EP0219487A1 - Method of controlling the motion of an all over swivelling cutter boom and control device for carrying out the method - Google Patents

Abstract

A method for controlling the movement of an all-way pivotable cutter arm of a partial cutting cutter with a first hydraulic drive (8) for lifting and lowering the cutter arm and a second hydraulic drive (12) for pivoting the cutter arm transversely to the lifting and lowering direction consists in that at the end the propulsion movement of the cutting arm in one of the two directions when the cutting direction is reversed, in particular when the desired profile is reached, the other drive (8) is simultaneously acted on by pressure medium. In the reversal of the cutting direction, a predetermined volume of pressure medium is expediently pressed into the other drive (8). A control device for carrying out this method has a stepped piston (21) which can be pressurized with pressure medium via a central working chamber (28) and a separate annular chamber (25) with a larger radius, and controllable valves (30, 32), which are optional Connect the central working chamber (28) of the stepped piston (21) on the side of the stepped piston (21) opposite the pressure medium inflow to a drive (8) of the cutting arm for a direction different from the other drive (12) of the cutting arm, which is simultaneously pressurized with pressure medium.

Description

The invention relates to a method for controlling the movement of a cutting arm which can be pivoted on all sides of a partial cutting cutting machine with a first hydraulic drive for lifting and lowering the cutting arm and a second hydraulic drive for pivoting the cutting arm transversely to the lifting and lowering direction, and to a device for carrying it out Procedure.

Partial cutting machines with a cutting arm that can be pivoted on all sides usually have hydraulic cylinder piston units for raising and lowering the cutting arm in a substantially vertical direction, and a swivel drive, which can be brought about, for example, by the engagement of a hydraulically operated rack in the ring gear of a swivel mechanism. The swiveling of the cutting arm generally takes place about an axis which is substantially normal to the drive plane and the hydraulic cylinder-piston units for lifting and lowering the cutting arm are also pivoted about this essentially vertical axis with the swivel mechanism. The cutter arm can thus be raised or lowered from any swivel position in the horizontal direction.

For cutting profiles, partial cutting machines, in which cutting heads rotatably mounted at the free end of the cutting arm transversely to the longitudinal axis of the cutting arm, are mostly selected in the direction of advance in the axial direction of the rotary movement of the cutting heads. When the target profile is reached, the cutting arm is raised or lowered by the so-called chip specification, whereupon the propulsion movement in the opposite direction and is again carried out in a substantially horizontal direction. Due to the construction of such cutting machines, a rib remains in the middle between the two cutting heads at the free end of the cutting arm when the cutting arm is raised or lowered to achieve the new chip specification. This rib must subsequently be broken away when the cutting arm is pivoted in a substantially horizontal direction. Depending on the nature of the rock and the construction of the machine, this rib can be too large to be easily broken away by swiveling the cutting arm. In these cases, the swiveling of the cutting arm in the new position is not easily possible and expensive manual controls are required to break this rib first before the cutting can continue in the opposite direction.

The invention now aims to provide a method of the type mentioned in which the reversal of the cutting direction, in particular when the desired profile is reached, is ensured in a simple manner without the risk that the machine is blocked by a remaining rib in the pivoting movement becomes. To achieve this object, the method according to the invention essentially consists in the fact that at the end of the advancing movement of the cutting arm in one of the two directions when the cutting direction is reversed, in particular when the desired profile is reached, the respective second drive is simultaneously pressurized. Characterized in that when reversing the cutting direction or the propulsion movement, both hydraulic drives are pressurized at the same time, a diagonal cutting is achieved in which the risk of a remaining rib can be eliminated. The slope of the diagonal part of the cutting arm movement depends only on the speed of advance in the other direction for a given amount of pressure medium, and if the cutting arm swivels rapidly in the opposite direction, there can be a flatter increase can be achieved, whereas with a slower pivoting movement a correspondingly steeper increase in the diagonal part of the arm movement is achieved. The chip specification is essentially a function of the volume which is made available to the second hydraulic drive, and the procedure is advantageously such that a predetermined pressure medium volume is pressed into the second drive when the cutting direction is reversed.

Cutting machines of the type mentioned initially usually have a common pressure medium source for the swivel drive and the drive of the arm in a substantially vertical direction. In order to ensure the method according to the invention without using an additional drive and to be able to press a predetermined volume into the respective other drive, the device according to the invention is essentially characterized in that a stepped piston is provided which has a central working space and a separate annular space A larger radius can be acted upon by pressure medium and that controllable valves are arranged which optionally connect the central working space of the stepped piston on the side of the stepped piston opposite the pressure medium inflow with a drive of the cutting arm for a direction different from the other drive of the cutting arm which is simultaneously acted on by pressure medium. Due to the fact that a step piston is provided in the device according to the invention, an embodiment can be realized in which the pressure medium which acts on a drive acts on one side of the step piston on a larger cross-sectional area than the central working space of the step piston on the other Side corresponds, and the stepped piston can be moved in one direction due to the effective cross-sectional differences, with pressure medium in the other from the central working space with a smaller cross-sectional area on the opposite side of the stepped piston Drive can be squeezed out. The volume of this pressed-out pressure medium can be specified in a particularly simple manner by limiting the stroke of the stepped piston, which is advantageously adjustable. With such a device, largely automated work can be realized, in which a short partial area is first cut diagonally each time the cutting direction is reversed after the target profile has been reached, after which the cutting is then continued in the usually selected direction of advance. As previously mentioned, the usually selected direction of advance is the direction which is achieved by pivoting the cutting arm about an essentially vertical axis, the cutting heads being moved in the axial direction of their axes of rotation.

A further automation can be achieved in that a control pressure source is provided, which can be connected via a preselection device with a control slide for the direction of movement of the cylinder piston unit acted upon by the volume displaced from the working space of the stepped piston and which can also be connected to controllable check valves in branch lines of the supply and Derivation to the other hydraulic drive of the cutting arm is connectable. By means of such an additional control pressure source and the preselection device, the direction of the chip specification for the next work step, for example upwards or downwards, can first be specified when the cutting direction is reversed. At the same time, the control of the controllable check valves which is subsequently necessary can also be ensured with such a control pressure source. The differential piston or stepped piston only has to be pressurized during the intended reversal of the cutting direction and it can therefore be used in normal operation, ie when one of the two drives for the propulsion movement of the head or heads, the working spaces of the Step piston remain closed by check valves. Only in the case of reversal of the cutting direction must the control of such check valves, which are connected directly to the pressure line to the activated propulsion drive or a return line of the same, be controlled, whereupon a predetermined volume to the other side of the stepped piston in the chip specification effecting drive is squeezed.

The training is hiebei made so that the branch lines of the supply and discharge to the other hydraulic drive are each connected to the annular spaces on both sides of the stepped piston and that branch lines from these annular spaces, which via non-return valves closing to these annular spaces with the respective central work rooms are connected to the same side of the stepped piston. With such an arrangement of the valves it is ensured that when the annular space is applied to one side of the stepped piston, the central working space to the same side of the stepped piston can also be acted on, whereby the desired difference in the contact surfaces for the purpose of pressing out a predetermined volume from the opposite central one Working space is ensured. If the cross-sectional area of the annular space is dimensioned sufficiently large, such a connection of the central working space on the same side to the respective annular space via the check valve can be omitted. Simultaneously with the shifting movement of the stepped piston in one direction, the central working space on the side opposite to the loaded side should be opened in the direction of the drive of the cutting arm, for which purpose check valves which can be opened and which open to the central working spaces of the stepped piston are advantageously provided in lines which the central Working rooms of the stepped piston via the spool with the working rooms of the Connect the cylinder piston unit for driving the cutting arm. The control of such check valves can in principle also be ensured by the control pressure source via the preselector. Advantageously, however, the training can be such that the control lines for the check valves of a central work space are connected to the branch line to the opposite annular space or central work space.

With regard to the preferred mode of operation, in which the feed direction or the direction of advance takes place in the axial direction of the rotating cutting heads, the drive which is pressurized in the normal operating state is the drive of the horizontal swivel mechanism. In these cases, the design according to the invention is such that the branch lines to the annular spaces of the stepped piston are connected to the lines for the horizontal pivot drive of the cutting arm.

The invention is explained below with reference to an embodiment shown schematically in the drawing. 1 shows a schematic side view of a cutting machine, FIG. 2 shows a plan view of the machine according to FIG. 1, with insignificant details being omitted, FIG. 3 shows a schematic circuit arrangement of the device according to the invention for controlling the cutting arm movement, and FIG. 4 shows the picture the movement of the cutting arm projected onto the face.

In Figure 1, 1 denotes a cutting machine, the crawler track 2 of which can be moved on the sole. In addition to a loading ramp 3 which is usually present and which can be raised and lowered via a hydraulic cylinder piston unit 4, the cutting machine has a cutting arm 5. The cutting arm 5 is pivotable on a swivel mechanism 6 in the direction of the double arrow 7 in the vertical direction, for which hydraulic Cylinder-piston units 8 are provided. In addition, a pivotability in the direction of an essentially vertical axis 9 in the direction of the double arrow 10 is provided. The pivot drive for this horizontal pivoting is illustrated in Fig.2.

The free end of the cutting arm 5 carries rotatable cutting heads 11, a rotary drive for these cutting heads 11 being provided in the interior of the cutting arm 5.

As can be seen from FIG. 2, the pivoting in the direction of the double arrow 10, that is to say in a substantially horizontal plane, is carried out by hydraulic cylinder piston units 12, which mesh with toothed wheels 13 with a gearwheel 14 of the swivel mechanism 6. As can also be seen from the illustration according to FIG. 2, an intermediate space 16 remains between the cutting heads 11, which are rotatably mounted about an axis 15 that essentially cuts the longitudinal axis of the cutting arm. The cutting machines of this type are usually driven by actuating the Swivel drive 12 and thus in the direction of the axes of rotation 15. The chip specification takes place in that the scraper arm 5 is raised or lowered in the sense of the double arrow 7 in FIG. 1, this chip specification in the case of particularly soft material, such as coal, potash or the like. can not always be achieved due to the gear housing and the free space 16. In any case, however, when the cutting arm 5 is raised or lowered in the direction of the double arrow 7, a rib corresponding to the space 16 remains in the rock and during the subsequent feed movement by pivoting in the direction of the double arrow 10 or moving the cutting heads 11 in the direction of their axis of rotation 15 this remaining rib will be broken away. This is not easily possible, especially with hard rock.

In order to make the new chip specification when the cutting direction is changed in such a way that a rib does not remain between the cutting heads 11, the circuit arrangement according to FIG. 3 is provided. The hydraulic drive for lifting and lowering the cutter arm is again designated 8, whereas the hydraulic drive for pivoting the cutter arm 5 about the essentially vertical axis 9 is again designated 12. With a 4/2-way valve 17, which has not been drawn through in detail, the pressure supplied by the pump 18 can optionally be supplied to the working spaces of the cylinder piston units 8 or 12. Controllable non-return valves 20 are inserted into the pressure medium lines 19 to the cylinder-piston unit 8, whereby when one of the two lines is pressurized, the non-return valve 20 in the other line used in this case as the return line is always activated. Likewise, the 4/2-way valve 17 can cause the pivoting in the horizontal direction about the essentially vertical axis 9 by acting on the cylinder-piston unit 12. In addition to these conventional valves for actuating the two drives, a control device is now provided which has a stepped piston 21 as the central element. Branch lines 24, which are each connected to annular spaces 25 on both sides of the stepped piston 21, open into the pressure lines 22 to the horizontal swivel cylinder 12 via controllable check valves 23. These annular spaces 25 can now be acted upon by the pressure prevailing in the lines 22 when the check valves 23 are opened. When the cutting arm is pivoted in one direction, one of the two lines 22 is effective as a pressure line, whereas the other is connected as a return line. When the check valve 23 is opened, the pressure medium can thus reach an annular space 25. Via the line 26 connected to this branch line 24, the respectively effective pressure medium can be supplied via a non-return valve 27 a central working space 28 of the stepped piston 21 opens, can also be pressed into the respective central working space 28. At the same time, the check valve 30 opening to the working chamber 28 is opened via a control line 29, the opening being carried out in such a way that the check valve 30 of the working chamber opposite the pressurized side of the stepped piston is opened. Due to the cross-sectional area effective when pressure is applied to an annular space 25 and, subsequently, after opening the check valve 27 and also the work space 28 lying on the same side, the stepped piston 21 can be displaced in the desired direction, the displacement path being stopped by stops 31 in the opposite central work space is limited. A predetermined volume is thus squeezed out of the opposite working space 28 and can be fed to the other drive, in the case shown the cylinder piston unit 8, for raising and lowering the cutting arm. For this purpose, a preselection device and a control slide are also provided, the control slide being indicated schematically by 32 and the associated preselector by 33. A control pressure source 34 is also provided, the pressure of which can be applied by the preselector 33 so that the control slide 32 can be moved in one of the two directions, which are symbolized by the arrow 35. Depending on the position of the control slide 32, a volume squeezed out of a central working space 28 becomes effective in the upper or the lower working space of the cylinder-piston unit 8, and it is therefore possible for a chip to be specified upwards or downwards depending on the selected volume. Since this pressing out of the volume from a central working space 28 takes place simultaneously with a swiveling of the cutting arm by acting on the cylinder piston unit 12 in a substantially horizontal direction, diagonal cutting results overall, as long as volume is still pressed out of the central working space 28. After squeezing of this volume, the chip specification has ended and conventional cutting can be carried out by actuating the horizontal swiveling mechanism or the cylinder-piston unit 12.

The check valves 23 in the branch lines 24 are also acted upon by a control line 36 in dependence on the position of the preselector 33, so that the diagonal cutting process can be triggered with the preselector 33. The tank in which the return lines open is indicated in FIG. 3 by 37, an additional tank 38 for the control pressure or the control pressure return line being indicated.

The movement of the cutting head over a working face 39 which can be achieved by means of such a device is indicated in FIG. The cutting process begins, for example, with horizontal cutting along line 40, the reversal of the cutting direction being activated after the target profile 41 has been reached. Due to the simultaneous loading of the horizontal swivel mechanism in the opposite direction and the hydraulic cylinder piston unit 8 in the sense of lifting, as can be predetermined by the adjustment of the control slide 32, a substantially diagonal portion of the movement now takes place when the direction of movement is reversed, which is shown in FIG .4 is designated by 42. After the end of the stroke or after carrying out the chip specification, the material is roughed in a substantially horizontal direction along the line 43 until the desired profile is again reached on the opposite side. Due to the diagonal line 42, with a new chip specification, there is no rib between the cutting heads and it is possible to continue cutting in the opposite direction without risk of overloading the drive. The process can be largely automated with a template control.

Claims (9)

1. A method for controlling the movement of a cutting arm (5), which can be pivoted on all sides, of a partial cutting cutting machine (1) with a first hydraulic drive (8) for lifting and lowering the cutting arm (5) and a second hydraulic drive (12) for pivoting the cutting arm (5 ) transverse to the lifting and lowering direction, characterized in that at the end of the advancing movement of the cutting arm in one of the two directions when the cutting direction is reversed, in particular when the desired profile is reached, pressure is applied to the second drive at the same time. 2. The method according to claim 1, characterized in that a predetermined pressure medium volume is pressed into the second drive during the reversal of the cutting direction. 3. Control device for carrying out the method according to claim 1 or 2, characterized in that a stepped piston (21) is provided which can be acted upon with pressure medium via a central working chamber (28) and a separate annular chamber (25) with a larger radius, and that controllable valves (30) are arranged, which selectively the central working space (28) of the step piston (21) on the opposite side of the pressure piston inflow of the step piston (21) with a drive of the cutting arm (5) for one of the other pressurized with the other Connect the drive of the cutting arm (5) in different directions. 4. Control device according to claim 3, characterized in that the stroke of the stepped piston (21) is adjustable. 5. Control device according to claim 3, characterized in that a control pressure source (34) is provided, which via a preselector with a control slide (32) for the Direction of movement of the cylinder piston unit acted upon by the volume displaced from the working space of the stepped piston (21) can be connected and which can also be connected to controllable check valves (23) in branch lines (24) of the supply and discharge lines to the other hydraulic drive (12) of the cutting arm. 6. Control device according to claim 5, characterized in that the branch lines (24) of the supply and discharge to the other hydraulic drive (12) are each connected to the annular spaces (25) on both sides of the stepped piston (21) and that these annular spaces (25) branch off lines which are connected to the respective central work spaces (28) on the same side of the stepped piston (21) via check valves (27) closing to these annular spaces (25). 7. Control device according to one of claims 3 to 6, characterized in that controllable, to the central working spaces (28) of the stepped piston (21) opening check valves (30) are provided in lines which the central working spaces (28) of the stepped piston (21 ) via the control spool (32) to the work areas of the cylinder-piston unit for the drive (8) of the cutter arm (5). 8. Control device according to claim 7, characterized in that the control lines (29) for the check valves (30) of a central work space (28) with the branch line (24) to the opposite annular space or central work space are connected. 9. Control device according to one of claims 3 to 8, characterized in that the branch lines (24) to the annular spaces (25) of the stepped piston (21) with the lines (22) for the horizontal pivot drive (12) of the cutter arm (5) are connected.

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