DE16523A - Rangefinder - Google Patents

Description

IMPERIAL

PATENT OFFICE.

h'ÖSCR

The invention is based on known geometric elementary sets, namely mainly on the following simple principle:

If one draws a parallel mn, Fig. I, to the base (or to any side) of any triangle, and the line mpl / mq from the point η , the ratios A: mq = B: ps (because mq = ηp ); C ': η s = B: ps; H: 0 r = B \ ps or, since the dash ps is the difference between base and parallels, the general theorem:

One or the other side or the height of any triangle behaves to the subsection in question like the base to the difference between base to parallels.

3 shows a perspective view of an apparatus constructed on the basis of this theorem represent.

The "bar CD (or the imaginary line me mh mg m-) is parallel to the bar AB (or the line of, base).

CD rests firmly on a plate which is fastened to the neck of a screw nut mounted in the beam, protruding to the edge of the split in the beam .S U (cross-section in FIG. 4).

The aforementioned nut and thus also the rod CD is by turning the handle x,. consequently the screw concerned (longitudinal section of the beam, Fig. 5), pushed back and forth without the slightest oscillation, and therefore CD never gets out of the parallel direction.

The base AB is immovable on the beam 5 U above the handle *.

The bar .S U is (after unscrewing) both around the vertical axis above the hoop d ω, and together with the upper part of the pedestal around the horizontal axis, with one and the other steering by means of the locking screw α c and the screw χ in set immediately in any direction and thus the position is fixed unrelated, rotatable.

The edge η r is parallel to the line connecting the centers of the diopter 0 and the visor bead m. If any point is therefore aimed at by ο m , the direction always remains the same and there is no steering by shifting CD.

In the present apparatus there is nrXof, although it is not necessary.

The imaginary lines me mh mg ml (that is, the centers of the Visirkörnchen connecting lines) by 2/1000 Y 1000, 10/1000 20 / i 000 smaller than the line (base) of (ie, ο the centers of the diopter and f connecting line).

On the left side of 5 U (side view of the bar, Fig. 6) one sees a metric scale and four rows of numbers (ie under each centimeter four different distances corresponding to the same and one or the other 'visor granule'). The distance corresponding to the grain e or the difference ² / iooo is 5 times as many meters as the section counts centimeters (= 1 m for every 2 mm, and therefore as many half a meter must be added as there are millimeters in addition ); the Λ distance 2 times as many meters ^ = 1 m per each

5 mm); the ^ distance ι times and the / distance V ₂ times.

A pointer is attached vertically below the line me on CD, close to SU, FIG. 6.

The rail gw, ι m long, can be pivoted about g and is connected at w to CD either by a ring and a rod or a rotatable pin in a channel attached lengthwise to CD. It is provided with a metric division.

The rail kt, V ₂ to _^3/4 are also provided m long, with metric division, is rotatable about t free.

The line gt is parallel of and ^J / s ^m long.

If one wants to determine the distance of any inaccessible point from the base AB (of), proceed as follows:

You unscrew, through the diopter ο you aim at the point in question, turn the bar SU up or down, left or right, until the visor bead m comes into the direction line oP (or into the optical axis), and screws tightly. Then one looks through / to the same point P. One chooses the visor granule which is closest. If it is on the left, GD is pushed toward it; if it is on the right, the same is pushed in until the viscera cone comes into the line of direction (optical axis). On the trajectory covered by displacement, which is read from the index, Fig. 6, you can see the distance you are looking for, ie the first, second, third or fourth number, depending on whether you have aimed at /, g, h or e.

To measure heights or depths, first determine the distance of the highest or lowest point in question using the method just described, then rotate the beam together with the upper part of the pedestal around the horizontal axis (the parallel line upwards or downwards, depending on the heights or depths are measured) in such a way that the lines of me are horizontal and the plane CABD is vertical, for which a dragonfly is used, and here one looks up or down through the diopter i over y , turns the vertical axis of the upper frame and pushes the CD over or down until iy and the point in question are in the same straight line. The already known side (hypotenuse) is multiplied by the number of millimeters covered by moving the bar. The product is the side you are looking for (or elevation or depth).

To determine the distance between two points that are distant from the point of view, one must first use the known method to determine the distance between the two points and the position. the two sides from the crown; Then you look through the diopter ν over ζ and align the line vz to the right of the two points in question, screw it tightly and then align the rail gw (or the line iy) to the by moving the parallels (the rod CD) second point on the left. Once this has happened, a section is determined on the rail gw from g , which relates to gt as the relevant already known sides relate to one another. The rail tk is steered in such a way that it cuts through the strip gw at the end point of the section just mentioned. Twice the product from the right, known side (distance) and the // £ -section within the legs (tb) is the sought-after side opposite the apex, or respectively. the distance between two points distant from the stand.

Fig. 7 shows how the use of telescopes in the present apparatus represents sighting through diopters and sighting bead, which is more advantageous and indispensable for great distances. The telescopes F and F ^x lie firmly on rails which can be rotated around points ο and f and in the middle, straight section of which a vertical needle instead of the sighting bead passes through by shifting CD . The telescope F is not steered, but F ¹ does.

Fig. 2 shows an auxiliary apparatus for determining an elongated base. Instead of ο m, Fig. 3, o ¹ m ¹ , Fig. 2, is directed towards the point in question. By means of a measuring cord, AB, Fig. 3, is placed in the line from ab, Fig. 2, and thus o ¹ m ^l parallel to o m. Finally, one looks through the diopter / in Fig. 3 and brings the same, the point in question and one of the visor granules in question (by moving the CD), in a line. The distance, from a, Fig. 2, is equal to the base times the bar segment divided by the difference. There is no need to prove how even considerable distances can be determined quite reliably even without telescopes using the latter method.

For determining heights, depths and distances, in general between two of the stand distant points, is the use of the auxiliary apparatus, as well as the telescope, after one has removed one or both points in question from the location, absolutely superfluous.

The construction of the one shown in FIG Apparatus is based on the following considerations:

i. The difference MN, FIG. 8, between the base (the one leg) and the parallel in a right-angled triangle can be viewed either as a cotangent or as the cosine of the angle VO M (VO = MN) . If it is viewed as a cotangent, then this is the corresponding one

Side section MO the relevant cosecante, and the other side section TZz = NO the radius. If you want to see it as a cosine, the corresponding side section MO is the half-diameter and the other section TZ =. MP the sinus.
- If the height section of the oblique triangles (v r = mn = .ps, Fig. 9) is viewed as a half-diameter, the difference 0 x, Fig. 9, is equal to the sum of the cotangents of the base (or the side) adjacent angle (ο χ : = ο m - \ - m χ = ο m - \ - rt = ctg / - + - ctg g), (see Fig. 10 ο d, difference = α d - \ - ( - α o) = mn - \ - ( - a 0) = ctgg - \ - ctgs), so that the following proposition can be established:

In any triangle, one side is equal to the other divided by that Sum of the cotangents of the angles adjacent to the latter and multiplied by the cosecant of the angle included by both.

If, however, A, Fig. 8, is one leg and B the other, one obtains:

B cosec r

A =

ctg r-i- Ctgf Ctgi ' B-: [ ctg r + B.

cotg ί '
and therefore B = A ' ctg i.

2. The difference between the parallel and the base (or any side), like it comes into play when using the available apparatus is that and always the same size which by the variability of the half-diameter and the cosecante (side section, by directing it back and forth at the same time) cotangent (or cosine) of likewise many angles, as changes in the half-diameter (increase or decrease of the same, Sliding back and forth of the parallel) can take place, Fig. 11.

In trigonometry, the radius is unchangeable (always ^ =. 1) and the cotangent, as well as the other angular functions, are variable, but here the radius (or height or leg section) is variable and the difference is unchangeable.

In trigonometry, the only thing that matters is the variability of the angular functions, and in the present method on the variability of the half-diameter. From this it follows that where in trigonometry z. B. ι mm in 100, 200, 500 .... would be divided (which is absolutely impossible, in spite of all devices previously devised for the purpose of which the trigonometric method is based here, on the other hand, the same division along the length of a meter or half a meter happens and the corresponding distances can be read off.

Let g M, Fig. 1.1, 1 mm, the base AB = ι m, the parallel CM also 1 m and also the half-diameter AC = 1 m. Now one aims from A via C and from B via g, see above Both lines directed beyond this meet at a point P, whose distance from A according to the present and according to the trigonometric calculation 1. 1: Y ₁₀₀ O (difference or cotangent) = iooom.

But if one wants to determine further or shorter distances trigonometrically from the same base AB , there is no other way than to observe the changes, divergence or convergence of the angle corresponding to the decrease and increase of the cotangent (difference).

In the present method, the difference (cotangent) and thus the corresponding quotient is determined in advance, and the distances result from the decrease or increase in the distance between the parallels and the base (half-diameter), ι m distance at V1000 difference = 1000 quotient the distance 1000 m, half a meter with the same difference g ¹ m ¹ = g M, Fig. 11, 500. The distances up to 500 m are therefore not on a millimeter divided into 500 parts, but on 500 equal parts of a half meter , ie read from the same number of millimeters.

The above relates to the range finder, the base of which is unchangeable. Should but the base and not the side section be changeable, the result is the following:

In the present method, the distance E is equal to the product of base B and section A divided by the difference D or

ΒΆ D.

If the section increases by 1, 2, 3. . nfold the difference to (or from), then:

- = E - + - 2 B etc.

If, on the other hand, the base B is around the 1-, 2-, 3-. . η times the difference expanded (or abbreviated), we get:

and from this the consequence:

The increase or decrease of the section by η-differences corresponds to the increase or decrease the distance by η-basis, and conversely, the increase or decrease of the basis by n-differences corresponds to increasing or decreasing the distance by n-sections.

Fig. 12 shows a second device, in which the change in the page section is not achieved by moving the Parallels, but rather through the simple steering of a bar resting on one level he follows.

fg, Fig. 12, forms the tripod for any (as in the first device, Fig. 3) horizontal or vertical position of the instrument.

B is a beam on which two rigid metal rails M and S are attached. A telescope F rests immovably on M , the optical axis of which is parallel, with the lines lnv attached to the broad rail S. The bar α b can be rotated about 0 at its edge by means of a micrometer screw k and a corresponding gear. A telescope F ¹ , the optical axis of which lies parallel to the mentioned edge, but in a plane perpendicular to it, is fixed on the latter and consequently also rotatable with the same. The pivot point ο and the point / (on the optical axis of F) form the endpoints of the base (im long, or whatever you want). Cross lines and lines parallel to the base are _{attached to the above-mentioned parallel lines (1/2} m long from the base, or longer, depending on whether you want to determine distances up to 250 and 500 m or more), which are metric share. The use is evident from the construction:

The point in question is sighted through telescope F (turn up or down, left or right. Towards bar C), screwed on and finally the same point is brought into the optical axis of F ¹ (steering of the bar α b). It looks like that In the two lines intersect the edge. The product of the division cut off at the relevant line and the relevant quotient (bi

Base

1000, 1000
or

ifference '
is the distance sought.

The determination of heights and depths can be carried out similarly to the first apparatus, Fig. 3, by attaching a rotatable and at the same time displaceable bar with this device be made.

Claims (3)

Patent claim: A new Mefsverfahren respectively. Distance meter, in which the height and the unknown sides of any triangle (or distances) from a stand (base or vertex): a) without any angular curve, b) without the use of vernier or similar, but from a simple scale in Centimeters and millimeters can be read reliably; and this happens: 1. by attaching two points (or two visor granules, corresponding to the diopter, or two the rails, whereupon the Telescopes lie freely to and fro, but not holders that allow sideways), which on a (in front of the base) movable back and forth and always parallel to the base Line and over which the sides to be measured respectively. Go through distances where therefore (since the difference is known and the one obtained by shifting the Parallels abbreviated or extended distance at the metric graduation, one side of the parallel crossbeam is to be removed) the planimetnsche Principle is made usable; or 2. by introducing a bar that can be rotated on a scale and on which the one Telescope rests while the direction of the other is unchangeable; 3. by attaching rotatable rails, by means of their heights and depths, etc. can be determined from the vertex. For this purpose I sheet drawings.