RU136048U1 - DEVICE FOR CORRECTING RAILWAY - Google Patents

Abstract

1. A device for straightening a railway track, comprising a track machine frame supported by straightening and straightening equipment, an on-board computer, a device for determining the distance traveled, a measuring trolley in contact with the rails, comprising a movable base, a spatial position sensor of the measuring trolley, an angle sensor track machine, while the outputs of these sensors and devices for determining the distance traveled are associated with the corresponding inputs of the on-board computer, exc characterized in that the spatial position sensor of the measuring trolley is mounted on the indicated movable base of the measuring trolley with the possibility of measuring the spatial position of the measuring trolley in plan and profile relative to the measuring base, which is used adjacent to the straightened railway track (rail) with known spatial coordinates and planned - high position relative to the straightening path. 2. The device according to claim 1, characterized in that as a sensor of the spatial position of the measuring trolley, it includes a laser rangefinder with an inclinometer installed with forced spatial orientation on the reference measuring base. The device according to claim 1, characterized in that as a sensor of the spatial position of the measuring cart it includes a laser scanner with a given scan angle. The device according to claim 2, characterized in that the spatial position sensor of the measuring trolley is fixed to a stem

Description

The utility model relates to the construction and repair of a railway track, in particular, to the technology of straightening a railway track, and can be used for planned and preventive straightening of a railway track, as well as for straightening a railway track during repair work, when finishing a railway track before commissioning after capital production track work.

A well-known technique for straightening a railway track is widely used in production, including measuring and comparing distances in control sections, at a given interval, for example, 100 m, between the axes of the straightened and adjacent tracks with the design position (from the straightening plot). Next, the calculation of the shift and elevation of the track in accordance with the differences obtained and the subsequent setting of the track in the design position. The leveling rail is used as a measuring instrument in this technology (Transport construction, 1/2012, p. 23-26).

This technology has significant drawbacks associated with the fact that from the moment of research to the beginning of ongoing work several months or even years pass. During this time, as a result of dynamic loads on the track, straightening during scheduled preventive work and the influence of other factors, the adjacent track to which the link is being shifted from its original position (from the moment of surveying) by an indefinite value. As a result, the design distances between the axes also change. This leads to the appearance of long irregularities in the plan and height during straightening of the path, which are copied from the neighboring path.

In addition, discrete measurements of 100 m do not allow to unambiguously determine the position of the path along the entire 100 m of the section, which also does not provide setting in the design position with the required accuracy.

A known system for controlling the alignment of a railway track, comprising a track machine, the frame of which is supported by running trolleys, and a device for straightening the railway track mounted on the frame, including a lifting and leveling device with a control unit and a measuring trolley that determines the position of the track axis. The system also includes a computing unit, with a memory unit and an information display unit connected to it (RF patent No. 2454498, E01B 29/04). The known system comprises a mobile reference station, a satellite positioning system, a tilt angle sensor connected to a computing unit, to which the output of the satellite positioning system receiver and a device for determining the spatial position of the measuring trolley are also connected. A device for determining the spatial position of the measuring trolley is placed under the track machine frame. An electronic model of the project of the position of the path in a three-dimensional spatial coordinate system is recorded in the memory block. The functioning of the system is based on determining the spatial displacement of the measuring trolley relative to the satellite dish. At each moment of time, the computing unit calculates the offset of the current position of the path in plan and profile relative to the design. Before the system starts, the source data is entered into the memory block of the computing unit - an electronic model of the project of the position of the path. The adjusted coordinates are developed jointly by the receiver and the reference station and indicate the location of the phase center of the antenna located on the track machine roof. To determine the spatial displacement vector of the measuring trolley relative to the antenna, measurements of the angular values and distances from the phase center of the antenna to the device for determining the spatial position (displacement) of the measuring trolley, as well as the readings of the displacement sensors of the measuring trolley relative to the track machine included in the device for determining the spatial position of the measuring trolley relative to phase center antenna satellite positioning system. In addition, information about the heel value is used, which enters the computing unit from the angle sensor. Data from the receiver of the satellite positioning system, the angle sensor and the device for determining the spatial position of the measuring trolley are fed to the input of the computing unit, which on the basis of these data calculates the current position of the path and compares it with the design position.

A similar technical solution is also known (RF patent No. 112209, ЕВВ 35/00, prototype), which describes a track machine containing an on-board computer, a frame supported by running trolleys, equipped with straightening and leveling equipment and a control and measuring system located under the frame, as well as the principle of operation of this device. The specified measuring system includes a measuring trolley containing a base in contact with the rails of the straightening track and a measuring base rigidly mounted in the lower part of the track machine frame in a plane perpendicular to the direction of movement of the track machine. The reference points of the indicated measuring base are equipped with linear displacement sensors installed to measure the change in the position of the center of the base of the measuring trolley relative to the measuring base, in height and in plan. A satellite dish is rigidly mounted in the upper part of the track machine at a fixed height relative to the measuring base of the measuring trolley. The phase center of the satellite dish is located in the initial state on the vertical axis passing through the center of the moving base of the measuring trolley. The outputs of the linear displacement sensors of the center of the moving base of the measuring trolley are connected by the on-board computer.

As sensors of linear displacements of the moving base of the measuring trolley relative to the phase center of the satellite antenna, in this technical solution, in particular, laser rangefinders or electromagnetic linear displacement sensors installed in a certain way along the measuring base are used.

The general disadvantages of the technical solutions described above include the structural complexity of the used control and measuring system and, as a consequence, the insufficient accuracy of measurements and, accordingly, the insufficient accuracy of setting the path to the design position. These disadvantages are associated with a significant impact on the operation of the device dynamic loads. The mobility of a track machine makes it difficult to synchronize in real time three interconnected measuring systems with different inertial characteristics - a satellite positioning system, a spatial positioning system for the measuring trolley, and a coordinate reduction system on the track axis (inclinometer).

The objective of the utility model is to expand the arsenal of technical means for straightening the railway track.

The technical result of the utility model is the creation of a device and a method for straightening a railway track with organizing measurements of the current spatial position of the straightened track relative to a neighboring railway track (nearest rail) selected as a measuring base with known spatial coordinates. Simplification, on this basis, of a device for straightening a railway track with ensuring high accuracy of measurements and, as a result, improving the accuracy of setting the straightened railway track in a predetermined (design) position, as well as simplifying the technology and increasing productivity when performing this type of work.

The specified technical result is achieved due to the fact that in the device for straightening the railway track, containing the track machine frame, equipped with straightening and leveling equipment, an on-board computer, a device for determining the distance traveled, a measuring trolley in contact with the rails, containing a movable base, a spatial sensor the position of the measuring trolley, the angle sensor of the track machine, while the outputs of these sensors and devices for determining the distance traveled According to the utility model, the sensors of the spatial position of the measuring trolley are mounted on the indicated movable base with the possibility of measuring the spatial position of the center of the measuring trolley in plan and in profile with respect to the measuring base, which is used as the adjacent railway track (rail) with known spatial coordinates and plan-altitude position relative to the straightening path.

Advantageously, as a sensor of the spatial position of the measuring trolley, the device includes a laser rangefinder with an inclinometer with forced spatial orientation to the reference measuring base.

In addition, as a sensor of the spatial position of the measuring trolley, the device may include a laser scanner with a given scanning angle.

The claimed technical result is also achieved by the fact that the spatial position sensor of the measuring trolley is fixed on a remote guide element rigidly connected to the center of the indicated movable base, installed at an angle of 90 degrees relative to the direction of movement, while the other end of the specified guide element interacts (slides) with the rail head of the adjacent railway track, which is a reference measuring base.

Advantageously, to determine the distance traveled, the device, according to the utility model, includes a satellite dish mounted on the roof of the track machine and a satellite receiver connected wirelessly to the reference (reference) stations, the output of the satellite receiver being connected to the corresponding input of the on-board computer.

At the same time, an odometer can also be used in the device to determine the distance traveled.

The essence of the utility model lies in the fact that this technical solution monitors changes in the spatial position (linear and angular) of the center of the measuring trolley, which determines the position of the axis of the straightened path relative to the external, stationary, measuring base, with known spatial coordinates. The spatial position of the indicated measuring trolley during the movement of the track machine along a predetermined path is compared with a predetermined design position of the path, and based on the received data, control signals for the lifting and straightening equipment are generated.

The drawing schematically shows a General view of a device for straightening a railway track, according to a utility model, in an advantageous implementation.

A device for straightening a railroad track comprises a track machine frame 1 supported by railway rails 2 by running trolleys 3. On the frame 1, straightening and leveling equipment 4 and a measuring trolley 5 are installed, comprising a movable base 6 and a spatial position sensor 7 of the measuring trolley 5, rigidly mounted in the center of the indicated movable base 6. The sensor 7 is strictly oriented in space to the rail head of the adjacent railway track, which is a measurement in this technical solution oh base 8. The specified orientation of the sensor 7 on the reference measuring base 8 is ensured by the fact that it is mounted on a guide element 9 mounted at an angle predominantly 90 ° (± 3 °) relative to the direction of movement in the center of the movable base 6, on its lower (facing rail tracks) surface. In this case, the guide element 9 is made so that its opposite end slides along the head of the adjacent rail when the track machine moves along the straightening path 2. This ensures strict orientation of the laser beam of the sensor 7 to the measuring base 8.

As the sensor 7, for example, a laser rangefinder with an inclinometer, for example, of the Disto 8 type, with a system for measuring range 1 and inclination angle β relative to the horizon, can be used. In addition, as the sensor 7 can be used means that do not require forced orientation, for example, a laser scanner with a given scan angle.

A satellite antenna 10 of the satellite receiver 11 is installed in the upper part of the track machine (on its roof), while the phase center of the satellite antenna 10 is mainly located on the vertical axis passing through the center of the movable base 6 of the measuring trolley 5. The satellite receiver 11 is connected to the first information the input of the on-board computer 12. Other information inputs of the on-board computer 12 are connected to the outputs of the sensor 7 and the sensor 13 of the angle of inclination of the track machine. The output of the on-board computer 12 is connected to the straightening equipment 4. Through the modem 14, the satellite receiver 11 can be connected to base (or reference stations) equipped with a complex of satellite navigation equipment 15. The satellite positioning system described above performs the function of a high-precision device for determining the distance traveled and provides spatial binding of design data and calculation of the distance traveled by the current coordinates. In this case, in order to determine the distance traveled, an odometer (a measuring wheel equipped with a speed sensor) can be used in this device.

Work on straightening the railway, according to the utility model, is as follows.

Before starting straightening work by measuring the spatial coordinates, the natural position of the adjacent track straightened out is adjusted to take into account possible changes in its spatial position from the moment of designing to the beginning of straightening work. One of the threads (rail) of the indicated adjacent path is taken as the measuring base 8. In accordance with the spatial data of the measuring base 8, the design position of the straightened path 2 is determined from the dependences known in geodesy in terms of (linear) and angular (in profile) relative to the measuring base 8. That is, the updating of design data is performed. If necessary, the data obtained is interpolated with a “step”, which takes into account the curvature of the rails and the functionality of straightening machines (for example, for data on the spatial position of the reference path taken as a measuring base, with a “step” of 0.1 m).

The coordinates of the measuring base 8, as well as the received, updated design data of the straightened path 2, the distance 1 between the axis of the straightened path 2 and the measuring base 8 and the angles β determining the height position of the straightened path 2 relative to the specified measuring base 8, are recorded in the on-board computer 12 of the track machine .

When the track machine moves, the measuring trolley 5 moves along the straightening path 2. In this case, the spatial position of the center of its movable base 6 changes in accordance with the current position of the straightened path 2. The sensor 7 detects changes in the spatial position of the center of the moving base 6 of the measuring trolley 5 in plan and profile relative to measuring base 8, measuring the angle β is the deviation of the sensor 7 from the horizon, which determines the current position in height h of the center of the movable base 6 relative to the measuring base 8, and the distance 1 from the center of the moving base 6 to the measuring base 8. The current (changing) values of the distances 1 and angle β, which characterize the spatial position of the measuring trolley 5 relative to the measuring base 8, measured in this way are fed to the second input of the on-board computer 12.

The on-board computer 12, according to a special computer program developed by the authors, compares the current values 1 and β corresponding to the current spatial coordinates of the measuring base with their design values rigidly tied to the spatial data (coordinates) of the straightened path at given intervals of the path.

Based on the obtained difference between the current and design values of 1 and β in the computer 12, a control signal is generated programmatically that arrives at the straightening and straightening device 4, which moves the straightened path 2 until the current values 1 and β are equal to their design values.

In this case, when the track machine moves to the computer 12, the following information simultaneously arrives:

- information from the satellite positioning system, from the receiver 11, (providing the binding of the measured data to the current coordinate of the path),

- the angle of inclination from the sensor 13 to introduce corrections for the deviation of the axis of the antenna 10 from the vertical and the calculation of the magnitude of the reduction,

- data on the spatial position of the center of the movable base 6 of the measuring trolley 5 relative to the reference measuring base 8, as described above.

All current information from the indicated sensors 7 and 13 is synchronized by the time stamps of the satellite positioning equipment 11, also received by the computer 12.

The device, according to the utility model, is inexpensive and reliable in operation. At the same time, the work technology implemented when using this device provides high quality track straightening due to the used measuring base, which is not subject to dynamic influences and changes in spatial position during the straightening process. Moreover, the measuring base itself can be curved, which reduces the material and financial costs of creating artificial rectilinear measuring bases, for example, laser reference planes or copier strings. Updating the spatial position of the measuring base immediately before dressing (for example, using GNSS) provides efficiency and high detail (≤1 m) in determining the coordinates of the measuring base and their interpolation, and subsequently high accuracy in setting the path to the design position.

Claims (6)

1. A device for straightening a railway track, comprising a track machine frame supported by straightening and straightening equipment, an on-board computer, a device for determining the distance traveled, a measuring trolley in contact with the rails, comprising a movable base, a spatial position sensor of the measuring trolley, an angle sensor track machine, while the outputs of these sensors and devices for determining the distance traveled are associated with the corresponding inputs of the on-board computer, exc characterized in that the spatial position sensor of the measuring trolley is mounted on the indicated movable base of the measuring trolley with the possibility of measuring the spatial position of the measuring trolley in plan and profile relative to the measuring base, which is used adjacent to the straightened railway track (rail) with known spatial coordinates and planned - high position relative to the straightening path. 2. The device according to claim 1, characterized in that as a sensor of the spatial position of the measuring trolley, it includes a laser rangefinder with an inclinometer installed with forced spatial orientation on the reference measuring base. 3. The device according to claim 1, characterized in that as a sensor of the spatial position of the measuring trolley, it includes a laser scanner with a given scan angle. 4. The device according to claim 2, characterized in that the spatial position sensor of the measuring trolley is fixed on a remote guide element fixedly connected to the center of the moving base of the measuring trolley, mounted at an angle of 90 degrees relative to the direction of movement, while the other end of the said guide element interacts ( slides) with the rail head of an adjacent railway track, which is a reference measuring base. 5. The device according to claim 1, characterized in that as a device for determining the distance traveled, it includes a satellite antenna installed on the roof of the track machine and a satellite receiver connected wirelessly to the reference (reference) stations, while the output of the satellite receiver is connected to the corresponding the entrance of the on-board computer. 6. The device according to claim 1, characterized in that for determining the distance traveled, it includes an odometer.

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