CS231864B1 - Method of direction finding,aligning a recificatoon of tracks by long chrd method with laser utilization - Google Patents

Abstract

The essence of the method is that from the polygon show the opposite pairs security tags calculated in the state coordinate system on their line, arbitrarily in the gauge track, using a vertical movable line the target of the first end lath stabilizes and signals more distant end of long chord the target is guided to the prepared track of the He-Ne laser beam and the same the second end lath is similarly placed in the proximal securing tag lines, thereby making them long chord with He-Ne laser in its extension, whereupon it is obtained the ends of the chords will be obscured by the tape to the appropriate line of securing marks and the coordinates are calculated again, then pre-dimensional detailed points selected in any density on the inner edge outside the rail aim the targeting laths with the target to a chord made by a laser beam taking points after calculating coordinates define the current track condition.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for quickly locating, setting out and rectifying railway tracks by the long chord method and to a device for carrying out the method.

The previously used methods for rectification of railway curves, in particular, solve the position of detailed points in their own coordinate system. At the same time, the point density of the so-called arc coordinate methods is 5.1 to 50 m for numerical or graphical-numerical processing, or 20 to 80 m for the axial polygon method, which is solved numerically.

The methods of numerical accuracy, ie mainly the evaluation of fluency, comply with the current CSD regulations. In all cases, the track is secured with concrete posts according to the relevant regulations.

The long chord method assumes other more appropriate, more economical track securing, more resistant to damage. Its securing points are geodetically determined in the national grid without exception.

The prior art is defined by the so-called end of long chords lying at the intersection of the track axis with the junction of opposing paired crimping points. The chord spanning two adjacent ends of the long chord is 20 to 90 m long.

After the numerical solution and approval procedure, the new state straddles the restored chord at a suitable arbitrary density of points. The chord is realized by a steel wire or a laser beam oriented at one of the end points of the long chords.

The method according to the invention makes it possible to measure the old state at any value of regularly spaced, pre-measured detail points, and the essence of the invention is to focus pairs of opposite securing marks calculated in the state coordinate system , the vertical end of the long chord is stabilized by means of the vertical line of the moving target of the first end lath, and the target is guided into the track of the prepared He-Ne laser beam and the same second end line is similarly placed into the closer line of the security marks. with the position of the He-Ne laser in its extension, after which the obtained chord ends are measured with the measuring band at the respective line of the securing marks and the coordinates are calculated again, after which the detailed points in the lined at any density on the inner edge outside the rail, using a target, aim the reading bars perpendicular to the chord realized by the laser beam, whereby the measured points define the current track state after the coordinates have been calculated.

SUMMARY OF THE INVENTION The device of the invention consists of two identical end laths on which are displaceable, transparent, shielded targets with a mirror equipped with a reading index for reading on a horizontal millimeter scale, each end lath being provided with two adjusting screws, seating edge and tubular vial for their placement on the connecting line of the locking markings for horizontal positioning, the end laths are insulated from the set screws to prevent conductive connection of both rails and from a reading lath of similar construction, provided with a right angled rod and reading lath target is complemented by a geodetic pentagon for aligning the lath into the comic to the chord of the laser beam.

The greater effect of the invention is manifested in many aspects. Because the arc is defined by a significantly greater number of points, the solution is not affected by local anomalies of the position at the point of the end of the long chord.

Endpoints can generally be off the track axis, reducing the time and labor requirements for aligning them, and eliminating the possibility of distorting solutions due to errors in measuring long chord ends.

The detailed points of the arc are orthogonally related to the long chord, realized by the visible laser beam as a line of sight. This makes it easy to calculate the coordinates in this system and to transfer them to the national system.

The perpendiculars are directly read on the reading lath with an accuracy of 0.5 mm, the aging is determined by the measurement of the position of the points and the direct alignment of the scales in lettering between the end lath and the reading lath at the end point of the chord along the laser beam.

Compared to the chord realized by steel wire, it is possible to choose without sacrificing accuracy of up to twice the chord length. The solution in the state system ensures better continuity of this method compared to other methods.

In the accompanying drawings, the method according to the invention is explained in more detail and an apparatus for carrying out this method is shown.

Fig. 1 shows the PB points of the subordinate railway polygonal sequence, most of which are polarly oriented pairs at the normally opposite L and 1 '' _značek · _ζζ · The laser position is marked 'L. "~

Into the connector of the distal pair 2Z is placed the end lattice KL (here klj), whose target is set to the laser track by means of a vertical line, which is centered on the connector of the distant pair ZZ.

This gives the so-called end of the long chord. jKT. In the same way, the second end rod KL1 is set in the laser connection of the closer pair ZZ and thus the ends of the long chord are determined. , ³ KT. Points. JkT and ^ KT define the so-called long chord and can be determined in coordinates. ~ ^- '~~'

In the same FIG. 1, a third chord is shown to advance the measurement in advance at a suitable density along the inner edge of the outer rail of selected detailed points P1. The cutting points CL are provided with the cutting edge CL, provided with a device enabling it to be perpendicular to the chord given by the laser beam.

The target of the reading lath is tracked and the perpendicular k is read on a millimeter scale. The coordinates of the detail points are calculated by transforming the values of the measured perpendicular k and the chainage calculated from the segments on the arc θ and the measured gauges, etc. Points. P £ define the old state. After calculating the new state, the same set can be used to set out a new state after the chord moves.

Giant. 2 shows the construction of an end batten KL, which is formed by a steel hollow beam 2, which is provided at one end with a bearing edge 10 at the bottom, which rests on the rail head from the inside from the side.

The horizontal contact surface 11 forming a unit with the blade 10 has a height of 10 mm and serves to compensate for any inverted / erroneous / elevation. At a distance of 1.45 mm from the cutting edge 10, a crossbar 12 of about 150 mm length is symmetrically placed at the bottom of the beam 1 perpendicular to its axis, in which two adjusting screws 20 of length 200 mm are positioned vertically. position according to the tubular level 3 located in their immediate vicinity.

About 100 mm in front of the crossbar 12, a pertinax insulation 10 is provided in the entire profile of the beam 2, preventing short-circuiting of the train path. On the upper horizontal surface of the beam _1 ³ and accurately positioned millimeter scale 9. A ' whose origin (zero) coincides with the abutment lip 10 and ends above the crossbar 12.

In this range, a translucent organic glass target 4 having a vertical line and / or a double line 5 is moved along the beam 1. FIG. 3 is a schematic side view of the end batten.

AND

The target 4 is guided on the beam 4 by a clear organic glass slider 13 which, on a horizontal surface adjacent to the scale 4, is provided with a reading line 4 which corresponds exactly to the vertical line 4 '.

A beam falling on target 4 is observed in the mirror? 7, which is supported by the lower end of the rider ¹¹ ' with the target 6 and deflects by about 40 [deg.].

The target 6, the mirror 7 and the sidewalls 6 form an observation folding shaft which increases the accuracy of the reading, prevents glare of the eye and allows a higher work culture, since it is possible to stand while working at the rail level.

FIG. 4 shows a detail of the middle portion of the end slat. KLj. ₂ ; FIG. 5,6,7 show a construction of a reading lath CL in which the elements are identical to the end lath elements KL1. ₂ , namely the beam 1, the blade 10, the contact surface 11, the scale 6, the insulation 8, the vial 8, the target 8 with the mark 5, the shielding 8, the mirror 8, the slider 13 with the mark 14.

The rectangular bar 15 of approximately 500 mm length is positioned to the horizontal position according to the vial. The bar 15 is positioned at the end of the beam opposite the cutting edge 10. On the target there is a device for placing the reading lath CL perpendicularly. laser beam.

The target 4 is provided on the face side on the vertical edges with guide bars 21 in which the slider 16 moves. This carries a double pentagon 17 which, when adjusted by the target 6 in transverse movement and the slider 16 vertically into the beam, wraps it. 90 ° on both sides, i.e. parallel to the vertical plane, intersected by the edge of the beam 6, thus also the target 6.

The impact of the kink track is caught on the auxiliary target 18, loosely mounted by the bracket 20 on the beam 10 and one of its ends, which is given according to the direction of illumination.

In practice, the device according to the invention serves for locating old state points, setting out new state points or setting out shifts perpendicular to the chord between the old and new state points of the same station.

In both types of stakeout, the long chord DT can be restored to the original position of focus or more preferably selected in a general position. A prerequisite is the use of programmable calculators to transform the stakeout elements from the original to the newly selected long chord DT system.

The device is necessarily complemented by series-produced He-Ne lasers. The device is built into the bed in the extension of the long chord DT. This eliminates the influence of its axial defects and it is not necessary to center and horizontal it at the end point of the long chord KT, which again speeds up the work progress. The laser must be equipped with a transverse support in order to allow the longitudinal chord DT to be restored to its original position.

Operation of the device of the kit according to the invention is simple. When aligning the end batten KL, the lip 10 rests against the inner edge of the outer rail. A pair of leveling screws 35 having a sensitivity 35 '

The length of the bolts' 2 must be sufficient to compensate for the maximum camber p »« 150 mm. At the same time, the entire end lattice KL is moved in the direction of the track axis so that the face side, i.e. the inside of the chord, of the translucent free-slide and slide detection target 6 is parallel to the band of opposed pairs ZZ realized by the band.

By repeating the procedure, the target 6 of the horizontal end batten KL is guided into the junction of the opposite pairs ZZ. The vertical center line (R) of the target (4), which, depending on the size of the laser track, can be replaced by a double line, will be superimposed on this link by a band, creating a new long position

The chord OTyor is set to the value specified by the documentation, which creates the restored long chord position DT.

In the first case, the trace of the coarse-targeted laser is searched for by the target 4, where we do not work with the laser provisions, so that the beam position cannot be pulled, in the second case the laser must be precisely targeted.

This procedure applies to the far end rail KLj. The procedure in the first case is the same for the proximal end bar KL1 to the laser. In the latter case, the entire laser is aimed by the transverse support, and the procedure for targeting the rear end batten, KL ₂ and the front end batten KL 4, must be repeated several times. ""

This clearly defines in each case the long chord points KT through which the long chord DT passes. For use on lines with low-current safety equipment, the CL reader bar is divided and connected in conjunction with pertinax insulation 6.

In order to increase the accuracy of the adjustment, suppress daylight and substantially increase the comfort of the operator, a planar mirror 8 with leatherette sidewalls 8 is arranged behind the target 4 obliquely below about 30 °.

Custom target 4 is about 15 x 25 cm and is made of matt white plexiglass.

A precision millimeter scale with a zero above the bearing lip 10 is provided on the upper cross-sectional area of the reading latch to allow the rail axis to be changed, which is also used to measure the accuracy of the stationing.

The reading latch C1 is constructed similarly. It is attached to the measured detailed points of the arc. The right-angled rod 15 held by the operator is leveled horizontally. The target with the mark 5, and the shaft with the mirror 8 is completed on the vertical edges with guide rails 21, on the slider 13 a double geodetic pentagon 17 is mounted.

By adjusting the laser target on the track of the laser, when the slider 13 s 'pentago nem' 17 is moved vertically to the track level, a rectangular beam of 1 'to 2' is trapped on the opaque matt target 4 perpendicular to the axis of the reading bar. .

By moving the end of the slat with the rod 15 in the direction along the axis of the track, a trace of the angled beam is obtained on a vertical line 8 of the target 6 which is offset from the slat edge by the same value e as the facing edge of the pentagon 17.

The target 4 is displaceable to both ends of the lath CL according to the sun's illumination of its surface. The Pentagon 17 is double, ie it breaks the incident beam on both sides.

In this way, the reading bar CL is perpendicular to the chord with an accuracy of 1 * to 2. In the extension of the line 5, the required value of the perpendicular is read or set or scaled, or the offset of the track axis is to be.

Claims (3)

SUBJECT OF THE INVENTION A method of locating, setting out and rectifying railway tracks by a long chord method using a laser, characterized in that the polygonal sequence is aimed at pairs of opposing securing marks calculated in the state coordinate system, the connecting line of which is arbitrarily in track gauge by vertical line The moving end plate stabilizes and signals the far end of the long chord, and the target is guided into the trace of the He-Ne laser beam and the same second end laE is similarly placed in the proximal line of the locking marks, thereby realizing the long chord with the He- Ne position. Not the laser in its elongation, whereupon the obtained chord ends with the measuring band are tanned to the respective locking mark line and the coordinates are recalculated, whereupon the pre-measured detailed points are selected at any density at the inner edge of the outer the oiler points the target with a reading latch perpendicular to the chord realized by the laser beam, whereby the measured points define the current track state after the coordinates are calculated. Device for carrying out the method according to claim 1, characterized in that it consists of two identical end laths / KL. - /, on which are displaceable, transparent, shielded targets (4) with a mirror (7), equipped with a reading index for reading on a horizontal millimeter scale (9), each of the end laths (KLp KL ₂ ) being equipped with two adjusting pins screws (2), bearing lip (10) and tubular vial (3) for their placement on the locking line for alignment, the end battens (KL ^ KL ₂ ) are insulated before the adjusting screws (2) (6) provided with a rectangular angled rod (15) and the target (4) of the reading lath (Cl) is supplemented by a geodetic pentagon (17) for adjusting the reading lath (CL) perpendicular to the chord realized by the laser beam. 3 drawings