SU1755044A1 - Method for checking prism angle and double-side reflector - Google Patents

Abstract

The invention relates to a measurement technique and can be used to control the angles of prisms and dihedral reflectors. The aim of the invention is to improve the control accuracy by doubling the sensitivity. A controlled prism and a reference dihedral reflector are installed on a base basis. The autocollimator measures two dihedral angles formed by the corresponding faces of the controlled prism and the reference dihedral reflector, after which the deviation of the angle of the controlled prism from the nominal value is calculated using the formula (3 (yi) / 4 + Q), where yi and ys are the distances between autocollimation flares in the angular measure in the plane of the eyepiece grid for each of the two angular mirrors formed by the faces of the object being monitored and the reference dihedral frame; (O is the deviation of the angle of the reference dihedral reflector from the calculated value. 6 ill.

Description

The invention relates to a measurement technique and can be used to control the angles of prisms and dihedral reflectors.

A known method of controlling the angles of prisms and dihedral reflectors, which consists in placing a controlled object on a base base of one of the reflecting faces perpendicular to the axis of the autocollimator, rotating the base base, successively reflect a collimated beam of rays from two faces forming a controlled angle, and remove counts on the limb, when the faces of the object, forming a controlled angle, are perpendicular to the axis of the autocollimator, which are used to calculate the deviation of the angle of the controlled object from a nominal value.

The disadvantage of the method is the low accuracy of the control, due to a single reflector of the collimated beam of rays from the object's faces, forming a controlled angle and, therefore, inaccurate alignment of the faces with respect to the axis of the base base to the axis of the autocol / Shmator, not simultaneous, but by separate observation of autocollimation glare from the edges forming a controlled angle.

A known method of controlling the angles of prisms and dihedral reflectors, which consists in installing a controlled object and a reference dihedral reflector on a base, so that the planes of their main sections are parallel, direct the beam of the autoclave to the rpafltf of the dual-dihedral object and the reference dihedral. reflector, measure the position of the autocollimation glare in the plane of the grid.

four

obtained after reflection from the edges of the object being monitored and the reference dihedral reflector, and the deviation of the angle of the object being monitored from the nominal value is calculated.

The disadvantage of this method is the low accuracy of the control, due to its low sensitivity. The magnitude of the angular distance between the autocollimation flare observed in the field of view of the autocollimator is proportional to only twice the deviation of the angle of the object being monitored from the nominal value. At the same time, the error in the mutual installation of the controlled and reference objects in the final result of the control is quadrupled, since the collimated beam of rays is reflected twice from the edge of the reference object.

The aim of the invention is to improve the accuracy of controlling the angles of prisms and dihedral reflectors.

This goal is achieved by the method of controlling the angles of prisms and dihedral reflectors, which consists in placing the controlled object and the reference dihedral reflector on a base, so that the planes of their main sections are parallel, direct the beams of the autocollimator on the edge of the object being monitored and the reference dihedral reflector, the position of the autocollimation flare in the grid plane is measured by the eye of the autocollimator after the registration of the beams of rays reflected from the faces is controlled the object and the reference dihedral reflector, after which the deviation of the angle of the object being monitored from the nominal value is calculated, the angle of the reference dihedral reflector is designed so that it complements the nominal value of the angle of the object being monitored up to 180 °, the object being monitored the symmetry of the angles of the object being monitored and the reference dihedral reflector were combined, the position of the autocollimation flare in the plane of the grid was successively measured ki of the autocollimator eye after reflection of the beam of the autocollimator rays from each of the two corner mirrors formed by the faces of the object under test & reference dihedral reflector and the deviation of the object to be monitored from the nominal value is calculated by the formula

y3 (yi 4-) 74 + so.

where y and 2 are the distance between the autocollimation glare in the angular measure in the plane of the grid of the eye of the autocollimator for each of the two angle mirrors formed by the faces of the object being monitored and the reference dihedral reflector;

a) —the deviation of the angle of the reference dihedral reflector from the calculated value.

In Fig.1, 2 shows a functional diagram of the device that implements the method of controlling the angles of the prisms and dihedral reflectors, and the sequence of operations when controlling the angle of 60 ° prism using a reference dihedral reflector with an angle of 120 °, made in the form of a prism; in Figures 3,4,5 and 6 a combination of prisms and dihedral reflectors with controlled angles of different nominal size and

reference dihedral reflectors with angles that add to controlled 180 °.

A device that implements the method of controlling the angles of prisms and dihedral reflectors, contains an autocollimator 1 and a reference dihedral reflector 2.

Before the autocollimator 1, a base with a controlled prism 3 is set on a base (not shown)

using stops, gauge or gauge, adjustable screws, etc. reference reflector in the form of a prism 2 so that their main section planes are parallel or coincide. At the same time, the nominal value of the reference dihedral angle of the prism 2 is made or selected so that it complements the nominal value of the controlled angle 60 ° of the prism 3 to 180 °, i.e. take a prism of 2 with

a reference angle of 120 °, and the planes of symmetry of the reference and controlled dihedral angles 120 and 60 ° of prisms 2 and 3 are combined with some small error. The edges of the object being monitored, prism 3, and the reference

dihedral reflector, prism 2 form two corner or corner mirrors. Prisms 2 and 3 are fixed in this position and the distance between the autocollimation highlights in the angular measure in the plane of the eye of the autocollimator is measured for each of the two corner mirrors. For this, the collimated beam of the autocollimator 1 reflect from the faces of the controlled and reference prisms 2,3, forming

first corner mirror. In this case, one part of the collimated beam of rays is first reflected from the first face of the prism 2, then from the first face of the prism 3 and returns to the autocollimator 1, the other part

The shammed beam is first reflected from the first face of the prism 3, and then from the first face 2 and also returns to the autocollimator 1. The angle of the first corner mirror, or more precisely, the deviation from 90 °, is determined by the position of the autocollimation highlights in the plane of the eye of the autocollimator. Then, the base base (not shown) together with prisms 2 and 3, without changing their relative position as a whole, move or unfold relative to the autocollimator 1 or the autocollimator 1 relative to the prism block 2 and 3, and install the second angle mirror in front of the autocollimator. In the same way, the angle of the second corner mirror is determined or, more precisely, the magnitude of its deviation from 90 °.

When determining the angle of the first angle mirror formed by the edges of prisms 2 and 3, the ratio

4 (/ 3/2 + 3 + cj / 2) yi,

and when determining the angle of the second angle mirror, the ratio

4 (/ 3/2 + d + y / 2) YI,

where the distance between the autocollimation highlights in the angular measure in the grid plane of the autocollimator's eyepiece for each of the two corner mirrors formed by the faces of the object being monitored and the reference dihedral reflector;

(3) the deviation of the angle of the controlled prism 3 from the nominal value;

6 - angular error of alignment of the planes of symmetry of the reference and controlled dihedral angles of prisms 2 and 3;

(a is the deviation of the angle of the reference dihedral reflector from the calculated value.

From the two relations it is easy to get the formula

/ 3 (yi + кУ4 + о.

The combinations of the controlled and reference dihedral angles of 2.3 prisms, amounting to 180 °, can be very different in their nominal size. Figure 3.4 shows, for example, combinations of prisms 2.3 with a controlled angle of 30 ° and a reference angle of 150 ° and a controlled angle of 90 ° and a reference angle of 90 °, respectively. The dihedral reflector with a reference angle can be made both in the form of a prism, and in the form of a mirror unit. Figure 5b shows a combination of a prism 2 with a controlled angle of 30 ° and a mirror unit 3 with a reference angle of 150 ° and a prism 2

with a controlled angle of 90 ° and a mirror unit 3 with a reference angle of 90 °, respectively. Obviously, the mirror unit can be controlled, and the prism - the reference. In combination with prism ribs

the controlled and reference dihedral angles face each other, and in a combination of a prism and a mirror block, the edges of said dihedral angles face in opposite directions. In this way, combinations of prisms and prisms and a mirror unit are different.

The process of determining the deviation from the nominal value of the dihedral angles of prisms in both combinations remains without

change.

Thus, in the proposed method, due to the formation of two angular mirrors by faces of a controlled and reference dihedral angles of a prism or a prism and a mirror unit, their accuracy in controlling the angle of prisms has increased, since the detected deviation of the controlled angle from the nominal value is inversely proportional to not double the value of the angular the distances between the autocollimation flare in the grid plane, and the quadruple, since the two parts of the collimated beam of rays are reflected from the edges of the controlled angle and both carry formation about his

deviation, increasing the mutual shift of autocollimation glare by a factor of two. At the same time, by measuring the magnitude of the angles of both corner mirrors formed by the monitored and the reference objects, the error of their mutual installation is eliminated and does not affect the results of the control. The effect of the error of the reference angle is two times less than in the known method. The proposed method can

control the most diverse angles of prisms and dihedral reflectors.

Claims (1)

The invention of the method of controlling the angles of prisms and dihedral reflectors is the fact that they install a controlled object and a reference dihedral reflector on a base base so that the planes of their main sections are parallel, direct the beams of the autocollimator on the face of the object being monitored and the reference dihedral reflector, measure The application of autocollimation glare in the plane of the grid of the autocollimator's eyepiece after the registration of the beam of rays from the faces of the object being monitored and the reference dihedral reflector, after which it calculates the deviation of the angle of the object being monitored from the nominal value, characterized in that, in order to increase the control accuracy, the angle of the reference dihedral reflector is performed so that it complements the nominal value of the angle of the object being monitored up to 180 °, the controlled object is installed on the base base so that the planes of symmetry of the angles of the controlled object and the reference Dihedral reflector are escheny successively measured position autocollimation glare grid plane ocular avtokollima1gora ray beams after reflection autocollimator from each of the two corner mirrors formed by the faces of the object being monitored and the reference dihedral reflector, and the deviation of the angle of the object being monitored from the nominal value is calculated by the formula 0 (У1 +} ъУ4 + о, where yi and ft are the distances between the autocollimation highlights in the angular measure in the plane of the grid of the eye of the autocollimator for each of the two angular mirrors formed by the faces of the object being monitored and the reference dihedral reflector; "O is the deviation of the angle of the reference dihedral reflector from the calculated value. 1 2 / I 30 ° ± jS Fig.Z 3Q ° ± j & FIG. five 90 ° ± uJ Fig 90 ° ± J3 90 ° ± o)