HU183301B - Method and measuring vehicle for admeasuring the axial section of tunnel tubes - Google Patents

Abstract

Track-mounted measuring vehicle with a mounted on a, with continuous (non stop) advancing movement arranged - formed of laser transmitter and -mpfaenger - distance measuring device and with this connected devices for displaying or registering the profile measurement data and a distance measuring device connected to these. The object of the invention lies in a much more accurate and faster-by special simplicity and reliability excellent Laengs-profile measurement. The object is to harness the exceptional precision of laser rangefinders for direct, continuous Laengs profile measurement of tunnel tubes or the like. This is achieved in that the distance measuring device provided for the Laengs profile measurement is formed by a common arrangement of the laser transmitter and receiver with matching optical axis extending in a plane perpendicular to the track or tunnel axis, and to the continuous and stepwise or Continuously continuous Laengs measurement - with the path measuring device via a control member is in communication, and - for optional measurement of different Laengsprofile within at least a portion of the Querprofilumfanges - position adjustable and fixable.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for substantially continuous, non-contact measuring of longitudinal gauge of track moving vehicle tunnels, culverts and similar narrow spaces, having at least one continuous-motion vehicle, in particular a propulsion vehicle, it has a measuring instrument for indicating or registering and, where appropriate, storing the measuring data and a connected encoder.

Austrian Patent No. 353,487 discloses a gauge moving vehicle which is suitable for non-contact measurement of the cross-sectional line of tunnels or the like, which has a laser distance gauge embedded in a circular path parallel to the axis of rotation, scans with a laser beam. The measurement provides many consecutive unique signals, each of which extend over the entire cross-sectional area, and are recorded or stored in an appropriate medium by analog or digital means. Evaluating the measurement data gives an overview of the cross-sectional line along the entire measurement section, the relative position of the track relative to the tunnel axis, and local deformations or constrictions of the tunnel profile.

U.S. Patent No. 2,440,321 discloses a tunnel-moving vehicle on a track by means of which one or more laser rangefinders can be used to scan the longitudinal section of the tunnel wall at any one time. Each of these rangefinders consists of a fixed laser beam emitting mechanism perpendicular to the tunnel axis and a longitudinal image evaluator comprising a high-speed electric motor slotted disk and an optical system provided by the laser emitter on the wall of the tunnel mapping, and including a slot element, which is designed as a multiplier, and thus a counter is controlled. Aside from the fact that these rangefinders are extremely complex and costly in structure and cost, there are many sources of error due to the distance between the image evaluator and the optical axis of the two, and the high degree of uncertainty in the applied measurement principle. which makes it impossible to carry out the exact gauge survey required by the railway undertaking. These inaccuracies are the result of indirect distance measurement by scanning a laser spot with an expansive surface at one end with a laser beam at an acute angle.

Swiss Patent No. 522,202 discloses an additional tunnel profile measuring vehicle, which is equipped with a laterally adjustable measuring device, which includes a laser emitting arrangement for creating two laser beams which are cohesive towards the tunnel wall. By adjusting the measuring device laterally, the intersection of the two laser beams on the tunnel wall can be adjusted to produce a single laser spot. In order to measure the longitudinal section line along the track during continuous movement of the measuring vehicle, either the distance between the measuring equipment and the tunnel wall must be kept constant by continuously adjusting the ddalb setting, or alternatively constantly changing distance between two non-overlapping laser spots continuously measured and recorded. Aside from the significant handling and control problems that occur especially with the latter operation, this measurement method does not give an accurate result, given the sources of measurement inherent in the measurement principle, so that the goose spray in this solution is outside the given tolerance.

It is an object of the present invention to provide a measuring vehicle of the kind described in the introduction, which is considerably more accurate, faster than the known, and which is particularly suited to practical requirements, and which is distinguished by its simplicity and operational reliability. This object is solved by the use of a common arrangement of the laser emitter and laser receiver for measuring the distance gauge according to the invention and having the same optical axis running in a plane perpendicular to the axis of the track or tunnel and continuously or incrementally or continuously it is connected to the encoder via a control member and is adjustable and lockable for positioning and locking it in at least a part of the cross-sectional region for measuring various longitudinal sections.

The invention first makes it possible to provide a laser rangefinder having an optical axis of a laser emitter and a laser receiver that is surprisingly advantageous for direct, substantially continuous measurement of the longitudinal section of tunnels or the like. With extremely high accuracy, this measurement method provides easy and versatile evaluation and reproducible measurement data due to the fixed setting of the gauge structure, ε, which provides information on any change in the gauge or track position relative to the tunnel axis in subsequent comparative measurements. yourself. The path-dependent control and operation of the structure ensures that each measuring position is accurately assigned to a specific track position for each position of the distance measuring device, providing the additional advantage that individual measuring paths can be performed at longer intervals without the need to complete the measurement program. it would adversely affect the accuracy of many test runs. Thus, especially on heavily used main sections, the measuring passages can be performed at any time during the train breaks by changing the distance setting device so that the track locks can be left out.

The invention thus allows for a very rational way of working, since the measurement of the longitudinal section is limited to certain subsections of the cross-sectional area that may be of interest, so that unnecessary measurement work can be avoided and the time required to complete the entire measurement program can be minimized. Thus, for example, if only the ability to exceed the load dimensions, that is to say, the dimensions of the freight transport, with its contours projecting from the standard luminaire profile, is to be reviewed, the longitudinal gauge is

183 301 may be limited to those portions whose distance from the outline of the material being conveyed is reduced by the dimensions of the load exceeding the standard luminous profile. In most cases, this affects only the upper lateral regions of the tunnel.

In each case, it is possible to determine the shape of the cross-section from the measurement of the longitudinal section of each track at practically each location in the section in question and in the entire region of the cross-section profile.

A further advantage of the invention is the extremely simple construction of the apparatus and the use of laser structures which are often well-proven. Finally, it is also possible to retrofit existing vehicles, particularly superstructure machines, with the structure according to the invention.

According to a further highly preferred embodiment of the invention, the distance measuring device is rotatably mounted about an axis parallel to the track axis and is connected to or provided with an adjustable conveyor belt, such as an angle dial or the like. This arrangement, which makes it possible to manually adjust the inclination of the optical axis of the rangefinder to the desired accuracy, is not only due to its extreme structural simplicity, but also due to its central arrangement of the rotational axis of the rangefinder substantially aligned with the tunnel axis. in each setting position, the same advantageous measurement conditions are obtained, namely, that the optical axes of the laser emitter and laser receiver are substantially perpendicular to the tunnel wall at all times and that there is substantially the same distance between the distance measuring device and the tunnel wall.

According to a further advantageous feature of the invention, the distance measuring device is embedded in height and / or lateral adjustment and is connected or provided with at least one adjustable member which can be locked in any height or lateral position. Such an arrangement, which may optionally be combined with an adjustable pivotable bearing of the distance measuring device, also provides advantageous measuring conditions when longitudinal measurement is to be made in the range of objects crossed by paths or substantially planar surfaces.

According to a further feature of the invention, the actuator is preferably a hole disk or a plate having holes at the same angular or longitudinal distance and having at least one locking pin or the like mounted on the vehicle chassis and connected to the hole disk. This not only simplifies the setting of the distance measuring device at the start of each test pass to a specific P: adjustment position, but also provides a reassuring baseline for comparative measurements with the same or similarly designed measuring vehicle. In order to meet different requirements for the accuracy and density of the structure, multiple rows of holes may be formed on the disc or plate, or the discs or plates may be interchangeable.

According to a further preferred embodiment of the invention, the distance measuring device can be locked in position adjustment or stepwise! or is driven or interconnected for continuous positioning, preferably automatic positioning, especially at the beginning and end of each test passage. This arrangement allows the actuator to be remotely actuated from a central control panel or to run the adjustment process automatically before an additional longitudinal section is evaluated.

According to a very simple embodiment of the invention, the adjusting or adjusting drive bt is designed as an electromagnetically actuated stepper. Preferably, a self-locking toothed lock or the like may be used for this solution.

According to a further preferred embodiment of the invention, the encoder which actuates the distance measuring device is formed in particular as a pulse transmitter which can be influenced or operated by the track sections, such as rail fastening devices. With this solution, a direct connection can be made between the individual distance measurement values and the track reference points when the distance gauge is actuated individually. In addition, there is the possibility of multiplying the number of individual measurements by two pulses between successive actuations per unit length of the measuring section, thereby increasing the density of the measurements.

The invention further relates to a method for substantially continuously measuring the longitudinal section of tunnels, runways and similar narrow spaces in accordance with Figures 1-7. A measuring vehicle according to claims 1 to 5. The object of this procedure is to continuously measure, record, and continuously measure the distance between the gauge structure or its axis of rotation and the tunnel wall or narrow object during continuous movement of the gauge vehicle. optionally storing, and then making an additional longitudinal measurement passage while continuously adjusting the optical axis alignment until the measured hsc sections are available for the entire transverse section at any desired sub-section. With this solution, it is advantageous to have the measuring vehicle run alternately in the opposite direction with different distance adjusting devices for successive surveys of a longitudinal section, thus reducing the total duration of the measuring program by half. Changes in direction of travel are not affected by the measurement result, since the ratio of the measurement locations to the longitudinal line of the track does not change.

DETAILED DESCRIPTION OF THE INVENTION The invention will be more fully understood from the drawings which illustrate an exemplary embodiment of a measuring vehicle according to the invention. The

Figure 1 is an axonometric view of the measuring vehicle, a

Figure 2 shows another embodiment of a part of a measuring vehicle, also axonometically, a

Figure 3 shows a tape-shaped information carrier on which a line of a rail section can be drawn.

Figure 1 is a schematic and simplified view of a section of a railway track tunnel using a measuring vehicle 1 which is movable on a track. The measuring vehicle 1 is preferably equipped with a tensioning and retaining device 2 which is driven by a hydraulic cylindrical piston drive, by means of which the vehicle body 3 of the measuring vehicle 1 is permanently flanked on the right or left track 5 by four tracked wheels 4 on the track 5. the game lies flat and moves towards the 7 track axes3

-3183 301 can be changed. Such devices 2 for driving the vehicle along a guide rail, such as the outer rails of the track curves and the track center, without play, are common on measuring vehicles and track-building machines and are preferably used to obtain accurate measurement data.

In the illustrated embodiment, the measuring vehicle 1 is provided with its own driving vehicle 8, which can be reversed on the vehicle chassis 3. However, instead of propelling the vehicle itself, it is possible to use a connection with another self-propelled vehicle, in particular a track-building machine, e.g. It is important, however, that the measuring vehicle 1 can run the track section to be measured in both directions at a predetermined, particularly continuous speed.

The measuring vehicle 1 has an encoder 9, which in the embodiment shown comprises an impulse transmitter 11 which can be inductively influenced or operated by the rail fastening means 10, in particular the foot bolts. The pulse transmitter 11 is connected to the control member 13 via the cable 12, which in turn is connected to the structure 14 for indicating, registering and optionally storing the measurement data of the gauge.

On the bearing part 6, which is connected to the vehicle chassis 3 by means of supports 15, a distance measuring device 17 is rotatably mounted about an axis 18 parallel to the track axis 7. This distance measuring device 17 consists of a laser emitter 19 and a laser receiver 20 having an optical axis 21 which is substantially perpendicular to the axis 18. By "coinciding" we mean that the laser emitter and receiver are not only precisely coaxially positioned, but that which is technically much easier to solve, namely, that the optical axes of the laser emitter 19 and laser receiver 20 are as short as possible. The distance measuring device 17 is connected to an optional angularly adjustable actuator 22 which, in Fig. 1, is configured as an adjustable disc based on the fixed angle scale 23. For remote actuation and adjustment of the distance measuring device 17, it is connected to an actuator 24 configured as an electromagnetically operated step switch or the like. The drive 24 is connected to the vehicle chassis 3 by means of the supports 15. The drive 24 and the distance measuring device 17 are connected to the control member 13 by means of wires 25 and 26, respectively.

Assuming that the tunnel longitudinal section survey is to cover a predetermined subsection 27 of the cross-sectional area 28, the following procedure is preferred for carrying out the measurement program.

Prior to the first passage, the distance measuring device 17 is rotated by the actuator 22, either manually or after the drive 24, about the axis of rotation until the optical axis 21 has a predetermined reference direction perpendicular to the axis of rotation 18, e.g. a defined angle of elevation ₀ corresponding to the upper limit of the portion 27 of the cross-sectional area to be measured. The encoder 9, the control member 13, the device 14 and the spacer 17 are then put into operation and the measuring vehicle 1 is driven by a vehicle drive 8 in the direction 30 (forward). As the first 6 sleepers pass through, the position of the longitudinal track into the measurement log! is indicated or to be marked, and it is advisable to permanently mark it, the impulse transmitter 11 is inductively influenced by the rail fastening means 10 of this sleeper 6 so as to emit a signal. The control pulse transmitted from the pulse impulse 11 via the line 12 and the vein member 13 enters the structure 14 for signaling or registering the position signal. At the same time, the pulse actuates the distance measuring device 17 via line 6, whereby the following alternatives to control types exist:

If the length of the tunnel is to be continuously measured throughout the entire measurement period, the distance measuring device 17 is switched to continuous measuring mode by the first pulse of the path, and the measurement data is continuously indicated, recorded and / or stored by the device 14. Only at the end of the measuring period, turn off the distance measuring device 17 - manually or automatically when the measuring vehicle 1 stops. However, for continuous incremental and point-by-point measurement of the tunnel longitudinal section, the distance measuring device 17 performs individual measurements for each pulse of the path and / or the local distance measurement value is individually indicated or registered by the structure 14. In both cases, the tunnel wall was fixed at an elevation angle of ₀ and was scanned along component 32, and the distance between the tunnel wall and the axis 18 of the structure 14 was always measured.

At the end of the measurement phase to its previous setting position! the fixed distance measuring device 17 is rotated about the axis 18 at a predetermined angle and fixed in the new position. Its optical axis 21 extends at an angle to horizontal 29. The vehicle drive 8 is then set to reverse and the measuring vehicle 1 is moved in a continuous direction in the direction of the dashed arrow 31. During this, the direction of movement of the respective signaling device, such as a tape or a recording strip, is automatically reversed. Further along the tunnel wall 33, the distance measuring device 17 is continuously scanned until the measuring vehicle 1 reaches the starting point of the first measurement run and the sleeper 6 indicated above. During further measuring passages, in each case in opposite directions and with varying adjustment of the distance measuring device 17, additional tunnel walls 34-37 are formed; scans along until the measured longitudinal sections are available for the entire 27 ranges to be measured. Meanwhile, for the last three test passages, for the 35, 36, and 37 creators, the distance measurements in the tunnel impingement area 38 are changing dramatically.

From the measurement data stored by the structure 14, it is possible to determine not only the tunnel longitudinal section along the section 27, but also the cross section of the tunnel section such that different elevation angles and their associated distance values from the axis 18 radially applied and the endpoints of these rays connected to each other to form a cross line, as indicated by lines 39, 4C in FIG. Of course, this evaluation can also be done electronically.

Thus, according to the invention, the apparatus described above can advantageously also provide a method which, while the measuring vehicle 1 is continuously moving in the longitudinal direction of the track, the distance measuring device 17 and its axis 18 and

The distance between the wall of the tunnel 183 301 and the narrow object with continuous adjustment of the optical axis 21 of the distance measuring device 17 can be continuously measured, recorded and optionally stored, and an additional longitudinal measurement path can be performed at any time with the changed optical axis adjustment 21 for the cross-sectional area, the measured longitudinal sections are not available in the optional 27 sub-sections.

It is extremely important for the accuracy of the measurement data obtained that for each fixed adjustment of the distance measuring device 17 the position of the optical axis 21 is given in a plane 41 perpendicular to the axis 18 and the track axis 7, respectively.

2, the adjusting member 22 for adjusting the optical axis 21 in the plane 41 is formed as a hole disk 42 which is rotationally connected to the distance measuring device 17. It is provided with holes 43 equally spaced about the circumference of the hole disk 42, to which a locking pin 44, which is pivotally mounted on the bearing portion 16, engages. This locking pin 44 can, for example, be loaded with an axial biasing force in the direction of the disk 42 by means of a coil spring located in the spring housing 45 or the like. In contrast to the embodiment shown, it is also possible to use a disc having a plurality of concentricly arranged rows of holes having different circumferential divisions and circumferential spacing of the components in accordance with the respective accuracy requirements. In order for the measuring program to run fully automatically, it is desirable that the locking pin 44 be electromagnetically remotely operated via the actuator 24 and the control member 13 at the beginning and end of the test passages.

Figure 3 illustrates the simplest embodiment of an information carrier for continuously plotting measurement data of the recording strip 46, which shows measurement data obtained in the region of the tunnel wall of Figure 1. The arrow 47 shows the direction of movement of the recording strip 46 when drawing the longitudinal section of the vehicle in forward motion, and the arrow 48 shows the corresponding direction of movement at the reverse. In order to assign the measurement data to the longitudinal line of the track, the control pulses emitted from the pulse transmitter 11 of the encoder 9 as each sleeper 6 passes are drawn as successive placeholders 49. In order to represent the individual longitudinal sections separately and without overlapping, a separate baseline 50 corresponding to the axis 18 is used for each adjusting position of the distance measuring device 17 and for each rising angle of the optical axis 21, from which the tunnel wall begins. and the respective measured distances 51 between the axes 11 and 11 are applied transversely to the feed direction of the recording strip 46 in a sufficiently reduced scale. For the longitudinal section corresponding to the creator 32, both versions of distance measurement and registration are depicted in Figure 3. The full through line corresponds to a continuous uninterrupted distance measurement, while the successive measurement points 52 correspond to the individual distance measurement at each location signal 49. In the case of continuous distance measurement, the gauge for each track location can be determined from the local distance data and the current elevation angles at these locations. In the case of spot measurements, the gauge can also be defined at any of the 49 positions indicated at any time. Two such sites, where, for example, the cross-sectional lines 39, 40 of Figure 1 can be defined, are depicted in Figure 3 as lines 53 and 54.

Of course, within the scope of the invention, it is possible to register and store longitudinal measurement data in digital form, and to use the predetermined limits to measure the distance and location of these measurement data outside the tolerance during the measurement passage. determine and register separately. In addition, by specifying appropriate gauge data reasons, the load overrun can be reviewed by directly comparing the measurement data received by the distance measuring device 1.

From a structural point of view, many variations are possible within the scope of the invention, other than those described and illustrated above, in particular the adjustable arrangement of the rangefinder and the indication, registration and storage of auxiliary devices such as actuators, gauges, and measurement data. structures. For example, instead of rotation, a height and / or laterally adjustable and lockable bearing can be provided for the distance measuring device. In addition, the actuator member may be configured as a lockable rack arrangement and the actuator drive may be, for example, a self-locking screw drive driven by an electric motor. Finally, the encoder may also be located in the region beyond the pedestal pitch in order to obtain denser pulses.

Claims (7)

Patent claims 1. Apparatus for continuous continuous contactless measurement of the track gauge of track-moving vehicle tunnels, culverts and similar congested spaces, having at least one continuous-motion vehicle, in particular self-propelled vehicle chassis and laser rangefinder and receiver it has interconnected structures for indicating, registering and, where appropriate, storing measurement data, and an encoder connected thereto, characterized in that the distance measuring device (17) for measuring the longitudinal section is the laser emitter (19) and the laser receiver (20). ) is arranged in a common arrangement and has the same optical axis (21) running in a plane (41) perpendicular to the axis of the track or tunnel (7) and connected to the encoder (9) by a control member (13); the transverse section region (28) being configured in position and lockable within at least one portion (27) of the cross section. An embodiment of a measuring vehicle according to claim 1, characterized in that the distance measuring device (17) is rotatably mounted about an axis (18) parallel to the track axis (7) and can be fixed at any angular position by an adjusting member (22), e.g. ), is connected or provided with. An embodiment of a measuring vehicle according to claim 1, characterized in that the distance measuring device (17) is adjustable in height and / or laterally and has at least one height or lateral position. It is connected or provided with a lockable actuator in position 183 301. An embodiment of a measuring vehicle according to claim 2 or 3, characterized in that the adjusting member (22) is a hole (42) or a plate having holes (43) preferably formed at the same angular and longitudinal distances and having at least one having a locking pin (44) or similar mounted on a chassis and connected to the hole disc. 5. Measuring vehicle according to any one of claims 1 to 4, characterized in that the distance measuring device (17) is preferably provided with a position adjusting device which can be fixed at the start or end of each measuring passage or a step or continuous, preferably automatic positioning drive (24). connected. An embodiment of a measuring vehicle according to claim 5, characterized in that the adjusting or adjusting drive (24) is designed as an electromagnetically actuated stepper. s 7. An embodiment of a measuring vehicle according to any one of claims 1 to 3, characterized in that the odometer device (9) for actuating the distance measuring device (17) can be influenced or actuated by a pulse transmitter (11), in particular from track sections such as rail fastening means (10). 3. A method for substantially continuously measuring the longitudinal section of tunnels, culverts, and similar narrow spaces as set forth in Figures 1-7. A vehicle q according to any one of claims 1 to 5, characterized in that during the continuous movement of the measuring vehicle the distance between the longitudinal track of the track or its axis of rotation and the tunnel wall or the narrow object with constant adjustment of the optical axis of the track. continuously measuring, recording, and optionally storing, and then making a further longitudinal measurement passage while continuously adjusting the optical axis alignment until the measured longitudinal sections are made available to the entire transverse section at any desired subsection.