TAMPING ASSEMBLY FOR A TRACK TAMPING MACHINE

Abstract

A tamping assembly for a track tamping machine comprises a carrier guided in a height-adjustable manner with respect to a tamping assembly frame along guides, on which carrier pairs of tamping tools formed as oscillating levers are pivotably mounted, the tamping tools of which can be oppositely driven by an oscillation drive and can be hydraulically adjusted relative to one another, said tamping tools being intended for introduction into a ballast bed. To reduce the number of required drives, several of the tamping tools are combined into tamping units with a compartment between them engaging around a rail and are mechanically connected to each other, and each oscillating lever is associated with a tamping unit and an adjusting drive, wherein the guides, especially the guide rods, act directly on the respective carrier and run in fixed guides of the tamping assembly frame.

Claims

1. A tamping assembly for a track tamping machine, said tamping assembly comprising: a carrier guided in a height-adjustable manner with respect to a tamping assembly frame along guides pairs of tamping tools formed as oscillating levers pivotably mounted on said carrier, the tamping tools being oppositely driven by an oscillation drive and being hydraulically adjustable relative to one another, said tamping tools being configured to be introduced into a ballast bed, wherein each of the tamping tools of a pair of tamping tools is associated with an adjusting drive, wherein several of the tamping tools are combined into tamping units which have a compartment therebetween engaging around a rail and are mechanically connected to each other, and each oscillating lever is associated with a tamping unit and an adjusting drive, wherein the guides, especially the guide rods, act directly on the respective carrier and run in fixed guides of the tamping assembly frame.

2. A tamping assembly according to claim 1, wherein the oscillating drive and the adjusting drive are arranged in a central vertical plane of the carrier and the tamping units, and the adjusting drive is connected to the oscillating lever directly via a hinge pin for power transmission.

3. A tamping assembly according to claim 1, wherein the oscillating drives are formed as linear drives.

4. A tamping assembly according to claim 3, wherein the oscillating drives simultaneously form the adjusting drives.

5. A tamping assembly according to claim 1, wherein the oscillating levers, which are joined into said tamping units and accommodate the tamping tools, each comprise a respective common tool holder holding tamping tines of the associated tamping unit.

6. A tamping assembly according to claim 1, wherein at least two guides are provided for the carrier.

7. A tamping assembly according to claim 1, wherein the fixed guides of the tamping assembly frame guide the carrier and one or more additional carriers independently from each other so as to form a multiple tamping assembly.

8. A tamping assembly according to claim 1, wherein the guides are arranged outside of the working area of the oscillating levers.

9. A tamping assembly according to claim 3 wherein the linear drives are hydraulic cylinders.

10. A track tamping machine having a tamping assembly comprising: a tamping assembly frame; guides supported on the tamping assembly frame; a carrier guided on the guides in adjusting vertical movement with respect to the tamping assembly frame; oscillating levers pivotably mounted on said carrier; each of said oscillating levers having a tamping unit thereon comprising a number of tamping tools on the oscillating lever, said tamping tools being configured to be introduced into a ballast bed; each of said tamping tools being supported on the associated oscillating lever so as to form a pair of tamping tools with a respective other of the tamping tools on another of the oscillating levers; an oscillation drive connected with and driving said oscillating levers so as to oscillate the tamping tools thereon opposingly to the other of the tamping tools of the associated pair of tamping tools; the oscillating levers each being connected with a respective adjusting drive that provides hydraulically adjusting movement of the tamping tools thereon relative to the other tamping tools of the associated pairs of tamping tools; wherein in each tamping unit, the respective tamping tools are mechanically connected to each other and define a compartment therebetween receiving therein a rail; and wherein the tamping assembly frame has fixed guide structures, and the guides comprise guide rods that act directly on the carrier and run in the fixed guide structures.

11. A track tamping machine according to claim 10, wherein the oscillating drive and the adjusting drives are arranged in a central vertical plane of the carrier and the tamping units, and the adjusting drives are each is connected to the respective oscillating lever directly via a hinge pin through which power is transmitted.

12. A track tamping machine according to claim 10, wherein the oscillating drives are in the form of linear drives.

13. A track tamping machine according to claim 12, wherein the oscillating drives also constitute the adjusting drives.

14. A track tamping machine according to claim 10, wherein the oscillating levers, which are joined into the tamping units and accommodate the tamping tools, each comprise a respective tool holder holding tamping tines of a tamping unit.

15. A track tamping machine according to claim 10, wherein at least two guides are provided for the carrier.

16. A track tamping machine according to claim 10 wherein the fixed guides of the tamping assembly frame guide one or more additional carriers independently from the carrier and from so as to form a multiple tamping assembly.

17. A tamping assembly according to claim 10, wherein the guides are arranged outside of the working area of the oscillating levers.

18. A tamping assembly according to claim 12 wherein the linear drives are hydraulic cylinders.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0016] The subject matter of the invention is shown in the drawings by way of example, wherein:

[0017] FIG. 1 shows a double-tie tamping unit according to the prior art in a side view;

[0018] FIG. 2 shows a side view of a double-tie tamping unit in accordance with the invention with connected tamping arms and a central drive;

[0019] FIG. 3 shows a variant of a double-tie tamping assembly in accordance with the invention in a side view with moved guide columns and fixed guide with four linearly acting tamping drives and only four tamping arms and tool consoles for the tamping tines in a side view;

[0020] FIG. 4 shows a triple-tie tamping assembly in a side view, and

[0021] FIG. 5 shows the triple-tie tamping assembly of FIG. 4 with guide columns and associated fixed guide with six linearly acting tamping drives and six tamping arms in a perspective oblique view.

DESCRIPTION OF THE PREFERRED EMBODIMENT

[0022] In FIG. 1, which shows the prior art, a known double-tamping assembly C is schematically shown, which comprises a continuous vibration shaft, via which four adjusting drives 5 act via connecting rods on the left side of the eccentric shaft and four adjusting drives 5 act via connecting rods on the right side of the eccentric shaft C. Left and right designate the regions to the left and right of a rail of a track. A formerly conventional double-tie tamping assembly C comprises a total of eight tamping arms 3 for each rail (four each for the region to the left of the rail and four for the region to the right of the rail), eight adjusting cylinders 5, sixteen tamping tools 6 and an oscillating drive with pump 7 and a flywheel. The same effort must be provided for the second rail of the track. For this purpose, two vertical guides 8 are required in the region above the track, a lifting and lowering drive 11 and a tamping frame 9.

[0023] A tamping assembly C, D, E, F for a track tamping machine comprises among other things pairs of tamping tools 6 which are pivotably mounted on a carrier 4, 18, 23 and formed as oscillating levers 3, 19, whose tamping tine ends determined for penetrating a ballast bed 24 can be driven in opposite direction by an oscillating drive 7, 17, 20 and can be hydraulically moved towards each other by adjusting drives 5 with an adjusting path B. The carrier 4, 18, 23 is guided in a height-adjustable manner with guides 8, 15, 22 in a tamping assembly frame 9, 14, which can also be formed in the manner of a table, and can be moved by an actuator 11 to the desired height position. The tamping tools 3 are formed as two-arm levers, which are pivotably mounted on the carrier 4, 18, 23. One arm of the respective tamping tool consists of the swivel arm 3 and the tamping tine 6, and an adjusting drive 5, which is a hydraulic cylinder, acts on the other lever arm.

[0024] FIG. 2 shows an embodiment in accordance with the invention of a double-tie tamping assembly D, in which the tamping arms 3 are connected to the left and the right of the rail 2 via continuous pins 12, 13. The tamping tools 6 to the left and right of the rail 2 are combined to form tamping units S, which leave a compartment between themselves for engaging around a rail and are mechanically connected to each other. Furthermore, each oscillating lever 3, 19 is associated with a tamping unit (S), an oscillation drive 7, 17, 20 and an adjusting drive 5, and the guides 8, 15, 22 are arranged outside of the working area of the oscillating levers 3, 19.

[0025] Only one adjusting cylinder 5 each acts on the transverse pins 12, 13. In order to allow a conventional double-tie tamping assembly D to be equipped with a centrally arranged oscillating drive 7, the vertical guides 8 must be moved to the outside. The connecting rods, which are connected to the adjusting cylinders 5, then act in the region of the centre of the vibration shaft. As a result, a conventional single-tie or double-tide tamping assembly D makes do with only four adjusting cylinders 5, instead of the eight cylinders provided according to the prior art. The oscillating drive 7, 17 and 20 and the adjusting drive 5 are arranged in a central vertical plane of the carrier 4, 18, 23 and the tamping units S, and the adjusting drive 5 is connected to the oscillating lever 3, 19 for power transmission directly via a hinge pin 12, 13. The unit D is lifted or lowered via a lifting and lowering drive 11. The carrier arm 4 must be exempt in the region of the inner tamping drives 5 so that the pin 13 that transversely connects the tamping arms 3 does not collide with the carrier arm. The carrier arm 4 runs externally via guides 10 on the guide columns 8. The guide columns 8 are offset to the outside to such an extent that the outer tamping arms 3 do not collide with said columns during the adjustment B.

[0026] FIG. 3 shows the embodiment in accordance with the invention of a double-tie tamping assembly E with only four tamping arms 19, four adjusting cylinders 20, and the guide columns 15 which are fixedly connected to the tamping assembly carrier 18 and which run in guides 14 which are rigidly fixed to the machine frame of a track tamping machine (not shown in closer detail). In order to compensate deflections in the curved track, the tamping assemblies E are moved themselves on transverse guides 16. The vibration is superimposed in the illustrated embodiment in the hydraulic cylinders 20 by means of proportional valves 17 of the adjusting movement B. The oscillating levers 19 are formed integrally with a tool holder 25 for the tamping tines 6. The guides 15, especially the guide rods, act directly on the respective carrier 18, pass through the tamping assembly frame 9, 14, and run in fixed guides of the tamping assembly frame 9, 14. The oscillating drives 7, 17, 20 are formed as linear drives, especially as hydraulic cylinders, and can simultaneously form the adjusting drives 5.

[0027] A triple-tie tamping assembly F in accordance with the invention (FIGS. 4 and 5) consists of two carriers 18, 23 which can be moved independently up and down. As a result, the triple-tie tamping assembly F can also be used as a single-type unit in the case of irregular division of the track ties. In this case, only a partial unit 18 or 23 is lowered. The innermost oscillating lever 19, which is directly adjacent to the other partial unit, can remain in a non-actuated state in the single-tie mode. Each tamping assembly has its own guides 15, 22 which run in a common guide console for example of the tamping assembly frame 14. It is understood that said guide console can principally also be formed in a separate manner for each unit. In order to compensate deflections in the curved track, the tamping assemblies F are moved on transverse guides 16. The vibration is superimposed on the adjusting movement B in the illustrated embodiment in the hydraulic cylinders 20 by means of proportional valves 17. The configuration of a triple-tie tamping assembly F in accordance with the invention is shown in FIG. 5 in a perspective view.