TAMPING UNIT FOR TAMPING SLEEPERS OF A TRACK

Abstract

In a tamping unit for tamping sleepers of a track, both squeezing drives of a tamping tine pair are articulatedly connected to a common connecting carrier. A vibration exciter fastened to the tine carrier is connected to the connecting carrier, likewise fastened to the tine carrier, for transmission of tamping tine vibrations from the connecting carrier to the squeezing drives and the tamping tines.

Claims

1. A tamping unit (1) for tamping sleepers of a track, including a tine carrier (5) mounted for vertical adjustment on an assembly frame (3) and connected to tamping tines (4), wherein the tamping tines (4) which are mounted on the tine carrier (5) for pivoting towards one another in pairs and form a tamping tine pair (6) are each connected to a hydraulic squeezing drive (8) and are designed to be set into tamping tine vibrations by means of a vibration exciter (13), wherein: a) both squeezing drives (8) of a tamping tine pair (6) are articulatedly connected to a common connecting carrier (12), b) the vibration exciter (13) fastened to the tine carrier (5) is connected to the connecting carrier (12) for transmission of the tamping tine vibrations from the connecting carrier (12) to the squeezing drives (8) and to the tamping tines (4).

2. The tamping unit according to claim 1, wherein the vibration exciter (13), designed as a hydraulic linear motor, is arranged centrally between the two tamping tines (4) of the tamping tine pair (6) and has a lifting axis (17) extending parallel to a direction of vertical adjustment of the tamping unit (1).

3. The tamping unit according to claim 1, wherein the connecting carrier (12) is mounted on the tine carrier (5) for rotation about an axis of rotation (14) extending parallel to pivot axes (9) of the tamping tines (4), and the vibration exciter (13) is provided for rotation of the connecting carrier (12) about the axis of rotation (14).

4. The tamping unit according to claim 2, wherein a longitudinal axis (19) of each squeezing drive (8) encloses an angle α of about 40 to 50 degrees, preferably 45 degrees, with the lifting axis (17).

5. A tamping unit (1) for simultaneously tamping two sleepers (2) of a track, including a tine carrier (5) mounted for vertical adjustment on an assembly frame (3) and connected to a total of four tamping tines (4) arranged one behind the other, wherein the tamping tines (4) which are mounted on the tine carrier (5) for pivoting towards one another in pairs about a pivot axis (9) and form a tamping tine pair (6) in each case are each connected to a hydraulic squeezing drive (8) and are designed to be set into tamping tine vibrations by means of a vibration exciter (13), wherein: a) the squeezing drives (8) of both tamping tine pairs (6) are articulatedly connected to a common connecting carrier (12), b) the vibration exciter (13) fastened to the tine carrier (5) is connected to the connecting carrier (12) for transmission of the tamping tine vibrations from the connecting carrier (12) to the squeezing drives (8) and to the tamping tines (4).

6. The tamping unit according to claim 5, wherein the vibration exciter (13), designed as a hydraulic linear motor, is arranged centrally between the two central tamping tines (4) provided for immersion into a common sleeper crib (16) and has a lifting axis (17) extending parallel to a direction of vertical adjustment of the tamping unit (1).

7. The tamping unit according to claim 5, wherein the connecting carrier (12) is mounted in a vertical guide (18), fastened to the tine carrier (5), for adjustment in the lifting axis (17) relative to the tine carrier (5).

8. The tamping unit according to claim 5, wherein the connecting carrier (12) is mounted on the tine carrier (5) for rotation about an axis of rotation (14) extending parallel to the pivot axes (9) of the tamping tines (4), and the vibration exciter (13) is provided for a rotation of the connecting carrier (12) about the axis of rotation (14).

9. A tamping unit (1) for simultaneously tamping at least three sleepers (2) of a track, including tine carriers (5) which are vertically adjustable independently of one another and mounted for vertical adjustment on an assembly frame (3) and are each connected to tamping tines (4) arranged one behind the other, wherein the tamping tines (4) which are mounted on the tine carrier (5) for pivoting about a pivot axis (9) are each connected to a hydraulic squeezing drive (8) and are designed to be set into tamping tine vibrations by means of a vibration exciter (13), wherein: a) the squeezing drives (8) of all of the tamping tines (4) mounted on a common tine carrier (5) are articulatedly connected to a common connecting carrier (12), b) each connecting carrier (12) is connected to a vibration exciter (13), fastened to the tine carrier (5), for transmission of the tamping tine vibrations from the connecting carrier (12) to the squeezing drives (8) and to the tamping tines (4).

Description

[0008] The invention will be described in more detail below with reference to an embodiment represented in the drawing.

[0009] FIG. 1 shows a side view of a tamping unit for simultaneously tamping two sleepers of a track,

[0010] FIG. 2 shows a view of the tamping unit in the longitudinal direction of the rails according to arrow II,

[0011] FIGS. 3 to 7 show further variants of a tamping unit according to the invention.

[0012] A tamping unit 1, shown in FIGS. 1 and 2, for the simultaneous tamping of two sleepers 2 of a track has a tine carrier 5 which is mounted for vertical adjustment on an assembly frame 3 and connected to a total of four tamping tines 4 arranged one behind the other. The tamping tines 4, forming a tamping tine pair 6 in each case, are mounted on the tine carrier 5 for pivoting in pairs towards one another about a pivot axis 9. For executing this squeezing motion (arrow 7), each tamping tine 4 is connected to a hydraulic squeezing drive 8. The tine carrier 5 is mounted on the assembly frame 3 for vertical adjustment by means of drives 10 (FIG. 6).

[0013] Strictly speaking, each tamping tine 4 provided for immersion into ballast of the track is fastened on a tamping lever 11 which is mounted on the tine carrier 5 and connected to the squeezing drive 8. For the sake of simplicity, however, merely the expression “tamping tine” will be used in the following for this lever assembly pivotable about the pivot axis 9.

[0014] The total of four squeezing drives 8 of both tamping tine pairs 6 are articulatedly connected to a common connecting carrier 12. A vibration exciter 13 fastened to the tine carrier 5 is connected to the connecting carrier 12 for transmission of tamping tine vibrations from the connecting carrier 12 to the corresponding squeezing drives 8 and the tamping tines 4 linked thereto.

[0015] The connecting carrier 12, which is designed approximately disk-shaped in the example shown, is mounted on the tine carrier 5 for rotation about an axis of rotation 14 extending parallel to the pivot axes 9 of the tamping tines 4, and the vibration exciter 13, configured as a hydraulic linear motor, is provided for a slight cyclic rotation or vibration of the connecting carrier 12 about the axis of rotation 14.

[0016] The vibration of the connecting carrier 12 produced by the vibration exciter 13 is transmitted in further sequence to all of the linked squeezing drives 8 and from these to the corresponding tamping tines 4 (the ideal tamping tine frequency for tamping is 35 Hz). By appropriately regulating/controlling the hydraulic vibration exciter 13, it is possible to quickly change various tamping parameters, such as the vibration frequency, the vibration amplitude, and also the duration of the vibration. Thus, a tamping cycle intended for the tamping of the two sleepers 2 can be optimally adapted to the particular ballast conditions. Additionally, as already described by EP 1 653 003, a tamping cycle can also be composed of several sequences, each having different tamping parameters.

[0017] As a result of the interposition, according to the invention, of a connecting carrier 12 between the vibration exciter 13 and the squeezing drives 8, a significant simplification of the structural expense can be achieved, since merely a single vibration exciter 13 is required for four squeezing drives 8. Furthermore, by suitable positioning of the articulation points of the squeezing drives 8 on the connecting carrier 12, an exact synchronisation of the tamping tine vibrations is possible.

[0018] As visible in FIG. 2, the expression tamping tines 4 of a tamping unit 1 always refers to the tamping tines 4 mounted on a tamping tine carrier 12 and designed for immersion on one longitudinal side of a rail 15 of a track. As is well known, the tamping tines 4 designed for immersion on the other longitudinal side of the rail 15 can be mounted on separate tine carriers 5, resulting in two independently vertically and transversely displaceable tamping units (split-head). Alternatively, however, these two tamping units 1 can also be connected into a single tamping unit.

[0019] A variant of a tamping unit 1 shown in FIG. 3 differs with regard to the just-described tamping unit 1 to the effect that the vibration exciter 13, designed as a hydraulic linear motor, is arranged in the middle between the two central tamping tines 4 provided for immersion into a common sleeper crib 16 and has a lifting axis 17 extending parallel to a direction of vertical adjustment of the tamping unit 1.

[0020] The connecting carrier 12 connected to four squeezing drives 8 is mounted in a vertical guide 18, fastened to the tine carrier 5, for adjustment in the lifting axis 17 relative to the tine carrier 5. A cyclic vibrating motion of the vibration exciter 13 along the lifting axis 17 is here also transmitted to the connecting carrier 12 and from there to the four squeezing drives 8 and in further sequence to the tamping tines 4.

[0021] A tamping unit 1 shown partially in FIG. 4 has two tamping tines 4, squeezable towards one another by means of the squeezing drives 8, for tamping a single sleeper. The vibration exciter 13, designed as a hydraulic linear motor and fastened to the tine carrier 5, is arranged centrally between the two tamping tines 4 of the tamping tine pair 6 and has a lifting axis 17 extending parallel to a direction of vertical adjustment of the tamping unit 1. A longitudinal axis 19 of each squeezing drive 8 encloses an angle α of about 40 to 50 degrees, preferably 45 degrees, with the lifting axis 17.

[0022] As can be seen in the schematic representation in FIG. 5, the connecting carrier 12 of the tamping unit 1 described with reference to FIG. 4 could alternatively also be mounted on the tine carrier 5 for rotation about an axis of rotation 14 and connected to the vibration exciter 13.

[0023] A tamping unit 1 shown schematically in FIG. 6 is designed for simultaneously tamping three sleepers 2 and is composed—as seen in a direction extending perpendicularly to the pivot axis 9—of two similarly designed tamping unit components 20. Each of these has three tamping tines 4 which are articulatedly connected to a common connecting carrier 12. Each of the two connecting carriers 12, which are independent of one another, is mounted on the respective tine carrier 5 for rotation about an axis of rotation 14 in each case and connected to a vibration exciter 13 for producing the tamping tine vibrations. In case an obstacle to tamping is present, it is possible to selectively lower for the tamping operation only the tamping unit component 20 which is not located above the obstacle. In this case, the vibration exciter 13 of the tamping unit component 20 which is not lowered would be switched non-operational,so that no vibrations are produced.

[0024] In FIG. 7, a tamping unit 1 for the simultaneous tamping of four sleepers 2 is shown which is known in principle already from U.S. Pat. No. 6,389,979. Like the tamping unit 1 described with reference to FIG. 6, this tamping unit is composed of two tamping unit components 20 which are of similar design and arranged one behind the other. However, a third tamping unit component 20 having two tamping tines intended for immersion into the same sleeper crib 16 is located between the former. Now, according to the invention, each of the three tamping unit components 20 is equipped with a connecting carrier 12 mounted on the respective tine carrier 5 for rotation about the axis of rotation 14, wherein a separate vibration exciter 13 is associated with each connecting carrier 12.

[0025] Instead of the above-described hydraulic linear motors, the vibration exciters could also, of course, produce the vibrations acting on the connecting carrier 12 or the tamping tines in a different known manner, for example electro-dynamically.