DE102013001555A1 - Method for improving the processing in reflection seismics - Google Patents

Abstract

For the iterative improvement of the processing in the reflection seismic on the PC or with the help of EDP with the help of an appropriate software interference signals of the geophones, not interesting head waves and unusable signals / waves sorted out. In addition, the tectonic stress of the mountain and the resulting rock and reservoir geometry are iteratively adjusted by stacking the loops. Dislocations, discarding changes and / or changes in the suspensory dimensions and / or displacement values are introduced into the processing and the consequences for the neighboring mountain areas are incorporated.

Description

The invention relates to a method for iteratively improving the processing in the reflection seismic on the PC or the computerized by means of an appropriate software, wherein based on the raw data interfering signals of the geophones, the head waves not interesting and indistinct and unusable signals / waves sorted out and on the wave structure the lowest dislocation values are determined and from this the finished seismogram (base model) is processed.

The seismic wavelengths of the reflection seismic limit the resolution of discontinuities in the rock geometry down to a size of 15-20 m. This fact is actually for the economic mining of minerals and / or for the oil, gas and / or water production and / or the start-up of routes and / or tunnels and / or landfill of water and / or air hazards and / or polluting substances and / or insufficient to deal with earthquake problems. The reflection seismic method is a method for the determination of layer boundaries in the subsurface, whereby the measurements aim to gain knowledge about the structure of the subsoil from the reflected P-waves and to determine and represent the geological interfaces. These seismic waves are generated artificially, whereby these waves, which are usually generated by seismic explosions or vibrations, propagate underground and are then reflected and refracted at interfaces. Part of the reflected wave field returns to the surface, where the corresponding data is recorded via geophones. After processing, ie the processing of seismic data in the reflection seismic investigations, a seismogram is available from which the position and depth of these determined layer boundaries can be seen. This interfering signals and unusable waves are turned off during processing, so that then results in the above-described image, in which by the limited resolution a mostly limited seismogram can be obtained.

The invention is therefore based on the object of substantially improving the possibility of interpretation of seismic profiles determined via the known reflection seismics and, if possible, extending them down to the millimeter and nano ranges.

According to the invention, this object is achieved by supplementing the suspensions and deportations ascertained via the seismic measures beyond the resolution accuracy / detectability limit of seismics and transforming them into the basic model, that the equidistances are then refined by locating their corresponding blade displacements, then the coarse tectonics of the tectomechanical Linking the blade displacements is incorporated or completed, whereupon the small tectonics built into the base model and thus refined to tektomechanischen reservoir model and this is iteratively adjusted by further tektomechanische Verwurfsänderungen and / or changes Aufschiebungsmaße and / or displacement values and adjacent mountain areas. Through the use of seismic and tectonic knowledge advantageous data and documents are to be obtained for the decision on costly measures (drilling).

Basically, tectonic relationships in the field of many deposits and other areas are known, these tektomechanischen relationships determine the mountain and deposit geometry. There are recurrent connections in the rock geometry. This fact makes it possible to apply the mountain geometric findings to improve the interpretation of reflection-seismic profiles down to the millimeter and nanoscale with the help of the benefits of tektomechanischen local conditions and thereby transferred to the processing of reflection seismics. This is done by iteratively adapting the seismic evaluations to the tecto-mechanics of the mountains by stacking the loops and vice versa. Furthermore, it happens on the basis of the dislocations detected and / or detected by the wave structure and the gradual reduction of these dislocations. This means that the discard change and / or change of postponement measures and / or offset values are usefully incorporated into the processing. This is done by considering the consequences of the change in the neighboring mountain or reservoir areas. The gradual reduction of dislocations and their consequences are iteratively carried out down to the millimeter and nano range in order to record all technically relevant tectomechanical structures. The values determined by drilling are also incorporated into the tectomechanical deposit model in this way. There are recurrent connections in the rock geometry. This fact makes it possible to obtain the mountain geometric findings ( DE 43 39 418 A1 . EP 0 760 900 B1 and EP 0 861 365 B1 ) to improve the interpretation of reflection seismic profiles down to the millimeter and nanoscale using the benefits of tectomechanical local conditions and thereby improve the processing of reflection seismics. With the help of this iterative approach and thus the incorporation of small-scale tectonics and other findings, it is possible, Kluftsysteme in the mountains above the carbon to determine which are adapted to forward the gas according to or store below a corresponding mountain layer, so that after detection of such a fracture system and corresponding tektomechanischer stresses this area can be targeted drilled to win the gas there.

It is advantageous if according to the teaching of the invention in the suitably adapted tektomechanische deposit model technical variants, for example, the distractions of holes regarding installed and selected from the corresponding technical proposal and incorporated into the final tektomechanische reservoir model. The findings determined by the method according to claim 1 are immediately converted into a technical solution and thus inserted into the final tekomechanische deposit model.

It is also expedient to iteratively transform the consequences of the discrepancy changes and / or changes in the postponement values and / or shift values down to the millimeter and nano range into the refined seismic base model or the tectomechanical deposit model. Thus, the necessary data for the finest process management are built into the deposit model and taken into account.

With the aid of a procedural variant, the pulse systems are iterated and / or the position of the pulse generator and / or the intensity of the pulses varied and / or the frequencies varied until a match to the local tectomechanically created structures of the rock geometry is present. The aim is to exploit the relationships between seismic wave technology and the tectomechanical processes.

A further refinement is possible by adapting the processing and its exploitation of the wave-related systems of the tectomechanical stress of the mountains and / or compression, decompression, crushing and neutral areas in the mountains and / or material transport in the mountains and / or the behavior of the geopressure and the energies and / or the relativity of the energy contents and / or the interdependencies in the large-scale tectonics and / or the interdependencies between large and small tectonics and / or the interdependence between large, small and micro-tectonics down to the millimeter and Nanoscale and / or the entanglements of small and micro-tectonics are determined and used. The tectomechanical connections arise at the same time as the mountain geometries due to the energy that exists in the mountains. In this context arise local energy supply, energy reduction, energy transfer, energy directions and energy content and their three-dimensional changes that need to be considered. In particular laterally to the side acting changes lead to Aufocherungen in the mountains, which reach down to the millimeter range and below. The mountains become anisotropic in this way. This fact influences the behavior of the so-called P waves or compression waves, which act in the mountains with compression and decompression. The resulting heat varies, depending on whether mylonitis in the mountains can occur or not, d. H. how big the mylonitisings are. According to a preferred embodiment of the invention, as described above, the above facts additionally and / or separately from the previous processing used for further processing. This is done by iteratively adapting the seismic evaluations to the rock geometry created by tecto mechanics by stacking the loops. This is also done here, starting from the dislocations that are detected by the wave structure, by the gradual reduction of these dislocations and also by observing the consequences for the neighboring mountain areas. The gradual reduction of dislocation, i. H. the discard change and / or change of the suspending measures and / or shift values are introduced into the processing and their sequences are iteratively performed down to the millimeter and nano ranges for the neighboring areas of the dislocation.

In a supplementary step, the pulse systems can be varied iteratively until there is a match to the tectomechanical structures. The aim is to exploit the relationships between wave technology and tecto-mechanics in order to expand the interpretation of seismic profiles down to the millimeter and nano range and / or to clearly record the rock geometries. In terms of material balance, loosening or decompression, compression or compression, bruising and neutral zones are created.

According to an embodiment of the invention, the material balances are set in relation to the P-waves. In the area of decompressions or loosening, the movements in the mountains caused by the P-waves are greater than in compression or compression areas, where the shear waves are passed through faster. In bruises, mylonitisations are already present. Their activation is usually difficult. In neutral zones, only the pruning sheds, which are related to the different transitions of tectonic energy, as well as the pruning sheds, which are related to the material transport. With the application example Note that the speed of the P-waves depends on the density of the rock. This does not only increase with the depth. It is also different in the same level. This results in a different propagation of the wave velocity.

These facts lead to contradictions and / or incompatibilities and / or mutually exclusive between the interpretations of the reflection seismic profiles and the real results of the tectomechanical stress of the mountains. These contradictions are used purposefully to systematically and iteratively adapt the interpretation to the realities of the mountains. In addition, it is envisaged to apply the mountain-geometric findings that have created the rock geometries to improving the interpretation of reflection seismic profiles down to the millimeter and nanoscale using the benefits of tectomechanical contexts by iterating the seismic evaluations to the tecto-mechanics of the mountain range Stacking and grinding in processing is adjusted. Further gradual reduction of dislocation and its consequences will result in more accurate results.

Also exploited is the fact that the P waves generate heat as they pass through the mountain. This process depends on the shearing of the mountains, d. H. the process depends on the intensity and the direction of one or more culling operations. It is not only the density of the mountains, but also the emergence of mylonite on the shear planes significant. Mylonite arises in this context primarily in Auflockerungs- or decompression areas and less in crushing and compression or compression areas. Of importance is that the static friction passes into sliding friction, which reduces the intensity of the waves and this reduction is vector dependent. Fundamentals for improving the interpretation of seismic profiles with the help of the use of tectomechanical contexts are developed. At the same time, evidence arises for improving the arrangement of reflection seismic measurements and their variations. On the one hand the compression and decompression areas are used on the basis of optimizations of the reflection seismic, on the other hand compression and decompression areas are recognizable from the reflection seismic profiles, d. H. for creating reservoir models.

Further, it is advantageous according to the invention, if in particular the material balances are used for the so-called. S-waves or secondary waves and that if deep water is present. Then the loosening slows the propagation of the S-waves stronger than compressions or bruises. In other words, there is an anisotropy of the propagation of S waves in the mountains. The deep water horizons can be determined advantageously with such a method step.

According to a supplementary embodiment of the invention, the above fact is used additionally and / or separately from the preceding processing for improving the interpretation of reflection seismic profiles, d. H. Technically used for the processing of reflection seismics by iteratively adapting the seismic evaluations to the tecto-mechanics of the mountains by stacking the loops.

Next is exploited according to the invention that the tektomechanische stress of the mountains for mountain areas with different density has ensured. The denser the rock, the greater the speed of propagation. According to the transitional qualities, the direction of the waves is broken. Arches are created over the course of the seismic waves. The permeability (permeability) of the seismic waves is different. Again, this fact is used for improving the processing.

Exploiting the interpretation of seismic profiles by comparing them with tectomechanical relationships is an iterative process. First of all, the structures recognizable in the conventional seismic profiles are read out with discontinuities of more than 15-20 m and placed in profiles and horizontal sections or floor plans. The key is the assignment of the strike directions to the systems, deportations, shifts and postponements. In this case, this assignment initially takes place in compliance with the strike directions valid for the interpretation area.

In this work, the first findings on the tectonic energy arise after an application example of the invention. In addition, there are findings on the emergence of material balances and / or on the probable material transport. Correspondingly, the arrangement of wave generation can already be reduced iteratively and discrepancies in the interpretation system can be eliminated.

It is further provided according to the invention to use the energy supply, energy reduction, energy transfer, energy direction and energy contents for creating the reservoir model or for creating the rock geometry and in conjunction with improving the interpretation of profiles of reflection seismics. there but not necessarily started with the deportations. In the further course of the interpretation, the position of shifts follows. These shifts are presumably a consequence of the dehydration of the mountains. This creates open spaces into which the mountains are more or less pushed horizontally by tectonic pressure or by geoprinting. As these shifts occur at an early stage, the investment and the design of the resulting deportations are affected. This happens according to the nature of balancing the energy content in the mountains. This compensation causes the deportations to change their strike direction, even at the deflections deflected by the displacements, or when the energy effect, which is deflected by the displacements, increases the strike pressure of the geoprint. This happens when the deportation occurs. The same applies to the change of the Verwurfs, because the Geodruck, which acts parallel to the displacements, counteracts the emergence of larger wastes, so that the Verwurf decreases in the range of said displacements. For the same reason, deportations expire or start again. Furthermore, the collapse changes as a result of the strike direction changes of the deportations. This results in new findings with regard to the behavior of energy, material balances and material transports in the mountains. This fact is used in addition to or separate from the previous processing for improving the interpretation of reflection seismic profiles in the manner described above.

As stated earlier, the momentum systems can be varied iteratively until they match the tectomechanical structures. The goal is the extensive exploitation of the relationships between wave technology and tectomechanics. The result is a deposit model, the dismantling of deposits and / or the orientation of the hole in the natural gas, oil and / or water extraction and / or the optimal location, development and / or development of routes and / or tunnels and / or Resolving earthquake problems and / or affecting the surface of the day. The iterative method consists in that, in the case of discontinuities with regard to the recognized tectomechanical relationships, the results are reduced to the basic seismic measurements in order to direct the interpretations to the areas of the discontinuities or differences. This situation is necessary because the seismic profiles do not always allow distinctive interpretations due to the reflection mechanism in the mountains. The explanations on the effect of the tectomechanical stress on the seismic confirm this fact that not always unique interpretations for the current seismic profiles are possible.

In this way, recognized tectomechanical relationships are also introduced for improving the interpretation of seismic profiles. In doing so, the connections between the structures of large-scale tectonics, the relationship between large-scale tectonics and small-scale tectonics, as well as the relation of large and small-scale tectonics to miniature structures are introduced. It was recognized that these relationships are always repeated. This fact is related to improving the interpretation of seismic profiles to the behavior of energy with energy input, energy reduction, energy transfer, energy directions and energy contents and their changes to the side and perpendicular. In other words, the sequence of tectomechanical stress in the formation of the rock geometry is used meaningfully. With regard to the mining of minerals, the position and intensity of the shear and its entanglement give rise to the magnitude of the tectomechanical stress of a region. This fact is essential for the profitability of mining operations. This decreases with the intensity of the tectomechanical stress. This means that the mines in less stressed areas are economical and serve the capital service for the previous run-ups. Areas that are spared from custody absorb tension in the mountains. The tension is not reduced by mini movements on existing shear surfaces. Tension can be reduced by first removing the less stressed areas. In this case, no voltage islands, which lead to rock strikes. In addition, the mountain damage situation is significant. In this context, more heavily used areas take up the movement processes in the mountains stronger. The above-ground depressions become flatter and even. Harmful effects decrease strongly. The strike direction of the said shear shears is essential for the optimal mining directions. Shearing, which run perpendicular to the mining directions, lead to stronger eruptions of the mountains in the field of mineral extraction. Improving the interpretation of reflection seismic profiles directly influences the technical-economic degradation of minerals. By improving the interpretation of reflection seismic profiles, the exact location of shifts is detected. The early emergence of the shifts is due to the state of knowledge back to the deposition area. This means that there is a connection between washouts and the displacement systems. Improving the interpretation of reflection seismic profiles early eliminates these areas for degradation.

Location, behavior and optimal expansion of the routes are dependent on the tectomechanical stress. In bruising areas as well as in areas with entangled shearing the routes are worse and are costly. Improving the interpretation of reflection seismic profiles down to the millimeter and nanoscale makes the system of track emergencies much more efficient. Location and expansion of the tectomechanical stress can be correspondingly better selected, especially by a stronger expansion and / or a shorter construction distance is generally used in routes in tectonically more damaged areas.

The extraction of oil, natural gas and / or water depends on the quality of the circulation routes in the mountains. The recognition of the pruning by improving the interpretation of the reflection seismic profiles serves to recognize these circulation paths. Their quality depends on the compression and decompression in the mountains. The decompresses, which are essential for a good circulation, are recognized including their boundaries. According to the invention it is then envisaged that in the orientation of extraction wells the derrick with equipment and the casing will use the result of the iterative improvement of the processing as a basis, in particular the casing will be reinforced in areas of greater stresses in the mountains.

In order to be able to safely deposit air- and water-hazardous substances, it is advantageous if the potential circulation paths determined by the iterative improvement of the processing are glued. You need areas that are compact and therefore not pared down. Such areas are directly related to the tectomechanical stress of the mountains. This leaves areas unaffected and often for millions of years. Improving the interpretation of reflection seismic profiles provides essential foundations for finding compact areas in the mountains for landfilling hazardous substances.

The earthquake problems are dependent on the changes in the rock geometry, if the changes are not continuous but jerky. There is therefore a direct connection between the emergence of rock geometries and the problems of earthquakes. Due to the tectomechanical stress of the mountains and the related improvement of the interpretation of reflection seismic profiles, the solving of seismic problems is classified in the overall context of all underground activities including the movements of the surface of the day or of the s. Where there are strong shearing, continuous movements can be expected. Where such shearing is missing, stress concentrations are to be expected. Earthquake-preventive measures receive an additional basis.

According to the invention, it is advantageous to use the iterative improvement of the processing of reflection seismics for the determination of areas susceptible to stress in the case of earthquake problems, in which case stress relief holes are drilled and / or stress blasting is carried out in the areas susceptible to stress. The tectomechanical stress on the mountains and the associated improvement in the interpretation of the reflection seismic profiles thus classifies the solving of seismic problems as part of the overall context of all underground activities, including the movements of the surface of the day or the seafloor. Where there are strong shearing, continuous movements can be expected. Where such shearing is missing, stress concentrations are to be expected. Earthquake-preventing measures thus receive an advantageous interpretable additional basis.

Improving the interpretation of seismic profiles is, according to the invention, an iterative method that combines processing with the geometry of the rock created by the tectomechanical stress and blurring within the seismic profiles of the reflection seismic and / or contradictions and / or incompatibilities and / or each other exploits the exclusive between the seismic profiles and tektomechanischer stress of the mountains to improve the processing and / or adjust the creation of seismic profiles the tektomechanischen conditions. In this case, the tectomechanical relationships of the rock geometry and / or the densities of the rock determined by the tectomechanical stress and / or the shear rates therein are used as an influencing mechanism for the generation of heat and thus for reducing the wave energy and / or the P or shear waves and / or the S and secondary waves respectively are used for improving the values and / or the processing of the reflection seismics is adapted to the results of the tectomechanical relationships. It is further provided that pre-processing and / or speed analyzes and / or migration and / or diagrams and / or reflection seismics to consult and / or reprocess the seismic data and / or other data arise and / or the processing EDP-moderately to the Tektomechanik of the mountain range iteratively by stacking the loops, starting from the dislocations captured by the wave structure and iteratively adapting the gradual reduction of the dislocation and its consequences for the neighboring mountain areas to the millimeter and nano range. It is further provided that the arrangement of the pulse systems are varied iteratively and / or that the processing and its exploitation of the wave-related systems with the tektomechanischen stress of the mountains and / or that by the processing of the decomposition of deposits and / or the orientation of holes at natural gas and / or oil and / or water extraction and / or in determining the optimal location, development and / or development of routes and / or tunnels and / or solving earthquake problems and / or the protection of the surface of the day the mountain geometry Reality compliant considered and introduced.

Further details and advantages of the subject invention will become apparent from the following description of the accompanying drawings in which a preferred embodiment with the necessary details and individual parts is shown. Show it:

1 a seismic deposit profile according to the prior art,

2 corresponding, iteratively revised seismic deposit profile,

3 a gem. Prior art adjusted base model,

4 the reservoir model, which was iteratively revised around the gross tectonics and the other determined values,

5 the 4 appropriate and supplemented by deflection variants of the hole deposit model,

6 the iteratively revised deposit model with the final technical solution proposal,

7 another deposit profile determined by seismic and

8th one 7 corresponding iteratively revised seismic deposit model.

The profile section containing only seismic data is in 1 shown and with 1 designated. Recognizable in this deposit profile 1 , so the seismic profile section the layers of Buntsandseins 2 , the Zechstein 3 , the red-faced one 4 and the underlying carbon 5 , The corresponding limits are at least hinted at in this seismic profile. With 6 is called a jump of several meters while other disturbances here at the seismic reservoir profile 1 are not identifiable. With 10 is the previous production hole, where it can be seen that the old endpoint 16 the production well 10 in an area below the Rotliegende 4 lies. This production hole 10 has come to a standstill with her production output. By this time, around 560 million cubic meters of gas have been produced. The promotion then had to be stopped because of large inflow of water. With the help of the method according to the invention was the reservoir profile 1 iteratively revised and determined an area that could be expected due to the found fracture systems and its location below the gas impermeable layers a satisfactory gas yield. With 13 Two areas are marked where the seismic results are so unclear that unambiguous tectonic structures could not be identified. 21 is the depth indication and 22 the geophone display of seismics. 24 is the day surface and 25 generally the overburden. After application of the method according to the invention and determination of these new hilly mountain areas, the production well was deflected as described further below and propelled into this area, with approximately 150 cubic meters of gas being pumped anhydrous last year.

2 shows the final result of the method according to the invention. It is recognizable that in addition to large-scale tectonics 6 from the seismic profile further influences of the mountains with the marks 7 . 8th . 9 are designated and reproduce a complementary tectonics. It is made clear by this 2 that through these iterative measures it was possible to prove that below the Red Lies 4 Zones are present, which you see as a broken area 14 can identify. Numerous influences of the mountains have meant that even in anhydrous anhydrite in the area of transition Zechstein 3 , Rotliegendes 4 , Carbon 5 the anhydrous anhydrite is so disturbed that it could operate optimally as a gas bearing over time. Therefore, this area can be considered a new production area 15 or target area 20 be designated. As a larger area, it can also serve as an area of expectation 26 be considered.

Because of the iterative work after the 3 . 4 and 5 it was recognizable that by distraction of the production bore 10 the expectation area 26 or the destination area 20 was reachable. This deflection variant bears the reference numeral 11 , The results of this displacement variant available in the meantime 11 have shown that with the help of these iterative works a huge gas deposit has been developed. While at the old location a total of around 560 million Cubic meters of gas could be extracted from the current production area already in a year about 100 million cubic meters of gas (anhydrous).

The following 3 . 4 and 5 show the individual iterative steps, taking 3 First of all, the adjusted seismic deposit profile is displayed. Here are the individual layers clearly visible and also with the 13 designated special, unidentifiable tectonic structures. This in 4 reproduced deposit profile 1 . 100 shows how iteratively the more or less known gross tectonics 6 by supplemented tectonics 7 . 8th . 9 Can lead to expectation 26 or even new production areas become apparent, which can be expected in the present case, a gas accumulation. This supplemented tectonics 7 . 8th . 9 is the result of evaluations of various wells and findings from other areas of the Carboniferous and its overburden 25 ,

Out 4 recognizable are now different borehole deflections 11 . 12 been considered, with which one the target area 20 or the new production area 15 can reach low. From these considerations and calculation is then after 6 a deflection variant 11 ' been developed at the beginning of the deflection and the given borehole radius 19 placed so that there is the shortest possible additional drilling effort. With 18 is the new end of the deflection 11 ' which lies exactly where the expected gas reserves can be optimally This image of the iteratively revised deposit profile 1 . 100 will now be like in 2 associated with the seismic profile, creating a new reservoir profile 100 results.

The 7 and 8th show a seismic deposit profile 1 , comparable to 3 , where another deposit is shown here. It is clear that, in turn, only a limited knowledge of the large tectonics from the seismic profile 1 is removable. With these documents it was not possible to judge in the least whether there were any other areas of gas storage in this area. 8th shows the new deposit profile 100 in which like in the 3 . 4 and 5 shown, iterative further tectonic findings and technical considerations have been incorporated. While initially with the old production hole 10 from the old production area about 4,000-5,000 cubic meters of gas per hour were to be gained, this occurrence ended after about 95 million cubic meters of production. The production well 10 should be stopped, because at last only about 4,000 cubic meters per day or about 160 cubic meters per hour were to win. Thereupon this deposit profile became 1 revised with the help of the method according to the invention and it turned out that a new production area 15 from which 20,000-30,000 cubic meters of gas per day can currently be extracted. It can be assumed that around 1 billion cubic meters of gas will continue to be generated from this production area in the near future.

All mentioned features, including the drawings to be taken alone, are considered to be essential to the invention alone and in combination.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4339418 A1 [0005]
• EP 0760900 B1 [0005]
• EP 0861365 B1 [0005]

Claims (13)

Method for iteratively improving the processing in the reflection seismic system on the PC or with the EDP with the aid of an appropriate software, whereby on the basis of the raw data disturbing signals of the geophones, the non-interesting head waves and indistinct and unusable signals / waves sorted out and on the wave structure the lowest dislocation values determined and from the finished seismogram (base model) is processed, characterized in that the determined by the seismic suspensions and deportations beyond the Auflösungsgenauigkeits- / detectability limit of seismics addition and transformed into the base model, that then the Equidistanzen by localization of their corresponding blade shifts then the gross tectonics of the tectomechanical linkage of the blade displacements is incorporated or completed, whereupon the small tectonics are incorporated into the basic model and thus to the tectomechanical bearing refined model and iteratively adjusted by further tektomechanische Verwurfsänderungen and / or changes in Aufschiebungsmaße and / or displacement values and their consequences for the neighboring mountain areas. A method according to claim 1, characterized in that incorporated into the suitably adapted tektomechanische deposit model technical variants, for example, the deflection of bores regarding and selected from the corresponding technical proposal and incorporated into the final tektomechanische reservoir model. A method according to claim 1, characterized in that the processing EDV-moderately adapted by stacking the loops. A method according to claim 1, characterized in that the consequences of the Verwurfsänderungen and / or changes of the Aufschiebungswerte and / or shift values are iteratively transformed into the refined seismic base model down to the millimeter and nano range. A method according to claim 1, characterized in that in the reflection seismic arrangement of the pulse systems iteratively and / or the position of the pulse generator and / or the intensity of the pulses is varied and / or the frequencies are varied. A method according to claim 1, characterized in that the processing and its utilization of the wave technical relationship systems of the tectomechanical stress of the mountains is adjusted and / or compression, decompression, crushing areas and neutral areas in the mountains and / or material transport in the mountains and / or the behavior of geopressure and energies and / or the relativity of energy contents and / or the interdependencies in large-scale tectonics and / or the mutual dependencies between large and small tectonics and / or the interdependencies between large, small and micro-tectonics up to the millimeter and nano range and / or the entanglements of small and micro-tectonics are determined and used. Method according to one of the preceding claims, characterized in that the iterative improvement of the processing of reflection seismics according to the preceding claims for the technical-economic mining of deposits (minerals) and / or for the economic orientation of the holes, especially the extraction wells in the natural gas , Oil or water industry and / or for the optimal location, development and / or development of routes or tunnels and / or for the resolution of earthquake problems and / or for the protection of the surface of the day. A method according to claim 7, characterized in that selected by the iterative improvement of the reflection seismic processing, the less loaded by small and micro-tecnology areas for the mining sequence and / or for the startup of equipment and device lines in minerals mining. A method according to claim 7, characterized in that the degradation direction is not selected parallel to the strike direction of the shearcuts and / or unfavorable strike directions of small and micro-tecnology in longwall extension expansion caps are used. A method according to claim 7, characterized in that in stretches in tectonics more heavily damaged areas basically a stronger expansion and / or a shorter construction distance is used. A method according to claim 7, characterized in that in the orientation of extraction holes of the derrick with facilities and the piping is the result of the iterative improvement of the processing used as a basis, in particular the piping is reinforced in areas of greater stresses in the mountains. A method according to claim 7, characterized in that in the landfill of hazardous substances, the potential, determined via the iterative improvement of the processing circulation paths are bonded early. A method according to claim 7, characterized in that the iterative improvement of the processing of the reflection seismic is used to determine voltage hazardous areas in earthquake problems, then drilled relaxation holes and / or relaxation blasting carried out in the voltage hazardous areas.

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