EP1672122A1 - Method and apparatus for controlling a road working machine - Google Patents

Abstract

The process controls the path of a road treatment machine (2) moving on a ground surface (1) and the working height of a height-adjustable working part (4). It measures the spot of a positioning element (11), plots a travelling direction and determines the working height of the working part. The postioning element is placed horizontally to this part and the positioning height of the positioning element is converted into the working height of the working part using at least one value of a reference calculation.

Description

The invention relates to a method according to the preamble of claim 1 and a device according to the preamble of claim. 9

When creating and repairing streets and squares, machines are used for various work steps that travel along a given route and perform a desired processing step. For example, asphalt pavers are used to apply asphalt pavers with a vehicle and a height-adjustable trowel or screed fastened thereto. The asphalt material is distributed by the vehicle along the front edge of the screed. As the machine advances on the prepared road bed, the screed sweeps and smoothes and densifies the asphalt material to provide a continuous asphalt pavement having a desired surface course.

Various solutions are known from the prior art with which the screed bar can be positioned vertically so that a desired surface profile is achieved as accurately as possible. For vertical positioning, for example, a reference is used. If, as a reference line, a rope or a wire has to be stretched along the road to be paved, this is a great expense. If the base surface on which the asphalt is applied is used as a reference, it must be formed very precisely with great effort. According to another solution, a laser beam is used as a reference, in which case with a sensor attached to the screed bar records the height of the screed relative to the laser and maintains the screed bar at a desired height.

DE 100 60 903 describes a prior art in which the position of a reference surface is detected with a touch probe or with three spaced apart in the direction of movement laser measuring heads. In order to avoid a complicated construction for holding the laser sensors, it is proposed to arrange at one point above the screed bar three differently aligned laser distance meters which detect the distance to three measurement points one behind the other in the direction of movement. The distance values are each converted into a height and a horizontal distance. Depending on the detected heights and height, a height control signal is generated for the screed or other processing tool.

The accuracy of the height determination with the obliquely aligned laser distance meters is reduced by the mounting accuracy and the fact that at least one measuring point is located on the already applied coating. In road construction machines, an exactly constant sensor alignment is hardly achievable due to vibrations as well as large temperature and humidity fluctuations. For obliquely forward-facing distance meters, a small unrecognized angle change already leads to a significant error in the height calculated from the measurement assuming the wrong orientation.

From US 5,549,412 a method is known in which a road processing machine with a height-adjustable working part together with at least a transmitter is used. In this case, a sensor on the machine receives at least one signal of the at least one transmitter and from the received signal, a height position information is derived, which is used for vertical positioning of the height-adjustable working part. As a system of transmitter and sensor is about a GPS system used. In order to achieve a desired pad surface over a reference surface, the reference surface is run over without processing only for detecting the reference surface layer, which is associated with a double driving effort.

A solution is known from EP 1 079 029 A2 in which a GPS system and a tilt-adjustable rotary laser system are used for the three-dimensional control or leveling of a construction machine. The GPS system on the construction machine determines two location coordinates of the construction machine, which are transmitted to the fixed rotation laser system. The current location coordinates are assigned a desired altitude and the rotating laser is aligned to mark the desired altitude for a linear laser receiver of the construction machine. The laser receiver determines the current deviation of the working tool from the desired height. According to this deviation, the altitude of the working tool is adjusted. This solution is very expensive because it includes a GPS system, a complex rotary laser system, a radio link between these systems, a linear laser receiver and at least one controller. In addition, there are problems in areas such as under bridges where the satellite signals required by the GPS system can not be received.

Further possibilities for determining the height of the working part can be found in DE 196 47 150 in which an apparatus and method for controlling the installation height of a paver are described. The height of the screed edge is detected here by potentiometer sensors, ultrasonic sensors or laser receivers.

DE 199 51 297 C1 relates to an automatic longitudinal control of a paver during the installation of a road layer. Solutions are based on tracking a prism mounted on the paver using a laser total station. This station tracks the prism by means of an alignable in all directions optics. The position of the construction machine or screed is calculated from the solid angle of the optics, the distance between the prism and the optics and the position of the total station. For precise height adjustment of the screed, the prism must be arranged as directly above the screed trailing edge as possible. However, there are then steering inaccuracies that negatively affect the course of pavement. To compensate for the effects of steering inaccuracies are slidable parts of the screed proposed transversely to the direction of travel, so that even with an inaccurate track through an optimal lateral displacement of these parts a precise application of the coating is guaranteed.

A road processing machine with laterally movable screed parts is mechanically complex. In construction machines without lateral adjustment, the problems resulting from the steering inaccuracy remain.

The invention is based on the object to find a simple solution with which a height-adjustable working part of a road processing machine can be precisely positioned in the vertical direction and the steering function of the road processing machine can be improved.

This object is solved by the features of claim 1 and 9. The dependent claims describe alternative or advantageous embodiments.

In the solution of the problem has been recognized that the prism arranged horizontally away from the working part and thus the steering function can be improved without thereby the height regulation of the working part is deteriorated. For this, however, the height determination at the prism must be converted into a height at the working part (screed) using at least one value of at least one reference determination.

It goes without saying that, instead of a laser total station and a passive prism, an active positioning element, for example a GPS device, can also be used. An active position element should be able to determine its position with the help of other elements whose positions are known. The other elements can again be active or passive elements. If a GPS device is used as the position element, then this should also be able to determine the position in the vertical direction as accurately as possible. Optionally, a position element in the form of a modified GPS device yet another signal from a Vertikalpositioniersender, for example, as a rotating laser supplied, so that from the satellite signals and the other signal, the spatial position of the position element are determined very accurately in the vertical direction can.

For this purpose, suitable methods and devices for positioning or height measurement with laser reception are described for example in US 4,807,131.

If the position element is connected to the working part via a fixed connection, an effective height difference between the position element and a point at the working part can be determined for each possible alignment position of this connection. For the determination of the effective height difference, it is most accurate if the inclination of the direct connecting line between the position element and the point at the working part, ie an angle to the vertical or to the horizontal, is determined.

If the connection consists of at least one substantially vertical and one substantially horizontal portion, so the respective inclinations of both sections can be detected. However, if the fixed connection is rotated substantially only about a single horizontal axis, then a single tilt determination is sufficient.

The horizontal pivot axis of the working part leading linkage is changed by a height adjustment in height. This allows the working part to float on the warm asphalt material. In order to determine the exact position of the working part on the basis of the detected position of the position element, a height difference between the position element and the working tool must be determined with at least one value derived from a reference determination.

The reference determination preferably comprises an inclination determination with which the current orientation of the fixed connection is detected. If necessary, the alignment of the fixed connection can also be determined by means of two distance measurements to the base surface or to a reference height. For this purpose, the distances from two different points of the fixed connection to a reference position are determined.

Because the roadworking machine travels forward on the base surface, two points offset in the direction of travel are skewed over the same area of the base surface. If now the horizontal distance between the two points of the fixed connection is divided by the driving speed, one obtains the time interval which should elapse between a distance measurement at the first and a distance measurement at the second point. This time interval can be used to ensure that the two distance measurements are made on the same reference surface. Alternatively, the position determination with the help of total station and prism can be used.

From the two distances to a reference surface, the height difference between position element and working part can be determined. With a known height of the position element can be determined exactly the height of the working part or a working edge with the determined height difference. This height determination for the working part can also be carried out if there is no firm connection between the position element and the working part. This means that, for example, in the direction of travel at the front of the road processing machine, a position element and a first distance sensor for determining a distance to the base surface are arranged. At the working part, a second distance sensor is arranged offset to the first sensor in the direction of travel to the rear. This arrangement can also be used without firm connection between the working part and the position element for determining the height of the working part in straight running of the machine. In curves, the position determination can be used.

If the height adjustment device performs only a parallel displacement of the fixed connection during adjustment, the height difference does not depend on the adjustment height. For a base surface whose orientation is substantially the same everywhere, for example horizontally, the height correction is constant and it only needs to be checked that no further correction is needed. Accordingly, the reference determination is to monitor the parallel alignment.

In the case of a base surface whose orientation changes along the travel path, the orientation of the roadworking machine or of the underlying base surface can be determined with at least one inclination determination. The measured slope can be used as a reference for correcting altitude. From the position of the position element and this height correction results in the current height of the working part.

Because the height position of the working part can always be precisely determined even in the case of a position element remote from the working part, the position element can be arranged so that the travel path of the roadworking machine can also be optimally monitored can. In order to ensure a high sensitivity with respect to vehicle movements away from the travel path, the positioning element is fastened to a location of the roadworking machine which is as far away as possible from the turning axis.

Because roadworking machines usually rotate with a height-adjustable working part when driving a curve such that the working part does not swing or at least only slightly swings out, the position element must be as far away from the working part as possible. When the working part is arranged in the rear end region of the machine, the positioning element is arranged in the front end region. In an undesirable lateral swinging of the vehicle, the position element is noticeably moved away from the driving line. A correction control can immediately bring the road processing machine back on the desired track. The working part essentially always stays on the desired path.

The attachment of the position element or the prism as far forward as possible also simplifies the design of the control algorithm so far simpler, since the control of the direction of travel can be turned off directly to the horizontal error and the longitudinal axis of the road processing machine does not need to be known. Their additional knowledge naturally improves the regulation.

In the solution according to the invention, with only one position tracking with one position element, eg GPS or a prism, a precise travel movement and a precise height positioning of the working part can be achieved. To determine the height of the working part At least one type of reference determination must be carried out.

• Fig. 1 eine schematische Seitenansicht einer Strassenbearbeitungsmaschine mit einem Neigungssensor und
• Fig. 2 eine schematische Seitenansicht einer Strassenbearbeitungsmaschine mit zwei Distanzmesseinrichtungen

The drawings illustrate the invention with reference to two embodiments. It shows

• Fig. 1 is a schematic side view of a road processing machine with a tilt sensor and
• Fig. 2 is a schematic side view of a road processing machine with two distance measuring devices

1 and 2 show a roadworking machine 2 traveling on a base surface 1. The illustrated machine is a road paver with a vehicle 3 and a working part 4 fastened thereto in a height-adjustable manner in the form of a screed. The asphalt material 5 is distributed by a distributor 6 along the front edge of the working part 4. As the road working machine 2 advances on the prepared base surface 1, the working part 4 passes over the asphalt material 5 and smoothes and compacts it to provide a continuous asphalt pavement 7 having a desired surface course. The positioning of the working part 4 at a desired height via a slight pivotal movement of two sides of the machine pivotally mounted supports 8, the pivot bearing 9 are movable as pivot points of hydraulic cylinders as actuators 10 and adjustable in height.

In order to simplify an exact machining along a desired route, the current position and / or points should be determined at points along the route Determined direction of travel, determines the working height of the working part and the determined position or direction of travel with a desired position or desired direction and the working height are compared with a desired height. As soon as the position or direction of travel deviates from the desired position or desired direction at the corresponding location, a control signal should be provided with which the deviation can be compensated by a corresponding control of the roadworking machine 2. If the working height deviates from the desired height, the working part 4 should be raised or lowered by the supports 8 until the desired height is achieved.

A position element arranged on the roadworking machine 2 can be tracked with a laser total station 12 when it is equipped with a prism 11. This station 12 tracks the prism 11 by means of an alignable in all directions optics. From the solid angle of the optics, the distance between prism 11 and optics and the position of the total station 12, the position of the prism 11 is calculated. For comparison with a desired route, the positions and / or directions along the desired route must be present as set points for the road-building machine 2 at the location where the prism 11 is located. In order to ensure a desired processing path in the working part, the curve behavior of the road-working machine 2 should be taken into account in the determination of the desired path for the prism 11, so that the working part 4 moves along the desired path. The direction of travel can be determined from successive positions.

Because 2 directional changes by lateral movements of the front end of the machine usually show more clearly in road processing machines than in the region of the working part, and because the control algorithm of directional control due to the position of the prism without knowledge of the longitudinal axis of the machine is easier, the prism 11 is as far as possible placed in front. This allows a good control of the machine with only one prism.

The permissible tolerances for the working height are smaller than for the lateral alignment of the working part. For the comparison of a recorded working height with a desired height, the current height of the working part 4 must be recorded extremely accurately. Between the positional height of the prism 11 and the working height of the working part 4 there is no fixed relationship, because they are arranged offset in the longitudinal direction of the machine. When the base surface 1 is inclined in the direction of travel, the working part 4 is lower relative to the height of the prism 11 than in the case of a flat base surface 1. Lifting and lowering movements of the carrier 8 and also variable inclinations of the base surface 1 change the height difference between the prism and the working part 4 ,

In order to be able to derive as precise a working height as possible from the positional height of the prism 11, at least one value of at least one reference determination should be used for the calculation of the working height in the working part.

The laser total station 12 is provided with an evaluation and control device (not shown) for evaluating the position information of the position element, here of the prism 11 - and connected to provide control signals for controlling the roadworking machine 2 and for controlling the height adjustment of the working part 4. Also, the at least one reference sensor for performing at least one reference determination is connected to the control device. At least a part of the connections are designed as radio links. The control device is preferably arranged on the roadworking machine 2, but could possibly also be arranged at the laser total station 12. If the control device is arranged on the machine 2, the connections to sensors and actuators can be formed as line connections.

According to FIG. 1, it is proposed in the context of a first embodiment to form a fixed connection 13 from one of the carriers 8 to the prism 11. This connection 13 comprises, for example, a substantially horizontally extending connecting part 13a and a vertically connected connecting part 13b connected thereto. When the prism 11 is connected to the working part 4 via a fixed connection, an effective height difference between the prism 11 and a point at the working part 4 can be determined for each possible alignment position of this connection 13. For the determination of the effective height difference, it is most accurate if the inclination of the direct connecting line between the prism and the point at the working part 4, ie an angle to the vertical or to the horizontal, is determined. For this purpose, a tilt sensor 14 aligned in the direction of the direct connection line to a part of the fixed connection 13 are attached.

In the illustrated embodiment, the tilt sensor 14 is attached to the horizontally extending connecting part 13a. Optionally, a second tilt sensor, aligned perpendicular to the first tilt sensor, is also arranged on the fixed connection, so that the inclination of the fixed connection can be detected in two different directions. A transversely mounted to the direction of inclination sensor can thus provide additional information.

According to FIG. 2, at least one first distance measurement to the base surface 1 and temporally offset at the working part 4 with a second distance measuring device 16 at least one second distance measurement to the base surface 1 is performed in a second embodiment for reference determination at the prism 11 with a first distance measuring device 15. The time offset between measurements belonging together should be chosen based on the driving speed so that the two measurements are made essentially at the same reference point. Between the prism 11 and the working part 4 now no solid connection must be present. The prism is connected to the roadworking machine 2 via a support bar 13c.

Between the prism 11 and the first distance measuring device 15, there is a fixed distance in the vertical direction and a substantially vanishing distance in the horizontal direction. Analog must be given between the working part 4 and the second distance measuring device 16 in the vertical direction a fixed and in the horizontal direction the smallest possible distance. Because asphalt material 5 is distributed by a distributor 6 in the working part 4, the second distance measurement preferably has to be made directly in front of the distributor 6 be carried out so that the base surface is still exposed. If the distance measurement is made laterally next to the discharged asphalt, it can also be done directly next to the working part. It goes without saying that the arrangement of the second distance measuring device 16 can be adapted to the respective working part 4.

It goes without saying that methods with at least one inclination determination and additionally at least one first distance measurement to the base surface 1 and offset in time at the working part 4 of at least one second distance measurement to the base surface 1 can be advantageously used.

Claims (11)

Method for controlling the travel path of a roadworking machine (2) traveling on a base surface (1) and the working height of a working part (4) arranged height-adjustable thereon, in which method the spatial position of a positional element (11) is detected, possibly from at least two spatial positions, in particular to two times or from two position coordinates, a driving direction determined, and the working height of the working part (4) is determined, wherein - The working height with a desired height, and / or - The detected position with a desired position and / or the determined travel direction is compared with a desired direction, characterized in that
the position element (11) is arranged at a position that is horizontally away from the working part (4) and that the positional height of the spatial position of the position element (11) is converted into the working height at the working part (4) using at least one value of at least one reference determination becomes. Method according to claim 1,
characterized in that
between the position element (11) and the working part (4) is formed a fixed connection. Method according to claim 2,
characterized in that
for determining the reference, at least one inclination determination is carried out with a tilt sensor (14) arranged on the fixed connection. Method according to claim 3,
characterized in that
for reference determination, two tilt determinations are carried out by two differently oriented inclination sensors (14) arranged on the fixed connection. Method according to claim 3 or 4,
characterized in that
a height difference between the positional height of the position element (11) and the working height at the working part (4) is derived from the at least one inclination determination. Method according to one of claims 1 to 5,
characterized in that
at least one first distance measurement to the base surface (1) and temporally offset at the working part (4) at least a second distance measurement to the base surface (1) is performed, wherein the time offset is selected based on the driving speed or a position determination so that the two measurements are made essentially at the same reference point. Method according to claim 6,
characterized in that
the position of the reference point is derived from the positional height of the positional element (11) and the at least one first distance measurement, and preferably a base height of the base surface (1) is detected at least along a line when the roadworking machine is being driven. Method according to claim 6,
characterized in that
from the positional height of the position element (11), the at least one first distance measurement and the at least one second distance measurement at least one working height is derived and when driving the road processing machine preferably the working height of the working part (4) is detected at least along a line. Device for carrying out a method for controlling the travel path of a roadworking machine (2) traveling on a base surface (1) and the working height of a working part (4) arranged height-adjustable therewith, with a position element (11), at least one station (12) for detecting the spatial Position of the position element (11), an evaluation and control device for evaluating the position information of the position element (11) and for providing control information for controlling the road processing machine (2) and the height adjustment of the working part (4),
characterized in that
the device comprises at least one reference sensor (14, 15, 16) for carrying out at least one reference determination, the positional height of a position element (11) arranged away from the working part (4) using at least one reference value derived from the reference sensor (14, 15, 16) a working height at the working part (4) is to be converted. Device according to claim 9,
characterized in that
at least one reference sensor is formed as a tilt sensor (14) which is to be arranged on a fixed connection (13) between the position element (11) and the working part (4) and a height difference between the positional height of the position element (11) and the working height of the working part ( 4) makes derivable. Device according to claim 9,
characterized in that
at least two reference sensors are designed as first and second distance sensors (15, 16), wherein the first distance sensor (15) is to be arranged at the position element (11) and the second (16) at the working part (4), so that distance measurements to the base surface (1) are detected offset in time so that the two measurements essentially take place at the same reference point.

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