SU1165882A1 - Device for checking rectilinearity - Google Patents

Abstract

A DEVICE FOR CONTROL OF A STRAIGHTNESS, containing a mark intended for placement on a controlled object, a compensator made in the form of a plane-parallel plate, a reading drum connected to the compensator, and a sequentially mounted lens, a lens element with a mechanism for its movement along the optical axis of the device, perpendicular to the mark plane , a grid and an eyepiece, forming a sighting tube, characterized in that, in order to improve the measurement accuracy, it is provided with successively located and A light source, a pinhole, an axicon and a reflective element are installed on the optical axis of the tube between the compensator and the lens with a reflecting face in the direction of the lens at an angle to the optical axis so that the lens's light diameter partially overlaps and the grid is mounted so that it is perpendicular optical axis of the tube. S (L with: Ci SP 00 00 GcE

Description

The invention relates to a measurement technique and can be used to measure the linearity and flatness of objects in machine building and instrument making. A device for controlling linearity is known, containing a mark intended for placement on a controlled object, a compensator made in the form of a plane-parallel plate, a reading drum connected to the compensator, and successively installed objects, a lens element with a mechanism for moving it along the optical axis of the device perpendicular to the plane marks, a grid and an eyepiece, forming a sighting tube 1. A disadvantage of the known device is the displacement of the sighting line during refocusing, which reduces the measurement accuracy. The aim of the invention is to increase the measurement accuracy. This goal is achieved by the fact that a device for controlling linearity, containing a mark intended for placement on a controlled object, a compensator made in the form of a plane-parallel plate, a reading drum connected to the compensator and a sequentially mounted lens, a lens element with a mechanism for moving it along the optical axis The devices, perpendicular to the mark plane, the grid and the ocular p, forming the sighting tube, are provided with a successively located light source, a dotted a fragment, an axicon and a reflective element mounted on the optical axis of the pipe between the compensator and the lens with a reflecting face in the direction of the lens at an angle to the optical axis so that the lens's light diameter partially overlaps, and the grid is installed so that it can move in a plane perpendicular to the optical axis of the pipe. FIG. 1 shows a diagram of the device; in fig. 2 is a floor view of the sighting tube. The device contains a compensator 1, made in the form of a plane-parallel plate, installed with the possibility of tilting and fastened with a reading drum (not shown), objective 2, lens element 3, installed with the possibility of movement along the optical axis of the device, grid 4, eye 5, mechanism 6 focusing and connected to the lens element 3, the light source 7, the condenser 8, the pinhole 9, the axicon Yu, giving a sharp image of the diaphragm on the grid 4, the reflecting element 11 mounted on the optical axis and the guide radiation s light source 7 to the grid 4, the grid mechanism 12 perem.escheni 4. The reflective member 11 partially shields only a central portion of the lens. FIG. 2 shows an image 13 of a pinhole on a grid 4, a grid cross 14, an image of the 15th mark on the grid. The device works as follows. A mark is placed on one of the extreme positions (not shown) on the object to be monitored, but a sighting tube opposite it. A mark may be, for example, illuminated. With the help of lens 2 and lens element 3, the image 15 is drawn on the grid 4 on the grid 4. The image of the brand is viewed with an ocular 5. When the 15 image deviates from the cross 14 grid 4 by turning the compensator 1, they are fixed by fixing the result on the reading drum. At the same time, the light source 7 is switched on, its light beam is projected by the condenser 8 onto the pinhole 9 and its image 13 is formed on the grid 4 using the axicon 10, the reflecting element 11, the objective 2 and the lens element 3. The optical axis of the axicon 10 is conjugated through the reflecting element 11 with a pipe sighting axis. In the field of view (Fig. 2) of the pipe, image 13 of the illuminated pinhole 9 must coincide with the center of the cross 14 of the grid. Then the mark is moved along the controlled object, the lens element 3 is refocused to a sharp image of the 15th mark on the grid 4. Due to the inaccurate operation of the focusing mechanism, due, for example, to wear of its parts or misalignment, the sighting line is led away (focusing on the final distance) . Due to the presence of new elements (illuminator 7 and 8, dotted aperture 9, axial ° of the reflecting element I), this screen can be detected by shifting the image 13 of the dotted diaphragm 9 relative to the center of the cross 14 of the grid 4 (position shown in Fig. 2). Since in the device the grid 4 is installed with the possibility of adjusting its position in a plane perpendicular to the optical axis OjO4, removal of the sighting axis can be compensated for by moving the grid 4 by means of the mechanism 12 to a position in which the image 13 of the point aperture 9 coincides with the center of the cross 14 of the grid. Then, the non linearity of the test surface is measured. To this end, using the compensator 1, they align the cent of the image of the mark 15 with the center of the cross 14 of the grid and take the countdown. Thereafter, the mark is transferred to the next point of the test surface and the described processes of refocusing the tube, eliminating the diversion of the sight and measuring are repeated.

The combination of measurement results for various points on the surface characterizes its non linearity.

The positive effect lies in the ability to control and eliminate the diversion of the sighting line when adjusting the pipe to different finite distances, which ultimately contributes to an increase in the measurement accuracy.

Claims (1)

DEVICE FOR CONTINUITY OF LINEARITY, containing a brand designed to be placed on a controlled object, a compensator made in the form of a plane-parallel plate, a counting drum connected to the compensator, and a series-mounted lens, a lens element with a mechanism for moving it along the optical axis of the device, perpendicular to the plane of the mark, a grid and an eyepiece forming a sighting tube, characterized in that, in order to improve the accuracy of measurement, it is equipped with sequentially located sources light beam, a point diaphragm, an axicon and a reflective element mounted on the optical axis of the tube between the compensator and the lens with the reflecting face towards the lens at an angle to the optical axis so that the lens’s light diameter partially overlaps, and the grid is mounted with the ability to move in a plane perpendicular to the optical pipe axis. SU „, .1165882> FIG. 1