EP0760900B1 - Process for the best possible extraction of gas in a large coal seam which has not or only limitedly been prospected - Google Patents

Abstract

In a process for establishing the starting point for gas extraction drillings in a tectonically stressed coal seam, the aim is to improve safety with an economical establishment of the starting points. To this end, the drillings are made in tectonically determined regions in which gas is very likely to be present and with an adequate gas circulation, in which, besides the underlay, the run and the hade of the faults, account is taken of the dispersions, creasing and pressures and the tectonic mass transport influenced thereby as bases for planning.

Description

The invention relates to a method for determining the starting points of the gas production in a tectonically stressed and mines not or only slightly clarified hard coal deposit serving, the holes can be made both from above and from an underground mine.

In the course of gas production, it is a primary goal to orient the holes in a deposit body to be used for gas production and to guide them in such a way that low production costs are incurred. In this respect, it is important to determine the most favorable starting points for the holes and, in addition, measures to loosen the mountain body, for example by deflecting the holes in the mountain body or by blasting, if there is no sufficient natural loosening of the mountain body due to the tectonics. The problem here is to determine the applicable tectonic structures, which offer good conditions for gas production.

The result of the tectomechanical process is the reality of the existing tectonics with shifts or leaves, shifts or jumps and shifts or changes. They are summarized as tectonic disturbances together with the behavior of the mountain strata in the geometry of the deposit as a uniform picture. The reality, that is, the reality of the disturbances, is justified by their position in space and thus by strike, stroke length, dip, dip directions, distances and their changes. In addition there are discards, displacement and thrust dimensions and also their changes. This reality of tectonics can be traced back to its causes in the tectomechanical process. As a causal cause for tectomechanical structures and thus for the determination of the gas opening for the approach and the control of boreholes for gas production, the loosening, crushing and pressing defined as material balances offer themselves as a result of the design of tectonic disturbances; in addition there are material transports in the mountains at disturbances, within folds, from bruises after folds and between folds themselves.

Material balances and material transports are in turn the result of different supply of folding energy and different conditions for its reduction. Thus there is a causal relationship between folding or tectonic energy and the deposit geometry. This allows reality to be traced back to its origin when drilling gas wells and vice versa. In this way, the most favorable starting points for the holes for optimal gas production can also be determined in a large-scale coal mine deposit that is not or only slightly mined.

It should be noted that tectonics is not known in many cases as an important influencing variable for the orientation of the boreholes, so that it is necessary to configure the tectonics based on known tectonic conditions. In the case of gas extraction solely from boreholes, there is a lack of mining outcrops in the form of mines, so that only the knowledge or idea of the deposit body given on the basis of deep boreholes and seismic surveys is the starting point for determining the starting points for boreholes.

In a large-scale deposit that is not or only slightly mined, especially the coal deposit, the prospective location of the tectonic disturbances and thus the location of the areas for favorable gas extraction must be determined from the existing outcrops, so that a basis for planning the starting points of the boreholes and the Loosening measures such as carrying out explosions and the like is given. Usually, for the planning of mining operations conducted in the course of the day, the deposit is also designed as a planning basis, the basis of which are the incidence, the deletion and the dimensions of the faults. The known outcrops are usually geometrically connected to each other in such a way that a supposedly accurate picture of the deposit is created as a basis for planning. The often considerable gaps between the outcrops are closed exclusively on a geometrical basis by the continuation of lines which reflect the position of the areas to be represented, such as seams or tectonic disturbances in the spatially arranged deposit body should. In this case, the chronological principle according to which the younger disturbance is said to have disturbed the older one is also used as a simplification, for example when projecting a meeting of two disorders.

If the design of the drilling of holes for gas production is to be based on such a design consideration for the formation of the deposit, it is to be regarded as disadvantageous that the tectomechanical process has not been taken into account and only an apparent accuracy due to the exclusive limitation of the projection to the geometry enables. For example, movements that have occurred after the formation of jumps are ignored on a change, but these can have a considerable influence on the orientation of the holes and, if necessary, additional loosening measures in the mountains. Furthermore, taking into account the tectomechanical process gives indications of where there is a lot of gas and / or where a lot of gas can flow on bad, fissures and faults.

The invention is based on the object of specifying a method of the type mentioned at the outset in which the informative value of the planning bases is improved and thereby greater security is achieved with a cost-effective determination of the starting points for bores.

This object is achieved, including advantageous refinements and developments of the invention, from the content of the patent claims, which follow this description.

The basic idea of the invention is that the bores are arranged in zones of high gas permeability and sufficient gas circulation, taking into account the tectonics, whereby in addition to the incidence, the removal and the amount of discard of the disturbances, the loosening, crushing and pressing caused by the tectonic energy as well as the tectonic mass transports affected by this can be used as a planning basis. Tectonic energy, the reduction in energy and the direction of energy flow are also used. The invention is therefore associated with the advantage that the tectomechanical relationships when the planning of gas production from both surface and underground starting points from underlying depository bodies are created can now be used as the basis for planning for determining the starting points of the wells, with more precise information about Design and behavior of tectonics improve the basics of planning. In this way, the relationships within large electronics between large and small electronics and between initial and subsequent faults can be used for planning gas production. Taking into account the tectomechanical relationships allows an earlier indication of whether, for example, the rejection of a known disturbance is likely to remain the same or to increase or decrease in one or the other strike direction. With the method according to the invention, sizes of strike direction and dip changes in detected faults can be determined in an advantageous manner and conclusions can be drawn for gas contents, gas contents and gas circulations, so that the best possible arrangement of the starting points from the gas extraction holes follows; it is also possible to provide information on the tearing of jumps depending on Collapse of the rock strata, that is to say depending on the state of the unfolding and also to align the starting points for the boreholes; more precise information on the design and behavior of large and small electronics is also possible, which significantly improves the basics for planning gas production and thus gas production itself.

According to one embodiment of the invention, the course of the folding energy is now determined in a mountain area to be planned, and the planning of the bores and any additional local loosening measures to be carried out, such as blasting, are based on this. In general, the folding energy in a mountain body is opposed by a counter pressure which is provided by the mass of the mountain; the folding energy overcomes this counterpressure and does work by creating and designing tectonic disturbances, whereby from the detected course of the folding energy the design of a disturbance can be recognized as the basis for planning the starting points for drilling. In individual cases, the possibility of gas extraction depends to a large extent on whether the folding energy has been conducted through the mountains without new tectonic structures being created or existing structures still being changed.

Thus, according to one embodiment of the invention, the course of the folding energy at movement locks and movement free zones is determined and the gas extraction possibility in the areas concerned is determined. This is based on the knowledge that the folding energy is only converted locally as long as there is a free space, such as that Daily surface for which tectonic structures are present; So the gas production possibility depends on the presence of movement free zones, which are opposed to movement restricted zones. It is generally more favorable to assess the gas extraction option in movement restricted zones than in the movement free zones.

The movement processes in the mountains as a result of the stress caused by the folding energy result in pressure zones, squeeze zones and loosening zones. Since pressure zones arise when folding energy and rock material are increasingly fed to one another, the movement possibilities for small tectonic disturbances in the mountains are restricted in such zones, so that holes for gas production can only be arranged to a limited extent here; As there are no circulation routes, additional local loosening measures may be required.

Crushed zones are characterized by the fact that folding energy and rock material strive towards one another, so that gas could not flow away here during the geological period due to the disturbances. However, there are only a few circulation paths, so that the number of boreholes is increased and the additional local loosening measures are increased in order to set useful gas extraction options in these areas.

On the other hand, there are loosening zones when the folding energy and mountain material diverge, and the loosening associated with this offers scope for the discharge of gas when there are disturbances such as jumps as a flow path nearby; such areas are only very limitedly accessible for gas production. If, on the other hand, there are loosenings at a greater distance from tectonic disturbances which persist until after days, according to one embodiment of the invention, holes for gas production will preferably be drilled at these locations, in particular those of days.

The existence of compression, squeezing and loosening zones necessitates intermediate areas in which there is a tectomechanical mass transport. Mass transport has a significant impact on the expected small electronics and thus on possible circulation routes for gas. The invention therefore proposes in one exemplary embodiment to select, in particular, areas of mass transport in the vicinity of a crushing or pressing for the preferred determination of starting points for bores; there is gas nearby and circulation paths are available.

Changes to the discard of jumps result in loosening in areas with less warping and pressing in areas with greater warping. The balance between loosening and pressing is carried out by mass transports, on which the gas could flow to the jumps in the loosening area. In areas with greater rejection at the jumps, the mountains are pressed and the gas could not drain off there. Nevertheless, there are circulation paths for the gas in the mountains, so that, according to one embodiment, possibilities for extracting the gas are improved.

Loosening occurs in the run-out area of clump-limiting jumps, and there the gas was able to flow and migrate towards the jumps, so that the conditions for gas production only become better at a greater distance from a jump.

Sedimentation deposits, such as a hard coal deposit in particular, are characterized by storey tectonics, in which thrusting starts at depth, which strike more or less at right angles to the jumps. If a corrugated bearing with or without small-tectonic shifts and / or shifts or small-tectonic shifts and / or shifts without undulating storage is unlocked, with sloping areas undisturbed or above that no digestions are available, then larger over-shifts occur at depth. In this case, a layer-parallel glide occurs in the discharge area of the thrusts, which lubricates the fissures and leads to a gas jam with a lot of gas. In this case, such areas are suitable according to an embodiment of the invention for the preparation of holes. If layer sliding and loosening are to be planned at the same point, then gas and circulation paths for the gas are available, such as in the outlet area of jumps and where loosening is present on jumps as a result of changes in the coating direction; these areas are also suitable for drilling holes.

Changes in the strike direction of thrusts result in snow plow and funnel effects, with snow plow effects with loosening and funnel effects with Contusions are connected. If snow plow effects and stratified gliding are now to be assumed in the same area, then the gas contents are particularly large and circulation paths for the gas are present, so that the holes for gas production are preferred in such areas. This area is enlarged if there is a pinch or squeeze on a block delimiting jump at a distance of less than 900 m; in this case, the holes for gas production are arranged parallel to the thrust because there are shear surfaces that strike an angle of about 30 gon. The same applies if the snow plow and funnel effects are also less than 900 m apart.

Stratified sliding also occurs when there is a change in the degree of thrusting at thrusting and in the discharge areas of thrusting downwards, and there are loosening areas which favor a preferred orientation for bores for gas production.

The floor tectonics not only apply to the occurrence of thrusting, but also apply to the saddle structures and convex bending axes. While undisturbed conditions usually prevail in the upper areas, underneath in the saddle area and convex bending axes follow shifts, including shifts; Thrusts are associated with stratified sliding and smearing of the fault areas, and therefore the gas content is high in the area of the thrusts, but especially below. Displacements in saddle areas and convex bend axes indicate looseness in a saddle, and the gas can circulate there. For these reasons Bores for gas production are concentrated on saddle areas and convex bending axes between thrust zones and displacement zones according to an embodiment of the invention, the gas-open areas reaching right up to the cleat-limiting jumps if there are bruises or pressures there.

As a rule, the mountains are divided at certain intervals by larger, approximately parallel displacement zones or displacements in adjacent tracks. A more or less horizontal mass transport has taken place at the displacements. The mass transport hits the respective neighboring clods, which creates pressures with high gas contents.

At the same time, the mass transport creates a backward pull on the displacements, which leads to loosening at clump-limiting jumps. The gas was able to migrate here in the geological period, so that the gas content in these areas is lower. In addition there is the fact that in the area of the displacements the discard at the jumps often has minimum values; the loosening that occurs as a result of the mountain slipping on the jumping surfaces has consequent shrinkage that can serve as movement paths for gas circulation. Therefore, according to one embodiment of the invention, the bores for gas production are primarily oriented in areas in which the mass transport impinges on the neighboring clods due to displacements. In these cases, the displacements themselves are avoided because the gas has migrated locally in their area. If there were opposing movements at displacements or at displacement zones, the mountains are mylonitized and smeared, and in these cases the gas content is very high, but at the same time the circulation possibilities for the gas are restricted. In such a case, the wells for gas production are oriented in the direction of the shift zone and the rock around the wells is loosened up locally, for example by loosening up blows, such as in the region of bisectors of angles between the strike directions of jumps and thrusts, jumps and shifts, thrusts and Displacements and plaice bisectors. This also includes areas of the large shifts to be determined.

If there are two loosening zones at a distance of less than 600 m from each other and if the loosening is triggered by the behavior of the jumps, there are opposing movements on shear surfaces, but the gas has flowed out here during the geological period; for this reason, holes are not arranged there.

If, on the other hand, shifts meet thrusts, the gas contents are usually large, in particular below the thrusts, although there are no circulation paths for the gas. For this reason, according to an embodiment of the invention, the holes for gas production in these areas are primarily arranged.

The shear areas intersect in the run-off areas of thrusts and displacements, caused by mass transports in the mountains. Shear surfaces also intersect when bisectors intersect with shear surfaces that are triggered by the expiry of thrusts and shifts. Furthermore, shearings cross when cross larger shifts. If there are loosening of jumps at a distance of more than 400 m when the thrusts are running out and at a greater distance than 1000 m when the shifts are running out, holes for gas extraction should preferably be oriented in the intersection areas; local loosening measures around the wells are restricted. However, if there are slides parallel to the layer at the same point, the local loosening measures are reinforced.

If stratified glides are present in two directions, such as in the hanging of jumps, which change their depth at depth and over-thrusts at the same point, where the degree of thrust changes, the gas content in these areas is particularly large, although there are fewer circulation paths for the gas are. Thus, an embodiment of the invention provides for orienting the bores for gas extraction in these areas while at the same time providing local loosening measures to be provided; this applies in particular to the areas under the thrust.

Shift sliding in two directions also occurs when trough and saddle lines collapse as well as changes in the degree of thrusting of thrustings at a bank distance from the thrusting of less than 400 m.

The division of the mountains at certain intervals by means of larger, approximately parallel displacement zones or displacements in adjacent tracks gives indications of areas that are open to gas and thus of the location of conveniently located wells for gas extraction in large and extensive hard coal deposits. These are hard coal deposits where there are mining outcrops are not available or are far from each other or only a few reconnaissance wells and / or reconnaissance seismics are available.

Displacement zones or displacements must be demonstrated in the strike direction over longer distances. In many cases, the displacements over certain distances do not exist as such or are designed as small and very small electronics (shearings). It is always to be expected that an accompanying electronic system is available, as it will be unlocked where larger shifts are unlocked.

The division of the mountains at certain intervals by larger, such as parallel displacement zones or displacements that span a greater distance in adjacent paths, gives a large-scale reality with a fault pattern that - with minor uncertainties - can also be determined in less known deposits. For example, the distance between major east-west "main shifts", which can also be latent, is 5.2 km; in between there are further displacement zones or displacements at a distance of 1.1 to 1.5 km after reducing the folding energy.

The division of the mountains at certain intervals by larger, approximately parallel displacement zones or displacements influences the folding energy and the counter pressure. The folding energy and the back pressure are deflected by the displacements. Since the folding energy is supplied to the mountains on a broad front, the side-by-side deflections of the energy are one Addition of energy and also back pressure combined to ever increasing values. As a result, the design of other tectonic disorders is legally influenced depending on the causal relationships. As a result, jumps in the area of the larger displacement zones and displacement generally have less warping or come from both sides in the neighboring area from the displacements or start again; the direction of the jumps also changes. The same applies to thrusts. On the basis of these relationships in the tectomechanical process, larger distortions at the jumps are to be expected between the displacement zones. There, mountain material is increasingly fed to one another, so that the movement possibilities of small tectonic disturbances in the mountains are restricted in such zones. As there are no circulation routes, additional local loosening measures may be required.

In the area of larger displacement zones, which as such do not exist over certain distances, there are loosening areas where the jumps run out, which offer space for the gas to flow away; Such areas, which lie in a straight line or in large arches one behind the other, are only very limitedly accessible for gas production.

If jumps are known in punctiform fashion between two adjacent displacement zones, the position of expected loosening over longer distances can be determined from the directions in which the displacement zones and the jumps strike. According to an embodiment According to the invention, holes for gas production are preferably made in the middle or at a greater distance than 400 m from the exit points of the jumps or the intersection of the jumps with the displacement zones and are deflected perpendicular to the displacement zones. If it turns out that the direction of strike of jumps on displacements is deflected due to the tectomechanical process, then bruises and loosening zones arise up to 600 m from the large-scale displacements as a result of the rock movements on the jumps. If jumps between two adjacent displacement zones are also known here, the position of the zones over greater distances can be determined from the directions in which the displacement zones and the jumps strike.

It is expediently determined whether one of these zones is additionally compressed by the mass transport at the displacements and whether the gas extraction possibility in all relevant areas is determined. This is based on the knowledge that gas could not flow off in squeeze zones during the geological period. However, there are only a few circulation paths, so that the number of boreholes is increased and the additional local loosening measures are increased in order to set useful gas extraction options in these areas.

According to an exemplary embodiment of the invention, starting points of bores are preferably selected in loosening zones which are pressed together by the mass transport at the displacements. The gas could not flow out there due to the pressure. In spite of this, there are circulation paths for the gas, so that gas extraction possibilities are consequently improved.

In the area of thrusting, the design of large-scale displacements is hindered by the tectomechanical process, nevertheless, shearings in the strike direction of the large-scale displacements can be expected. Jumps in the area of the larger displacement zones and displacements are less discarded and run from both sides or start again. At the same time, the shift zones influence the deletion directions of thrust; thrusts also often run out of shift zones. As a result, after the tectomechanical process, snow plow and funnel effects with fractions, loosening and crushing occur, the consequences of which for gas production have already been explained above. According to the invention, the points of intersection of displacement zones and thrusts over greater distances can be determined if punctiform outcrops are present. This allows more precise information on favorable starting points and favorable distractions for the holes to be specified.

The above causal relationships are of interest for gas production in large and extensive deposits, as well as in areas that are less well-known due to drilling and / or seismic, conclusions can be drawn about gas contents, gas contents and gas circulations, so that the best possible results can also be found there The arrangement of the starting points of the gas extraction wells follows. The basics for planning gas production and thus gas production itself have been significantly improved.

From the division of the mountains at certain intervals by larger, approximately parallel displacement zones or displacements that cover longer distances, These zones can be defined in adjacent lanes. The causal connection between convolutional energy or tectonic energy and its reduction with the gas opening in connection with the geometry of the deposit provides evidence of loosening, strains, pressures, material transports in the mountains over longer distances, as well as fractions and intersecting fractions, their local consequences for gas production and their technical arrangement have been explained above.

Mine gas often collects below the overburden. In this context, too, tectonics, depending on the tectomechanical process, influences the gas opening and the success of gas production. Since the large jumps often continue in the overburden up to the surface of the day, there are drainage options for the gas from the mountains after several days. As a result, loosening, pressing, squeezing and slashing in the mountains are also the basis for the area below the overburden for the tectonic arrangement or implementation of gas production as well as in deeper areas.

For the implementation of the invention, it is irrelevant whether the bores for gas production from the deposit are made from above ground or underground.

According to one exemplary embodiment of the invention, the planning basis is improved by taking into account gas contents, gas contents and outgassing results that are actually determined in the form of the configuration of the tectonics, and in particular taking the results into account with and without loosening measures. Specifically, ascertained gas contents, gas contents and gas inflows and their differences allow information about the behavior of the tectonics, so that this also results in the best possible arrangement of the starting points for the gas extraction holes.

The features of the subject matter of these documents disclosed in the above description and the patent claims can be essential individually or in any combination with one another for realizing the invention in its various embodiments.

Claims (22)

1. Method for establishing the locations for gas extraction wells in a tectonically stressed hard coal deposit which has been the subject of little or no mining exploration, characterised in that the wells are arranged in zones, defined taking account of the tectonics, with large gas reserves and adequate gas circulation, whereby - in addition to the dip, the strike and the throw of the faulting - the disaggregation, crushing and compression caused by the tectonic energy and the tectonic mass transportation influenced by the latter are used as a planning tool.
2. Method according to claim 1, characterised in that the pattern of the folding energy is defined at movement barriers and unrestricted movement zones and the gas reserves are determined for the sections of the deposit investigated.
3. Method according to claim 1 or 2, characterised in that the wells are arranged at a relatively long distance from disaggregation zones on tectonic faults which continue to the surface.
4. Method according to claim 1 or 2, characterised in that the wells are arranged in areas where there is mass transportation close to crushing or compression.
5. Method according to claim 4, characterised in that the wells are arranged in areas of compression on faults with a relatively large throw.
6. Method according to claim 1 or 2, characterised in that the wells are arranged in the run-out zone of overthrust faults with bedding slip.
7. Method according to claim 6, characterised in that the wells are arranged in the area of disaggregations on overthrust faults with a change in the direction of strike.
8. Method according to claim 7, characterised in that the wells are arranged in the area of an overlying snow plough effect with bedding slip in the presence of overthrust faults with changes in the direction of strike.
9. Method according to claim 7, characterised in that the wells are arranged in a pattern which is parallel to the overthrust fault in the presence of crushing or compression at a distance of less than 900 m on a fault delineating a fault block.
10. Method according to claim 7, characterised in that the wells are arranged in a pattern which is parallel to the overthrust fault in the presence of snow plough and funnel effects at a distance of less than 900 m in the area of an overthrust fault.
11. Method according to claim 1 or 2, characterised in that the wells are arranged in anticlinal areas with convex bending axes and between overthrust zones and displacement zones.
12. Method according to claim 1 or 2, characterised in that the wells are arranged in areas in which the mass transportation, caused by tectonics on displacements, strikes an adjacent fault block.
13. Method according to claim 1 or 2 characterised in that the wells are arranged in areas where displacements and overthrust faults meet.
14. Method according to claim 1 or 2, characterised in that the wells are arranged in areas where there is an intersection between overthrust faults and displacements, both of which are running out.
15. Method according to claim 1 or 2, characterised in that the wells are arranged in areas where there is a bedding slip in two directions.
16. Method according to one of the claims 1 to 15, characterised in that the wells are arranged in the centre between two displacement zones.
17. Method according to one of the claims 1 to 15, characterised in that the wells are arranged at a greater distance than 400 m from the intersections between the faults and the displacement zones.
18. Method according to one of the claims 1 to 15, characterised in that the wells are arranged in disaggregation zones which are pressed together by mass transportation on displacement zones.
19. Method according to one of the claims 1 to 15, characterised in that the wells are arranged in disaggregation zones of faults in the area of displacement zones and interlayered bedding zones.
20. Method according to one of the claims 1 to 19, characterised in that the wells are concentrated in the area under a cap rock.
21. Method according to one of the claims 1 to 20, characterised in that additional disaggregation measures are undertaken depending on the tectonics of the boreholes sunk.
22. Method according to one of the claims 1 to 21, characterised in that gas concentrations, gas content and gas emission results are included in modelling the tectonics with and without disaggregation measures.