EP1029150A1

EP1029150A1 - Device for cutting or kirving material

Info

Publication number: EP1029150A1
Application number: EP98954053A
Authority: EP
Inventors: Otto Krassnitzer
Original assignee: Voest Alpine Bergtechnik GmbH
Current assignee: Sandvik Mining and Construction GmbH
Priority date: 1997-11-04
Filing date: 1998-11-03
Publication date: 2000-08-23
Anticipated expiration: 2018-11-03
Also published as: WO1999023356A1; AU744239B2; EP1029150B1; AU1135299A; ATE220760T1; ZA9810055B; DE59804836D1; PL189331B1; AT407421B; ATA186597A; PL340382A1

Abstract

The invention relates to a device for cutting or kirving material on an essentially flat working face. Said device has a kirving tool which is mounted on a swivelling boom in such a way that it can rotate. Said boom consists of at least two boom parts (6, 7) which pivot in relation to each other. The swivelling axis of the boom and the swivelling axes (8, 9) of the boom parts (6, 7) pass through the breast. Planetary gears are arranged coaxially to the swivelling axes (8, 9) of the boom or boom parts (6, 7) and decrease the rotational speed of the turning drives for the swivelling drive to a reduced swivelling speed of the boom or the boom parts (6, 7).

Description

Device for cutting or chamfering material

The invention relates to a device for cutting or chamfering material on a substantially flat dismantling front with a cutting tool which is rotatably mounted on a pivotable boom arm consisting of at least two pivotable arm parts, the pivot axis of the boom arm and the pivot axes of the Cantilever arm parts penetrate the working face.

A device of the type mentioned is known from AT 380 925 B. The known device aimed to create a cutting machine which, seen in the direction of advance, is very short in construction, while at the same time the extension of the route to the face is possible without interrupting the cutting work and without endangering or impairing it. The pivotable cantilever arm parts can be pivoted about axes which are directed essentially normally towards the working face, so that a pivoting angle of at least 180 ° is required for the lower cantilever arm part and a correspondingly larger pivoting angle is required for the cantilever arm parts mounted on this first pivotable arm part to be able to actually dismantle a flat working face with the appropriate swivel position. High demands are placed on the swivel drive, since this swivel drive naturally also has to absorb reaction forces when cutting. Due to the required swivel angle, in particular the required swivel angle, for further cantilever arm parts articulated on a first pivotable cantilever arm part, conventional cylinder piston units are excluded as drives. A rotary drive, which could be designed as a hydraulic motor in a conventional way in cutting machines, now requires a reduction gear for exact positioning and for safe absorption of the cutting forces, which ensures a high reduction ratio. The reduction gear used must also be protected and the invention aims to provide a device to create the type mentioned, the reduction gear, the length seen in the direction of advance not increased and can be accommodated in the smallest space. The invention further aims to design such a reduction gear so that, in addition to a short design, a high reduction ratio and a secure arrangement in the respective parts of the cutter arm or cantilever arm are made possible. To achieve this object, the device according to the invention essentially consists in that planetary gears are arranged coaxially to the pivot axes of the cantilever arms or the cantilever arm parts, which reduce the rotational speed of rotary drives for the swivel drive to a reduced pivoting speed of the cantilever arm or the cantilever arm parts. Characterized in that coaxial to the pivot axes of the cantilever arms or the cantilever arm planetary gears are arranged, such gears can be made extremely short in the axial direction of the pivot axis and be protected in the Schrämarm- or cantilever arm part. The design according to the invention is advantageously made such that the gears in the area of the swivel axes are constructed identically and in each case a driven sun gear has a plurality of rotating planet gears mounted on a carrier and a two-part ring gear divided in the axial direction, the ring gear parts being rotatably fixed in different ones from one another Parts of the boom are fixed. Such a two-part ring gear divided in the axial direction ensures a particularly high reduction with an extremely short overall length when viewed in the axial direction. Because one of the two ring gear parts is fixed in the first cantilever arm part in a rotationally fixed manner, the planet wheels must rotate with their carrier when the sun gear is driven. The fact that the second part of the divided two-part ring gear is now connected in a rotationally fixed manner to the cantilever arm part pivotably mounted on the preceding part results in an effective and extremely high reduction when either the planet gears are divided and a relatively small number of teeth in the has two sections. In principle, however, it is also possible to have a uniform planetary gear, which is located over the The entire axial length extends to be used if the formation is made so that the ring gear parts carry different numbers of teeth to achieve a correspondingly high reduction.

Advantageously, the design is such that the planet gears rotate in the axially adjacent ring gear parts on different pitch circle diameters. In such a construction, a so-called profile shift can be used, the planet gears can be made in one piece. In order to obtain a differential number of teeth, for example three, there is a profile shift inward in the stationary ring gear part of one cantilever arm and a profile shift outward in the aborting ring gear part which is rotatably connected to the cantilever arm part pivotally mounted on the preceding cantilever arm part. In this case, the planet gear meshes in two ring gear parts on different pitch circle diameters. The pitch circle diameter results from the multiplication of the module and the number of teeth.

The design according to the invention is thus advantageously made such that the number of teeth of adjacent ring gear parts is increased by at least one. preferably three to four, is different from one another, which results in a particularly high reduction ratio and at the same time requires the smallest overall length in the axial direction.

According to the invention, the rotary drives can be formed by hydraulic motors in a particularly simple manner. The drive for the cutting head or the cutting rollers, which is arranged on the outermost cantilever arm part, can advantageously be designed as a hydraulic motor, with a protected arrangement of the hydraulic lines to the respective hydraulic motors being made possible in a particularly advantageous manner by the fact that the Sun gears on hollow shafts for the implementation of Hydraulic lines are arranged to be arranged on the following pivotable cantilever arm hydraulic motors.

A particularly small space requirement for the cantilever arm results from the fact that the aborting ring gear of the first gear stage and the fixed ring gear part of the planetary gear of the outer cantilever are arranged in the same vertical plane.

The invention is explained in more detail below on the basis of an exemplary embodiment shown schematically in the drawing. In the drawing, FIG. 1 shows a schematic side view of a cutting machine according to the invention, FIG. 2 shows a section through the gears in the cutting or cantilever arm parts, and FIG. 3 shows a view in the direction of arrow III of FIG. 1, partly in section.

In Fig. 1 a cutting machine 1 is shown, the stationary machine frame is designated by 2.

A carriage which is L-shaped in side view and whose upwardly projecting end region, which is designed as a portal, is designated by 3 and can be displaced relative to the box-shaped machine frame 2. The slide encompasses a guide tube 5, which is in turn connected to the rigid machine frame 2. The slide and in particular the portal-like end 3 of the slide, on which the cantilever arms 6 and 7 are rotatably mounted about pivot axes 8 and 9, can be moved overall relative to the machine frame 2 in the direction of the double arrow 10 to the face, without the machine itself their crawler track 11 must be moved.

An anchor drilling and setting device is indicated schematically at 12. In order to keep the distance a between the positions in which the anchor drilling and setting device 12 comes into effect and the working face 30 as small as possible, one arm remains for the cantilever arm parts 6, 7 Schrämmotor 13 and a cutting head 14 only little space, the dimensions in the axial direction can only be reduced accordingly by appropriate design of the drive and the gear for the cantilever arm parts 6 and 7. The details of this drive are shown in Fig. 2.

In Fig. 2 it can be seen that a first cantilever arm part 6 is arranged on the portal 3 pivotable about an axis 8. A hydraulic motor 15 is provided for the drive and is connected to a sun gear 17 via a gear train 16. The gear train 16 can be formed here, for example, as a chain drive.

The sun gear 17, which is thus connected to the drive motor 15, meshes with planet gears 18, which rotate together with their carrier. The ring gear, in which the planet gears 18 engage, is of split design, a first ring gear part 19 being connected in a fixed manner to the portal 3, with which the planet gears 18 are driven to rotate about the axis 8. The output takes place via the second ring gear part 20, which is again connected in a fixed position to the first pivotable cantilever arm part 6. The number of teeth in the ring gear parts 19 and 20 differs from one another, so that in the case of a uniformly designed planet gear 18 there is a corresponding speed reduction and a high transmission ratio is set.

The drive for the second cantilever arm part 7 is designed in an analogous manner. The hydraulic motor is designated 21 here and drives a central sun gear 22. In the representation of this sun gear 22 it can be seen that this sun gear is hollow and has an axial bore 23 for the passage of hydraulic lines, which can be arranged in a protected manner inside the cantilever arm parts 6 and 7 and also for the cutting drive for the cutting head 14 to lead. A rotary feedthrough for the supply lines is designated 29. With the sun gear 22 in turn mesh planet gears 24, the external ring gear in turn being formed in two parts. The ring gear part 25 is in turn rotatably connected to the cantilever arm part 6, whereas the second part of the ring gear 26 is rotatably connected to the cantilever arm part 7. Due to the difference in the number of teeth in the ring gear parts 25 and 26, it is again possible to develop a high reduction ratio, which is sufficient with correspondingly small hydraulic motors 21 and 15, and nevertheless the necessary supporting forces and reaction forces can be safely absorbed.

3, the planet gears and the respective ring gears can be seen partly in section. The planet gears are each mounted on common carriers and can rotate according to the double arrow 27 depending on the number of teeth of the respective ring gear parts. For the rest, the reference numerals of the preceding figures have been retained in the illustration according to FIG. 3. In addition to the frontal portal 3, the frame spars 28 of the slide construction can now be seen, which is guided on the tubes 5 so as to be displaceable in the machine longitudinal direction. Furthermore, the box profile of the rigid machine frame 2 is clearly visible that the stationary machine frame 2 is designed as a box profile and receives a track conveyor 30 which is slidably mounted in the box-shaped profile in the longitudinal direction of the machine.

Claims

Claims:

1. Device for cutting or chamfering material on an essentially flat dismantling front with a cutting tool which can be pivoted on a cantilever arm part (6, 7) which can be pivoted relative to one another

Cantilever arm is rotatably mounted, the pivot axis of the

Cantilever arm and the swivel axes (8,9) of the cantilever arm parts

(6,7) enforce the face, characterized in that coaxial to the pivot axes (8,9) of the cantilever arms or the cantilever arm parts (6,7) planetary gears are arranged, which reduce the speed of rotation drives for the swivel drive to a reduced swivel speed of the Reduce the boom arm or the boom arm parts (6,7).

2. Device according to claim 1, characterized in that the gear in the region of the pivot axes (8,9) are constructed identically and each have a driven sun gear (17.22) a plurality of rotating planet gears (18, 24) mounted on a carrier and have a two-part ring gear divided in the axial direction, the ring gear parts (18, 19; 25, 26) being fixed in a rotationally fixed manner in parts (6, 7) of the cantilever arm which are different from one another.

3. Device according to claim 1 or 2, characterized in that the ring gear parts (18, 19; 25, 26) carry different numbers of teeth.

4. Device according to claim 1, 2 or 3, characterized in that the planet gears (18, 24) rotate in the axially adjacent ring gear parts (18, 19; 25, 26) on different pitch circle diameters.

5. Device according to one of claims 1 to 4, characterized in that the number of teeth of adjacent ring gear parts

(18, 19; 25, 26) is at least one, preferably three to four, different from one another.

6. Device according to one of claims 1 to 5, characterized in that the rotary drives are formed by hydraulic motors (15, 21).

7. Device according to one of claims 1 to 6, characterized in that the sun gears (17,22) on hollow shafts for the implementation (29) of hydraulic lines to the following pivotable cantilever arm part (6,7) arranged hydraulic motors (15,22) are.

8. Device according to one of claims 1 to 7, characterized in that the abortive ring gear (20) of the first gear stage and the fixed ring gear part (25) of the planetary gear of the outer arm is arranged in the same vertical plane.