SU841607A3 - Device for determining object slope direction - Google Patents

Abstract

Angle indicating device, to indicate when there is a predetermined angular position between a fixed first part and a movable second part relative to said fixed part by an easily recognizable indication, in which said fixed and mobile parts have an optical constitution, screen constituted by an image or grid that comprises opaque lines separated by interspaces that at least in the image located in the zone of vision closest to the observer are transparent.

Description

(54) DEVICE FOR DETERMINING THE DIRECTION OF OBJECT TILTING

stoppers in two mutually perpendicular planes.

FIG. 1 shows schematically fixed and moving parts with rasters on them (the first option); in fig. 2 — frontal projection of the device acting as a bubble level; in fig. 3 section of the device; in fig. 4 - 6 - disk lattices (rasters), with each of the figures showing the indication in the main position of the disk lattices with respect to each other; in fig. 7 and 8 — the first and second gratings with four zones (the second variant) in FIG. 9 — rectangular lattice; in fig. 10 - 12 disc gratings, each of the figures shows an indication of the main position of the disc gratings with respect to each other.

Invention. Applicable to devices used as bubble levels. In this application, a raster with one pitch is applied on a fixed part, and a raster with another pitch is applied on a movable part, which is designed in such a way that under the action of gravity is set in a certain position, in which the center of gravity of the movable part is located offset from the axis rotation of the movable part.

Obviously, the movable part will always be installed in a certain position, with the center of gravity positioned vertically on the axis of rotation. The moire pattern, which is formed between the Ш of the Ш of the fixed part and the movable part, when the fixed part with the edge or end used for this purpose is attached to the exactly horizontal or vertical part, will assume a certain and easily recognizable shape. A simple implementation of a device intended for use as an inclinometer includes a stationary part in the form of a body in which a movable part with a center of gravity is located, rotated relative to the axis of the axis and the display window to observe the moire pattern.

FIG. Figure 1 shows two disk arrays (rasters) 1 and 2 consisting of a circular disk equipped with a plurality of opaque lines constituting the grid. The first disc grille 1 is fixed on the fixed part and the second 2 on the moving part. The disc grille 1 has a pitch 3, which differs from a pitch. L on the second, disk lattice 2. The first disk lattice 1 is provided with three parallel regions 5-7 with 1 lattices, each of the regions having lattices different from those in the neighboring regions. The second disc grille 2 is equipped only

Grid 4, Areas 5 and 7 have a smaller step than the central area b. Unsigned lines 8 have equal

the width in three regions 5-7 on the disk grid 1 and on the disk grid 2, Lines 8 have a width on the order of 0.6 mm. The distance between the lines of the central region b is about 0.2 mm, in areas 5 and 7, about 0.4 mm, and in grid 4 it is about 0.3 mm. Interference between gratings of the type described above results in distinct patterns in different positions of grids 1 and 2.

Fig. 2 shows a device used as a bubble level. It contains a stationary hour 9 in the form of a square case (Fig. 3) contains an internal cavity 10 in the form of a cylinder, in which the movable part is mounted in the form of a second disk grill 2 in such a way that it rotates around a horizontal axis 11 of rotation. The lattice 2 has the shape of a circular disk with plane-parallel sides and can be made of a transparent plastic material,

The center of the disk tin is displaced from the axis 11 of rotation. The housing 9 has an indication window 12 located above the axis of rotation 11 (Fig. 2).

With the passage of light through two gratings, an interference image is created due to the interference between the opaque lines 8 and the transparent gaps between the lines on the first disk array and the grid on the second disk.

Figs 4-6 show three ti f interference images that are created by two disk arrays 1 and 2.

The arrangement of the disk arrays 1 and 2 leads to the fact that three different interference images can be obtained when the arrays 5-7 are combined with the second disk grating 2.

When the grids 1 and 2 have a position in which the lines of the disk grate are parallel 8, an interference pattern is obtained, which consists of essentially three different patterns.

Wide dark bands 13-15 parallel to the grating lines (Fig. 4). Each wide strip 13–15 is centrally located in each area of 5–7. Lines 13–15 C9 set the pattern sensitive to the rotation of the first disk relative to the second, since at a small angle between the lines of the grid 1 and 2 of the disks there are wide lines 13–15 will not be parallel along the entire length.

Claims (3)

When the second disc grating 2 is rotated counterclockwise at a small angle relative to the first disc grating, an interference pattern is created (Fig. 5), the outer bands 13 and 15 are angled with an inclination to the right, while the central strip 14 is tilted to the left. The ends of the central band are connected with the ends of the outer 13 and 15 to form a figure in view 2. When the disc grating 2 is rotated clockwise at a small angle relative to the first, a pattern in the form of 2 is created. This is a mirror image of the figure Z. of the first case (Fig. 6). Thus, the device indicates the direction of inclination of the surface with respect to the horizontal or vertical plane. If the device is used as a bubble level, only the first disk grille can rotate c and fix in two positions perpendicular to each other, for example, when the grid lines 8 are parallel to the longitudinal axis of the object being measured or they are perpendicular to the specified axis. FIG. 7 shows two disk grids in accordance with the second implementation of the invention. The discs 16 and 17 may be round, rectangular. Each of the discs 16 and 17 contains four regions provided with gratings, and the gratings with one type of partitions are in two regions of each part, different from those in two other regions of each part. The grids 18 and 19 are limited to the outside of the disk by two chords 20 and 21, and the indicated areas are limited by chords 20 and 21 to one diameter running parallel to the chords and the diameter passing perpendicular to the chords, so that the areas form four quadrants 22-25. The grids 18 and 19 consist of opaque lines 8, having a width of 0.6 mm on each of the two disks 16 and 17, the distance between the lines in the grids in two quadrants 22 and 24 is less than in the other two squares 23 and 25 The spacing between lines 8 in quartz 22 and 24 is about 0.2 mm, and at 23 and 25 it is about about 0.4 mm. In the assembled state of the device, the disks 16 and 17 are arranged in such a way that the rectangular regions of the grids are located one above the other. When the grids 1 and 2 are rotated, an interference image is obtained having the form depending on which direction the first disk grating is rotated relative to the second one. When, for example, the stationary part 9 is located on a surface inclined to the horizontal plane, the grille of the disk 16 is inclined to the horizontal plane, while the lattice of the disk 17 is installed parallel to the horizontal plane under the action of its center of gravity, located outside of its center of rotation. When the disk grids 18 and 19 on the disks 16 and 17 are parallel to each other, an interference image is obtained consisting of wide black bands 26 parallel to the opaque lines 8 (Fig. 10). If the disc grating 17 is rotated clockwise with respect to the disc grating 16, an interference shape of a diamond shaped 27 is obtained. (Fig. 11), when the disc grating 17 is turned counterclockwise relative to the grating 16, the interference image has the shape of a cross ( Fig. 12). When the disc grating 17 is rotated with respect to the disc grating 18, first clockwise and then against, the diamond 27 is compressed to a strip 26 (FIG. 10), which, with continued counterclockwise rotation, is divided into a cross-shaped image 28 (FIG. 12 ) ,. The device provides clear and easily perceived information about the inclination of the fixed part 9 with respect to a certain position and the direction of the angle of inclination from this position. Claim 1. A device for determining the direction of inclination of an object, comprising a body, fixed and movable parts with rasters applied on them, forming moire patterns upon imposing and reciprocal rotation of said parts, and rasters are applied to movable and stationary parts with different pitch, characterized by that, in order to simplify the determination of the direction of inclination, the rasters applied on the fixed part are divided into several adjacent zones, square or rectangular in shape, in each of which the rasters have a different shape Different from the pitch area adjacent raster and on the pitch of the corresponding zone raster applied to the movable part .. 2. The device according to claim 1, characterized in that the non-moving part is divided into three parallel zones, and the raster of the central zone has a step different from the same one. step of the zones surrounding the central zone, and the raster step of the movable part is equal in magnitude to half the step of the central and its surrounding zones. 3. The device according to claim 1, characterized in that