DE302436C - - Google Patents

Description

The present invention relates to a range finder which contains a horizontal line, the entry openings of which lie above the head of the observer and in which an objective mirror system, insensitive to rotations in the measuring plane, behind each of the two entry openings, which enters the range finder through the relevant entry opening The beam bundle system that has entered at the level of the entry opening in question deflects the direction of the base line. Only one type of this rangefinder type has so far become known, namely that dealt with in Austrian patent specification 38463. In this known type, the divider prism system is also at the level of the inlet openings; This position of the two prism system made it possible to unite this prism system and the lenses in front of it by the focal length in a rigid pipe system (extending in the direction of the base line), outside of which no parts needed to be located that would influence the accuracy of the measurement ; the length of this system was about ¹ tube approximately equal to twice the length of the focal length of the lenses.

With the new rangefinder, the prism system is at 'the height of the Eyepiece lenses and the rangefinder lenses lie in the vicinity of the mirror system that is used in the new one Rangefinder still necessary to deini otherwise optical parts must be added to the two of) the lens game gel systems to deflect the coming cluster of rays from the direction of the standÜinie. These Arrangement of the separating prism system on the one hand and the lenses on the other hand are in the neuani rangefinder, the divider prism system, the lenses and the aforementioned newly added mirror system in one (perpendicular to the Unite the rigid pipe system extending in the direction of the base line, its length is only approximately the same as the focal length of the lenses and is therefore more resistant enough ggani shape changes can be made; may be as a result, in the case of the new rangefinder, even the usual, decisive one optical parts bearing, from changes in shape of the outer tube of the rangefinder unaffected inner tube can be dispensed with.

With a suitably chosen design of the additional mirror system and the divider prism system even then, there are no mutuals with the new rangefinder Movements of the two images presented to the observer in the direction the baseline when the separating prism system. towards the lenses and the additional mirror system suffers small changes in its position, so that in this If the pipe system mentioned does not have any special requirements for its resistance needs to suffice. Any such. Lägeäniderung can be thought of as arose from a maximum of three displacements and a maximum of three rotations, namely from a shift in the direction of entry

visual axis, a shift in the direction of the base line and a shift in a ¹ to serving two directions perpendicular direction just mentioned · and of a rotation. around the viewing axis, a rotation around the base line and! a turn. about an axis perpendicular to the two axes just mentioned. A more or less extensive insensitivity in the

ίο the meaning just explained can be particularly easy to achieve if the additional mirror system is designed in such a way that the two Reflections through which one and the other of the two beam bundle systems dem Ocular prism system is supplied, each take place in a plane perpendicular to the starid line. The extension of this additional mirror system is in the direction of the Baseline is particularly low and thus the construction of the pipe system mentioned in this one Direction particularly stubborn, if one looks at these two reflections in one and the same Level can be done.

Will the invention on a stereoscope! ■■ see rangefinder applied, in which when measuring the apparent distance a spatial image of the measurement object with the apparent distance of a stereoscopic one Measurement mark is compared, the mark images resulting from this measurement mark play including the prisms lying between them and the lenses in the here in Consider the role of the vaginal rangefinder system of a unocular rangefinder.

In the drawing the invention is through

some embodiments illustrated.

From that shown in Fig. 1 to 3

first example, the optical system of a coincidence distance meter, which the observer presents two upright images, Fig. ι shows a view from the eyepiece side, Fig. 2 is a view from above and Fig. 3 is a cross-section. The lens mirror systems.

are formed by two pentagonal prisms α ¹ and α ² , of which the single mirror surface is designed as a roof. The measuring device is indicated by two mutually rotatable, breaking wedges ¹ and l · ² ..

The two objectives are labeled c ¹ and c ^2. They are located directly in front of the additional mirror system arranged in the middle of the base line, which consists of two single reflecting prisms d ¹ and d ² , each of which has the associated axis beam through a reflection in a plane containing the base line and perpendicular to the measuring plane by 90 ⁰ distract. The separating prism system consists of two simply reflecting prisms e ¹ and e ² , of which e ¹ deflects the axis beam belonging to the left end of the base line and the ^{axis beam belonging to the right end of the base line v} back in the direction of the base line and out two simply reflecting, crossed prisms / ¹ and f ² , which are each half as high as the prisms e ¹ and e ² and are effective in a known manner. The rangefinder's eyepiece consists of a field lens g ¹ and an eye lens g ² . As a simple investigation shows, of the three displacements and three rotations mentioned above, only a displacement of the separating prism system in the direction of the viewing axis or a rotation of the ocular prism system around the stationary line would cause a mutual movement of the two images presented to the observer in the direction of the stationary line ; the other two displacements and the other two rotations, on the other hand, would be without such an influence.

In Fig. 4 to 6, the system of a coincidence rangefinder is also shown as a second example, which presents the observer with two upright images, namely in two views and a cross-section, which correspond to the first example in terms of their position. The objective mirror systems a ¹ and a ² , the measuring device V, b ² , the objectives c ¹ and c ² and the ocular lenses g ¹ and g ^{2 are} similar to those of the first example. The additional mirror system consists of two single reflecting prisms ei ³ and d ⁴ , each of which deflects the associated axis beam by 90 ° in a plane parallel to the measuring plane, and a single reflecting prism d ⁵ , which consists of the two prisms d ^s and d * absorbs emerging ray bundle systems and ^{deflects the axial rays by 90 0} in a plane perpendicular to the base line. The sheath prism system consists of two simple reflective prisms ^e% and e ^i, which each deflect the passing axle beam in a direction perpendicular to the base line plane by 90 ^0, two einflach reflecting prisms s ⁵ and s ^6, the parallel depending on the hindurchgebanidlen axle beam in a to the measuring plane Deflect plane by 90 ⁰ , and two crossed prisms f ¹ and f ² , which are the same as in the first example. None of the shifts and rotations of the divider prism system mentioned above would cause the two images to move in the direction of the base line.

The third example shown in Figs. 7 to 9 in the same way as the first two examples, the optical system of a stereoscopic rangefinder, is similar to the second example with regard to the objective mirror systems a ¹ and α ² , the objectives c ¹ and c ^{2 urid} the additional mirror system d ^s ,

d \ d ⁵ . Two single mirror prisms / ³ and f * each deflect the axis beam passing through by 90 ° in a plane perpendicular to the base line. Each of the eyepieces consists of a field lens g ¹ and an eye lens g ² , between which a twice reflective prism h of diamond-shaped cross-section is arranged so that .'by rotating the eyepieces each around the incoming axis beam

to the mutual spacing of Eini of sight of the telemeter be adapted to the interpupillary distance of the observer Kanmu front of each of the two eyepieces is i a plane-parallel glass plate whose back surface is located in the focal plane of the corresponding eyepiece and is equipped with brands / that ¹ in both eyes, observation ¹ a series of sterepscopic measuring marks results from the marks of the two oculars. None of the mentioned shifts and rotations of the ocular prism system would cause a reciprocal movement of the two images in the direction of the base line.

The fourth example in Fig. 10 to 12 shows the optical system of a coincidence rangefinder, which presents the observer with an upright image and an image that is inverted perpendicular to the direction of the base line, together with the mechanical parts used to accommodate the optical parts, namely in three sections, which are shown in their position corresponding to the two views ¹ and the section of the first three examples. The main body of the range finder consists of a middle part k ¹ , to which two head pieces k ⁴ and k ^{s are} connected by two tubes k ² and k ^a. In the head piece fe ^{4 there} is a pentagonal prism a ¹ , in the head piece k ^B a pentagonal prism a? arranged; ¹ of each of the mirror surfaces of these pentagonal prisms is designed as a roof surface. The measuring device is indicated by two refractive prisms b ¹ and b ² arranged in the tube k ^s , for the mutual rotation of which a drive button b ^s is used. The additional mirror system consists of three simple, reflective prisms d ^e , d ⁷ and d ^s and a roof prism d ⁹ . The prism d ^e takes dla's from the left end of the base line rays coming tufts system and directs the Achisenstrahl in the measuring plane 90 ⁰ in the direction of the measured object out from. Dais prism d niimmt ⁷ coming from the right end of the base line beam bundle system and directs the beam axis in the Meßidbene 90 ⁰ opposite to the other axle beam down so that the two axle beams lie in a straight line. The prism d ⁹ deflects the axis beam that has emerged from the prism d ⁶ , the prism d ⁸ the axis beam that has emerged from the prism ^{d 7} by 90 ° in a plane perpendicular to the base line. Ft at the central part ¹ includes at the bottom a flat tube /; ⁶ , which contains two objectives c ¹ and c ² and below carries a housing / e ⁷ in which the ocular prism system is arranged. is. The separating prism system consists of a prism / ⁵ with a diamond-shaped cross-section to which a mirror prism / ⁶ . is cemented. The upper half of the cement layer is designed as a double-sided reflective separating layer / °, while the lower half allows the rays falling on it to pass through. The bundle of rays coming from the left end of the base line is taken up by the prism / ⁵ , that graining from the right end is taken up by the prism / ^e . The eyepiece is pushed into a sleeve k ^s seated on the housing k ⁷ ; the field lens is denoted by g ¹ and its eye lens is denoted by g ^2. The filling of the lower half of the image field comes from the left end of the standiline and is. An image that is inverted perpendicular to the direction of the stand line, the filling of the upper half of the image field comes from the right end of the stand line and is an upright image. Of the above-mentioned shifts and rotations of the separating prism system, only a rotation around the winding axis or a rotation around the axis perpendicularly intersecting the viewing axis and the stand line would result in a mutual movement of the two images in the direction of the stand line: the influence of these rotations is reversed the smaller, the smaller the mutual distance between the two points at which the prisms / ⁵ and / ⁶ direct one and the other axis beam in the direction of the ocular axis. .

The fifth example, shown in Figs. 13 to 15 in the same way as the first three examples, is the optical system of a coincidence rangefinder which is similar to the fourth example in terms of the filling of the image field, but its optical system is so redesigned that . it is not sensitive to any of the aforementioned 'displacements and rotations in the aforementioned respects'. The optical one. The system of the .110 fifth example is the same. its objective mirror systems a ¹ and a ?, its measuring device b ¹ , b ² and its eyepiece g ¹ , g ² the corresponding optical parts of the fourth example. Similar to the additional mirror system of the fourth example, the additional mirror system consists of three simple mirror prisms. d ^e , d ⁷ .and, d ", .and. a roof prism d ¹¹ , however the prisms ei ¹⁰ and d ¹¹ each deflect the axis beam by more than 90 ^° . The objectives c ¹ and c ² are below, des additional mirror system so arranged

net that the focal point of each of the two lenses coincides with the point of intersection of the two axis rays. The separating prism system consists of a single glass body f. The two entry ^{surfaces / s} and f are each penetrated uninterrupted by the relevant axial ray. Two mirror surfaces f ¹⁰ and Z ¹¹ that are inclined towards one another and acting by total reflection are

ίο arranged so that the edge / ¹² , in which these two surfaces intersect, lies parallel to the base line and contains the point of intersection of the two axis rays. The Okular.g ^a , g ² picks up only the part of the beam bundle system coming from the lens c ¹ that falls on the mirror surface f ¹¹ , and picks up only the part of the beam bunch system coming from the lens c ² that hits the Mirror surface / ¹⁰ falls.

The edge / ¹² consequently acts as a cutting edge. Since the mutual distance between the two points at which in the separating prism system the one and the other axis beam is directed in the direction of the ocular axis is equal to zero, then, as mentioned, none of the above-mentioned shifts and rotations of the separating prism system would cause a mutual movement of the two Effect images in the direction of the baseline.

Claims (4)

Patent Claims: i. The baseline in the abstaining, horizontal rangefinder, the entrance opening of which is above the head of the Observer lie and at the one behind each of the two entrance openings Objective mirror system that is insensitive to rotations in the measuring plane Beam bundle system that has entered the range finder through this entry opening at the level of the relevant inlet opening in the direction of · the Deflects stand line, characterized in that the separating prism system in the Height of the eyepiece lenses and the objectives in the vicinity of that mirror system lie that the two ray bundle systems, they. from the direction of Distracting stand line, feeds to the divider prism system. 2. Distance meter according to claim 1, characterized in that the two ■ reflections through which the one and ¹ the 'other of the two beam bundle systems dern separating prism system is carried out in a plane perpendicular to the base line. 3. Distance meter according to claim 2, characterized in that the mentioned Reflections for both ray bundle systems take place in the same plane. 4. Unocular rangefinder according to claim 3, characterized in that the two axis rays meet in the dividing line of the two fields presented to the observer, without having previously experienced a "reflection" in the separating prism system. 1 sheet of drawings.