CS274160B1 - Method of mapping and device for realization of this method - Google Patents

Abstract

The design concerns the method of mapping and device for application of this method and handles the problem of operational direction finding, possibly also heights of points and plotting of these points into the map in geological surveys, especially in opencast mines or quarries, even within areas with locally interrupted geomagnetic field. The principle of the design lies in the fact that, in mapping of the area, to advantage above fixed datums, at least two measuring scales are located on the stands in the way that they shape a triangle with each aimed point the geometer stands on, while the known mutual angular orientation of the measured scales, which are to advantage oriented with the beginning of their protractor division mutually opposite each other. Subsequently, the numerical values of directions of the connecting lines of the aimed point with the measured scales are deducted on the measured scales from the aimed point, whereupon the protractor discs are fixed in the mutual position and orientation on the drawing-plane-table, while this position and orientation corresponds to the position and orientation of the measured scales in the terrain, and the offset scales, representing the connecting lines of the aimed point with the measuring scales, are set in the way that the numerical values of directions of the connecting lines of crossing points of the offset scales with the protractor discs correspond to the values of directions measured in the terrain. The principle of the design with devices lies in the fact that it consists of two measuring scales (17), telescope (19) with an gradient indicator and plumb bob, and drawing-plane-table (21), which is equipped with a connecting scale (27), whose groove (29) contains two circular discs (31), which are attached to the connecting scale (27) by means of fastening screws (30) in a displaceable and rotational manner. Two offset scales (33) are also connected to the fastening screws (30) in a displaceable and rotational manner.<IMAGE>

Description

The invention relates to a mapping method and a device for carrying out the method, particularly in geological surveying in any environment, i.e. in a locally damaged geomagnetic field.

Until now, a detailed geological survey of mine fields, large construction sites, and the associated geological phenomena, has been carried out very rarely due to its time and personnel demands. It fell into two to three terrain and two office stages carried out in the following time sequence. First, a detailed geological mapping is carried out, during which a sketch of geological and possibly other phenomena and objects, some of which can be used for orientation in the terrain, is drawn during a terrain walk, for example in a surface mine. Then geodetically survey geological or other phenomena and objects, respectively characteristic, i.e., breakpoints of their orbit and ae orienteering points, then the coordinates and heights of these points are calculated and their position plotted on a map or plan. At the same time, the geological situation is drawn into a detailed geological map or plan based on the field sketch, followed by a possible confrontation of the geological map or plan, respectively geological profiles with reality.

Existing methods useful for locating the position of geological or other phenomena and objects can be divided into intersection methods, in which the meter stands, operating the measuring instrument or measuring table at the surveying points, which bypasses and places the measuring instrument on them, or intersecting methods forward or polar methods, in which the meter stands outside the surveyed points, at fixed points, ie points with known coordinates and height, from which there is a good view of the mapped area. They then place a measuring instrument or measuring table on them and the aiming points bypass the helper with the target or target, or the measuring lath or reflective prism and the like.

The disadvantage of these methods is the personnel intensity of the measurement, which requires, in addition to the geologist, one meter and one helper. If a geologist represents the meter or helper, this is at the expense of the geological work itself. Another disadvantage of these methods lies in the necessity of acquiring a geological sketch, in which the points are also indicated. At the same time it is necessary to solve the cooperation of the geologist and the meter and further avoid the possibility of confusion of detailed points.

The aforementioned disadvantages of the prior art measuring methods eliminate the method of mapping and the apparatus for carrying out the method according to the invention, wherein the mapping is performed with a direct graphical record on the drawing board using the measuring scales. The principle of the method is that at least two measuring scales are placed on tripods in the mapped area, preferably above fixed points, so that a triangle is formed with each point of orientation on which the mapper is positioned, whereby the relative angular orientation is known measuring scales, which are preferably oriented at the beginning of their angular division with respect to each other, then the numerical values of the directions of the points of the aiming point with the measuring scales are subtracted from the surveying point, then the protractor discs are fixed on the drawing board corresponds to the position and orientation of the measuring scales in the field, and the extension ruler representing the point-to-point connection with the measuring scales is set so that the numerical values of the intersection points of the intersection rulers with the protractor discs correspond to the measurement direction values in the field. The apparatus for carrying out the method consists of two measuring scales consisting of protractors of annular shape, a telescope with a inclinometer and a plumb line and a drawing board. The principle of the solution of the device consists in that on the measuring scale there is provided a supporting plate, on the perimeter of which is fixed an arched cover with guide grooves in its lower and upper part, in which a numerical scale shading is provided. at the ends of the arch cover. The drawing board is provided on its vertical sides with a linear scale and a guide groove, in which a slider is provided, provided with a fixing screw and a pin to which a connecting ruler provided with a linear scale and a groove is slidably connected. In this groove

CS 274160 B1 two circular discs equipped with a protractor scale are slidably and rotatably attached to the connecting ruler by the fixing screws in the center and at the same time two linear scales with a linear scale are slidably and rotatably attached to the fixing screws in their groove. The extension rulers are connected to each other by a double slider, the two parts of which are displaceably mounted on the two extension rulers, are connected by a removable hollow axis provided with a recording tip. The drawing board is further adapted to be provided on its horizontal sides with map winding systems consisting of a housing in whose bearings located at the front of the housing are rotatably mounted winding spools provided with a slot and a clamp, the winding spools being rotatable on the side of the housing buttons. The two adjacent sides of the drawing board are further provided with winding drums, on which rotary knobs are provided, and in whose teeth the perforations of the strip fit where the numerical values of the coordinates of the conventional maps are marked.

An advantage of the method according to the invention is that all geological mapping work is carried out by a single geologist. A geologist who, after prior preparation associated with the deployment of measuring scales, moves only on mapped geological objects, after position and height measurement, preferably by means of a hand-held telescope centered by a plumb line above the aiming point, which also depicts geological phenomena, ie it performs its own geological mapping. The drawing board is carried in the hand or attached to the mapper body. This eliminates the drawing of a geological sketch, since the geologist directly draws the geological map on a uniform scale; it is possible to immediately detect any discrepancies and correct the map. All five stages of detailed geological mapping take place simultaneously, while the office stages are reduced to the final layout of the map. This greatly shortens the time to produce a detailed geological map and reduces the workload of the geologist himself. It can be mapped in any environment, ie where the regional geomagnetic field is violated.

An exemplary embodiment of a mapping method and apparatus according to the invention is shown in the accompanying drawings, which are not to be construed as limiting the invention, wherein FIG.

FIG. 2 shows a measuring scale 17 formed by an annular-shaped protractor disk 6, which is provided with a protractor scale 2 on its periphery. The protractor disk 4 is slidably connected to a holder 3 which is slidably connected to a vial 7 frame 4. The frame 4 is further provided with a pin 8 for seating in a tripod 9 mounted on a geodetic or photographic tripod 10. A support plate 11 is rotatably mounted on the pin 8, on the periphery of which At the ends of the arch cover 12, winding drums 15 are mounted on the ends of the arch cover on which a screen 14 provided with a numerical scale 16 is provided.

Giant. 3 shows a plan view of the measuring scale 17 where the guiding of the screen 14 by the winding drums 15 can be seen. The screen 14 is guided in guide grooves 13, which are provided with an arch cover 12 in their upper and lower parts.

FIG. 4 shows a rectangular drawing plate 21 having a linear scale 23 and a guide groove 22 on its vertical sides in which a slider 25 is provided with a fixing screw 24 and a pin 26 to which the best transparent connecting ruler is slidably attached 27, provided with a linear scale 28 and a groove 29, in which two preferably transparent circular discs 31 provided with a protractor scale 32 are attached to the connecting ruler 27 by fixing screws 30, preferably perforated, sliding and rotatable in their center. The two best transparent delivery rulers 33 provided with a linear scale 34 are slidably and rotatably connected to their groove 35. The delivery rulers 33 are connected to each other by a double best transparent slider, the two parts 36 and 37 of which are slidably mounted on both delivery lugs.

CS 274160 B1 of the lids 33 are connected by a removable hollow axis 38 provided with a writing tip 39. The drawing board 21 is further adapted to be provided on its horizontal sides with a map winding system 40 consisting of a housing 41 in whose bearings located at the front of the housing 41, the winding coils 42 provided with the slot 43 and the clamp 44 are rotatably mounted, the winding coils 42 being disengaged from the sides of the housing 41 in the form of a rotary knob 45 with a clamp lever 46 in its cutout. they are further provided with winding drums 47, on which rotary knobs 50 are provided, and in whose toothing 48 the perforations of the band 49 are inserted, on which the numerical values of the coordinates of conventional maps are marked. By means of the rotary knobs 50, the respective coordinate values can be set in the slots 51.

The function of the device is characterized as follows: We place each of the measuring scales 17 on a fixed point, ie a point of known coordinates and height, which is visible from the largest part of the mapped area. In this case, we select preferably fixed points whose respective pair forms together with each of the measured detailed points a triangle whose arms adjacent to the measured point make an angle of 30 to 150 °, preferably 90 °. and the length of these arms does not differ in the order of magnitude. The orientation of the protractor scale 4 of each protractor disc 4 is oriented to the south or to the north for absolute orientation, or the pair of protractor discs is oriented toward each other at the beginning of the protractor scale li for relative orientation. In general rotation of the protractor scales je it is necessary to know their mutual directional orientation. If we do not know the coordinates of the points on which the portable measuring scales 17 are located, it is necessary to measure their mutual distance beforehand; We then orient the protractor discs 1 against each other at the beginning of the protractor scales 2. After positioning and orientation of the measuring scales 17, we stand on the measuring point and use the telescope 19, which is held in the hand or mounted on a tripod and its position can be guided by a plumb line. the numerical value of the direction or azimuth of the connection line of its station, which is identical to the measured point, and the measuring scale 17. We then subtract the position of the projection of the filament 6 passing through the axis of the protractor disk 1 on the front and rear sides of the protractor disk. In this case, the screen 14 is set to a position in which its values of the numerical scale 16 coincide with the values at the rear of the protractor disk 6 as viewed by the observer against which the screen 14 is set. This allows the front and rear parts of the protractor disc 4 to be mutually aligned at any inclination angle to the protractor disc. As a result, the error in reading the angular value of the direction of the line of sight is reduced by half in comparison to the mere reading of the projection position of the filament 6. At the same time, the error caused by the possible eccentricity of the filament 6 relative to the axis of the protractor disk 1 is also eliminated. If we also determine the altitude of the measured points, we measure the inclination by one or more pendulum inclinometers. The elevation of the measured point with respect to the measuring scales 17 can be either calculated or found in a graph. In addition to the measured elevation angles, the input data are also the project lengths of the measuring scales 17. These project lengths are measured from the map to which we have plotted the position of the measured point as follows: First, fix both circular disks 31 to the ruler 27 points in the field. The orientation of their protractor scales 32 is aligned with the orientation of the protractor discs 6 of the measuring scale 17 in the field. Then set the extension rulers 33 to a position where the numerical values on the protractor scales 32 coincide with the values read in the terrain on the measuring scales 17. The intersection of the two extension rulers 33 indicates the position of the measured point on the map.

The mapping method and the apparatus for carrying out the method can advantageously be used to locate geological or other phenomena and objects and to plot their location on a map or plan. They are most often used for mapping areas with large and numerous geological ones

C3 274160 B1 exposures, particularly in open-cast mines or quarries, even in area b by a locally damaged geomagnetic field.

Claims (2)

A method of mapping with a direct graphical record to a drawing board using measuring scales, characterized in that at least two measuring scales are placed on tripods in a mapped area, for example above fixed points, such that with each surveyed point on which they stand the mapper forms a triangle, whereby the angular orientation of the measuring scales is known, which are preferably oriented at the beginning of their angular division with respect to each other, then the numerical values of the directions of the connecting point of the measuring point with the measuring scales are subtracted The protractor discs are fixed to each other in the position and orientation that correspond to the position and orientation of the measuring scales in the field, and the extension rulers representing the points of the aiming point with the measuring scales are set so that the numerical values of checks rulers with úhloměrnými discs correspond to the directions measured in the field. 2. Apparatus for carrying out the method according to claim 1, comprising two measuring strips, consisting of protractors of annular shape, a telescope with a inclinometer and a plumb line and a drawing board, characterized in that a supporting plate (11) is provided on the measuring scale (17). on its periphery there is attached an arch cover (12) provided in its lower and upper part with guiding grooves (13), in which the screen (14), provided with a numerical scale (16), which surrounds the winding drums (15) the drawing plate (21) is provided on its vertical sides with a linear scale (23) and a guide groove (22), in which a slider (25) provided with a fixing screw (24) and a pin (26) is provided ), to which a connecting ruler (27) provided with a linear scale (28) and a groove (29) in which the fixing screws to the connecting ruler (27) are fixed by screws (30) two circular discs (31) provided with a protractor (32) are displaceably and rotatable in their center and at the same time two extension rulers (33) provided with a linear scale are slidably and rotatably attached to the fixing screws (30) in their groove (35) (34), wherein the extension rulers (33) are connected to each other by a double slider, the two parts (36 and 37) of which are displaceably mounted on the two extension rulers (33) are connected by a removable hollow axis (38) provided with a recording tip ( 39), wherein the drawing board (21) is further adapted to be provided on its horizontal sides with map winding systems (40) consisting of a housing (41) in whose bearings located at the front of the housing (41) are rotatably mounted winding the spools (42) provided with the slot (43) and the clamp (44), the winding spools (42) being provided with rotary knobs (45) on the side of the housing (41), and two adjacent sides to the the die plates (21) are further provided with winding drums (47) on which the rotary knobs (50) are provided, and whose teeth (48) fit the perforation of the tape (49) on which the numerical values of the coordinates of conventional maps are marked.