TAMPING UNIT FOR TAMPING SLEEPERS OF A TRACK

Abstract

The invention relates to a tamping unit for tamping sleepers of a track, comprising a tamping unit segment with opposing tamping tools tiltably mounted on a height-adjustable tool carrier, with the respective tamping tool being coupled with a vibration drive via a transmission element. The respective transmission element is connected with the assigned tamping tool via a first joint and with a squeezing drive supported on the same tamping tool via a second joint. This design enables a space-saving arrangement of the squeezing drives, resulting in a compact design.

Claims

1. A tamping unit for tamping sleepers of a track, comprising a tamping unit segment with opposing tamping tools tiltably mounted on a height-adjustable tool carrier, with the respective tamping tool being coupled with a vibration drive via a transmission element, wherein the respective transmission element is connected with the assigned tamping tool via a first joint and with a squeezing drive supported on the same tamping tool via a second joint.

2. The tamping unit according to claim 1, wherein the respective transmission element is linked to the vibration drive via a third joint.

3. The tamping unit according to claim 2, wherein the third joint is arranged between the first joint and the second joint.

4. The tamping unit according to claim 1, wherein the vibration drive is designed as an eccentric drive.

5. The tamping unit according to claim 4, wherein each transmission element is connected with an eccentric arm mounted on an eccentric section of an eccentric shaft of the eccentric drive in an articulated manner.

6. The tamping unit according to claim 1, wherein the respective squeezing drive is designed as a hydraulic cylinder with an approximately vertically aligned cylinder axis.

7. The tamping unit according to claim 6, wherein each squeezing cylinder is linked to the assigned tamping tool on the cylinder side and to the assigned transmission element on the piston rod side.

8. The tamping unit according to claim 6, wherein an angle () between the respective cylinder axis and a vertical axis is at most 20, in particular at most 10, during a squeezing process.

9. The tamping unit according to claim 1, wherein the respective tamping tool has an upper lever arm and a lower lever arm, that the lower lever arm comprises at least one tamping tine, and that the upper lever arm is connected with the assigned transmission element.

10. The tamping unit according to claim 9, wherein at least one tamping tine is arranged in a tamping tine support that can be tilted upwards.

11. The tamping unit according to claim 1, wherein the respective tamping unit segment comprises only two tamping tools for tamping a single sleeper of the track.

12. The tamping unit according to claim 11, wherein several tamping unit segments are arranged one behind the other for the simultaneous tamping of adjacent sleepers of the track.

13. The tamping unit according to claim 12, the tamping unit segments arranged one behind the other are arranged in a shared tamping unit frame and that each tamping unit segment is height-adjustable separately by means of an assigned height-adjustment drive.

14. The tamping unit according to claim 12, wherein only some of the tamping unit segments (4) have tamping tine supports (12, 13) that can be tilted upwards.

15. A track tamping machine according to claim 12, wherein at least two tamping unit segments are of identical design.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] In the following, the invention is explained by way of example with reference to the accompanying figures. The following figures show in schematic illustrations:

[0022] FIG. 1 Tamping unit segment in a front view

[0023] FIG. 2 Tamping unit segment in a side view

[0024] FIG. 3 Kinematic model of a tamping unit segment

[0025] FIG. 4 Inline tamping unit

DESCRIPTION OF THE EMBODIMENTS

[0026] The tamping unit 1 shown in FIG. 1 comprises several tamping unit frames 2, which are laterally shiftably mounted on a machine frame 3 of a track construction machine not described in more detail. At least one tamping unit segment 4 is arranged in the respective tamping unit frame 2. The respective tamping unit segment 4 comprises a tool carrier 5, which is height-adjustably guided in vertical guides of the assigned tamping unit frame 2. A lowering or lifting movement takes place by means of an assigned height-adjustment drive 6.

[0027] During work operation, the track construction machine travels along a track with sleepers 7 supported on a ballast bed and rails 8 fastened to it. The sleepers 7 are tamped by means of the tamping unit 1. Usually, each sleeper 7 is tamped by means of several tamping unit segments 4 arranged next to each other. These tamping unit segments 4 arranged next to each other are advantageously arranged so that they can be rotated about a vertical axis and shifted laterally in a turning and shifting unit in order to enable a positioning above a diverging rail of a turnout. In a tamping unit 1 for the simultaneous tamping of adjacent sleepers 7, several tamping unit segments 4 are arranged one behind the other (FIG. 4).

[0028] On the tool carrier 5 of the respective tamping unit segment 4, two opposing tamping tools 9 are mounted tiltably in relation to a sleeper 7 to be tamped. The respective swivelling axis 10 is aligned in the transverse direction of the track. At least one tamping tine 14 is attached to a lower lever arm 11 of the respective tamping tool 9 in a tamping tine support 12, 13. Swivelling movements of the tamping tools 9 about the respective swivelling axis 10 cause squeezing movements or return movements of the opposing tamping tines 14 during a tamping process.

[0029] An upper lever arm 15 of the respective tamping tool 9 is connected with a first joint 16 of a transmission element 17. The respective transmission element 17 is connected with an assigned squeezing drive 19 via a second joint 18. Additionally, the transmission element 17 is linked between the first and second joint 16, 18 via a third joint 20 to a vibration drive 21 (FIG. 2). In a simpler variant, the transmission element 17 is rigidly connected with an element of the vibration drive 21.

[0030] In the embodiment of the transmission element 17 shown, the axes of rotation of the three joints 16, 18, 20 are arranged at the corners of an isosceles triangle in the side view. The respective squeezing drive 19 is designed as an approximately vertically aligned hydraulic cylinder with a cylinder body 22 (cylinder tube and cover) and an upward-facing piston rod 23. The lower end of the respective cylinder body 22 is linked to the assigned tamping tool 9 in an articulated manner. A pin with a plain bearing is arranged at the end of the piston rod 23. This creates an articulated connection with the assigned transmission element 17 via the second joint 18.

[0031] In the embodiment shown, the respective transmission element 17 serves as a lever for transmitting a squeezing force from the respective squeezing drive 19 to the assigned tamping tool 9. The third joint 20 acts as the middle lever joint, which is connected with the assigned vibration drive 21. In this way, the kinematic system consisting of tamping tool 9, squeezing drive 19, and transmission element 17 is set into vibration when the vibration drive 21 is active. For example, a vibration drive 21 with an electromagnetic actuator is arranged. In this, an armature is moved back and forth within an electromagnetic or magnetic field at a vibration frequency.

[0032] In the example shown, the vibration drive 21 is designed as an eccentric drive. With the eccentric drive, the rotational speed of an eccentric shaft 24 determines the vibration frequency. Several eccentric sections are arranged on the respective eccentric shaft 24. For example, a first section with a first eccentricity is located in the centre between two eccentric shaft bearings. Two sections with a second eccentricity are designed on either side of this. A first eccentric arm 25, which is coupled with one of the opposing tamping tools 9, is mounted on the first eccentric section. A second eccentric arm 25 is mounted on the two adjacent eccentric sections with two fork-shaped bearings. This second eccentric arm 25 is coupled with the other of the two opposing tamping tools 9.

[0033] The alignment of the two eccentric arms 25 and the rotational position of the eccentric sections towards each other is chosen in such a way that vibrational movements with the desired vibration amplitudes in opposite directions occur in the third joints 20 of the connected transmission elements 17. The length ratio of the upper and lower lever arm 11, 15 of the respective tamping tool 9 determines the vibration amplitude effective at the tip of the assigned tamping tine 14 according to the lever principle.

[0034] FIG. 3 schematically shows the kinematic arrangement of a tamping tool 9 with the assigned transmission element 17, the squeezing drive 19, and the vibration drive 21. The arrangement of the opposing tamping tool 9 is symmetrical in structure to the axis of symmetry 26. As a result, equally large eccentricities on the eccentric shaft 24 result in equally large vibration amplitudes of the opposing tamping tools 9.

[0035] The approximately vertical alignment of the squeezing drives 19 enables a particularly narrow design of the respective tamping unit segment 4. During a squeezing process, the respective squeezing drive 19 only performs a small swivelling movement. An angle between the cylinder axis 27 and a vertical axis 28 remains within a narrow range of 10 at most, in particular 5 at most, during this movement.

[0036] An extension of the piston rod 23 causes a tipping movement of the transmission element 17 about the third joint 20, whereby the first joint 16 is shifted outwards in relation to the swivelling axis 10. The corresponding shifting path determines the squeezing distance at the tip of the assigned tamping tine 14 according to the lever principle. If the third joint 16 is missing, the tipping movement takes place about an axis of rotation of the vibration drive 21.

[0037] Advantageously, an inner tamping tine support 12 and an outer tamping tine support 13 are arranged on the lower lever arm 11 of the respective tamping tool 9 for fixing at least one tamping tine 14 on each support. The designations inner tamping tine support 12 and outer tamping tine support 13 refer to the position of two tamping unit segments 4 that can be lowered on both sides of a rail 8 (FIG. 1). The tamping tines 14 of the inner tamping tine supports 12 are lowered closer to the rail 8.

[0038] Each tamping tine support 12, 13 can be swivelled about an axis aligned in the longitudinal direction of the rail using its own swivel drive 29. This means that each tamping tine 14 can be tilted up separately before the tamping unit segment 4 is lowered if there is no space for penetration between the sleepers 7 and rails 8. This occurs especially when tamping turnouts or crossings, where diverging or crossing rails as well as adjusting means are obstacles. In FIG. 1, the positions of the tamping tines 14 tilted up on the left tamping unit segment 4 are drawn with dotted lines.

[0039] FIG. 4 shows a tamping unit frame 2 with three tamping unit segments 4 arranged one behind the other. With this inline tamping unit, three sleepers 7 arranged directly one behind the other can be tamped simultaneously during each tamping process. The tamping unit segments 4 can also be shifted in height individually due to the separate bearing in the shared tamping unit frame 2. This option is useful for avoiding collisions with obstacles or for tamping twin sleepers.

[0040] The invention comprises further tamping units 1, which can be assembled in a simple manner due to the narrow design of the tamping unit segments 4. For example, two tamping unit segments 4 are arranged one behind the other in the respective tamping unit frame 2, with only the respective front or the respective rear tamping unit segment 4 comprising tamping tine supports 12, 13 that can be tilted upwards. These tamping unit segments 4 are used in particular in turnouts. All tamping unit segments 4 together serve to efficiently treat a track line, with two sleepers 7 being tamped simultaneously during each tamping process.

[0041] In a further embodiment of an inline tamping unit, asymmetrical tamping unit segments 4 are used in the front row or in the rear row in order to realize greater squeezing distances. In such an asymmetrical tamping unit segment 4, only one of the opposing tamping tools 9, including the squeezing drive 19 and transmission element 17, is of a narrow design. Here, the angle between cylinder axis 27 and vertical axis 28 is at most 5, for example. This applies to the side that borders on the rear or front tamping unit segments 4 of the inline tamping unit.

[0042] On the free side of the asymmetrical tamping unit segment 4, the lower bearing of the squeezing drive 19 is moved outwards. As a result, a longer hydraulic cylinder with a increased stroke can be used as a squeezing drive 19. In this way, the squeezing distance of the assigned tamping tool 9 increases. The angle between the cylinder axis 27 of the longer hydraulic cylinder and the vertical axis 28 is greater than 20, for example 40.