3 and 7, as well as their physical and mechanical parameters (for example,

5 modulus of elasticity) and grows with the approach of ring 2 to body 1 with constant external dimensions of the additional ring 55, depending on these parameters, reaches values of 100 and

0 more.

Thus, the frame for the optical element 4, placed by the rta ring 2, perceives much less the errors of manufacture of the adjusting screws 6 and the deformation of the ring 2, and can be moved perpendicular to the axis of the device by a small amount with an accuracy higher than i by the known device . In a separate case, it is easy to imagine when the resistance moments of elastic rings 3 and 7 are equal, while the ring 2 carrying the frame for the optical element 4 will move by an amount 35 times smaller than the additional ring 5 ". the accuracy of the centering is doubled, or the manufacturing tolerances of the adjustment screws are doubled. In some cases, when the centrioscale device must move several optical elements to a different size, several additional rings can be aligned with housing 1 at distances determined by the required gear ratio.

In the proposed device, by introducing an additional ring and an elastic element, a gear appears. the exact ratio between the adjusting screws and the main ring 2 with the rim for the adjustable element 4; the introduction of the gear ratio with I leads to a reduction in the manufacturing requirements of the device. This suggests that the production of the proposed device is simpler, cheaper and does not require highly qualified specialists.

Due to its small longitudinal dimensions, the proposed device can be used most effectively in vacuum equipment and space technology, where special requirements are placed on the accuracy of the mechanism, as well as in waveguide spectroscopy systems of the far infrared region, where there is very little space.

waveguides for accommodating optomechanical assemblies.

Claims (1)

Invention Formula A centering device comprising a housing, a holder with an optical element, connected to the housing by means of an elastic element and adjusting screws, the axes of which are perpendicular to the optical axis of the device, differing from the fact that, in order to expand operational capabilities by increasing the kinematic rigidity and loading capacity, into it an additional elastic element is introduced, both elastic elements are made in the form of cylindrical rings coaxially with the holder of the optical element that is placed between them, and the adjustment elements are arranged to cooperate with the additionally introduced ring, which is placed inside the case of coaxially elastic elements. 2