EP4303365A1 - Road finisher and method for controlling the operation thereof - Google Patents

Abstract

A road paver (1) comprises a tractor (2), a material bunker (3) which is arranged at the front of the tractor (2) in a direction of travel (R) and is configured to accommodate paving material (4), and a paving screed ( 5), which is mounted on the tractor (2) by pulling arms (6) so that it can pivot about a pulling point (7), whereby the screed (5) can be towed behind the tractor (2) in the direction of travel (R). The paver further comprises a control system (11) which has a height detection device (10) which is configured to detect vertical movements of the screed (5) relative to a height reference (9) and to generate a height signal (12) based thereon, and an actuating cylinder (8) connected to the tractor (2) and to one of the traction arms (6) and configured to adjust a height of the traction point (7) relative to the tractor (2). The control system (11) is configured to compare the height signal (12) with a setpoint (13) and thereby calculate a control difference (14), an adjustment path (20) of the actuating cylinder (8) based on the control difference (14). to limit a maximum value (17), the maximum value (17) being proportional to the control difference (14), and to adjust the actuating cylinder (8) based on the control difference (14) and taking the maximum value (17) into account.

Description

The invention relates to pavers with automatic leveling and to methods for regulating the operation of such pavers.

Road pavers are known that use a screed for compacting paving materials, such as. B. asphalt, and a tractor for towing this screed. The screed is usually mounted on the tractor so that it can pivot around a pulling point. The height of the pull point can be adjustable, for example using a hydraulic cylinder. From the DE 10 2011 001 542 A1 There is a so-called tar machine known there. A screed bar is disclosed that is attached to a towing point on the machine. The stroke of this tow point can be adjusted using a tow point cylinder. The amount of adjustment that can be made over a distance of 5m covered by the machine should be limited to 3mm. Furthermore, a calculated lifting/lowering value should only be set by the cylinder if it is higher than 1mm. The disclosed control is based on the assumption that the drag point cylinder may never be adjusted by more than 3mm over a distance of 5 m.

However, in some installation situations such rigid boundaries may be impractical. It is therefore an object of the invention to provide an improved paver and an improved method for regulating its operation, which enables more flexible operation.

This task is solved by a paver with the features of claim 1 and by a method with the features of claim 7.

A paver is disclosed that includes a tractor and a material bunker arranged at the front of the tractor in a direction of travel and configured to receive paving material. The paver further includes a screed that is pivotally mounted on the tractor by pull arms about a pull point, whereby the screed can be towed behind the tractor in the direction of travel, and a control system that includes a height detection device configured to generate a height signal , and an actuating cylinder connected to the tractor and to one of the traction arms and configured to adjust a height of the traction point relative to the tractor. The control system is configured to compare the height signal with a setpoint and thereby calculate a control difference, to limit an adjustment path, in particular an actually set adjustment path, of the actuating cylinder to a maximum value based on the control difference, the maximum value being proportional to the control difference, and adjust the actuating cylinder based on the control difference and taking the maximum value into account.

Advantageously, the height detection device can be configured to detect vertical movements of the screed relative to a height reference and, in particular, to generate the height signal based on this.

For example, a wire reference, a curb, an edge of an already laid asphalt layer or a laser beam can be used as a height reference. Accordingly, the height detection device can be configured to detect the respective height reference and include a height sensor, for example a sensing arm, an ultrasonic sensor, a camera or a laser sensor. A height detection device with a laser sensor can be configured to detect a laser beam as a height reference and/or to detect an edge by emitting and detecting a line laser. Particularly in the latter case, the height detection device can also contain its own laser source.

Alternatively or additionally, the height detection device can comprise one or more inclination sensors. The inclination sensor can be configured to detect an inclination, in particular a transverse inclination, of the screed. Several inclination sensors can be configured, for example, to detect the inclination of screed parts of the paving screed. When generating the height signal based on an output from an inclination sensor, a length, in particular a length defined transversely to the direction of travel, of the screed or a screed part of the screed, the inclination of which is detected by the inclination sensor, can be taken into account. This can serve to convert an angle signal into a, preferably vertical, height signal. Particularly in embodiments in which the height detection device is not configured to detect vertical movements of the screed relative to a height reference, the height of the screed can be manually tracked on one side. The height on the side of the screed opposite in relation to the direction of travel can then be regulated by a height detection device with inclination sensors, as explained in more detail above.

Alternatively or additionally, the height detection device can comprise a processing unit. The processing unit can be configured to generate the height signal based on an output of one or more of the aforementioned sensors, in particular a height sensor, a probe arm, an ultrasonic sensor, a camera, a laser sensor and an inclination sensor. A height signal can in particular be generated based on an output of a height sensor and one or more inclination sensors, e.g. B. by adding the height signals generated by the individual sensors as explained above.

Limiting the travel distance to a maximum value that is proportional to the control difference can enable the maximum value to be automatically adjusted to the respective installation situation. At the same time, undesirable effects of inertia in the controlled system, such as. B. overshoot or excessive vibrations can be avoided. It can happen that a change in the pulling point only has a delayed effect on the height measured by the height detection device. Without a limit on the adjustment path, this could undesirably increase or decrease due to a control difference that persists for a long time. In addition, in the case of small control differences, which may only be caused by temporary and/or short-term disturbances, such as: B. Vibrations are caused, the travel can also be limited to such an extent that the effects on the installation result can be minimized. The control system can contain suitable electronic components and/or assemblies, in particular for calculating, comparing and generating signals. Individual assemblies or components can each carry out one or more of the functions mentioned. It is conceivable that a central control of the paver carries out these functions.

It is conceivable that the maximum value is defined relative to a reference value. For example, a specific extended position of the actuating cylinder can be viewed as a reference value. For example, the reference value can be set to an extended position that is extended by 160 mm compared to a fully retracted position of the actuating cylinder. If the adjustment path is now limited to a maximum value of 5mm relative to the reference value, the adjustment of the actuating cylinder can be limited to extended positions in a range between 155mm and 165mm.

It can be advantageous if the reference value can be set by an operator. This can be particularly useful at the beginning of an installation journey, for example to specify an initial reference value. It is particularly advantageous if the control system is configured to automatically adjust the reference value. For example, it can be provided that the reference value is automatically adjusted when the control system detects that it is in a steady state. A steady state can be viewed as a state in which the height signal corresponds to the setpoint and/or the control difference is zero, close to zero or less than 2mm. In this way, the reference value can be tracked to a changing extension position.

It is conceivable that the maximum value is defined by multiplying the control difference by a proportionality factor, for example 2. The proportionality factor can be adjustable, for example by an operator of the paver.

It is conceivable that an upper limit is defined for the maximum value. This can z. B. an extension range of the actuating cylinder can be taken into account, ie an extension of the actuating cylinder up to its end stops can be counteracted. The upper limit can be defined depending on the reference value, in particular the currently set reference value. For example, with a maximum possible extension position of the actuating cylinder of 200mm and With a currently set reference value of 150mm, the upper limit for the maximum value is 45mm in order to avoid a stop at the end position of the actuating cylinder.

Furthermore, a method for regulating the operation of a paver is disclosed. The paver includes a tractor, a material bunker which is arranged at the front of the tractor in a direction of travel and is configured to receive paving material, a paving screed which is pivotally mounted on the tractor by pulling arms about a pulling point, whereby the paving screed is mounted behind the tractor in the direction of travel Tractor is towable, and a control system, with a height detection device and an actuating cylinder that is connected to the tractor and one of the towing arms. The method includes generating a height signal by the height detection device, calculating a control difference by comparing the height signal with a setpoint, limiting an actuating path of the actuating cylinder to a maximum value that is proportional to the control difference, calculating a control signal based on the control difference, taking into account the maximum value for the Adjusting travel and setting a height of the pull point based on the actuating signal from the actuating cylinder.

It may be advantageous if the method further comprises detecting a movement of the screed relative to a height reference by the height detection device, wherein the height signal can preferably be generated based on the detected movement of the screed relative to the height reference. All explanations given above with reference to the disclosed paver may also be applicable to the disclosed method.

As already mentioned with reference to the paver explained above, limiting the adjustment path to a maximum value that is proportional to the control difference can enable the maximum value to be automatically adjusted to the respective paving situation. At the same time, undesirable effects of inertia in the controlled system, such as. B. overshoot or excessive vibrations can be avoided. In addition, in the case of small control differences, which may only be caused by temporary and/or short-term disturbances, such as: B. Vibrations are caused, the travel can also be limited to such an extent that the effects on the installation result can be minimized. The control system can contain suitable electronic components and/or assemblies, in particular for calculating, comparing and generating signals. Individual assemblies or components can each carry out one or more of the functions mentioned. It is conceivable that a central control of the paver carries out these functions.

It is conceivable that the maximum value is defined relative to a reference value. As already explained above, a specific extended position of the actuating cylinder can, for example, be viewed as a reference value.

It can be advantageous if the reference value can be set by an operator. As already explained above, this can be particularly useful at the beginning of an installation journey, for example to specify an initial reference value. It is particularly favorable if the method includes an automatic adjustment of the reference value by the control system. For example, it can be provided that the reference value is automatically adjusted when the control system detects that it is in a steady state. In this way, the reference value can be tracked to a changing extension position.

It is conceivable that the maximum value is defined by multiplying the control difference by a proportionality factor, for example 2. The proportionality factor can be adjustable, for example by an operator of the paver.

It is conceivable that an upper limit is defined for the maximum value. As already explained above, this can z. B. an extension range of the actuating cylinder can be taken into account, i.e. H. An extension of the actuating cylinder to its end stops can be counteracted. The upper limit can be defined depending on the reference value, in particular the currently set reference value.

• Figur 1 zeigt eine schematische Seitenansicht eines Straßenfertigers.
• Figur 2 zeigt eine schematische, perspektivische Ansicht eines Straßenfertigers während einer durch eine Höhenreferenz geleiteten Einbaufahrt.
• Figur 3 zeigt eine schematische Ansicht von Komponenten eines Regelungssystems eines Straßenfertigers.

The invention relates to a road paver and to a method of the type described above. An advantageous embodiment is explained below by way of example with reference to drawings.

• Figure 1 shows a schematic side view of a paver.
• Figure 2 shows a schematic, perspective view of a paver during a paving journey guided by a height reference.
• Figure 3 shows a schematic view of components of a control system of a paver.

In Figure 1 a paver 1 is shown in a schematic side view. The paver can include a tractor 2. Furthermore, the paver can include a material bunker 3. The material bunker 3 can be arranged at the front of the tractor 2 in a direction of travel R. The material bunker 3 can also be configured to accommodate installation material 4 (see Figure 2 ). The paver 1 can also include a screed 5. The screed 5 can be mounted on the tractor 2 by pulling arms 6. As shown in the exemplary embodiment, the screed 5 can be mounted on the tractor 2 so that it can pivot about a pull point 7. The tractor 2 can be configured to tow the screed 5, preferably floating on an asphalt layer to be compacted. The paver can also include an actuating cylinder 8. The actuating cylinder 8 can be connected to the tractor 2 on the one hand. On the other hand, it can be connected to the pulling arm 6, in particular at the pulling point 7. The actuating cylinder 8 can be configured to adjust a height of the pulling point 7 relative to the tractor 2.

In Figure 2 the paver 1 is shown in a schematic, perspective view from the front and above. Figure 2 also shows schematically a subgrade on which an asphalt layer is to be laid, as well as a height reference 9. As in the present exemplary embodiment, the height reference 9 can be a wire reference. The paver 1 may include a height detection device 10. As in the present embodiment, the height sensing device 10 may be an ultrasonic sensor that may be configured to sense the wire reference 9. The height detection device 10 can be firmly connected to the screed 5 and/or to the pull arm 6. As a result, the height detection device 10 can be configured to detect essentially vertical movements of the screed 5 relative to the height reference 9. To adjust the height of the pull point 7 by the actuating cylinder 8, the paver can include a control system 11, which will be described below with reference to Figure 3 will be explained in more detail.

In Figure 3 a schematic diagram is shown to illustrate the functioning of the control system 11. The control system 11 may include the height detection device 10. The control system 11 can further include the actuating cylinder 8. The altitude detection device 10 may be configured to generate an altitude signal 12 based on the detection of the altitude reference 9. The height signal 12 can in particular represent a height of the screed 5 above the subgrade. The control system 11 can be configured to compare the altitude signal 12 with a setpoint 13. The control system 11 can further be configured to calculate a control difference 14 based on the comparison of the setpoint 13 with the height signal 12.

The control system 11 can further include a computing unit 15. The computing unit 15 can be configured to calculate a raw control signal 16 based on the control difference 14. In parallel, the control system 11 can be configured to calculate a maximum value 17 based on the control difference 14. The control system 11 can also have a limiter 18. The limiter 18 can be configured to adapt an actuating signal 19 sent to the actuating cylinder 8 in such a way that an actually set actuating path 20 of the actuating cylinder 8 is suitably limited, in particular to the calculated maximum value 17. The limiter 18 can be configured so that the actuating signal 19 based on the raw control signal 18 and the maximum value 17.

When generating the control signal 19, a reference value 21 can also be taken into account. If the reference value 21 is not taken into account when generating the control signal 19, the control signal 19 can represent an adjustment path of the control cylinder 8 that is to be set. Based on the control signal 19, the control cylinder 8 can then be adjusted by the travel distance to be set. If the reference value 21 is taken into account, the actuating signal 19 can represent an extended position of the actuating cylinder to be set. In the latter case, the actuating cylinder 8 can do this be configured to independently adjust the extended position to be set based on the control signal 19 transmitted to it. In both procedures, the actually set positioning path 20 of the actuating cylinder 8 can be limited to the calculated maximum value 17. There is a difference in the type of control of the actuating cylinder 8.

The maximum value 17 can be proportional to the control difference 14 and can preferably be calculated by multiplying it with a proportionality factor 22. The proportionality factor 22 can be adjustable, in particular by an operator of the paver 1. In particular, the maximum value 17 can be set, for example. B. correspond to twice the control difference 14. The reference value 21 can be adjustable by an operator. Alternatively or additionally, the control system 11 can be configured to automatically adjust the reference value. It is, for example, conceivable that the reference value 21 is set by an operator at the beginning of an installation journey and is continuously adjusted independently by the control system 11 during the installation journey.

Apart from and the actuating cylinder 8, all of them can be used Figure 3 The units shown are understood as logical units. These can be implemented as electronic circuits, in software or a mixture of both. In particular, the height detection device 10 can be implemented as a combination of electronic circuits and software.

Claims (14)

Paver (1), comprising: a tractor (2), a material bunker (3), which is arranged at the front of the tractor (2) in a direction of travel (R) and is configured to accommodate installation material (4), a screed (5), which is mounted on the tractor (2) so that it can pivot about a pulling point (7) by pulling arms (6), whereby the screed (5) can be towed behind the tractor (2) in the direction of travel (R), a control system (11) comprising a height detection device (10) configured to generate a height signal (12) and an actuating cylinder (8) connected to the tractor (2) and to one of the traction arms (6). and is configured to adjust a height of the towing point (7) relative to the tractor (2), wherein the control system (11) is configured to compare the height signal (12) with a setpoint (13) and thereby calculate a control difference (14), a positioning path (20) of the actuating cylinder (8) based on the control difference (14) to limit to a maximum value (17), the maximum value (17) being proportional to the control difference (14), and to adjust the actuating cylinder (8) based on the control difference (14) and taking the maximum value (17) into account. Road paver according to claim 1, wherein the height detection device is configured to detect vertical movements of the screed (5) relative to a height reference (9) and to generate the height signal (12) based thereon. Paver according to claim 1 or 2, wherein the maximum value (17) is defined relative to a reference value (21). Road paver according to claim 3, wherein the reference value (21) is adjustable by an operator. Paver according to claim 3 or 4, wherein the control system (11) is configured to automatically adjust the reference value (11). Road paver according to one of the preceding claims, wherein the maximum value (17) is defined by multiplying the control difference (14) by a proportionality factor (22), which is preferably adjustable. Road paver according to one of the preceding claims, wherein an upper limit for the maximum value (17) is defined. Method for regulating the operation of a road paver (1), which has a tractor (2),
a material bunker (3), which is arranged at the front of the tractor (2) in a direction of travel (R) and is configured to accommodate paving material (4), a paving screed (5) which is secured by pulling arms (6) around a pulling point (7 ) is pivotally mounted on the tractor (2), whereby the screed (5) can be towed behind the tractor (2) in the direction of travel (R), and a control system (11) with a height detection device (10) and an actuating cylinder (8 ), which is connected to the tractor (2) and one of the traction arms (6), the method comprising: Generating a height signal (12) by the height detection device (10), Calculating a control difference (14) by comparing the height signal (12) with a setpoint (13), Limiting an actuating path (20) of the actuating cylinder (8) to a maximum value (17), which is proportional to the control difference (14), Calculating a control signal (19) based on the control difference (14), taking into account the maximum value (17) for the control path (20) and Setting a height of the pull point (7) based on the actuating signal (19) by the actuating cylinder (8). The method according to claim 8, further comprising detecting a movement of the screed (5) relative to a height reference (9) by the height detection device (10), wherein the height signal (12) is preferably based on the detected movement of the screed (5) relative to the Height reference (9) is generated. Method according to claim 8 or 9, wherein the maximum value (17) is defined relative to a reference value (21). Method according to claim 10, wherein the reference value (21) can be set by an operator. The method according to claim 10 or 11, further comprising automatically adjusting the reference value (21) by the control system (11). Method according to one of claims 8-12, wherein the maximum value (17) is defined by multiplying the control difference (14) by a proportionality factor (22), which is preferably adjustable. Method according to one of claims 8-13, wherein an upper limit for the maximum value (17) is defined.

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