SU1597535A1 - Method of certifying pentagonal unit - Google Patents

Abstract

The invention relates to a measurement technique and can be used to control pentagonal blocks. The aim of the invention is to improve the control accuracy by eliminating the influence of the installation error of flat reflectors on the certification results. The platform 2 is rotated around an axis perpendicular to the optical axis of the autocollimator 1 until an image of the autocollimation brand corresponding to the reflection of the beam of the autocollimator 1 from the pentagonal block 6 and the flat reflector 4 is obtained in the field of the autocollimator 1, and then the reading α ₁ on the autocollimator 1 scale is taken. Then turn the table 5 together with the pentagonal block 6 by 90 °; in the field of view of the autocollimator 1, an image of the autocollimation mark corresponding to the reflection of the beam of rays of the autocollimator 1 from the pentago is obtained cial unit 6 and the flat reflector 3, and α ₂ is removed readout on scale 1. Furthermore autocollimator platform 2 is rotated around an axis perpendicular to the autocollimator optical axis approximately 180 ° to give a field of view 1 autocollimator image autocollimation mark corresponding optical communications autocollimator 1 through block 6 pentagonal flat reflector 4, and ₃ α remove count on scale 1. Then autocollimator table 5 is rotated by 90 °, wherein autocollimator 1 is optically coupled through the pentagonal block 6 flat trazhatelem 3 and α ₄ is removed readout on scale 1. autocollimator angle deviation δ pentagonal block from 90 ° is calculated from the formula δ = (Α -Α _{1 2)} + (Α ₄ -Α ₃₎ / 8. 2 Il.

Description

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with

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improving the control accuracy by eliminating the influence of the installation error of the flat reflector on the certification results. The platform 2 is rotated around an axis, perpendicular to the optical axis of the autocollimator 1, to obtain in the field of view of the autocollimator 1 an image of the autocollimation mark corresponding to the reflection of the beam of rays of the autocollimator 1 from the pentagonal block 6 and the flat reflector 4, then take the reading from scale of autocollimator 1. Then turn table 5 together with pentagonal block 6 by 90, in the field of view of autocollimator get 1 image of aiticcollimation mark corresponding to the reflection of beam of rays of autocollimator 1 from pentagonal block 6 and flat

The invention relates to a measurement technique and can be used to control pentagram blocks.

The aim of the invention is to improve the accuracy of control by eliminating the effect of the installation error of flat reflectors on the certification results.

FIG. Figures 1 and 2 show a functional diagram of a device that implements an attestation method for a pentagonal block, with two positions of flat reflectors.

The device contains (Fig. 1) a base (not shown), a 1-liter autocollimator firmly attached to the base, a platform 2 mounted on the base with a rotatable axis, a perpendicular optical axis of the autocollimator 1, two flat reflectors 3 AND; 4, mounted on platform 2 on opposite sides of its axis of rotation so that the normals to them are perpendicular to the axis of rotation of platform 2 and form an angle d between them, table 5,,: installed 1 between flat reflectors 3 and 4 with the possibility of rotation around the axis coinciding with the axis of rotation of the platform 2. Controlled pentagonal block 6 is set on the table 5. The angle must satisfy the following condition:

the reflector 3, and take the reading on the scale of the autocollimator 1. Next, the platform 2 is rotated around the axis perpendicular to the optical axis of the autocollimator, approximately 180. before obtaining in the field of view of the autocollimator 1 an image of the autocollimation brand corresponding to the optical communication of the autocollimator 1 through a pentagon block 6 with a flat reflector 4, and take a reading on the scale of the autocolli ator 1. Then the table 5 is turned 90 by 90, while the autocollimator 1 will be optically connected through the pentagon block 6 with a flat reflector 3, and the count is taken (/ 4 on the scale of the autocollimator 1. The angle cG of the deviation of the pentagonal block from 90 ° is calculated by the formula f (oil- of,) + () / 8. 2 ill.

with | / 2-Sco

0

0

with

0

where (1 is the angle of the field of view of the autocollimator 11

 And - the angle between the optical axis of the autocollimator 1 and one of the flat reflectors 3 and 4; mix the limit value of the deviation of the angle of the pentagonal block from 90.

I The method is carried out as follows.

Controlled pentagonal block. 6 are oriented on table 5 so that one of its reflectors is optically coupled to the autocollimator 1; the parallel beam of rays of the autocollimator 1 is successively reflected from the pentagonal block 6 (Fig. 1), the flat reflector 4, then again from the pentagonal block 6 and enters the autocollimator 1. They take 1 corner count 0 / on the autocollimator scale. Then the table 5 is rotated together with the pentagonal block m 6 by 90 °, while the second reflector of the pentagonal block 6 is optically connected with the autocollimator 1 R in this case the parallel beam of the autocollimator 1 is successively reflected from the pentagonal block 6, the flat reflector 3 then again from

pentagonal block 6 and falls into the autocollimator 1. They remove on the scale of the autocollimator 1 corner count about.

For the first position of the pentagonal block, the following relationship is very fair:

2.- 2 "/ 1,

where is the angle deviation of the pentagonal block 6 from -jf, is the angle between the optical axis of the autocollimator 1 and the flat reflector 4.

For the second position of the pentagonal block 6, the following relationship holds true:

2 y, -f 2/5 s (.

where is the angle between flat reflectors 4 and 3. From these two ratios, one obtains

 (-) - 2/3. .

Next, the platform 2 is rotated approximately 180 to obtain in the field of view of the autocollimator 1 an image of the autocollimation mark corresponding to the reflection of the beam of rays of the autocollimator 1 from the pentagonal block 6 and flat reflector 4, and take the countdown from / 2 on the scale of the autocollimator 1. Then turn the table

5 to 90, in the field of view of the autocollimator, 1 an image of the autocollimation mark is obtained, corresponding to the reflection of the beam of rays of the autocodulator 1 from the pentagonal block

6 and a flat reflector 3, and take the countdown 0 / on a scale of autocollimator 1.

For this position of flat reflectors 3 and 4, the ratio

- r () 2/5.

From the two explanations obtained for cr we can exclude the angle UZ then we get

 -g- (g-H) + (From the obtained compression it follows that the angle between the flat reflectors 3 and 4 does not affect the measurement results.

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about

Thus, the proposed method will eliminate the effect of the error in setting the angle between the flat reflectors 3 and 4 tia, and thereby increase the accuracy

Claims (1)

certification of the pentagonal block 6. The formula of the invention ten The method of certification of the pentagonal block is that. install a pentagonal block between two flat reflectors, j direct a parallel beam of light through the pentagonal block to the first reflector and fix the angle d of the beam direction at the output of the pentagonal block after reflecting 20 from the first reflector, then rotate the pentagonal block to a position where the parallel the beam of rays through the pentagonal block falls on the second reflector, and an angle of 0/2 of the direction of the beam is fixed at: the output of the pentagonal block after reflection from the second reflector, and the angle of the pentagonal block is calculated, characterized in that, in order to increase the control accuracy, the reflectors installed at a given angle to each other are rotated 180 around an axis parallel to the axis of rotation of the pentagonal block, after which the pentagonal block is rotated the beam of rays through the lentagonal reflector falls on the first reflector, and the angle of the beam direction is fixed at the output of the pentagonal block after it reflects from the first reflector, then rotated In-position pentagonal block at which the parallel-beam of rays is through the pentagonal30 35 40 45 0 The new reflector falls on the second reflector, and the angle o is fixed. the direction of the beam at the output of the pentagonal block after its reflection from the second reflector and calculate the angle of deflection of the pentagonal block f from 90 ° rf -o / O -I- (s / 4-s / O eight 2