RU2054620C1 - Method of measuring angles of bihedral reflectors - Google Patents

Abstract

FIELD: testing and monitoring technique. SUBSTANCE: method comprises steps of guiding a light beam onto a bihedral reflector; determining an angle between the light beams of the reflector by measuring a distance between m-images of a reading mark, arranged according to a direction of the light beam before the bihedral reflector and spaced from it by a predetermined distance. EFFECT: enlarged range of angle values to be measured. 2 cl, 1 dwg

Description

 The invention relates to a measurement technique and can be used to measure arbitrary concave and convex dihedral angles formed by flat mirror surfaces, as well as control angles.

A known method of measuring the angles between optically smooth faces of an arbitrary polyhedron, which consists in the fact that the angle between the faces is determined by mechanical rotation of the table with a limb graduated in angular units, on which a polyhedron is fixed, illuminated by the light of the collimator, and taking readings of the limb sequentially at the moments when the beam is reflected first from one, then from the other face into a radiation receiver having a fixed position. Turning to the exact angle requires precision mechanics; The method is implemented in the device reflective goniometer [1]
Closest to the invention, the technical solution is a method for measuring the angles of dihedral reflectors, which consists in directing a beam of rays at the measured dihedral reflector, determining the angle between the beam beams reflected from the faces of the dihedral reflector, determining the angle between the faces of the dihedral from the angle between the reflected beam beams reflector [2]
The disadvantage of this method is the limited range of measured angles.

 The purpose of the invention is the expansion of the range of measured angles of dihedral reflectors.

 The drawing shows a diagram of the implementation of the proposed device.

 The essence of the method lies in the fact that, considering the image of an object simultaneously in both mirrors of a dihedral angle, you can get information about the value of this angle.

 In particular, set the reference mark 1 along the rays in front of the dihedral reflector 2 at a given distance from it.

 One of the options for implementing the reference mark is to make holes in it, and the observation of the m-th images of the brand is carried out through the hole in the mark itself.

< m <

+

где
Φ приближенное значение угла между гранями двугранного отражателя.The angle between the reflected beams of rays is determined by measuring the distance between the two m-th images of the reference mark, the magnitude m of the multiplicity of the images of the reference marks is determined from the ratio:

<m <

+

Where
Φ is the approximate angle between the faces of the dihedral reflector.

 When controlling angles, the nominal value of the angle Ф can be used as the value of Ф. The value of Ф can also be determined by "rough" measuring means, for example, a protractor.

Claims (2)

1. METHOD FOR MEASURING ANGLES OF DOUBLE-REFLECTED REFLECTORS, consisting in directing a beam of rays onto a measured dihedral reflector, determining the angle between the beam beams reflected from the faces of the dihedral reflector, determining the angle between the faces of the dihedral reflectors, the angle between the faces of the dihedral reflector, characterized in that that, in order to expand the range of measured angles of dihedral reflectors, the angle between the reflected beams of rays is determined by measuring the distance between two m-m images about counting marks installed along the beam in front of the dihedral reflector at a predetermined distance from it, and the magnitude m of the multiplicity of the images of the reading marks is determined from the ratio

where φ is the approximate value of the angle between the faces of the dihedral reflector.  2. The method according to p. 1, characterized in that the reference mark is performed with a hole, and the observation of m-x images of the mark is carried out through the hole in the mark itself.

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