SU1352208A1 - Device or measuring curvilinear surfaces - Google Patents

Abstract

The invention relates to the field of optical instrumentation and can be used in the installation of cylindrical storage tanks. The purpose of the invention is to increase the measurement performance. The device contains mounted on the base 1 can be rotated. around a common horizontal axis 4, lasers 2 and 3. The optical axis of laser 2 is perpendicular to common axis 4, and laser 3 can rotate around axis 5. In this case, the optical axes of both lasers lie in the same plane. The device is equipped with a vertical stand 6, mounted for movement on the carriage 7 by means of a screw 8, and also a means 9 for counting the displacement of the vertical stand 6. When the axis 4 rotates, the laser body 3 slides on the vertical stand 6, turning around the axis 5, Consequently, the rays Lasers 2 and 3 always intersect at a vertical straight line, separated from the device at a distance corresponding to the indication of the indicator 9.1 Il. I (L

Description

The invention relates to optical instrumentation and can be used when mounting cylindrical tanks of oil storages.

. The aim of the invention is to improve the performance of measurements. The drawing shows the proposed device and the following notation is adopted: 1 - leveling base; 2 and 3 — radiation sources, for example, lasers mounted rotatably around a common horizontal axis 4; 5 is the axis of rotation of the laser 3, perpendicular to the horizontal axis 4; 6 - vertical rack mounted on the carriage 7; 8 - screw for moving the carriage 7; 9 is a means of sampling a vertical post 6, for example, an indicator; 10 - tripod; 11 - auxiliary support. I The device works as follows.

A tripod 10 with a base 1 fixed on it is placed in the center of the structure to be measured, for example a tank. The other end of the base is supported on the auxiliary support 11 so that the base 1 is located in the horizontal plane. Using a screw 8, the indicator 9 sets the distance at which the beams of lasers 2 and 3 intersect, equal to the radius of the tank. Moreover, if the tank wall is closer or farther than a given radius, it will have two spots from the radiation of lasers 2 and 3. Rotate the screw 8, converging both spots into one and the indicator 9 determines the true radius of the tank at this point and, respectively , deviation from the specified radius. By turning the device around a horizontal axis 4, the tank is measured at the desired horizon in the same way. Since during the rotation of the device around the horizon editor L. Povcan

Compiled by I. Gaponenko

Tehred A. Kravchuk Proofreaders. Muska

Order 5550/35 Circulation 677 Subscription

VNIIPI USSR State Committee

for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5

. Production and Printing Enterprise, Uzhgorod, ul. Proektna, 4

4, the body of the laser 3 slides on a vertical stand 6, rotating at this point around the axis 5, the rays

Lasers 2 and 3 always intersect at the same vertical straight line, separated from the device at a distance corresponding to the indication of indicator 9. Due to this, the device

allows to measure the tank on any horizon without recalculating the readings of the indicator 9 depending on the vertical angle of rotation of the lasers 2 and 3.

Claims (1)

Invention Formula Device for measuring curvilinear surfaces, preferably vertical cylindrical structures containing a levelable base mounted for rotation around a vertical axis, two optical devices, one of which is a source of radiation mounted rotatably around a common horizontal axis, while the optical axis of the radiation source is perpendicular to a common horizontal axis, characterized in that, in order to increase the measurement performance, a vertical bar is installed in the device mounted on the base moving in a direction parallel to the common horizontal axis and provided with a means of counting the movement, the second optical device is also a radiation source and is installed with the possibility of rotation of the circle axis perpendicular to the common horizontal axis so that the optical axes of both radiation sources lie in the same plane, at In this case, the body of the second radiation source is spring-loaded and contacts the vertical stand when it is rotated around a common vertical axis.