EP2444356A1 - Method for operating a winch of a tracked vehicle and snow groomer - Google Patents

Abstract

The method involves detecting the speed of chain (4) and rope. The angle of winch arm (3) is detected along the longitudinal axis of vehicle (1). The running speed of vehicle is determined, based on the rope speed and the angle of winch arm. The cable force is detected, by comparing the chain speed and the running speed of vehicle. A target value is determined for power cable, based on the difference between the chain speed and running speed of vehicle. An independent claim is included for runway crawler-type vehicle.

Description

• Erfassen einer Kettengeschwindigkeit,
• Erfassen einer Seilgeschwindigkeit,
• Erfassen eines Winkels eines Windenarmes relativ zu einer Fahrzeuglängsachse,
• Bestimmung einer Fahrgeschwindigkeit aus der erfassten Seilgeschwindigkeit und dem Winkel des Windenarmes relativ zur Fahrzeuglängsachse und
• Vergleichen der erfassten Kettengeschwindigkeit mit der bestimmten Fahrgeschwindigkeit,

sowie eine Pistenraupe mit einer Seilwinde sowie mit einer Vorrichtung zur Durchführung eines derartigen Verfahrens.The invention relates to a method for controlling a winch of a tracked vehicle with the following steps:

• Detecting a chain speed,
• Detecting a rope speed,
• Detecting an angle of a winch arm relative to a vehicle longitudinal axis,
• Determining a driving speed from the detected rope speed and the angle of the winch arm relative to the vehicle longitudinal axis and
• Comparing the detected chain speed with the determined driving speed,

and a snowcat with a winch and with a device for carrying out such a method.

Such a method for controlling a winch of a tracked vehicle is from the EP 1 431 236 B1 known. By the known method, the rope speed of the pull rope is regulated.

The object of the invention is to provide a method and a snowcat of the type mentioned, which allow a small load on the winch rope in the winch operation of the snow groomer.

• Erfassen einer Seilzugkraft,
• Bestimmen eines Sollbereiches für eine Differenz aus Kettengeschwindigkeit und Fahrgeschwindigkeit und
• Bestimmen eines Sollwertes für eine Seilzugkraft unter Berücksichtigung des Differenzsollbereiches.

For the method, this object is achieved in that the following further steps are provided:

• Detecting a traction,
• Determining a target range for a difference between chain speed and driving speed and
• Determining a setpoint for a cable pull force taking into account the difference target range.

By the solution according to the invention a cable traction control is achieved, which is superimposed on a slip control within a predetermined differential or slip target range. By the angle of the winch arm relative to the vehicle longitudinal axis can also be detected together with the selected direction of travel, whether the tracked vehicle downhill or uphill. Because in winching operation of the tracked vehicle, especially a snow groomer for snow grooming, the winch arm is always aligned relative to a stationary anchorage at the top of a snow field to be machined, whereas the snow groomer turns away under this winch arm. A differential target range, also referred to as the target slip range, instead of a predetermined desired slip value is provided, since different control criteria may be present when driving downhill or uphill. Thus, in a direction of travel downhill and appropriate orientation of the winch arm opposite to the direction of travel, the rope speed can be chosen to be less than or equal to the chain speed in order to achieve a braking effect. On the other hand, when driving uphill, the desired slip value can be defined so that the rope speed is greater than or equal to the chain speed is. The permanent monitoring of the traction and the corresponding regulation of the cable traction force make it possible to control the traction in low load ranges, which are just sufficient to achieve the desired slip range for the difference between chain speed and driving speed. This makes it possible to load the winch cable relatively low in winch operation and thereby increase the life of the winch cable relative to conventional cable winch controls. By means of the solution according to the invention, a slip control takes place within the desired slip range by regulating the cable pulling force. The control of the cable tensile force can be carried out in a particularly advantageous manner by controlling a winch drive and in particular by regulating a hydraulic pressure within a drive system of the winch drive. This results in a triple cascaded control, namely the slip control, the traction control and a pressure control of the winch drive.

In an embodiment of the invention, a vehicle gradient angle is detected, which is taken into account in the determination of the difference target range. The vehicle pitch angle is detected in addition to the angle of the winch arm relative to the vehicle longitudinal axis. This is advantageous because the difference between the chain speed and the calculated driving speed due to desired driving programs for uphill or downhill driving should be changeable within the limits of the differential target range.

In a further embodiment of the invention, a maximum angular amount of the winch arm is predetermined relative to the vehicle longitudinal axis, in which the cable traction control is turned off. This embodiment is based on the knowledge that a determination of the desired slip range can not be calculated over all angles of the winch arm relative to the vehicle longitudinal axis. This is especially true for one Angle of the winch cable and the winch arm relative to the vehicle longitudinal axis of 90 ° no rope speed more available. In angular ranges close to this right angle only a relatively low cable speed with respect to the vehicle is present. Therefore, a cable tension control does not make sense for these areas. In a particularly advantageous manner, a Seilzugkraftregelung only in angular amounts ranges between 0 ° and 50 ° - based on an orientation of the winch arm in the direction of travel - and between 180 ° and 130 ° - relative to an orientation of the winch arm against the direction of travel - made.

For the snowcat with a winch and with an apparatus for performing a method described above with at least one sensor for detecting the chain speed, with a sensor device for detecting a rope speed and with an angle sensor for detecting an angle of a winch relative to a vehicle longitudinal axis of the invention The underlying object is achieved in that a tensile force sensor for detecting a cable traction and a data processing unit comprehensive control unit are provided, which is connected for the reception and evaluation of data to the sensor, the sensor device, the angle sensor and the tension sensor, and a winch drive for Control of a cable traction depends on an evaluation of the received data. The snowcat is provided in a particularly advantageous manner for the processing of snow. The solution according to the invention enables particularly economical operation of the snowcat in winch operation, i. in steep terrain. In addition, a low and therefore gentle load on the winch rope is achieved by the invention.

In an embodiment of the invention, the sensor device for detecting the cable speed comprises a residual cable length sensor for detection the drawn from the reel or wound on the reel rope length. Since a total length of the rope is known, the respective distance of the winch arm and also the snowcat to the anchoring point at the top of the terrain can be determined taking into account the data of the residual cable length sensor. With the aid of the angle of the winch arm relative to the vehicle longitudinal axis, the instantaneous vehicle position can thereby also be calculated. The sensor device for detecting the cable speed advantageously also has a time measuring device in order to convert the cable path detectable by the residual cable length sensor into the cable speed.

In a further embodiment of the invention is provided as residual cable length sensor revolutions of the reel detecting absolute encoder. The absolute value transmitter is preferably arranged coaxially to a rotation axis of the reel and permanently detects the angle of rotation or the rotation angle change of the reel. Advantageously, the absolute value encoder can also be provided with a time module, so that the cable speed can be calculated directly via the data of the absolute value encoder. The absolute encoder is designed as a rotary encoder and measures the angle of rotation. The absolute encoder is designed as a multi-turn encoder to detect several revolutions of the reel.

Fig. 1

zeigt schematisch in einer Seitenansicht eine Ausführungsform einer erfindungsgemäßen Pistenraupe mit einem Blockschaltbild für ein erfindungsgemäßes Verfahren zur Steuerung einer Seilwinde,

Fig. 2

schematisch in einer Draufsicht die Pistenraupe nach Fig. 1 und

Fig. 3

schematisch einen Ausschnitt der Seilwinde nach Fig. 1 im Bereich einer Haspel.

Further advantages and features of the invention will become apparent from the claims and from the following description of a preferred embodiment of the invention, which is illustrated by the drawings.

Fig. 1

shows schematically in a side view an embodiment of a snow groomer according to the invention with a Block diagram of an inventive method for controlling a winch,

Fig. 2

schematically in a plan view of the snow groomer after Fig. 1 and

Fig. 3

schematically a section of the winch after Fig. 1 in the area of a reel.

A snowcat 1 according to the Fig. 1 to 3 is provided in a basically known manner with a winch 2, which supports a drive of the snowcat 1 especially in steep snowy terrain. For this purpose, a winch cable 13 ( Fig. 3 ) of the winch anchored to an upper portion of a steep slope to be machined stationary. The winch 2 has a winch arm 3, which about an unspecified, in the vehicle vertical direction extending axis of rotation relative to a vehicle longitudinal axis F ( Fig. 2 ) is rotatable by 360 °. The winch 2 is provided with a winch drive 7 shown only schematically, which will be described in more detail below.

The snowcat 1 has a pair of drive chains 4, which are driven by a respective Turasrad.

The winch arm 3 is - in the present embodiment together with the winch drive 7 - rotatably mounted on a mounted on a loading platform of the snowcat 1 socket about the axis of rotation described.

The Turasräder as part of a traction drive of the snowcat 1 are hydraulically driven by hydraulic motors. In an embodiment of the invention, not shown, electric motors are provided instead of hydraulic motors.

The winch 2 has a reel 10 rotatably mounted in an unspecified winch housing, on which the winch rope 2 is held up and unwound ( Fig. 3 ). The reel 10 has in the illustrated embodiment on its drum surface on a usable width, which is tuned to a thickness of the winch rope that in a winding layer 50 turns each side by side can be placed on the reel. In other embodiments of the invention, a smaller or larger depending on the purpose width is provided. In order to ensure a careful and uniform juxtaposition of the turns of a respective winding layer, a winding arm 12 is provided for the winding and unwinding of the winch cable 13 relative to the reel 10. The wrapping arm 12 is - relative to a cable extension direction - mounted in front of the reel 10 in the winch housing by means of a pivot bearing 14 pivotally. A pivoting plane of the winding arm 12 is parallel to a mantle surface of the cylindrical shape of the reel 10 and thus also parallel to the axis of rotation of the reel 10. A rotational angle β of the wrapping arm 12 is matched to the usable width of the reel 10, that the winch rope through the wrapping 12th for each of the windings distributed over the reel 10 of each winding layer can be performed.

The winch cable 13 is withdrawn via a spill gear not shown in detail from the reel 10 or wound onto the reel 10. The spool gear is part of the winch drive 7. The reel 10 has a reel drive, not shown, which is part of the winch drive 7. Both the reel drive and a drive for the capstan are hydraulically designed. For this purpose, the spill gear is preferably assigned a hydraulic motor. The reel drive can also be formed by an electric drive instead of a hydraulic drive. Also, the spill gear can be provided instead of a hydraulic motor with a sufficiently sized electric motor. At present Embodiment according to the Fig. 1 to 3 However, the winch drive 7 is executed exclusively hydraulically.

In a winch operation of the snowcat 1 takes place in predetermined angular ranges of the winch arm 3 relative to a vehicle longitudinal axis F, a regulation of the winch drive in the manner described in more detail below. The regulation is in angular amount ranges α according to Fig. 2 effective. The corresponding angular ranges extend, starting from an extension of the winch arm 3 along the vehicle longitudinal axis F in the direction of travel or counter to the direction of travel by 50 ° in both directions. In the in Fig. 2 shown alignment of the winch arm 3 is the winch arm 3 in a zero position. In a correspondingly reverse orientation, it is in a 180 ° position. This results in the remaining Winkelendbereiche dashed lines for the described Winkelbetragsbereiche. In the direction of travel, the control is effective between an angle of the winch arm 3 relative to the vehicle longitudinal axis F of -50 ° to + 50 °. Contrary to the direction of travel, the angular range of the winch arm 3, in which an effective control of the winch drive takes place, extends from 130 ° through 180 ° to 230 °. A corresponding axis of rotation for the angular ranges described is defined by the axis of rotation of the winch arm 3.

At least one Turasrad is associated with a speed sensor 5, by means of which a chain speed can be detected. Preferably, two Turasrädern the opposite chains 4 speed sensors 5 are assigned to make the determination of the chain speed via appropriate rotation direction and speed detection of the Turas. In the region of the axis of rotation of the winch arm 3, an angle sensor 8 is provided, which detects the angle of rotation of the winch arm 3 relative to the vehicle longitudinal axis F. In winch arm 3, a cable tensile force sensor 9 is provided in the region of a guide of the winch cable. moreover the winch 2 is associated with a sensor device 6 for detecting a rope speed during winding or unwinding of the winch cable.

The winch drive 7 comprises a hydraulic spill drive, not shown, with a spill gear and spill heads, over which the winch cable is deflected for withdrawal from the reel 10 or for winding onto the reel 10. The winch drive 7 also includes a drive for the reel 10, which drives the reel 10 at least in the winding direction. The reel drive is realized by a hydraulic constant motor. The spill drive has a controllable hydraulic motor which acts on the spill gear.

As a cable tension force sensor 9, a force measuring pin is provided in the region of a displaceable deflection roller in the winch arm 3 in the present embodiment.

The sensor device 6 has a residual length sensor 11, which is formed by an absolute value encoder in the form of a rotary encoder. The absolute encoder detects the revolutions of the reel in the winding or unwinding direction. In addition, the sensor device has a time module not shown in detail in order to achieve a supplementary time measurement to the distance measurement achieved by the residual cable length sensor. A total pitch or at least one usable pitch of the winch rope 13 is known. The diameter and circumference of the cylindrical drum surface of the reel 10 are known. Finally, the number of cable turns that can be lined up in a winding position on the reel 10, known. As a result, the cable length currently wound on the reel or extended and tensioned cable length can be determined via the residual cable length sensor 11. By additional time measurement with a corresponding winding or unwinding the rope speed is determined.

With the aid of the angle sensor 8, which detects the respective angle of the winch arm 3 relative to the vehicle longitudinal axis, it is possible to determine the traveling speed of the snowcat 1 via the detected cable speed. The snowcat 1 has an electronic control unit S, with which the tension force sensor 9, the sensor device 6, the angle sensor 8 and the speed sensor 5 are connected in order to transmit corresponding actual data to the control unit S. Depending on comparisons, calculations and evaluations of the detected actual data, the control unit S controls the winch drive 7 in order to regulate the cable pull force for the winch cable 13 in such a way that there is a difference between the travel speed and chain speed calculated from cable speed and angle of the angle arm 3 relative to the vehicle longitudinal axis results, this difference between the calculated driving speed and chain speed should be in a constant range of differences. In addition, the snowcat 1 is provided in a manner not shown with a tilt sensor, which is to detect a vehicle inclination relative to the horizontal and thus in particular an uphill or downhill of the snowcat 1. This additional inclination sensor is optional, since alternatively the detection of an uphill or downhill slope of the snow groomer also by the position of the winch arm according to Fig. 2 is detectable. Depending on the position of the winch arm for uphill or downhill, the difference between chain speed and calculated driving speed can be positive or negative, because when driving downhill calculated by the rope speed and the angle of the winch speed can be lower than the chain speed to achieve a braking effect , In contrast, when driving uphill, increased slippage of the chains 4 can be compensated by a higher travel speed relative to the chain speed and, consequently, a higher cable speed. Taking into account these different driving conditions, the control unit S predefines a defined difference target range, which is also referred to as the desired slip range. The Compliance with this difference or slip target range is achieved by regulating the cable pull force, wherein this is controlled in such a way that the lowest possible cable pull force, which still allows driving of the snowcat 1 within the desired slip range, is set. The regulation of the cable pull force is effected by means of a regulation of the hydraulic pressure of the winch drive 7. For this purpose, the hydraulic pressure of the hydraulic motor of the capstan drive is preferably controlled accordingly. The reel drive itself is not involved in this cable tension control. It is merely controlled so that a permanent tension for the winch cable between the capstan and reel 10 is given to allow a perfect winding or unwinding of the winch cable 13.

The central control unit S for controlling the winch 2 is assigned a control module S ₁ , which monitors the winding or unwinding of the winch cable 13 relative to the reel 10 and upon detection of a winding fault, which also means a rope fault, an error message to the driver of the snowcat first outputs. For this purpose, the angle arm 12 in the region of its pivot bearing 14 is associated with a rotation angle sensor 15 which is connected to the control module S ₁ . To the control module S ₁ also the absolute value encoder 11 is connected, which sits on the axis of rotation of the reel 10. Based on the detected actual values for the angle of rotation of the winding arm 12 and the counted revolutions for the reel 10, the control module S ₁ in comparison with the stored target data for the number of turns per winding and for the pivot angle β of the winding arm 12 between Begin and end of a winding layer determine whether a proper winding or unwinding has occurred, or whether the winch cable 13 performs a wrong winding or unwinding. As soon as the control module S ₁ has detected this, it activates a signal generator 16, which sends the corresponding error message to the driver's cabin of the snow groomer, preferably in a display region which can be quickly recognized by the driver. transmitted. The signal generator is preferably designed optically and / or acoustically. Additionally or alternatively, it can also be provided that it can be intervened in the traction drive or in the winch drive upon detection of a corresponding error message. For this case, the control module S ₁ via the central control unit S is suitably connected to a functional unit within the traction drive and / or the winch drive.

Claims (7)

Method for controlling a winch (2) of a tracked vehicle, comprising the following steps: Detecting a chain speed, Detecting a rope speed, Detecting an angle of a winch arm (3) relative to a vehicle longitudinal axis (F), - Determining a driving speed from the detected rope speed and the angle of the winch arm (3) relative to the vehicle longitudinal axis (F) and Comparing the detected chain speed with the determined driving speed, characterized in that the following further steps are provided: Detecting a tensile force, - Determining a target range for a difference of chain speed and driving speed and - Determining a setpoint for a cable tensile force taking into account the difference target range. A method according to claim 1, characterized in that a vehicle inclination angle is detected, which is taken into account in the determination of the difference target range. A method according to claim 1, characterized in that a maximum angular amount of the winch arm (3) relative to the vehicle longitudinal axis (F) is specified, in which the cable traction control is turned off. Snowcat (1) with a winch (2) and with a device for carrying out a method according to at least one of claims 1 to 3 with at least one sensor (5) for detecting the chain speed, with a sensor device (6) for detecting a cable speed, with an angle sensor (8) for detecting an angle of a winch arm (3) relative to a vehicle longitudinal axis (F), characterized in that a tension force sensor (9) for detecting a cable tensile force and a data processing unit comprising a control unit (S) are provided for the Reception and the evaluation of data with the sensor (5), the sensor device (6), the angle sensor (8) and the tensile force sensor (9) is connected and a winch drive (7) for controlling a cable traction depending on an evaluation of the received data controls. Snow groomer according to claim 4, characterized in that the sensor device (6) for detecting the rope speed comprises a residual rope length sensor (11) for detecting the length of rope taken from the reel (10) or wound onto the reel (10). Snow groomer according to claim 5, characterized in that as residual cable length sensor (L) a rotation of the reel (10) detecting absolute encoder is provided. Snow groomer according to claim 4, characterized in that an apparatus for carrying out a method according to claim 4 is provided with the following features: with a residual rope length sensor (11), - With a rotation angle sensor (15) for a winding arm (12) which guides the cable (13) in a winding and unwinding relative to the reel (10), - With a functional unit, in particular a signal generator (16) for signaling a cable winding error, and with a data processing unit comprehensive control module (S ₁ ), the data of the Restseillängensensors (11) and the rotation angle sensor (15) detects and compares with stored setpoints, and depending on a result of the comparison, the functional unit, in particular the signal generator (16), controls.

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