EP1195498B1 - Shield tunnelling machine - Google Patents

Abstract

The tunneling machine, with a driving shield, has a shield driving assembly (1) with a spoil removal system (10) with a throttle (9) between it and a screw conveyor (5), with at least one pair of facing rollers (13,14). The rollers rotate in opposite directions away from the spoil removal. The roller rotation action gives a combined to and fro movement to the spoil, so that heavy silt and coarse fractions are carried off without changing the drilling action or a need to feed additives.

Description

The invention relates to a Schildvortriebseinrichtung with a a conveyor screw having discharge device for Conveying material from a working space and with an on the discharge device connected to the discharge device for removing the material from the discharge device.

Such Schildvortriebseinrichtung is from the book "Maschineller Tunneling in shield tunneling "by Bernhard Maidl, Martin Herrenknecht and Lothar Anheuser, published by Ernst & Sohn publishing house for architecture and technical sciences GmbH, Berlin, 1994, known. The previously known Schildvortriebseinrichtung has a trained with a screw conveyor Abfördervorrichtung on, with the from a working space material is removable. The Schildvortriebseinrichtung still has via a discharge device, which as hanging down arranged rotary valve formed and to the discharge device connected. With the over a one-celled or multicellular paddlewheel having rotary valve is located in the discharge device material from the Removal device removable by acting under the action of Gravity in the rotary valve incident material with the or each paddle wheel is transported down.

Although with the rotary valve substantially from a Coarse fraction like gravel existing pourable material the discharge device removable, but occurs in flowable Material with a high silt content like clay is the problem on that on the one hand the entry into the rotary valve by Bonding of material already in the area of the discharge device is difficult and on the other there is a risk that the rotary valve itself due to in peripheral areas glued the or each paddle wheel adhesive material.

To solve this problem has been in the degradation of Material with a high silt content the rotary valve disabled and the heavily silty material, for example diluted with bentonite and by concrete pumps as discharge device removed from the discharge device. adversely this is in addition to the required change between two Operating modes, in particular the change in composition of the mined material, resulting in reuse an extremely costly refurbishment or otherwise an equally costly and environmental point of view adverse disposal has the consequence.

The invention is based on the object, a Schildvortriebseinrichtung specify the type mentioned, with the without changing the operating mode continuously both material with a high proportion of coarse fraction as well as heavily silty Material safe from additives Removal space is removable.

This object is in a Schildvortriebseinrichtung the The type mentioned above solved according to the invention in that the discharge device a throttle unit with at least a pair of opposed rollers, the each pair in opposite directions are rotatable, with the respective Direction of rotation of the rollers in their facing each other Points away areas of the discharge.

The inventive design of the discharge device as a throttle unit with at least one pair each other Opposite rolling results from the composition to be removed from the discharge device Materials basically largely independent conveying effect. The opposing rollers promote due to the suction and transport effect continuously both flowable, for example highly sulphurous material as well as a high proportion of Coarse fraction material without a change in the mode or the addition of additives must be made. Furthermore, the throttle unit according to the invention also causes at relatively low-viscosity degraded material due the increased flow resistance an effective pressure reduction, to reduce the risk of a collapse of the working face.

Advantageously, in a further development, the throttle unit in the region of a conveying direction of the discharge device connected end - formed compression space, in the extracted material is compressed.

It is useful in a further development that each Roller has a number of radially projecting protrusions, with which components of a coarse fraction comminuted are.

In the latter development is to achieve an in Dependence of the resistance of a coarse fraction against Comminution variable grain size expediently provided that the rollers are mutually displaceable. For example resort to achieving a relatively small Grain size in a first position the circumferential lines of the projections opposing rollers into each other. is however, the coarse fraction is relatively difficult to crush and thus to protect the projections a relatively small grain size advantageous, pointing in another Position the circumferential lines of the projections opposite each other Roll one opposite the diameter of the Roll up small clearance. Furthermore, it can also for Optimization of the residual pressure reduction of the flow resistance be varied within the throttle unit.

For manufacturing reasons, the projections are advantageously comb-like arranged in rows.

To simplify the comminution is expediently provided that the projections end a bevel and / or that the projections sawtooth with a front in the direction of rotation steep slope and with one of steep flank opposite flattened flank formed are.

It is also appropriate that the discharge device comprising a discharge unit connected to the throttle unit. This will make an efficient breakdown of one may still be achieved residual pressure.

In the latter development, it is with regard to a continuous removal of high quantities of material appropriate, that the discharge unit as a double-piston pump with at least two pistons working in opposite directions in pairs is executed and that further expediently the Abführeinheit arranged in extension of a respective piston Has curved discharge tubes, due to the inner Friction a significant flow resistance to Cause residual pressure reduction.

Fig. 1

in einer teilgeschnittenen Seitenansicht ein Ausführungsbeispiel einer erfindungsgemäßen Schildvortriebseinrichtung mit einer ein Paar von in einer ersten Stellung ineinandergreifend angeordnete Walzen aufweisenden Drosseleinheit, die endseitig an eine Abfördervorrichtung angeschlossen ist und mit einer Abführeinheit in Verbindung steht,

Fig. 2

in einer teilgeschnittenen Stirnansicht die Anordnung der Drosseleinheit gemäß Fig. 2 zwischen der Abfördervorrichtung und der Abführeinheit,

Fig. 3

in einer gegenüber dem Maßstab der Fig. 1 vergrößerten Seitenansicht das Ausführungsbeispiel gemäß Fig. 1 mit in einer weiteren Stellung mit ihren Umfangslinien beabstandet angeordneten Walzen und

Fig. 4

eine Draufsicht auf die Drosseleinheit in der Stellung der Walzen gemäß Fig. 3.

Further advantages of the invention are the subject of the following description of embodiments with reference to the figures of the drawing. Show it:

Fig. 1

in a partially sectioned side view of an embodiment of a shield advancing device according to the invention with a pair of intermeshing arranged in a first position rollers having throttle unit which is connected at the end to a discharge device and is in communication with a discharge unit,

Fig. 2

in a partially sectioned end view, the arrangement of the throttle unit of FIG. 2 between the discharge device and the discharge unit,

Fig. 3

in an enlarged compared to the scale of FIG. 1 side view of the embodiment of FIG. 1 with spaced in a further position with their circumferential lines arranged rollers and

Fig. 4

a plan view of the throttle unit in the position of the rollers of FIG .. 3

Fig. 1 shows a partially sectioned side view of an embodiment a shield propulsion device according to the invention 1 with a local in operation arranged on the breast side Cutting wheel 2, the dismantling in front of a working space 3 is arranged. The shield advancing device 1 has a removal device 4 on, one with its front end in the Removal space 3 protruding rotatable screw conveyor 5 and a screw conveyor 5 the back of the working space 3 surrounding Sheath 6 has.

The screw conveyor 5 ends to form a compression space 7 in the cladding tube 6 at a distance from that of the excavation space 3 groundbreaking end of the cladding tube 6. Bei Proper arrangement of Schildvortriebseinrichtung 1 is in the region of the compression chamber 7 via a curved Pipe socket 8 hanging down a throttling unit 9 attached to a discharge device 10. The throttle unit 9 is a compression chamber side closure slide 11 separated from the compression chamber 7. The Throttle unit 9 has a roller housing 12, in which at the illustrated embodiment by a first Discharge roller 13 and a second discharge roller 14 formed Pair of rollers is arranged. The first discharge roller 13 and the second discharge roller 14 are mutually displaceable, so that they are in different positions with different ones Distances are positioned from each other. This is the result Flow resistance within the throttle unit 9 for optimization the residual pressure reduction variable, wherein at relatively widely spaced discharge rollers 13, 14 a relatively small flow resistance with a relatively low Residual pressure reduction and at relatively narrow spaced Austragswalzen 13, 14 a relatively high flow resistance exists with a relatively high residual pressure reduction.

The discharge rollers 13, 14 are rotatable in opposite directions, wherein the respective direction of rotation of the discharge rollers 13, 14 in their facing each other from the compression space 7th the discharge device 4 points away. Through a variation of Speed and the distance of the discharge rollers 13, 14 is the Flow rate and the reduction of the am in the conveying direction of Abfördervorrichtung 4 rear end of the auger. 5 ruling residual pressure adjustable.

Each of the discharge rollers 13, 14 has a number of comb-like arranged in rows and in that shown in Fig. 1 Position of the discharge rollers 13, 14 circumferentially interlocking Walzenzähnen 15 as radially protruding projections on, in a manner explained in more detail below are arranged to be in the introduced into the throttle unit 9 To crush material containing coarse fraction.

Furthermore, the discharge device 10 has a Discharge unit 16, with the throttle unit 9 via an on the arranged from the compression chamber 7 pioneering outlet Abführseitigen closure slide 17 is in communication. The discharge unit 16 is a double piston pump with a executed first piston 18 and a second piston 19, wherein the pistons 18, 19 operate in opposite directions to from the Throttling unit 9 introduced into a chambered Abführraum 20 Material after passing through a Abführschieber 21st in a curved first discharge pipe 22 and in a curved second discharge pipe 23 to move. By the Curvature in the discharge tubes 22, 23 results in a relatively high flow resistance, with the one under circumstances at the outlet of the throttle unit 9 still prevailing Residual pressure is degradable.

Fig. 2 shows in a partially sectioned end view of the arrangement the throttling unit 9 according to FIG. 2 between the discharge device 4 and the discharge unit 16. From Fig. 2 it can be seen that the first discharge roller 13 and the corresponding in the Representation of FIG. 2 partially hidden second discharge roller 14 each have a motor-driven roller shaft 24 features, at which the comb-like arranged in rows and in the position of FIG. 1 circumferentially interlocking Walzenzähnen 15 are attached. Furthermore, Fig. 2 can be seen, that the pistons 18, 19 each in an associated Chamber of the Abführraumes 20 work.

Fig. 3 shows an enlarged in relation to the scale of FIG. 1 Side view of the embodiment of FIG. 1 with the discharge rollers 13, 14 in a further spaced Position are arranged, in which the circumferential lines of the roller teeth 15 a with respect to the diameter of the discharge rollers 13, 14 have a relatively small distance. In this position is relatively, for example, against crushing resistant coarse fraction up to a certain the roller teeth 15 not overstressing grain size comminuted.

From Fig. 3 it can be seen that the roller teeth 15 with a end-side bevel 25, in the direction of rotation of the discharge rollers 13, 14 with front steep flank 26 and with one of the steep Flank 26 opposite flattened edge 27 is formed are. This results in efficient comminution one contained in the entering into the throttle unit 9 material Coarse fraction.

4 shows a plan view of the throttle unit 9 according to FIG. 3. Fig. 4 it can be seen that the roller teeth 15 of the discharge rollers 13, 14 circumferentially at a relatively small distance are arranged one another, so that in the throttle unit. 9 entering coarse fraction is crushed to a particle size, the approximately corresponds to the distance of the roller teeth 15.

Claims (10)

1. Shield tunnelling apparatus with a conveying device (4) having a worm conveyor (5) for conveying material away from a face working space (3) and having a discharge device (10) connected to the conveying device (4), for removing the material from the conveying device (4), characterised in that the discharge device (10) has a throttle unit (9) with at least one pair of mutually opposed rollers (13, 14), which are rotatable as a pair in opposing directions, whereby the respective rotation directions of the rollers (13, 14) point away from the conveying device in their regions facing towards each other.
2. Shield tunnelling apparatus according to claim 1, characterised in that the throttle unit (9) is connected in the region of a compression chamber (7) formed at the end in the conveying direction of the conveying device (4).
3. Shield tunnelling apparatus according to claim 1 or claim 2, characterised in that each roller (13, 14) has a number of radially extending projections (15).
4. Shield tunnelling apparatus according to claim 3, characterised in that the rollers (13, 14) are displaceable relative to each other.
5. Shield tunnelling apparatus according to claim 3 or claim 4, characterised in that the projections (15) are arranged in comb-like rows.
6. Shield tunnelling apparatus according to one of the claims 3 to 5, characterised in that the projections (15) have a ground face (25) at their ends.
7. Shield tunnelling apparatus according to one of the claims 3 to 6, characterised in that the projections (15) are formed in saw-tooth manner with a steep flank (26) at the front in the rotation direction and with a flattened flank (27) lying opposed to the steep flank (26).
8. Shield tunnelling apparatus according to one of the claims 1 to 7, characterised in that the discharge device (10) has a removal unit (16) linked to the throttle unit (9).
9. Shield tunnelling apparatus according to claim 8, characterised in that the removal unit (16) is designed as a double piston pump with at least two pistons (18, 19) working in opposing senses as a pair.
10. Shield tunnelling apparatus according to claim 9, characterised in that the removal unit (16) has curved removal pipes (22, 23) in extension of each piston (18, 19).

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