EP4074648A1 - Ejector for a forestry winch - Google Patents

Abstract

The invention relates to an ejector (6) for a forestry winch (1), the ejector (6) having a rotatable ejector roller (7) over which a plastic cable (4) is guided and deflected. The ejector (6) has at least one rotating pressure roller (10; 10a; 10b) driven by a drive motor (12) and by means of which the plastic cable (4) is pressed onto the ejector roller (4).

Description

The invention relates to an ejector for a forestry winch, the ejector having a rotatable ejector roller over which a plastic cable is guided and deflected.

Designs with a steel cable and a plastic cable are known for forest cable winches.

In forestry winches with a steel cable, it is known to guide the cable located on a cable drum of the forestry winch over an ejector roller of an ejector that is actively driven by a drive motor. With the ejector roller driven by the drive motor, a desired axial force and thus cable tension can be applied to the steel cable when abseiling the steel cable from the cable drum and when roping the steel cable onto the cable drum, which ensures safe and orderly unwinding of the steel cable from the cable drum when abseiling and a Safe and orderly winding of the steel cable onto the cable drum when roping up. With the axial force applied to the steel cable by the driven ejector roller and thus cable tension, low operating forces for pulling the steel cable can still be achieved for an operator who has to pull the steel cable over a considerable distance of up to 100m when abseiling the steel cable from the cable drum . However, a disadvantage of forest cable winches with a steel cable is the high dead weight of the steel cable, which causes high load-bearing forces for the operator to carry the steel cable when the steel cable is unwound.

Furthermore, forestry winches with a plastic cable are already known. A plastic cable is a fabric cable made from a dimensionally unstable, flexible plastic thread structure, which has the advantage of being lighter than a steel cable. Furthermore, a plastic rope is insensitive when it is wound up on the rope drum of the forestry winch without any force and enables smaller deflection radii. A significant advantage of forestry cable winches with a plastic cable compared to forestry cable winches with a steel cable is the significantly reduced weight of the plastic cable, which means that when the plastic cable is unwound, result in low load-bearing forces for the rope carrying of the plastic rope for the operator.

However, known ejectors for forestry winches with a steel cable are not suitable for a forestry winch with a plastic cable. The reason for this is that the ejector roller is made of steel, so that the pairing of steel ejector roller and plastic rope results in very poor force transmission values, so that the ejector roller driven by the drive motor cannot transmit sufficient axial forces to the plastic rope to achieve the desired to achieve low operating forces for pulling the plastic rope when unwinding the plastic rope. Because of the low power transmission values between the driven ejector roller, which is designed as a steel roller, and a plastic cable, there is also slippage between the driven ejector roller and the plastic cable, which can quickly damage the plastic cable.

The object of the present invention is to provide an ejector for a forestry winch that is suitable for a plastic cable and avoids the disadvantages mentioned.

This object is achieved according to the invention in that the ejector has at least one rotatable pressure roller which is driven by a drive motor and by means of which the plastic cable is pressed onto the ejector roller.

The idea according to the invention is therefore not to drive the ejector roller in a forestry cable winch with a plastic cable, but to actively drive a rotatable pressure roller by means of a drive motor, which presses the plastic cable onto the ejector roller, so that the axial forces and thus the cable tension on the plastic cable are not caused by a drive the ejector roller, but are transmitted to the plastic cable by a drive of the pressure roller and generated on the plastic cable. The pressure roller driven by the drive motor thus presses the plastic cable onto the ejector roller and generates the axial force on the plastic cable. The driven pressure roller, with which the required axial forces are transmitted to the plastic cable, makes it possible to design the ejector roller as a steel roller, which only has to assume the function of a deflection roller for deflecting the plastic cable. Since the having the function of the deflection roller Ejector roller has to transmit the high nominal operating forces, the ejector roller is advantageously designed as a stable steel roller. The associated disadvantage, that the pairing of steel ejector roller and plastic rope results in very poor force transmission values, is overcome according to the invention in that the axial forces on the plastic rope are not caused by an ejector roller actively driven by a drive motor, but by the pressure roller actively driven by the drive motor be applied, since the pressure roller can be designed in a simple manner in such a way that good power transmission values result for power transmission to the plastic cable. Overall, an ejector is thus made available which is suitable and suitable for a synthetic rope and enables sufficient axial forces to be transmitted to the synthetic rope in order to achieve the desired low operating forces for pulling the synthetic rope when the synthetic rope is unwound.

According to an advantageous embodiment of the invention, the pressure roller has a rubberized surface, by means of which the pressure roller lies against the plastic cable. With a rubberized surface of the pressure roller, good power transmission values can be achieved in a simple manner from the pressure roller driven by the drive motor to the plastic rope, which means that sufficient axial forces can be transmitted to the plastic rope from the driven pressure roller in a simple manner in order to achieve the desired low operating forces for pulling of the synthetic rope when unwinding the synthetic rope.

According to an advantageous development of the invention, the pressure roller, which is actively driven by the drive motor, and the ejector roller are rotationally coupled. This makes it possible for the ejector roller not to be rotated via the plastic rope and thus driven, but rather rotated and thus driven by the pressure roller actively driven by the drive motor, which means that the ejector roller can be driven reliably, resulting in little wear on the plastic rope and the ejector roller.

According to one embodiment, a gear, for example a chain or belt drive, can be provided for this rotary coupling between the pressure roller driven by the drive motor and the ejector roller in order to drive the ejector roller via the pressure roller. Alternatively, between the of between the drive motor-driven pressure roller and the ejector roller, toothing that is insensitive to radial tolerances can be formed in order to take the ejector roller with you from the pressure roller and drive it.

According to an advantageous embodiment of the invention, a force entrainment for driving the ejector roller by the pressure roller is formed between the actively driven pressure roller and the ejector roller. In a particularly simple embodiment, the ejector roller can be entrained and thus the ejector roller can be driven by the actively driven pressure roller with force entrainment.

According to a development of the invention, at least one further pressure roller that is not actively driven by a drive motor can be provided, by means of which the plastic cable is pressed onto the ejector roller.

The pressure roller that is not actively driven by a drive motor can be designed as a passively running pressure roller.

According to a development of the invention, the further pressure roller and the ejector roller are rotationally coupled. Preferably, between the ejector roller and the at least one further pressure roller, which is not actively driven by a drive motor, a force entrainment for driving the further pressure roller by the ejector roller is formed. The pressure roller that is not actively driven by a drive motor is thus driven by the force entrainment of the drive roller, which in turn is driven by the pressure roller that is actively driven by the drive motor, for example by a force entrainment. This ejector-pressure roller combination thus represents a friction gear.

According to an advantageous embodiment of the invention, the pressure roller and the additional pressure roller that may be present have a rubberized surface, by means of which the pressure roller rests against the ejector roller. With a rubberized surface, good force transmission values for force entrainment from the pressure roller driven by the drive motor to the ejector roller to be driven by the pressure roller or from the ejector roller to the other pressure roller to be driven by the ejector roller can be achieved in a simple manner.

According to an advantageous embodiment of the invention, the ejector roller has a receiving groove for the plastic cable, the receiving groove having a groove base, in particular a flat groove base, on which the plastic cable rests, and having two lateral groove flanks, the pressure roller and any other pressure roller that may be present into the receiving groove of the ejector roller and the pressure roller and the additional pressure roller that may be present are designed to dip into the receiving groove in such a way that the plastic cable is pressed onto the bottom of the groove by an outer peripheral surface of the pressure roller or by an outer peripheral surface of the additional pressure roller and that end faces of the pressure roller abut against the groove flanks of the ejector roller for driving the ejector roller by the pressure roller or that end faces of the further pressure roller rest against the groove flanks of the ejector roller for driving the further pressure roller through the ejector roller issue. The contour of the ejector roller formed by the receiving groove and the contour of the pressure roller formed by the outer peripheral surface and the end faces of the pressure roller, which dips into the receiving groove, are designed in such a way that an increase in the power transmission to the synthetic rope, avoidance of rope wear on the synthetic rope and a shape adjustment to the non-dimensionally stable plastic rope is achieved, with which the construction-related flattening of the loaded plastic rope is taken into account. Such contours and such a shape of the ejector roller and the pressure roller also enable the ejector roller to be driven easily by the pressure roller actively driven by the drive motor by flank entrainment between the end faces of the pressure roller and the groove flanks of the ejector roller, so that the ejector roller does not first work via the plastic cable but directly set in motion by the pressure roller. Such contours and such a shape of the ejector roller and the further pressure roller also enable a simple drive of the further pressure roller by the ejector roller by flank entrainment between the groove flanks of the ejector roller and the end faces of the further pressure roller.

Advantageously, the outer peripheral surface that dips into the receiving groove and at least the areas of the end faces of the pressure roller that dip into the receiving groove are provided with a rubberized surface. With a rubberized surface on the outer peripheral surface, good power transmission values from the pressure roller driven by the drive motor can be achieved in a simple manner as well as the additional pressure roller on the synthetic rope. With rubberized surfaces on the end faces of the pressure roller, force entrainment in the form of flank entrainment between the end faces of the pressure roller and the groove flanks of the ejector roller can be formed in a simple manner for driving the ejector roller by the pressure roller driven by the drive motor. With rubberized surfaces on the end faces of the additional pressure roller, force entrainment in the form of flank entrainment between the groove flanks of the ejector roller and the end faces of the additional pressure roller for driving the additional pressure roller can be easily formed by the ejector roller.

For this it is possible to design the pressure roller as a solid rubber roller. Alternatively, it is possible to design the pressure roller as a steel roller, with the rubberized surfaces being vulcanized onto the pressure roller.

According to an advantageous embodiment of the invention, the pressure roller is prestressed in the direction of the ejector roller by means of a prestressing device, in particular a spring device. As a result, good wrapping of the plastic cable on the ejector roller can be achieved in a simple manner.

The number of driven pressure rollers can be adjusted accordingly depending on the design of the forestry cable winch and the associated different degree of required ejector cable forces. Depending on the design, one, two, three or even more driven pressure rollers can be provided for this purpose in order to be able to generate the required axial forces on the plastic cable.

The drive motor driving the pressure roller can be designed as a hydraulic motor or as an electric motor. If several driven pressure rollers are used, each driven pressure roller can have its own drive motor or a common drive motor can be provided for several driven pressure rollers, with the drive motor being able to drive several pressure rollers via a mechanical transmission, for example a chain or belt drive.

According to an advantageous development of the invention, the ejector has a cable ejector window for the plastic cable, which is laterally connected to two side plates is limited, between which the plastic rope is guided, the side plates having rounded inner edges as rope outlet curves. The result of this is that the ejector has a cable ejector window that is suitable for the plastic cable. Since there is very little friction between the plastic cable and steel bodies in the ejector according to the invention, with two side plates made of steel plates, which have rounded inner edges, for example circular segment-shaped, as cable outlet curves, sharp edges can occur on the surfaces of the side plates that come into contact with the plastic cable if the plastic cable is run out at the side easily avoided.

According to an advantageous embodiment of the invention, the side plates are arranged laterally on the ejector roller and have a circular peripheral surface in the area of the cable ejector window. In this way, disruptive edges are avoided in a simple manner when the plastic cable runs out upwards or downwards.

According to an advantageous development of the invention, the cable ejector window is delimited vertically at the top by an upper delimiting pin and vertically at the bottom by a lower delimiting pin. With appropriate steel pins as the upper and lower limit pins, the rope run-out of the plastic rope on the ejector roller can be limited vertically above and below.

The invention also relates to a forest cable winch which has a cable drum driven by a drive motor and an ejector according to the invention, a plastic cable being guided from the cable drum to the ejector roller and guided over the ejector roller. With the ejector according to the invention, a forestry cable winch is made available which can be used as a felling and/or tailing winch and which is provided with a plastic cable, the forestry cable winch having a comfortable cable ejection with low operating forces for pulling the plastic cable when unwinding the plastic cable, has low load-bearing forces for the rope carrying of the plastic rope for the operator and has a good winding quality of the plastic rope on the cable drum.

Figur 1

eine erfindungsgemäße Forstseilwinde in einer schematischen Darstellung,

Figur 2

einen Ausschnitt A der Auswerferrolle der Figur 1 in einer vergrößerten schematischen Darstellung,

Figur 3

die Auswerferrolle der Figuren 1, 2 mit dem Seilauswerferfenster,

Figur 4

eine Vorderansicht der Figur 3 und

Figur 5

einen Prinzipdarstellung einer erfindungsgemäßen Auswerferrolle mit mehreren Anpressrollen.

Further advantages and details of the invention are explained in more detail with reference to the exemplary embodiments illustrated in the schematic figures. Here shows

figure 1

a forest cable winch according to the invention in a schematic representation,

figure 2

a section A of the ejector roller figure 1 in an enlarged schematic representation,

figure 3

the ejector roller figures 1 , 2 with the rope ejector window,

figure 4

a front view of the figure 3 and

figure 5

a schematic diagram of an ejector roller according to the invention with several pressure rollers.

In the figure 1 a forest winch 1 according to the invention is shown in a schematic representation. the figure 1 shows a front view of the forestry cable winch 1 according to the invention.

The forest cable winch 1 has a cable drum 3 which is driven by a drive motor 2 and on which a plastic cable 4 is wound up. The cable drum 3 is arranged to be rotatable about an axis of rotation 5 and is driven by the drive motor 2 . The drive motor 2 can be designed, for example, as a hydraulic motor or an electric motor.

The forest cable winch 1 also has an ejector 6 with an ejector roller 7 which is arranged to be rotatable about an axis of rotation 8 .

The plastic cable 4 is guided from the cable drum 3 in the vertical direction V to the ejector roller 7, guided over the ejector roller 7 and deflected at the ejector roller 7 in such a way that the cable 4 is guided away from the ejector roller 7 in the horizontal direction.

The ejector 6 also has at least one pressure roller 10 which is arranged to be rotatable about an axis of rotation 11 and by means of which the plastic cable 4 is pressed onto the ejector roller 7 .

According to the invention, the pressure roller 10 is actively driven by a drive motor 12 . The drive motor 12 can be designed, for example, as a hydraulic motor or an electric motor.

How from the figure 2 can be seen in which the area A of the ejector 6 of figure 1 is shown in an enlarged view, the ejector roller 7 has a receiving groove 20 in which the plastic cable 4 is arranged. The receiving groove 20 has a flat groove base 21 on which the plastic cable 4 rests, and two lateral inclined groove flanks 22a, 22b. The pressure roller 10 driven by the drive motor 12 plunges into the receiving groove 20 of the ejector roller 7 and is designed in such a way that the plastic cable 4 resting on the groove base 21 is pressed onto the groove base 21 by an outer peripheral surface 25 of the pressure roller 10 and that two lateral and inclined Faces 26a, 26b of the pressure roller 10 rest against the groove flanks 22a, 22b of the ejector roller 7 for driving the ejector roller 7 by the pressure roller 10. In the exemplary embodiment shown, between the pressure roller 10 and the ejector roller 7 there is force entrainment between the inclined end faces 26a, 26b of the pressure roller 10 and the groove flanks 22a, 22b of the ejector roller 7 for a rotary coupling between the pressure roller 10 driven by the drive motor 12 and the ejector roller 7 . Alternatively, the inclined end faces 26a, 26b of the pressure roller 10 and the groove flanks 22a, 22b of the ejector roller 7 can be formed with teeth that are insensitive to radial tolerances for the rotary coupling between the driven pressure roller 10 and the ejector roller 7.

The ejector roller 7 is preferably designed as a steel roller.

In order to be able to transmit sufficient axial forces from the pressure roller 10 driven by the drive motor 12 to the plastic cable 4 and to achieve force entrainment for driving and rotating the ejector roller 7 by the pressure roller 10 driven by the drive motor 12, the outer peripheral surface plunging into the receiving groove 20 25 and at least the ones in the Receiving groove 20 plunging areas of the two end faces 26a, 26b of the pressure roller 10 provided with a rubberized surface.

For this purpose, the pressure roller 10 is preferably formed by a steel roller, onto which a rubber layer is vulcanized on the outer peripheral surface 25 and the two end faces 26a, 26b.

The pressure roller 10 is also prestressed in the direction of the ejector roller 7 by means of a prestressing device 30 . In the exemplary embodiment shown, the prestressing device 30 is designed as an adjustable tension spring.

The pretensioning device 30 thus pretensions the pressure roller 10 in the direction of the ejector roller 7 in such a way that the pressure roller 10 is in contact with the plastic cable 4 via the rubberized outer peripheral surface 25 and the plastic cable 4 is pressed onto the groove base 21 of the receiving groove 20 of the ejector roller 7 and that the end faces 26a, 26b of the pressure roller 10 come into contact with the groove flanks 22a, 22b of the ejector roller 7 in areas B1, B2.

The shape of the receiving groove 20 of the ejector roller 7 and the shape of the rubberized outer peripheral surface 25 and the rubberized end faces 26a, 26b of the pressure roller 10 is such that the flattening of the plastic cable 4 under a tensile load is taken into account, so that the driven pressure roller 10 Axial force can be applied to the plastic cable 4 and a force entrainment in the form of flank entrainment and a flank drive is achieved in the areas B1, B2, with which the ejector roller 7 is rotated and driven by the driven pressure roller 10.

In the Figures 3 and 4 the ejector 6 according to the invention with an ejector head 45 is shown in more detail. In the Figures 3 and 4 the driven pressure roller 10 is not shown in detail.

The ejector 6 has a holder 33 with which the ejector 6 can be pivoted about a vertical pivot axis 31, as shown in FIGS Figures 3 and 4 is illustrated by the arrow P1. The holder 33 can include a tube section 32 in which the plastic cable 4 is guided to the cable drum 3 .

The ejector head 45 forms a cable ejector window 35 for the plastic cable 4, which is delimited laterally by two side plates 36a, 36b, between which the ejector roller 7 is rotatably arranged and the plastic cable 4 is guided. The side plates 36a, 36b are fixed to the bracket 33. As shown in FIG.

The side plates 36a, 36b, which are made of steel, for example, and laterally delimit the cable ejector window 35, each have a rounded inner edge 37a, 37b, which form corresponding cable outlet curves. With the rounded inner edges 37a, 37b are thus - as from the figure 4 can be seen - gentle curves are achieved on the outer edges of the inner side flanks of the two side plates 36a, 36b, which represent surfaces tangent to the plastic cable 4 when the plastic cable 4 is pulled out slightly laterally from the ejector head 45, as in FIG figure 4 is shown. When the plastic cable 4 is pulled slightly laterally out of the cable ejector window 35 of the ejector head 45, sharp edges that could damage the plastic cable 4 are avoided.

The cable ejection window 35 formed by the two side plates 36a, 36b is limited vertically upwards by an upper limiting pin 40 and vertically downwards by a lower limiting pin 41. The limiter pins 40, 41 are preferably round steel pins suitably secured in the side plates 36a, 36b.

In the figure 3 the synthetic cable 4 is shown in an upper end position delimited by the upper delimiting pin 40 and in a lower end position delimited by the lower delimiting pin 41, the synthetic cable 4 - as illustrated by the arrow P2 - being pulled out of the cable ejector window 35 in every intermediate vertical pull-out direction can be.

The side plates 36a, 36b have a circular outer peripheral surface in the region between the two limiting pins 40, 41, at least when viewed in the peripheral direction. The outer radius R1 of the side plates 36a, 36b is larger than the outer radius R2 of the ejector roller 7, at least in the area between the two limiting pins 40, 41 as seen in the circumferential direction the circular side plates 36a, 36b are provided with the rounded inner edges 37a, 37b.

In the figure 5 an ejector with a plurality of pressure rollers 10, 10a, 10b is shown, with at least one further pressure roller 10a, 10b being provided in addition to the pressure roller 10 actively driven by means of the drive motor 12. The additional pressure roller 10a or 10b preferably has an identical structure to the pressure roller 10 and is pretensioned in the direction of the ejector roller 7 by means of a corresponding pretensioning device 30a or 30b.

The further pressure roller 10a or 10b can be configured as a pressure roller that is not actively driven by a drive motor or as a pressure roller that is actively driven by a drive motor. The other pressure roller 10a, 10b appears preferably analogous to the representation of figure 2 into the receiving groove 20 of the ejector roller 7 and is designed in such a way that the plastic cable 4 resting on the groove base 21 is pressed onto the groove base 21 by an outer peripheral surface 25 of the pressure roller 10a or 10b and that two lateral and inclined end faces 26a, 26b of the Pressure roller 10a and 10b rest against the groove flanks 22a, 22b of the ejector roller 7.

Furthermore, analogous to the pressure roller 10, the outer circumferential surface 25 dipping into the receiving groove 20 and at least the areas of the two end faces 26a, 26b of the further pressure roller 10a and 10b dipping into the receiving groove 20 are provided with a rubberized surface.

In the case of the embodiment as an additional pressure roller 10a or 10b actively driven by a drive motor, each pressure roller 10, 10a, 10b can be driven by its own drive motor or a common drive motor 12 can be provided for driving the pressure rollers 10, 10a, 10b, which a mechanical gear drives the pressure rollers 10, 10a, 10b. With one or more additional driven pressure rollers 10a, 10b, the axial force transmitted to the plastic cable 4 can be increased in a simple manner.

In the case of the embodiment as a non-actively driven pressure roller 10a or 10b by means of a drive motor, force entrainment for driving the further ones is preferred Pressure roller 10a or 10b formed by the ejector roller 7. This is done, for example, analogously to the pressure roller 10 actively driven by the drive motor 12 by flank entrainment between the groove flanks 22a, 22b of the ejector roller 7 and the end face 26a, 26b of the other pressure roller 10a and 10b. The pressure roller 10a or 10b not actively driven by a drive motor is thus driven by the drive roller 7 via this flank entrainment, which in turn is driven by the pressure roller 10 actively driven by the drive motor 12 via the corresponding flank entrainment.

The further pressure roller 10a or 10b can have the same diameter as the pressure roller 10 actively driven by the drive motor 12 . If it makes sense for reasons of space, the further pressure roller 10a or 10b can also have a smaller diameter than the pressure roller 10 actively driven by the drive motor 12.

Claims (16)

Ejector (6) for a forestry winch (1), the ejector (6) having a rotatable ejector roller (7) over which a plastic cable (4) is guided and deflected, characterized in that the ejector (6) has at least one means of a Drive motor (12) driven rotatable pressure roller (10), by means of which the plastic cable (4) is pressed onto the ejector roller (4). Ejector according to Claim 1, characterized in that the pressure roller (10) has a rubberized surface, by means of which the pressure roller (10) bears against the plastic cable (4). Ejector according to Claim 1 or 2, characterized in that the driven pressure roller (10) and the ejector roller (7) are rotationally coupled. Ejector according to claim 3, characterized in that between the driven pressure roller (10) and the ejector roller (7) there is a force entrainment for driving the ejector roller (7) by the pressure roller (10). Ejector according to one of Claims 1 to 4, characterized in that at least one further pressure roller (10a; 10b) which is not actively driven by a drive motor is provided. Ejector according to Claim 5, characterized in that the further pressure roller (10a, 10b) and the ejector roller (7) are rotationally coupled, in particular between the ejector roller (7) and the further pressure roller (10a; 10b) there is a driving force for driving the further pressure roller ( 10a; 10b) is formed by the ejector roller (7). Ejector according to one of Claims 4 to 6, characterized in that the pressure roller (10; 10a; 10b) has a rubberized surface, by means of which the pressure roller (10; 10a; 10b) bears against the ejector roller (7). Ejector according to one of Claims 1 to 7, characterized in that the ejector roller (7) has a receiving groove (20) for the plastic cable (4), the receiving groove (20) having a groove base (21), in particular a flat groove base. on which the plastic cable (4) rests and has two lateral groove flanks (22a, 22b), the pressure roller (10; 10a; 10b) dipping into the receiving groove (20) of the ejector roller (7) and the pressure roller (10; 10a; 10b) is designed to dip into the receiving groove (20) in such a way that the plastic cable (4) is pressed onto the groove base (21) by an outer peripheral surface (25) of the pressure roller (10; 10a; 10b) and that end faces (26a, 26b ) of the pressure roller (10; 10b; 10b) rest against the groove flanks (22a, 22b) of the ejector roller (7). Ejector according to Claim 8, characterized in that the outer peripheral surface (25) plunging into the receiving groove (20) and at least the regions of the end faces (26a, 26b) of the pressure roller (10; 10a; 10b) plunging into the receiving groove (20) have a rubberized surface. Ejector according to one of Claims 2 to 9, characterized in that the rubberized surface is vulcanized onto the pressure roller (10; 10a; 10b). Ejector according to one of Claims 1 to 10, characterized in that the pressure roller (10; 10a; 10b) is prestressed in the direction of the ejector roller (7) by means of a prestressing device (30; 30a; 30b), in particular a spring device. Ejector according to one of Claims 1 to 11, characterized in that the drive motor (12) is designed as a hydraulic motor or as an electric motor. Ejector according to one of Claims 1 to 12, characterized in that the ejector (6) has a cable ejector window (35) for the plastic cable (4), which is laterally delimited by two side plates (36a, 36b), between which the plastic cable (4 ) is guided, the side plates (36a, 36b) having rounded inner edges (37a, 37b) as rope outlet curves. Ejector according to Claim 13, characterized in that the side plates (36a, 36b) are arranged laterally on the ejector roller (7) and have a circular peripheral surface in the region of the cable ejector window (35). Ejector according to Claim 13 or 14, characterized in that the cable ejection window (35) is delimited vertically above by an upper limiting pin (40) and vertically below by a lower limiting pin (41). Forest cable winch (1), which has a cable drum (3) driven by a drive motor (2) and an ejector (6) according to one of Claims 1 to 15, a plastic cable (4) running from the cable drum (3) to the ejector roller (6 ) and guided over the ejector roller (6).

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