CS260221B1 - Universal structural geological gauge with improved orientation - Google Patents

Abstract

The solution falls into the field of geological gauges and relates to the construction of a universal geological gauge for mining works with improved orientability. The gauge with improved orientability consists of a contact part formed by a bracket, a bent arm and a universal suspension with a vertical goniometer system between the contact and suspension parts, a suspension part with a horizontal goniometer system and an orientation part formed by a supporting half-sleeve with a needle with a bearing carrying a magnetic needle and with an aiming element formed by a pointing rod, wherein a means for its optical orientation is arranged in the orientation part, connected to the pointing rod.

Description

The invention relates to the construction of a universal structural-geological meter with improved orientability, intended especially for equipped mine workings and solves the problem of allowing more accurate adjustment of the orientation part of the meter.

It is basically an improvement of the universal structural geological gauge according to MS. author's certificate no.

247 810, consisting of three interconnected parts: for loading, pendant and orientation, whose angular relations, as read on the protractor scales, represent the spatial orientation of structurally geological plenary and linear elements.

Disadvantages of universal structural-geological gauge according to MS. No. 247 810 consists in the limited accuracy of the orientation part by means of a guide rod, which the observer visually projects in a known direction, especially in those sections of mine workings which are characterized by uneven walls and along the wall in which the measured structural There is no straight pipe, cable or any other element that approximates the course of the wall in a straight line parallel to the axis of the known asa mut.

The above-mentioned disadvantages are reduced to an acceptable extent by the universal structural geological meter with improved orientability according to the invention, consisting of a loading part consisting of an appendix, an angled arm and a universal hinge with a vertical protractor system between the mounting and hinging parts; a bearing half-sleeve with a bearing needle bearing a magnetic latch with a sighting element formed by a directional rod, characterized in that in the orientation part there is a means for its optical orientation connected to the directional rod.

260 221

The gauge according to the invention may further be arranged such that the guide rod is further provided with a supporting arch slidingly mounted in a carrier half-sleeve provided with a sight glass, the supporting arc being provided with a small protractor scale on one side and .

The optical orientation means may be a diopter; collimator; a reflective surface slidably disposed on the guide bar, which is rotatable about an axis identical to or parallel to the axis of the guide bar; a pair of mutually perpendicular reflective pads positioned on the guide rod or on the guide rod. a pair of mutually symmetrically adjustable reflective surfaces on which a directional light source is directed, the axis of which passes through the axis of the angle drawn by the two reflective surfaces, and rotatable about an axis identical to or parallel to the axis of the directional bar or a bar which can be tilted and rotated symmetrically with respect to one another, respectively. A light source is situated on the guide rod and is located in a housing provided with a slot and hinged along an axis identical to or parallel to the axis of the guide rod.

The meter according to the invention can be further arranged in such a way that a carrier is connected to the support half-shell by means of collets, in the center of gravity of which a turntable with a guide for the turntable frame is mounted. The reflector is situated on one side; a collimator is attached at the bottom of the carrier.

An advantage of the meter according to the invention is that it is possible to more accurately adjust the directional part in a known direction, in particular the direction of the mine shaft axis. It is possible to use beams of light emitted in the direction with both arms of the guide rod, which is brought in the direction of the mine axis, or a plane mirror attached to the guide rod, which is rotated to the position in which the observed image of the mine track is observed. or a linear element of known direction aligns with the direction of rotation of the mirror. The same effect is achieved by illuminating the same mirror, for example with a mine lamp, and by indicating the longer side

260 221 of a reflection cast onto a track or other linear element of known direction into the direction of that element. When using a pair of perpendicular, respectively. Mirrors that are freely symmetrically adjustable and illuminated by a small source of rectified light, whose axis is located in the axial plane of the angle enclosed by the two mirrors and is foldable in this plane, are then emitted beams of light in either direction of the arms of the pointing rod, By bringing these light beams in the direction of the axis of the mine, or two different light beams emitting a predetermined angle with respect to each other, are inclined so as to intersect a linear element of known direction at two points.

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The reflective router, which is connected to the orientation part of the apparatus, consists of a directional rod, provided, for example, with a diopter or a collimator, and optionally directed towards both sides with directed light sources; The directional bar can be rotated not only in a known direction, eg the direction of the mine axis, but also by means of a small vertical protractor scale and index also to the appropriate inclination, corresponding to the inclination of the reference line such as mine rails. around an axis parallel to the aiming bar, the modification ensuring that the center of gravity of the mirror does not deviate from the vertical axis of the hinge portion of the apparatus. Alternatively, a pair of perpendicular or mutually perpendicular devices can be hung on the guide rod. mirrors of arbitrarily symmetrically adjustable illumination illuminated by a source of rectified light, the axis of which is located in the axial plane of the angle enclosed by the two mirrors and is foldable in this plane. Alternatively, it is on the routing bar. suspended light source located in a sleeve provided with a slot and hinged about an axis parallel to the pointing rod.

Alternatively, the orientation portion of the apparatus may be directed to a known direction by means of a light plane formed by the light source in the slot-provided housing; this light plane can be swiveled and tilted as needed to identify its track with a linear element of known spatial orientation.

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The above methods of bringing the orientation portion of the apparatus into a known direction assume a priori alignment of the pointing rod to the inclination of the reference linear element of known spatial orientation. This is done by the angular-indexing drive and the index or loyalty reading; * the easy adjustment of the inclination of the guide bar and the mirror allows the toothed arc-drive and the pinion to engage.

In a further configuration variant, the orient portion of the apparatus may be brought into the desired reference direction, e.g., the direction of the mine axis, by means of a diopter or collimator located on a hinged directional bar and observed, along with the distal mine section, 45 °.

This embodiment of the reflective router is particularly useful for measurements on the mine faces.

The meter according to the invention is illustrated in the accompanying drawings, which are not intended to limit the invention in any way.

Fig. 1 shows an overall diagram of a meter according to the invention with an adjustable pointing element and a reflective surface.

FIG. 2 is a plan view and FIG. 3 is a plan view of an orientation portion of the meter with a pair of reflective surfaces. FIG. 5 is a side elevational view and FIG. 6 of an orientation portion of the meter with a reflective surface and having a torque. Fig. 7 is a front elevation and Fig. 8 a side view of the gauge with a combination of a reflective pad and a collimator.

Referring to FIG. 1, the support part 7 is formed by an arm 8 to which a shim 5 is mounted perpendicularly on one side, which on the other side is arranged in a bearing pin 6 from the center of the bearing housing 7 extends two opposing axes 8 The hinge part 2 consists of two vertical discs 10 with a protractor scale, rotatably mounted on axes 8 and fixedly connected to the hinge 11, at the bottom of the hinge 12 a transparent horizontal protractor scale 13 is situated and its center is arranged in a half-housing the bearing 14 through which the hollow pin 15 of the transparent hollow passes

260 221 of the horizontal disc 16 with reading indices, the hollow pin 15 is guided radially and axially in the half-housing of the bearing 14 and the needle 17, provided on one side with an axial bearing 18 and on the other side connected to the supporting half-sleeve a bearing indicator 20 is attached to the needle 17 and a magnetic latch 21 is rotatably mounted on the tip of the needle 17 and an orientation portion 3 is fixed in the supporting half-shell 13.

The orientation part 2 consists of a telescopically retractable guide rod 22 provided with, for example, a collimator 23 or diopter 50 and optionally directed light sources, on the guide rod 22 a hanging mirror 24 is hinged about an axis 25 parallel to the guide rod 22. together with the mirror 24, it can be tilted by sliding the supporting arch 20 provided with a split scale 27 and toothing by means of a pinion 28 * against the index or vernier 29. The gauge is further arranged such that the first arresting means 30 for the transparent hollow horizontal disc 16 with respect to the horizontal protractor scale 13 and that a second locating means 31 for fixing the transparent hollow horizontal disc 16 relative to the horizontal direction indicator 20 is situated in the carrier half-shell 19.

Referring to FIGS. 2 and 3, there is a modification of the meter in which on the support arch 26 provided with a graduated scale 27 and displaceable relative to the index 29, the support half-sleeve 19 is fastened with a guide rod 22 onto which a reflective router 32 lights and a pair of perpendicular, respectively. Mirrors 34 freely mutually symmetrically rotatable about a common axis 35 movable in the slot 36 of the housing 37¾, both mirrors are further provided with tiny pins 38 allowing the symmetrical displacement of the mirrors 34 in the oblique cutouts 39 of the housing 37.

Fig. 4 shows an orientation portion in another embodiment. On the support arch 26, provided with a split scale 27 and displaceable relative to the index 29 of the support half-sleeve 19, a guide rod 22 is attached to which it is pivotally suspended

260 221 a rectified light source 33 housed in a housing 4u provided with a slot 41 and hinged about an axis 42 parallel to the direction bar 22.

Giant. 5 and 6 illustrate a directional portion in another embodiment, particularly useful for reading at mine readings.

A support 44 is rotatably connected to the support half-shell 19 via a support 43 in which a guide rod 22 is rotatable about its own axis. A reflective spot 46 intersected by a longitudinal axis of the directing rod 22 is attached to the guide rod 22 by means of a holder 45, with which the reflection pad forms an angle of preferably 45 °. An aiming device 23, e.g. a diopter or collimator, is mounted on the guide rod 22. The reflective plate may be provided with a pin 47 pivotable in the housing of the holder 45. The center of gravity of the guide element lies in the pivotal connection of the bed 44.

7 and 8 schematically illustrate yet another variant of a reflector representing a combination of a plane mirror 24 and a collimator 23 / resp. diopter 50, provided with a reflective surface 46 '.

A carrier 43 is attached to the support half-housing 19 of the apparatus by means of collets 51, to which a carrier 52 with a rotatably mounted frame 53 is attached to the center of gravity on whose arms a plane mirror 24 rotatable on axis 25 is connected on the one side; The collimator 23 is provided with a reflective surface 46 at its center of gravity mounted on the holder 45.

The tilt angle of the carrier 52 can be adjusted by means of the graduation of the scale 27 and the inclination indicators by means of the index or the index. vernieru 29.

The embodiment makes it possible to fix the carrier 43 with respect to the carrier half-sleeve 19 in two mutually opposed positions, avoiding undesirable disengagement of the two parts during their relative twisting. Maintaining the position of the center of gravity of the carrier 52 in the case of tilting of the holder 45 with the reflective surface 46, it is possible to displace the frame 53 of the plane mirror 24 in the carrier bed 52 and fix its position by the latch 55.

The function of the non-glue according to the invention is that the angular relationships of the three rotatably connected parts to each other are

260,221 and the loading orientation _{of the} pendant / úhloměrných read on the scale / provide information about the spatial orientation structure geological elements.

The vertical angle gripped by the loading part, the attachment of which is placed on the measured planar or linear element / and the suspension part expresses the inclination of the structural element. The horizontal angle (?) At the loading portion and the orientation portion given in a known direction, e.g., the direction of the mine axis axis, represents the angle between the structural member and the known direction. After a one-time adjustment of the azimuth value of the known direction by adjusting the two-handed horizontal angle indicator to the azimuth value of the known direction in the case of aligning the direction of the direction bar and the arm of the contact portion. The built-in magnetic latch controls the interference effect of the magnetic effects and, in the absence thereof, i.e. in an environment with an unaffected geomagnetic field, _z can serve to separately measure the azimuths of the structural elements.

The meter according to the invention is suitable for measuring in difficult conditions of equipped mine workings.

Claims (11)

Object of the invention 260 221 Universal structural geological meter with improved orientation 1, consisting of a lined part consisting of a lined part, a cranked arm and a universal hinge with a vertical protractor system between the loading and hinged parts, a hinge part with a horizontal protractor system and an orientation part formed and a bearing bearing a magnetic latch with a targeting element formed by a directional bar, characterized in that in the orientation part (3) there is situated a means for its optical orientation connected to the directional bar (22). 2. A gauge according to claim 1, characterized in that the guide rod (22) is further provided with a supporting arch (26) slidably mounted in a supporting half-housing (19) provided with a sight glass (48), the supporting arch (26) being provided with a measuring gauge 12.11 and, on the other hand, a toothing (49) engaging an adjustable pinion (28) laterally housed in the support half-housing (19). 3. A gauge according to claim 1, characterized in that the means for optical orientation is a collimator (23). Fourth gauge according to claim 1 or 2 _f, characterized in that the means for optical orientation dloptr / 58 /. Fifth gauge according to claim 1 or 2 wherein _from said means for optical orientation reflex / 24 /, slidingly mounted on the deflecting rod / 2 /, which is rotatable about an axis coincident or parallel with the axis of the bar code / 22 /. 260 221 6. A meter according to claim 1 or 2 _, characterized in that the means for optical orientation is a pair of mutually perpendicular reflective surfaces (34) slidably mounted on a guide rod (22) on which a small rectified light source (33) is directed, the axis of which it passes through the axial plane of the angle clamped by the two reflective surfaces (34) and which is rotatable about an axis equal to or parallel to the axis of the guide rod (22). 7th gauge according to claim 1 or 2 _/, wherein the optical orientation means has a pair of symmetrically adjustable reflective surfaces / 34 /, slidably stored in the Routing £ 1, which is directed toward the source / 33 / directional light whose axis passes an axial plane of the angle clamped by the two reflective pads (34) and rotatable about an axis equal to or parallel to the axis of the guide rod (22). 8. Gauge according to points 1 and 2 _? characterized in that the means for optical orientation are directionally directed light sources (33) on both sides, which are arranged on the directional rod (22) and which are symmetrically tilted and pivotable relative to one another. 9. A gauge according to claim 1 or 2, characterized in that the optical orientation means is a light source (33) located in a slot (41) provided with a housing (40) situated on a guide rod (22) which is tiltable along the axis. parallel to the axis of the direction bar (22). 10. A gauge according to claims 1 to 9, characterized in that the guide rod (22) is telescopically retractable. A gauge according to claim 1 _, characterized in that the guide rod (22) is configured as a rotatably mounted frame (53) situated in the guide (52) of the driver (52) located in the center of gravity of the carrier (43). 260 221 which is attached to the carrier half-sheath (19), wherein on the wounds of the wound (53) a reflective spot (24) is situated on one side and a counterweight (54) is situated on the other side and connected collisator (23).