CZ2011636A3 - Reflecting device for electronic measuring distances - Google Patents

Abstract

The reflective device for electronic length measurement is formed by at least three identical plates (6) in the shape of a rectangular rectangle, which are provided with a reflective foil (7) with a target at one of their side edges. The reflective foil (7) is positioned so that the vertical axis of the target lies at this side edge and one half of the target is located on one side of the board (6) and the other half is positioned against it on the far side of the board (6). The centers of the target on all plates (6) lie in the same plane parallel to the lower edges of the plates (6). The plates (6) thus formed are edges at which the reflective foil (7) is connected and the connection forms a longitudinal axis of the reflective device. The angles enclosed by the adjacent plates (6) are equal and equal to 360 [mu] s / n, where n is the number of plates used (6). The variant solution of the retro-reflector is made up of six identical plates (6.2) in the shape of an isosceles triangle, whereas the triangles of the triangle form an apex angle of 109.5.degree .. These plates are connected to each other in such a way that they meet at their apex angles and this is the center of the body. The plates (6.2) are provided on both sides at the apex angle with a reflective foil (7) with a portion of a circular disc-shaped target covering the entire area of the plate (6.2) at its apex angle, where the centers of these parts of the target are in the center of the resulting body.

Description

Reflective tool for electronic length measurement

Technical field

The present invention relates to a device which is intended for electronic length measurement enabling multi-directional targeting.

BACKGROUND OF THE INVENTION

For measurement of lengths, instruments with built-in electronic rangefinders, so-called total stations, are currently used in the field of geodesy, which need a reflection element in the mode to achieve higher accuracy. The reflective elements are corner reflectors and reflective foils, which also allow precise targeting to the point being measured, and reflective omnidirectional reflectors and shaped foils, which allow measurement from multiple directions. However, current omnidirectional reflectors and molded films do not allow accurate targeting and are therefore used only for measurements requiring lower accuracy.

However, on construction sites, for example, it is often not possible or economically feasible to place several omnidirectional reflectors in a group or several reflective foils, or it is necessary to measure the same point at the same time, but due to changes in site conditions disadvantageous, possibly dangerous or impossible, to turn the reflecting system. Such places are located, for example, at the tops of pillars or at the bottom of bridge deck structures and are therefore very difficult to access.

Measurement with sufficient accuracy in the measured length and targeting as well as the possibility of measuring from different directions remains a problem.

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The essence of the invention

The aforementioned drawbacks are eliminated by prehistory for electronic length measurement, both for positional and altitude measurements enabling multi-directional targeting according to the present solution. Its essence is. that, in the simplest embodiment, it is composed of at least three identical plates f * <* 44 '* XI t f4 t * * 1 * t * V in the form of a rectangular rectangle, provided with a reflective foil with a target at one side edge thereof. The foil is positioned such that the vertical axis of the target lies in this side edge and one half of the target is located on one side of the plate and the other half is opposite it, on the far side of the plate. The centers of the discs on all plates lie in the same plane parallel to the lower edges of the plates. The plates thus formed are joined together by edges where the reflective foil is connected to the target. The formed joint forms the longitudinal axis of the reflecting device. The angles formed by the adjacent plates are identical and equal to 360 ° / n, where n is the number of plates used.

In a further possible embodiment, the plates have their lower edges attached to a holder which is adapted to be connected to a measuring station. The plates and the holder may be formed as a single unit or detachably. In this case, the holder is provided with notches for inserting the plates.

If four plates are used, the plates are perpendicular to the plates in the plane where the centers of the plates are located, the horizontal plate being symmetrical about the longitudinal axis of the jig. This horizontal plate is provided with a reflective foil on both the lower and upper surfaces on which the target is placed. The center of the target lies in the longitudinal axis of the reflector, where the centers of the targets located on the plates also lie.

In a preferred embodiment, the largest dimensions of the horizontal plate are at most equal to twice the dimension of the plates in a direction parallel to a given edge of the horizontal plate.

The reflecting device may also be formed by assembling six identical plates in the form of at least part of an isosceles triangle whose straight shades are at an angle of 109.5 °. These plates are connected to each other so that they meet at their top angles and the joint is the center of gravity of the pyramid-shaped body. The plates are provided on both sides at an apex angle with a reflective foil with a portion of a circular-shaped disc covering the entire area of the plate at its apex angle. The centers of these parts of the discs lie in the center of gravity of the formed body. Individual plates can be made up of real triangles, ie their prefixes:: t::: ·;::

• · · «·. · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · However, it is always necessary to observe the condition of conformity of all boards.

In addition to the basic embodiment, the reflecting device may also be provided with a holder which is adapted to be connected to a measuring station. In this case, the vertical axis of the holder is identical to one, selected, intersection of the plates, which is also in the vertical axis.

The advantage of this solution is the versatility of use even at steep intentions and the choice whether the element will be connected to the measuring station. If the element is connected to the measuring station, the position will be maintained even in the longer time horizon. Without the connection, the element can be placed even where it is not possible to reach it normally.

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Examples of embodiments of a reflective device for electronic length measurement allowing multi-directional targeting are given in the accompanying drawings. An example of a multi-directional length measuring fixture mountable to a theodolite tripod is schematically shown in Figures 1-4, for attachment to a Leica mandrel. Figures 1 and 3 are top views and Figures 2 and 4 are side views. FIGS. 5 and 6 show how to use the jig for the variant shown in FIGS. 3 and 4. FIGS. 7 to 10 show variants for mounting on a Zeiss tripod, again in top and side views. Figures 11 to 16 show top and side views of variants with spatial division and without the use of tripods.

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Example Embodiment / invention

Figures 1 and 2 show an example of a reflective device for electronic length measurement, which generally consists of at least three identical rectangular plates 6. In this first example, the reflective device is formed by four square plates 6. The plates 6 may be made of metal or plastic so as to maintain their planarity. For example, their size is 120x120. Each of the plates 6 is provided with a reflective foil 7, for example 30 X 30 mm, at one of its side edges, with a printed target positioned so that the vertical axis of the target lies in this side edge and thus one half of the target is located on one side of the plate 6 and

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The other half is located opposite it, on the far side of the plate 6. The centers of the discs on all the plates 6 lie in the same plane parallel to the lower edges of the plates 6. The discs are positioned at a height h, which is preferably equal to the height of the telescope rotation axis, measured from the tripod of the Leica and Zeiss instruments, respectively. These plates 6 are joined together by the edges where the reflective film 7 is connected to the target and this joint forms the longitudinal axis of the reflective device. The angles formed by the adjacent plates 6 are identical and equal to 360 ° / n, where n is the number of plates 6 used, in this example the angle is 90 °. The size and color of the plates 6 must allow for clear targeting of the center of the foil 7 t to the edges of the plates 6, i.e. the plates 6 should be white with black intentional marks, for example triangles, at the edges. , or in a different color combination.

In practice, the film with the target in the longitudinal axis of the target can be folded along the side edge of the plate 6 to either side thereof, or the plates 6 can first be assembled to the desired shape and then the reflective film 7 glued to them from both sides.

In the simplest case, the reflective device is thus designed as a separate self-supporting part. In most cases, however, the plates 6 with their lower edges are attached to a holder 5, which is adapted to be connected to a measuring station and which ensures the position of the plates 4 to be invariable. The plates 6 and the holder 5 may be formed as one unit or separately, with the holder 5 being provided, for example, with notches for firmly inserting the plates 6. The holder 5 may be made of, for example, metal or hardened plastic so as to maintain the same positions of the plates 6 and at the same time ensuring that the intersection of the plates 6 forms the vertical axis of the entire fixture. The holder 5 can be used for mounting on conventional measuring stations such as Leica or Zeiss tripods.

In the case of using a Leica device, the holder 5 is mounted in a plastic holder 2 with a central hole 10 for placement on a classical pin 1, corresponding to the Leica solution. This pin 1 is provided with a spring 3 to maintain stability and height alignment. The spring 3 locks into the opening 9 in the pin L in the locked position.

In the release position with the fuse 3 pressed and the spring 4 pressed, the recess 8 in the fuse 3 allows the jig to be released from the pin T Further, the holder 2 can be replaced by a cylindrical pin with a groove corresponding to the · · ,, ,,::::::

7 to 10. In this case, the plate holder 5 is mounted on a cylindrical pin 10 made preferably of metal into which the groove 11 is milled.

3 and 4 show a similar embodiment, but only three plates 6 are used, so that the angle between them is 120 °

Another possible embodiment of the reflective device is shown in Figs. This is a variant where a horizontal plate 6.1 is arranged perpendicular to the plates 6 in the plane where the centers of the discs are located on the plates 6. whose shape is symmetrical about the longitudinal axis of the jig. This horizontal plate 6.1 is again provided on the lower and upper surfaces with a reflective foil 7 on which the target is placed. The center of the target lies in the longitudinal axis of the reflector, ie where the centers of the targets located on the plates 6 are located. It is desirable that the dimensions of the horizontal plate 6.1 be at most twice the dimensions of the plates 6 in a direction parallel to the edge of the horizontal plate 6.1. and make it difficult to target and position the product on the measuring station.

Finally, it is possible to form a reflective device as shown in FIGS. 15-16. The device here is formed by six identical plates of the isosceles triangle shape. However, it can also be formed by plates having the shape of at least part of an isosceles triangle, i.e. they have a hypotenuse formed by a general curve. The straight legs of these plates 6.2 are at an angle of 109.5 °. The plates 6.2 are connected to each other in such a way that they meet at their apex angles. This joint is the center of gravity of the pyramid-shaped body. The plates 6.2 are provided on both sides at an apex angle with a reflective film 7 with a portion of a circular-shaped disc covering the entire area of the plate 6.2 at its apex angle. The centers of these parts of the discs lie in the center of gravity of the formed body.

This type of reflecting device can also be self-supporting or is mounted in a holder 5, which is adapted to be connected to a measuring station. The vertical axis of the holder 5 is identical to one intersection of the plates 6.2, which is also in vertical position. Since the preparation is symmetrical, it does not matter which prism is selected. The holder 5 may be fixed, for example, by directly pushing the top of the pyramid into the holder 5 firmly. The shape of the boards 6.2 in case of their hypotenuse does not matter, but in case of use

The device without holder 5 is a preferred shape with sharp peaks so as not to be prone to flipping and sliding upon placement by accident.

An example of use of the formulation is shown in Figures 6 and 7 and is the same for all variants. In the measurement, the reflecting device targets targets 100 in the center of the target of the visible reflective film 7, which is currently most facing toward the apparatus. Next, a horizontal direction 200 is measured to the left edge of the plate 6 on which the film 7 is glued, and finally a horizontal direction 300 to the right edge of the plate 6 on which the film is glued. Electronic theodolite can be equipped directly with the SW product oro measurement per fixture or it is possible to register the resulting values and calculate the lengths during data processing.

Since it is possible to measure on the foils 7 and / or the discs on them up to a 45 ° inclination, it is guaranteed for each case that the reflecting device is rotated relative to the measuring direction that the measurement can be performed. no target at an angle allowing measurement. The measurement is always performed on a visible target on the film 7 on the fixture. The length measured on the jig, however, is dependent on its rotation and therefore, after measuring the length, the direction is measured on the left and right edges of the plate on which the film to which it was measured is glued. For the known rotation angles of the jig with respect to the line of sight, the value of the measured length is recalculated, since the difference between the measured length and the jig is functionally dependent on the jig rotation of the jig.

Industrial applicability

In addition to use on construction sites, the product can be used in all areas of geodesy where it is impossible, disadvantageous or dangerous to shoot reflective products. Furthermore, it is possible to use the preparation without attachment to a tripod, eg as control points for a laser scanning method in places that cannot be accurately identified (the targeting is not unambiguous) and is dangerous to enter, eg at places of rock slides or craters. In this case, the tool without the brackets is simply dropped to the desired location with a variation of a few meters, surveyed, scanned and then re-measured to verify its original position. The only requirement is the visibility of the fixture and its position between the time of measurement and scanning. At the end of the work, due to its many times lower price than current reflectors and possible use in hard-to-reach or dangerous places, it can be left in place.

Claims (10)

Reflecting the first product for the electronic measurement _of lengths, characterized in that it consists of at least three identical plates (6) is rectangular, which are provided on one of its lateral edges of the reflective film (7) with the dot positioned so that the vertical axis of the target lies in this side edge and one half of the target is located on one side of the plate (6) and the other half is opposite it on the far side of the plate (6), the center of the targets on all plates (6) lying in the same plane The plates (6) and the plates (6) thus formed are joined together by edges where the reflective film (7) is connected to the target and this joint forms the longitudinal axis of the reflector, the angles formed by the adjacent plates (6) always equal and equal 360 ° / n, where n is the number of plates (6) used. Reflecting device according to claim 4, characterized in that the plates (6) are attached with their lower edges to a holder (5) which is adapted to be connected to a measuring station. Reflecting device according to claim 2 _, characterized in that the plates (6) and the holder (5) are designed as one unit. Reflecting device according to claim 2, characterized in that the holder (5) is provided with notches for receiving the plates (6), Reflecting device according to claim 1 and any one of claims 2 to 4, characterized in that, when four plates (6) are used, the plates (6) are perpendicular to the plates (6) in the plane where the centers of the discs are located on the plates (6). a horizontal plate (6.1), the shape of which is symmetrical about the longitudinal axis of the jig, this horizontal plate (6,1) is provided on both the lower and upper surfaces with a reflective foil (7) on which a target is placed. preparation, where the centers of the discs located on the plates i Sy The reflective composition of claim 5 _; characterized in that the largest dimensions of the horizontal plate (6.1) equals at most twice the dimension of the plates (6) in a direction parallel to a given edge of the horizontal plate (6.1). A reflecting device for electronic length measurement, characterized in that it consists of six identical plates (6.2) in the form of at least part of an isosceles triangle whose straight offsets are at an angle of 109,5 °. The plates (6.2) are provided on both sides at the apex angle with a reflective foil (7) with a portion of a circular-shaped disc covering the entire area of the plate (6.2). ) at its apex angle where the centers of these parts of the discs lie in the center of gravity of the formed body, Reflecting device according to claim 7, characterized in that the overlap of the plates (6.2) is a straight line. Reflecting device according to claim 7, characterized in that the plate overlap (6.2) is a curve of any shape. Reflecting device according to claim 7 and any one of claims 8 or 9 _, characterized in that it is provided with a holder (5) adapted to be connected to a measuring station, wherein the vertical axis of the holder (5) coincides with one intersection of the plates