EP2247826A1

EP2247826A1 - Method for the controlled maintaining of a distance between the roof and the face in longwall mining operations

Info

Publication number: EP2247826A1
Application number: EP08715852A
Authority: EP
Inventors: Martin Junker; Armin Mozar
Original assignee: RAG AG
Current assignee: RAG AG
Priority date: 2008-02-19
Filing date: 2008-02-19
Publication date: 2010-11-10
Anticipated expiration: 2028-02-19
Also published as: AU2008351273B2; AU2008351273A1; US20100320827A1; PL2247826T3; CN101952548B; RU2010133869A; EP2247826B1; US8567870B2; WO2009103304A1; CN101952548A; RU2470156C2

Abstract

Disclosed is a method for the controlled maintaining of a mechanically favorable distance (33) between the roof and the face in longwall coal mining operations comprising a face conveyor (20), at least one extraction machine (22), and a hydraulic shield support. In said method, the inclination of the top canopy (13) and the floor skid (11) in the mining direction is determined by means of inclination sensors (17) mounted on at least three of the four main components of each shield support frame (10), such as the floor skid (11), the gob shield (14), the supporting connection rods (16), and in the gob zone of the top canopy (13), the effects on the distance (33) between the roof and the face are determined in a computer unit on the basis of the measured data when the angle of inclination of the top canopy (13) changes, and the parameters that are crucial for the working cycle of the shield support frame (10) are automatically adjusted, said working cycle consisting of a retracting, advancing, and setting process.

Description

Method for controlled maintenance of a cap-to-bullet distance in longwall operations

Description

The invention relates to a method for controlling a longwall conveyor, at least one mining machine and a hydraulic shield removal having longwall mining operations in underground coal mining.

A problem in the automation of longwall control is, inter alia, the control of the cap-coal-collision distance, which is referred to below as "KaKo." In general, it is endeavored in underground coal industry operations, after exposure of a hanging end surface of this Hangendfläche as early as In the case of long-distance mining operations, mining operations inevitably lead to slope areas without development support Extraction with a roller cutter the shield removal at the coal-thrust end of his hanging end cap such a distance from Coal thrust that a passing of the scraper blade without collision with the expansion is possible. Has the usually anticipatory, in the direction of the Schränschrladers front roller cut the upper bank of the seam and exposed the hanging wall, it is only at a certain distance behind the advancing Walzenschrämlader a preference of the shield extension possible, so that in this area support the hanging by the shield removal did not take place. The so far depending on the operating condition in the long-distance setting distance between the coal-end of the Hangendkappe shield shield and the collision (KaKo), so the free cantilever span of the hanging wall between the coal and its support on shield construction, significantly affects the risk of outbreaks in the hanging wall. Each outbreak can lead to an impairment of the extraction operation, especially in the desired automation of extraction and expansion work.

The invention is therefore based on the object to provide a method of the type mentioned, by means of which the cap-coal joint distance (KaKo) is monitored during the advancement of the face front with a view to minimizing the danger of Ausbruch the hanging wall and is adjustable.

The solution to this problem arises, including advantageous refinements and developments of the invention from the content of the claims, which are adjusted to this description.

The invention provides in its basic idea that for the controlled compliance of a rock-mechanically favorable cap-coal joint distance by means of at least three of the four main components of each shielding structure as Bodenkufe, broken shield, support arms and fractured area of the Hangendkappe mounted inclination sensors, the slope of Hangendkappe and Bodenkufe in the dismantling direction determined and based on the measured data in a computer unit in case of changes in Slope angle of the hang-end cap the impact on the cap-to-butt joint distance will be determined and an automatic adjustment will be made of the parameters prevailing at screw-in, pull-out and set duty cycle of the shield support frame.

The invention has the advantage that initially alone due to be determined with a comparatively low effort inclination angle of the individual shield expansion point in the degradation direction, it is possible to draw conclusions on the each adjusting cap carbonization distance, in which case in a particular case Affected shield expansion rack whose working cycle when walking or pulling by the computer unit in an automated process can be set so that each adjusts under the applicable conditions as optimal to be regarded cap-coal joint distance.

According to one embodiment of the invention, it is provided that, in addition to the determination of the inclination angle in the direction of degradation, the inclination of the individual shield expansion point is also determined by the inclination sensors transversely to the degradation direction and compared with the determined bank angle of adjacent shield expansion point and above a value set as permissible during the working cycle an alignment of the respective shield support frame in relation to its neighbor shield extension points takes place. This is to ensure that the individual adjacent shield extension point have no strong differences in their angular position to the longwall conveyor, so do not fall in an automatic process, the adjacent shield expansion point from their mutual association. If impermissible deviations are ascertained, then, when a corresponding critical overlapping situation is detected, the working cycle can be automatically adjusted or aborted when the shield-building frame moves, so that the position of the individual can be corrected Shielding rack is possible. Among other things, unwanted misalignments of a shield extension lead to an increase in the KaKo, so that this measure also ensures the mastery of the desired lowest possible KaKo.

Insofar as the effective KaKo for individual operating conditions depends on the support of the hanging wall on the shield support frame, the emergence of a mountain pad on the top of the hillside causes the hanging end to not be able to rest on the coal-body-side front end of the hanging end cap, but only on the usually in the rear of the hanging wall cap forming mountain cushion pads. For this reason, the formation of such mountain pads should be avoided. For this purpose, according to one exemplary embodiment of the invention, it is provided that the hanging end cap is adjusted during every working cycle of the shield support frame in such a way that the wall end cap falls off from its coal-body end to its fracture-end. In such a sloping position of the hang-end cap, a forming mountain pad is in each case stripped off as the shield-building frame moves. In this case, the control of the position of the Hangendkappe done in individual cases with the help of arranged on the shield frame corner cylinders, said corner cylinder between the Hangendkappe and the rupture shield are arranged so that the Hangendkappe can be aligned in position.

This desired position of the shield support frame can also be favored according to an embodiment in that the tilt of the Bodenkufe is set so that an increase in the Bodenkufe to the longwall conveyor results in each working cycle of the shield support, because by a lightly rising in degradation direction runner on optionally on the footing forming heap is favored. This slipping can be due to the induced by the inclination sensors knowledge of the shield position by an am Shield expansion rack in a known manner established lifting device can be brought about specifically.

If there has been an outbreak of the hanging wall in the region located in front of the coal-body-side end of the hanging-end cap, there is a risk that the hanging-end cap will enter the break-out region with its coal-body-side end; In such a case, such a position of the hanging wall is recognized by a change occurring between two working cycles in the slope of the hanging wall, as far as one can assume a substantially linear course of the hanging wall at a seaming. Thus, if there is an inclination of the hanging end cap in the direction of the outbreak, the coal-shaft-side end of the cap would get stuck in the outbreak at the next working cycle and thus prevent the further walking movement or increase the outbreak. To avoid this effect, it is provided according to an embodiment of the invention that when determining a change occurring between two working cycles in the slope of the hanging wall in the direction of dismantling the next cycle, the hanging end cap is set only with a slope that corresponds to the position of the hanging wall in a previous cycle , The same procedure also results if, after driving under the breakout, the rear, fracture-side end of the hang-end cap pivots into the breakout, which would result in a misalignment of the hang-end cap towards the conveyor. Even in such a case, the hanging end cap is to be set with the predetermined inclination.

In this case, it can be provided that the height of the extension of the hanging wall-carrying stamp of the shielding expansion frame is detected and the respective altitude of the hanging wallet cap is taken into account for the individual working cycles for determining the required position of the hanging end cap. The automatic finishing work is made more difficult in those cases where the shield extension are equipped with a so-called Nachsetzsteuerung. This Nachsetzsteuerung automatically ensures a setting of the shield support frame _f until the Hangendkappe against the hanging wall pushing stamp have reached a working pressure of, for example, 300 bar. In the presence of outbreaks or sagging Hangendbereichen this means that the Nachsetzsteuerung automatically presses the hangover cap until a correspondingly fixed resistance has set. Thus, it comes almost inevitably to misalignments of the Hangendkappe when driving through breakout zones. To avoid this, according to one embodiment of the invention, it is provided that the setting process of the shield support frame is automatically terminated when the slope sensor tilt indicator indicates a misalignment of the hanging end cap compared to its position in a previous cycle. Furthermore, according to one exemplary embodiment of the invention, provision may be made for a follow-up control set up in the case of a shield support frame to be automatically deactivated for the subsequent work cycle and then reactivated for the subsequent work cycle. These measures prevent misalignments due to the automated setting of shield extension points.

Thus, the position of the individual shield support frame relative to the longwall conveyor and guided on the longwall conveyor mining machine can be detected, according to an embodiment of the invention provides that the path of the pulling the Schildausbaugestells causing the longwall conveyor Schreitzylinder is detected by a Wegmessvorrichtung.

Insofar as to avoid collisions in the passage of the mining machine at the Schildausbaugestellen a corresponding, retained by the technical design of the longwall equipment KaKo If this KaKo has to be changed, a change in this KaKo always occurs when, in particular when passing through a trough or when driving over a saddle, the angle of inclination of the longwall conveyor and mining machine changes with respect to the inclination position of the individual shield body. In order to recognize such changes in good time and to compensate them by appropriate control measures, according to one embodiment of the invention it is provided that an inclined sensor is arranged on the longwall conveyor and / or mining machine and the angle of inclination of the longwall conveyor and / or mining machine is determined in the direction of dismantling. Here, the arrangement of an inclination sensor on the mining machine is sufficient. Although the extraction machine traveling on and guided on the longwall conveyor unit effectively forms a unit with the longwall conveyor, to improve the accuracy of the control, it may also be useful to detect the inclination of the longwall conveyor via a tilt sensor disposed thereon. Optionally, the arrangement of a tilt sensor differs only on the longwall conveyor for the purpose of control.

In this context, it is provided that when differences in the angles of inclination of longwall conveyor and mining machine on the one hand and Schildausbaugestell on the other hand, the difference angle between the footprints of longwall conveyor and shield support frame is determined. With this difference angle is expressed whether longwall conveyor and mining machine on the one hand and shielding scaffolding on the other hand move on a common plane in the degradation direction, or whether a relative position of longwall conveyor with mining machine and shielding structure to each other results due to a change in the seam.

Insofar as the differential angle is less than 180 degrees in the case of a throughput through the throughput, it would be sufficient to exploit the full travel distance of the shield mounting frame which is valid for normal operation Collision with the mining machine, so that it is provided according to an embodiment of the invention that at a detected differential angle of less than 180 degrees of the path of the shield support frame to the longwall conveyor during the work cycle is reduced such that a passage of the mining machine before the coal side cap tip of the hanging end cap is possible.

If there is a difference angle of more than 180 degrees when driving over a saddle, the KaKo is undesirably increased due to the position of the longwall conveyor and mining machine and shield support frame, so that in this case the advance of longwall mining conveyor with the mining machine is reduced in order to limit the KaKo. For this purpose, according to an embodiment of the invention, it is provided that at a detected difference angle of more than 180 degrees, the return path of the longwall conveyor to the coal thrust out at advanced Schreitausbaugestell and thus the cutting width of the extraction mesh is reduced such that the passage of the mining machine in comparison with the normal cutting width of the mining machine sets lower cap-to-chip distance.

Such situations are then better controlled, if it is provided according to an embodiment of the invention that the stroke of the Schreitzylinder is set to be greater than the cutting width of the recovery means, because even this solution can be prevented, the cap-coal joint distance to a large Extent grows.

The same considerations for mastering the KaKo also apply to embodiments of longwall equipment in which the Hangendkappe is extended by means of an extendable in the direction of the coal thrust Anstellschiebekappe, as far as in the Anstellschiebekappe also Inclination sensor arranged and the Ausfahrmaß the Anstellschiebekappe is detected via a arranged in the Anstellschiebekappe distance measuring system.

As far as changes in a designed as Lemniskatenschild shield extension the advancement of the kohlenstoßseitigen end of the Hangendkappe depending on the extension height of the stamp of the shield frame due to the conditional by the position of the arranged between Bodenkufe and break plate support Lemniskatenfehlers, it is provided that this error in the determination of KaKo is considered as a correction factor.

In the drawings, embodiments of the invention are shown, which are described below. Show it:

FIG. 1 is a schematic side view of a shield expansion frame with inclination sensors arranged thereon in conjunction with a longwall conveyor and a roller skid loader used as mining machine; FIG.

2 shows the longwall equipment according to FIG. 1 in use in a schematic illustration, FIG.

FIG. 3 shows the longwall equipment according to FIG. 2 in the case of a hanging wall to be feared due to a mountain padding resting on the hanging wall,

4 is a schematic representation of the desired position of a shield support frame for avoiding a mountain cushion which forms on the wall end cap;

5 shows a development situation according to FIG. 2 in the event of a hangover eruption, FIG. 6 shows the development situation according to FIG. 5 when the hangover is interrupted; FIG.

7 shows the construction situation according to FIGS. 5 and 6 in a subsequent work cycle, FIG.

8a-c show the influence of through-passage and saddle transfer on the KaKo in a schematic representation,

9 shows the longwall equipment according to FIG. 1 with a shield extension frame having an additional adjusting sliding cap, FIG.

Fig. 10 is a representation of the so-called Lemniskatenfehlers in a designed as Lemniskatenschild shield frame.

The longwall equipment shown in Figure 1 initially comprises a shield support frame 10 with a Bodenkufe 1 1, on the two pistons 12 are attached in a parallel arrangement, of which in Figure 1, only a stamp is recognizable and carry at its upper end a hanging wall 13. While the Hangendkappe 13 protrudes at its front (left) end in the direction of the still to be described extraction machine, at the rear, right end of the Hangendkappe 13 a breaker plate 14 is articulated by means of a hinge 15, wherein the broken shield of two in side view on the Bodekufe 1 1 resting support arms 16 is supported. In the illustrated embodiment, three inclination sensors 17 are attached to the shield support 10, namely a tilt sensor 17 on the bottom skid 11, an inclination sensor 17 in the rear of the hang end cap 13 near the joint 15, and a tilt sensor 17 on the fracture shield 14. Likewise can also be provided on the fourth movable member of the shield support frame 10, the support arms 16, three inclination sensors must be installed by the four possible inclination sensors 17 in order to determine the position of the shield support frame in a working space with the inclination values determined therefrom to determine. In this respect, the invention is not limited to the arrangement of the inclination sensors shown concretely in FIG. 1, but encompasses all possible combinations of three inclination sensors on the four movable components of the shield support frame.

The shield support frame 10 shown in Figure 1 is struck on a longwall conveyor 20, which also has a tilt sensor 21, so that in terms of the control of the longwall equipment in general also here data can be obtained in terms of conveyor position. On the conveyor 20, a recovery machine in the form of a Walzenschrämladers 22 is guided with an upper roller 23 and a lower roller 24, wherein a tilt sensor 25 is disposed in the region of the Walzenschrämladers 22, further, a sensor 26 for detecting the respective location of the Walzenschrämladers 22 in Strut and reed rods 27 for cutting height measurement.

As can be seen from FIG. 2, the use of the longwall equipment described in FIG. 1 in a long-distance operation is such that the longwall equipment is moved on the horizontal 3 1, with the rollers 23 and 24 of the drum cutter 22 capturing the coalburst 32. The hanging wall 30 is supported by the hangover cap 13 of each shield support frame 10, whereby with increasing Verhiebieb the hanging wall 30 falls as a break 40 after Strebdurchgang. From Figure 2 results in each individual operating situation between the top of the coal-side Hangendkappe 13 and the coal thrust 32 existing KaKo (cap-coal-butt-distance), which is a measure of the free-standing and not unterfangen area 34 of the hanging 30, this area 34 is basically considered to be outbreak risk.

As can be seen from FIG. 3, the KaKo 33 then increases when a mountain pad 35 forms on the hanging end cap 13 of the shield support frame 10, which forms the support for the hanging wall 30. In the embodiment shown in Figure 3 at the same time an embossment 36 in Area of the upper bank of the coal thrust 32 occurred, and it can be seen how without a fundamentally different position of the longwall equipment in comparison with Figure 2 results in a much larger KaKo 33, so that the outbreak-prone area 34 increases significantly.

From Figure 4 it can be seen that at a continuously set inclination of the wall end cap 13 with a drop from its coal-shaft end toward the fracture side 40 during the walking process a forming mountain pad 35 is stripped respectively. At the same time, it can be seen in the area of the floor skid 11 that the floor skid 1 1 is to be set towards the longwall conveyor 20 with a slightly increasing angle in the direction of dismantling 38, since this promotes slippage on heaps lying on the floor 31. These measures can be implemented in detail by arranged on the shield frame 10, but not shown in detail corner cylinder between the hanging wall 13 and the shield 14 and by a known lifting device in the region of the bottom skid 1 1 (so-called. Baselift) be realized.

If, therefore, the emergence of a mountain cushion on the hanging end cap is avoided on account of the driving method according to the invention, a smaller KaKo 33 accordingly arises.

In the figures 5 to 7, the passage of the longwall equipment is now represented by a Hangendbereich with an outbreak 37. For this purpose, it can be seen from FIG. 5 that, when an outbreak 37 has occurred, there is the danger that the coal-body-side end of the hang-end cap 13 will fit into the break-out 37, and this process can be detected by the tilt sensor 17 located on the hang-end cap 13. As a further identification feature for the presence of an eruption in the hanging wall can also change the altitude of the hanging wall 13 by determining the extension height of the punch 12, for example via the arrangement of corresponding sensors 18 on the punches 12, used become. If the Hangendkappe 13 would occupy the schematically indicated position with a protrude into the outbreak 37, it can be seen that - as hinted at Figure 6 results - the Hangendkappe 13 abut against the coal end of the eruption 37 and thereby either the further steps of Prevent shield expansion rack 10 or would increase the outbreak 37. In order to avoid such a disadvantageous consequence is provided to put the hangover cap 13 only in the degree or with the inclination that it has exhibited in the previous cycles in full-scale investment on the wall 30 also, so that a pivoting in the Hangendkappe 13 in the outbreak 37 not done. Thus, the hanging end cap 13, the breakout 37 is undercut, as shown in Figure 6 in principle. If the coal-body-side end of the hang-end cap 13 again comes into abutment against the hanging wall 30, there is no more tendency to incline with respect to an inclination of the hanging-end cap 13, and this can be tapped as a signal that the break-out 37 is undercut.

In the same way, in a subsequent work cycle, a situation to be observed results when, as can be seen from FIG. 7, the rear area of the hanging end cap 13 reaches below the breakout 37, because then this rear area also moves into the opening 37 due to the stamping pressure seeks, so that there is a corresponding inclination of the Hangendkappe 13 in degradation direction 38. Also, this situation is manageable by the hangover cap 13 is set only with their recorded in a previous cycle tilt.

While it is in the embodiments illustrated in Figures 2 to 7 to the control or mastery of the actually adjusting KaKo, this is the technical KaKo to distinguish, resulting from the interpretation of the longwall equipment as such. This technical KaKo corresponds to the safety distance, the Hangendkappe 13 when pushed against the coal thrust 32 Strebförderer 20th must be maintained in order to avoid a collision between the cutting roller 23 and the Hangendschild 13 when passing on the longwall conveyor 20 driving recovery machine. If the incidence ratios of the seam change, which may be associated with passing through depressions or passing over saddles, then different inclination positions of the shield construction frame and the longwall conveyor with extraction machine lead to a change in the KaKo which under-limits or even exceeds the technically necessary KaKo. If the technical KaKo falls below the risk of collision, there is a risk of collision between the mining machine and the shield extension, and if the technical KaKo is exceeded, the danger of an outbreak of the unsupported hanging surface increases.

As shown by the individual representations according to FIGS. 8a to 8c, the passage through the container and saddle traversing leads to an undesired change in the KaKo. As is first apparent from a comparison of FIG. 8b with FIG. 8a, the approaching of a trough (FIG. 8b) leads to a tilting position of longwall conveyor 20 and mining machine 22, via tilt sensors arranged on them

21 or 25 is detectable. The inclination values recorded here can be compared with the inclination values recorded on the shielding support frame 10, and this results in a difference angle which is based on the respective contact surface of the walking support frame 10 and the longwall mining conveyor 20

22 may be based on the lying 31. In the case throughput shown in FIG. 8b, a difference angle of less than 180 degrees results, and this leads to the distance, still given in FIG. 8a, between the coal-body-side end of the hang-end cap 13 and the extraction machine 22 being reduced, so that it does not arise here further illustrated KaKo. In order to eliminate the associated risk of collision, the invention provides that in such a situation, the shield support frame 10 is not retraced by the full amount, but with respect to the longwall conveyor 20 with Recovery machine 22 is left behind something, so that the necessary technical reasons, distance or KaKo is maintained.

A reverse situation arises in a saddle over-travel, as shown in Figure 8c in comparison with Figure 8a. This results in a difference angle of more than 180 degrees, which means that in Hangendbereich the distance between Hangendkappe 13 and mining machine 22, so that the KaKo is torn open. In order not to let the KaKo be too large, it is provided that in the automatic process the shield support frame 10 is pulled to the full path of passage forward, but that the cutting width of the mining machine 22 is withdrawn.

With an appropriately established monitoring of the technically conditioned KaKo and adapted driving style of the longwall equipment, it is possible in an advantageous manner, the so-called "plug-in", i. To reduce the distance between the shield support frame 10 and the longwall conveyor 20, so that while the hangover cap 13 projects further in the direction of the coal thrust 32 and thereby the KaKo 33 is reduced. Since the "plug-in" is changeable during operation, depending on the deposit conditions, the automatic operation of the longwall equipment can be adjusted by the preference of the shield removal station 10 is driven so far that the technically necessary KaKo is met.

As shown in FIG. 9, shield expansion points 10 are also known which have an outlet sliding cap 41 in the region of their hanging end cap 13. The invention is also to be realized with such shield expansion points 10, and it is provided that in the Ausstellschiebekappe 41 also a tilt sensor 17 and a displacement sensor 42 are arranged so that the position of the Ausstellschiebekappe 41 in relation to Bodenkufe 1 1 in the automatic sequence control of the duty cycle of the shield support frame 10 can be considered. Another error correction in the context of the application according to the invention is possible with the use of so-called Lemniskatenschilden in which the position of the coal-side end of the hanging wall 13 changes depending on the extension height of the shield, and indicated with 43 in Figure 10 Lemniskatenfehler is in the investigation of the KaKo in individual cases.

The requirements for mastering the cap-coal-butt distance in an automated operation of the shield extension can also be improved by the fact that constructive changes to the shield extension points can be carried out in over-day repair and maintenance. This also applies, in particular, to new designs of shielding outgoers, in which the requirements of the automated removal operation can be taken into account from the outset.

The features disclosed in the foregoing description, the claims, the abstract and the drawings of the subject matter of these documents may be essential individually as well as in any combination with each other for the realization of the invention in its various embodiments.

Claims

claims

A method for controlled compliance of a rock mechanically favorable cap-coal-butt-distance (33) in a longwall conveyor (20), at least one mining machine (22) and a hydraulic shield removal having longwall coal mines in which by means of at least three of the four main components each Schildausbaugestells (10) as Bodenkufe (11), Bruchschild (14), support arms (16) and fracture-side of the Hangendkappe (13) attached inclination sensors (17) determines the inclination of hanging wall (13) and Bodenkufe (11) in the degradation direction and based on measured data in a computer unit in the event of changes in the inclination angle of the hanging end cap (13), the effects on the cap-to-butt joint distance (33) are determined and an automatic adjustment of the screwing, pulling and setting existing working cycle of the shield support frame (10) relevant parameters he follows.

2. The method of claim 1, wherein by means of the inclination sensors (17) determines the inclination of the individual shield expansion point (10) transversely to the degradation direction and compared with the determined bank of adjacent shield extension (10) and above a value set as permissible during the work cycle an alignment of the respective shield support frame (10) takes place in relation to its Nachbarschildausbaugestellen.

3. The method of claim 1 or 2, wherein at j edem duty cycle of the shield support (10) the Hangendkappe (13) is adjusted so that a drop of the Hangendkappe (13) results from its coal-shaft end to its fractured end.

4. The method of claim 3, wherein the control of the position of the hanging end cap (13) by means of the shield support frame (10) arranged corner cylinders takes place.

5. The method according to any one of claims 1 to 4, wherein at each working cycle of the shield support frame (10), the inclination of the Bodenkufe (1 1) is adjusted so that an increase in the Bodenkufe (1 1) results in the longwall conveyor (20) ,

6. The method according to claim 5, wherein the control of the position of the Bodenkufe (1 1) by means of a Schildausbaugestell (10) is arranged lifting device.

7. The method according to any one of claims 1 to 6, wherein upon detection of a change occurring between two working cycles in the slope of the wall end cap (13) in the direction of dismantling the next cycle, the hanging wall (13) with a Slope is set, which corresponds to the position of the Hangendkappe (13) in a previous cycle.

8. The method according to claim 7, wherein the extension height of the Hangendkappe (13) bearing punch (12) of the shield support frame (10) detects and the respective altitude of the Hangendkappe (13) to Bodenkufe (1 1) in the individual cycles for determining the required position of the hanging end cap (13) is taken into account.

9. The method of claim 7 or 8, wherein the setting operation of the shield support frame (10) is automatically terminated when the inclination sensor (17) of the hanging end cap (13) indicates a malposition of the hanging end cap (13) compared to their position in a previous cycle ,

10. The method of claim 9, wherein subsequently set in a shield frame (10) Nachsetzsteuerung for the subsequent work cycle is automatically deactivated and reactivated for the subsequent cycle.

1 1. A method according to any one of claims 7 to 10, wherein the Schreitweg of the tightening of the shield support frame (10) to the longwall conveyor (20) causing scraper cylinder is detected by a Wegmessvorrichtung.

12. The method according to any one of claims 7 to 1 1, wherein at Strebförderer (20) and / or extraction machine (22) each have a tilt sensor (21, 25) arranged and the inclination angle of longwall conveyor (20) and / or extraction machine (22). is determined in degradation direction.

13. The method of claim 12, wherein when detected deviations in the inclination angles of longwall conveyor (20) and mining machine (22) on the one hand and shield support frame (10) on the other hand, the difference angle between the support surfaces of longwall conveyor (20) and shield support frame (10) is determined.

14. The method of claim 13, wherein at a detected differential angle of less than 180 degrees, the path of travel of the shield support (10) to the longwall conveyor (20) is reduced during the work cycle such that a passage of the mining machine (22) in front of the coalchip-side cap tip of Hangendkappe (13) is possible.

15. The method of claim 13, wherein at a detected difference angle of more than 180 degrees, the return path of the longwall conveyor (20) to the collision (32) out with advanced walking frame (10) is reduced such that at the passage of the mining machine (22) set as a maximum predetermined cap-carbon distance (33).

16. The method according to any one of claims 1 to 15, wherein the stroke of the Schreitzylinder is set larger than the cutting width of the mining machine (22).

17. The method according to any one of claims 1 to 16, wherein the hanging end cap (13) by means of a in the direction of the coal thrust (32) extendable Anstellschiebekappe (41) is extendable and arranged on the Anstellschiebekappe (41) an inclination sensor (17) and the Ausfahrmaß the Anstellschiebekappe (41) via a in the Anstellschiebekappe (41) arranged Wegmesssystem (42) can be detected.

18. The method according to any one of claims 1 to 17, that the Lemniskatenfehler (43) occurring in dependence on the extension height of the shield support frame (10) in the determination of the cap-coal-butt distance (33) is taken into account.