FI60780C - FOER REQUIREMENTS FOR THE MAINTENANCE OF DISTANCE MELLAN EN MAETNINGSPUNKT OCH ETT FOEREMAOL - Google Patents

Description

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Patent · och registerstyrelsen Antekui uttagd och utl.tkriftvn publkarad 11 8l (32) (33) (31) Requested priority —Baflrd prlorltct (71) (72) Jaakko Tapio Keinänen, Karsikkovaara, 73600 Kaavi,

Suomi-Finland (Fl) (7b) Oy Jalo Ant-Wuorinen Ab (5 * 0 Method and apparatus for measuring the distance between a measuring point and an object

The invention relates to a method and an apparatus for measuring the distance between a measuring point and an object (in particular for determining the distance between a rock quarry wall), the method sights (i.e., binoculars).

In a known measuring method, a sequence of fixed points is detected, the last two points of which form the base of the catheter with respect to the direction to be measured in the quarry. A laser beam is required to indicate the point of the measurement object. From these two points, observations and calculations are performed as a forward cut. The downside of this method of measurement is the necessary expensive measuring equipment, the large amount of work and time-consuming calculations.

The invention relates to a time-saving measuring method in which the calculations can be performed as a main calculation during the measuring work and, above all, the measuring means are cheap.

2 6 0 7 8 0 This object is achieved mainly on the basis of the features of the invention set out in claim 1. It is a further object of the invention to provide a simple, inexpensive and reliable device for carrying out the method according to the invention. The main device-specific features appear from claim 2.

Other advantages and features of the invention will become apparent from the following description. There, the invention is described with reference to the accompanying drawing, in which Fig. 1 shows a device according to the invention seen from above in quarry space measurement, Fig. 2 shows the same device in quarry space measurement seen from the side, and Figs. 3 and 4 show the principle of measuring light balloons and laser implementations.

The device according to the invention comprises a light source 1 in which, for example, a 7.2 w dot burner is used as the burner. The enclosure must be dark-walled so that no reflections occur. An ordinary double-convex lens emits a beam, creating a sharp-edged circle of light on the surface of the object to be measured. This size of the light circle can be reduced by turning the light circle adjuster away from the bulb. The light circle increases when the control piece is rotated closer to the burner. When the size of the light circle is measured, for example, from a distance of 50 m, the size of this light circle can be adjusted from the control piece. The diameter of the circle is then measured and divided by the length of the distance. This is how you know how much the light circle grows per meter or distance measured. The revised size of the light circle is kept constant throughout the series of measurements. The direction of the light circle can be guided horizontally and vertically. The magnitudes of the vertical and horizontal angles are measured, for example, with theodolite.

Thanks to its power, we can use the laser beam for longer distance measurements and even in the brightest places. The laser tube is placed, for example, by moving the marker needle in the tube to a certain horizontal angle in the graduated dimension 12 in the measuring stand 9 with the values we have obtained in the test measurement by how much the beam differs per meter of distance.

The diameter of the light circle is measured by means of line sights 10 'or sighting binoculars 11' in the measuring stand 9. The task is performed by placing either the left or right line sight 10 'perpendicular to the edge of the circle of light on the line of sight, and then the second line sight 10' toward the other edge. The readings are then read from the millimeter-sized measure in the measuring stand 9. The distance (= difference) between the line sights is calculated and is equal to the diameter of the light circle.

Now that we know the distance per meter of the growth of the light circle measured in the experimental measurement, we also know the length of the distance to be measured. The light circle can be measured at a distance of 0-50 m, in good conditions even longer, while the edge of the light remains relatively sharp when measuring the edge of the light circle.

Laser beam measurements are performed by means of line sights 10 'or measuring binoculars 11' in the same way as in light circle measurements. For example, the laser tube 2 is placed in the correct edge position and the line sight is aligned here. The Laser Tube is then moved to the left edge position and the line sight is aligned to this. Now you can read the difference between the line sights, so we also know the length of the trip.