SU763682A1 - Device for calibrating geodetical instruments - Google Patents

Description

The invention relates to control-adjusting devices for calibrating geodetic instruments, and, in particular, for determining corrections and certification of astronomical and geodetic theodolites, tachometers, quadrants, eclers and eclimeters, goniometers, kicks, and other similar instruments. To determine the basic error of a geodesic instrument and to identify the individual components of this error, various control-adjustment devices (commonly referred to as collimator stands) are used, including a system of collimators placed on a common basis. A device for calibration of geodesic devices is known, which contains several collimators and a table, on which the instrument under test and the reference mirror are alternately mounted for alignment of the collimators. The disadvantages of this device (which is only intended to determine one azimuth; peak correction) are the presence of a reference mirror and the associated cumbersome installation with a rail track, a massive stand of the reference mirror, and the lengthy process of calibration on the collimator of the reference mirror and the test instrument, a large area is occupied by the installation, and it is difficult to handle the measurement results in a cameral approach. The aim of the invention is to enhance the functionality, improve accuracy and simplify the calibration process. This goal is achieved in that the reference long-focus collimator (which can work in autocollimation mode) with an ocular micrometer is mounted on a common stand with a table for installing the test (or checked) device so that the axis of the collimator coincides with the axis of rotation of the test target device device, between the collimator and test 1M device on the same basis is placed a rotary unit, the axis of rotation of which is aligned with the axis of the collimator and has a through hole for the passage of beams learn from the collimator, the rotary unit contains an optical system that shifts the beam of rays from the collimator parallel to itself by no less than the dimensions of the largest of the devices being turned, and then turning this beam by 90 in the same plane as the offset at the intersection of the axis of the displaced beam with the collimation plane of the sighting device of the test device, the output of which is set penta prism. The optical system, mounted on a rotary unit, contains parts in which the number of reflecting surfaces is a multiple of two. On the first reflecting surface of the optical system, an area is marked where the rays from the collimator pass without reflection. The rotary unit is equipped with a high-precision limb and a reading device, anchoring and elevation devices. In this case, the limb is made rearranged. The installation table of the test device is equipped with a lifting mechanism and fixture. The drawing shows a device for surveying geodetic instruments. The device contains a reference collimator 1 for the focus, 1 the device under test 2, the common base of the device 3, a rotary unit 4 having an axis 5 in common with the collimator, a displaced optical system 6; pentaprism 7, counterweight 8, a high-precision device for counting the rotation angles 9, a supplementary prism 10 J through which the rays from the collimator pass without reflection, the lifting instrument table 11 of the test device, the clamping screw 12 of the lifting table, the device 13 for fastening and pointing the rotary unit 4 As is well known, optical prisms with two reflections with their small slopes do not change the mutual arrangement of the incoming. and outgoing optical beams, since the change in the angle of incidence on one of the reflecting faces is compensated by the opposite sign by changing on the other face. A description of the operation of the device is given for the most critical and characteristic calibrations of the azimuthal correction of astronomical theodolites and the inclination of the horizontal axis of any instrument. The test theodolite 2 is placed on the table 11 of the base. Using the lifting device of the table, the horizontal axis of the theodolite is aligned with the axis of the rotary unit, and secured with a screw. When determining the azimuthal correction, the bias optical system 6 is successively set to different zenith distance values and either the collimator mesh into the theodolite tube or theodolite mesh into the collimator tube 1 is observed with two circles, then corrected by appropriate mathematical processing of the measurement results. When determining the slope (non-perpendicularity of the horizontal and vertical axes of the theodolite), install the pipe of the theodolite at the greatest angle of inclination; the theodolite is brought by means of lifting screws to a position in which the theodolite grid coincides with the collimator grid both in the lower and in the upper position; then the circle of the theodolite is rearranged and, by aligning the grid of the theodolet with the grid of the collimator at one of the slopes, the mismatch of the grids is determined by pointing at the other position. When calibrating vertical circles, a high-precision vertical circle of the device, which has a permutation, is used by comparing the sample differences on the theodolite circle and the reference circle during its permutations. The adjustment of the device is carried out when the reference prism (or a polyhedron) is installed on the table with the help of the autocollimation eye of the collimator 1, measured at different positions of the rotary unit 4, the constancy of the position of the optical axis of the device after rotation of the tested devices to the collimation plane. The two-fold reflections in each optical element of the device provide stability — the position of the sighting beam during deformations associated with the rotations of block 4. A matte-scattering surface is used as a source of light for autocollimadiary adjustments of the device so that there is no phase angle from illumination. The device has a universal application. It can be used to determine the basic incidence of an angular-angle device, examine the limbs of the horizontal and vertical circles, determine the inclinations of the horizontal and vertical axes and the angle between them, you can see the extent of horizontal and vertical circles of theodolites with one-sided reading, examine telescope focusing lens stroke, determine azimuth corrections of astronomical theodolites caused by a number of factors, determine collimation, location zenith, place zero at different angles of inclination of the telescope. It is also possible to verify the kipregel in all parameters of the vertical circle, the correctness of the angle of the ekkers and eclimeters, vertical goniometers.

5763682

Claims (1)

Invention Formula A device for calibration of geodetic instruments, containing a reference long-focus collimator mounted on a common May-5 solid base with a table for installing a scanned instrument, characterized in that, in order to expand the functionality, improve the accuracy and simplify the verification process, between the collimator and the rotatable device is equipped with a rotary block containing a reading device and devices for fixing and pointing in height, the axis of rotation of the rotary block with-. placed with the axis of the collimator and made hollow for the passage of the beam of rays from the collimator, the rotary unit contains an optical system that biases the beam of light from the collimator parallel to itself by a size not smaller than the dimensions of the instrument being scanned, the output of which is a pentaprism, the first reflector / surface The bias optical system is configured to pass a portion of the light beam in the forward direction, and the instrument box is adjustable in height.