EP0105967A1 - Method and apparatus for the investigation of the structure and permeability of soil and rock formations - Google Patents

Abstract

A method is created with the help of which the structure and permeability of earth and rock areas can be examined. The method consists in introducing a measuring gas into the examination area and, after penetrating the examination area, collecting and measuring the measuring gas again at several points, it then being possible to draw conclusions about the structure and permeability of the examination area from the measurement data of the different measuring points. The method is particularly suitable for checking dams and for locating underground cavities and tectonic disturbances. In addition, devices for performing the method are disclosed.

Description

The invention relates to the study of the structure and permeability of earth and rock areas and creates methods and devices for performing such studies.

Experiments on the horizontal spread of natural gases in trenches have shown that the length of the spreading zone in the trench axis depends on the permeability and moisture of the soil or layers of soil. Furthermore, it is known from DE-OS 2 705 584 that the areal expansion of gases injected under pressure is dependent on the density and moisture of the soil. These findings are also already being used for a method for checking the tightness of underground oil pipelines.

It is the object of the present invention to create a method and devices on the basis of the diffusion of gases through earth and rock, with the aid of which it is possible to examine the structural and permeability conditions in earth and rock areas, natural or artificial dams Check seepage paths and strength behavior, check the barrier layers produced to prevent rinsing and flushing, locate underground cavities, determine tectonic structures and detect other faults in the subsurface structure and in the structure of fillings, in an economical and at the same time harmless manner.

The solution to this problem is characterized in the main claim. According to the invention, measurement gases are thus passed through the areas or layers to be examined and then collected at various measurement points, the comparison then being made in a grid-like manner distributed measuring points obtained a kind of X-ray image is obtained, which provides information about the structure and permeability of the objects being examined and faults, such as cracks or cavities, can be recognized perfectly. The method can be carried out comparatively economically and, particularly when carbon dioxide is used as the measurement gas, has no adverse consequences for the object under examination.

In the claims 2-11 special configurations of the method for different application purposes are characterized. Finally, claims 12-17 specify devices which ensure a particularly expedient implementation of the inventive method.

• Fig. 1, 1A, 2, 2A,2Bein erstes Ausführungsbeispiel der Erfindung in Anwendung auf die Überprüzweites fun^g eines Dammes,
• Fig. 3 ein^/Ausführungsbeispiel der Untersuchung eines und ^3A Damm-Untergrunds und einer Überprüfung einer dem Damm vorgelagerten Sperrschicht, und
• Fig. 4 ein Ausführungsbeispiel der Ortung eines unterirdischen Hohlraums und der Feststellung tektonischer Verwerfungen.

Details of the method and the devices are explained in more detail below on the basis of specific application examples in conjunction with the drawing. Show on the drawing:

• 1, 1A, 2, 2A, 2B, a first embodiment of the invention in application to the check ^g funz a dam,
• 3 shows an ^/ exemplary embodiment of the investigation of a and ^3A dam subsoil and a check of a barrier layer upstream of the dam, and
• Fig. 4 shows an embodiment of the location of an underground cavity and the detection of tectonic faults.

As a first embodiment of the invention, the control of the permeability and settlement conditions of a dam is explained below. Before the description of the measuring and control device with reference to FIGS. 1 and 2, the general principles and the method are first to be explained.

As mentioned earlier, it is through experimentation It is known about the horizontal spread of natural gases in pipe trenches that the length of the spreading zone in the trench axis depends on the permeability and moisture of the soil or soil layers. It is also known from press-in tests with gases for the purposes of plant fumigation that the areal expansion of pressurized gases also depends on the density and moisture of the soil: the invention now provides a method for checking the permeability and settlement conditions of flushed in or created by artificially poured earth and stone dams, which can be dams of dams, side dams of rivers and canals and dikes to ward off floods and storm surges.

The tightness of a dam against seepage water access is a crucial safety feature with regard to flushing out and uneven settling, whereby increased water permeability is mainly caused by structural changes and cracking and fracturing, which can ultimately result in a dam break. Structural changes and deformations occur, particularly in the upper area of multi-layered, high earth dams, where there may be different settlements between the individual layers of the earth if the construction is uneven. Cracks occur particularly parallel to the perineum axis and transversely or diagonally to it. The transverse or diagonal crack systems, which mostly fall almost perpendicular to the dam body, are of particular importance because they form paths for concentrated seepage, which can lead to erosion of the cover layers and the sealing core of the dam. The formation of horizontal cracks in the sealing core is particularly serious. Such cracks are not recognizable from the surface and are the main cause of intensive seepage and thus dam dams.

The dangers of the occurrence of deformations mentioned and cracking require careful inspection of the dams. To date, there are various methods for monitoring the dams during and after the actual construction phase. The best known methods include measuring the vertical and horizontal movements inside the dam with the help of inclinometers, strain gauges, piezometers and pressure transmitters. However, all previously known methods and constructional measures have the disadvantage that they are financially complex and can only capture locally limited dam elements.

In contrast, a largely safe and less complex control method is now created with the invention. The method is based on the determination and measurement of the flow paths of injected gases. As is known, gases are able to diffuse through the smallest pore cross-sections and pore connection channels if there is a pressure drop. Now dams usually have only a very low horizontal permeability for liquids and gases due to structural compaction or special settlement measures, but horizontal cracks of the type described above enlarge the structure of the

Dam body and thus allow a significantly increased gas passage. If, according to the invention, measuring gas is introduced into the dam under the lowest necessary pressure, a horizontally oriented flow pattern is obtained and a considerable part of the gases introduced can be collected and measured again on the opposite side of the dam. The concentrations of the gases arriving there and the time it takes to flow through the cross-section of the dam represent dimensions for the permeability of the dam. By arranging a large number of measuring points, an "image" of the inner structure of the dam can be obtained, which provides exact information about disturbances, such as horizontal cracks. It is also possible to have cracks parallel to the axis of the dam, more or less perpendicular to the natural subsoil, such as those with disturbed settlement conditions Slope demolitions, shearings and ground breaks can occur. In such a case, the injected gases only initially follow a horizontally predetermined flow path and then merge into the vertically oriented structure, which can be determined by gas measurements on the top of the dam.

The method according to the invention is therefore based on the fact that gases introduced into the dam body under pressure spread along the normal or disturbed sediment structures and normally follow a flow pattern comparable to the electrical potential. If the dams are considerably watertight, only a small part of the injected gases will reach the dam side opposite the injection side after a considerable delay of the order of hours. In the case of horizontal permeability due to crack formation, however, the amount of gases arriving on the other side increases while the diffusion time is reduced. This flow pattern of the injected gases changes, however, in the presence of cracks which are more or less vertical to the dam height and which can be parallel, diagonal or perpendicular to the dam axis. The gas propagation then preferably takes place in these cracks, as a result of which a larger proportion of gas migrates in the direction of the dam crown. Here, too, the concentrations and the time of the incoming gases are a direct measure of the location, size and permeability of the defects.

In particular, carbon dioxide is used as the injection gas, which has the advantage of easy availability, portability and measurability. The risk that CO ₂ with the leachate enters into a compound (H ₂ CO ₃ ) and thus increases the solubility of calcareous and merge-like dam materials is due to the short residence time of the gases in the dam body and the low tendency of C0 ₂ to carbonic acid with water form, negligible. Of course, other gases can also be used for example, methane, propane, S0 ₄ or activated gases are used, provided that they have no high reactivity or solubility with respect to water and dam material and are perfectly measurable or detectable.

A device for controlling a dam according to this method is shown in FIGS. 1 and 2. 1, a dam is designated in FIG. 1, on one side 10a, generally the so-called air side (land side), a gas injection device is provided. In the exemplary embodiment shown, the gas injection device consists of a first unit 11 and a second unit 12. The unit 11 has an essentially rectangular tubular frame, consisting of two vertical tubes 13 and four horizontal tubes 14. The vertical tubes 13 are at their ends closed. With 13a a gas connection is designated. The horizontal tubes 14 open into the tubes 13, i.e. are connected to the interior thereof and have openings in a uniform distribution, from which plastic tubes 15 with shut-off valves 16 extend, to which injection tubes 17 with a sealing cone 17a are connected, as best shown in FIG 1A can be seen. The further unit 12 corresponds essentially to the unit 11. Further units (not shown) can be provided which have rollers by means of which they can be moved on the unit 11, for which purpose the tops of the vertical tubes 13 of the unit 11 are rail-like are trained. This results in an arrangement in the manner of a pull-out ladder. Of course, the "pull-out ladder" can consist of several such units, depending on the height of the dam.

In a practical embodiment, the device 11 has a number of sixteen injection tubes 17 made of light metal with a length of 0.5 m, which are distributed equally between the four horizontal tubes 14. The device 11 has a length and a height of 3 m each. With another unit, a ver the height can be increased to 6 m. It should be pointed out that it is also possible to provide a separate, rigid frame which can optionally be telescopically extended, on which frame one or more units 11 or 12 are then arranged such that they can be rolled. The use of a separate frame provides the advantage that it can also serve as a ladder for the operators when crossbars are attached.

To operate the device, the injection tubes 17 are pushed into the dam or inserted into prepared boreholes, the cones 17a serving as a seal. Then carbon dioxide or another measuring gas under low pressure is supplied to the devices 11 and 12, namely by connecting the measuring gas source 18 (FIG. 2B) to the gas connection 13a or a comparable connection of the device 12. A tank with liquid can be used as the measuring gas source Carbon dioxide with evaporator, carbon dioxide pressure bottles or pressure bottles or containers with methane, propane or sulfur dioxide can be used. For a particularly uniform supply of the gas to the injection pipes 17, it can be advantageous to provide a gas connection not only at the designated point 13a but also on the undersides of the other vertical pipes 13.

Fig. 2 shows the opposite side 10b of the dam 10, generally the water side of the dam, on which the measuring device is provided. The measuring device consists of a plurality of measuring probes 20, each of which is connected according to FIG. 2A via a hose 21 and a solenoid valve 22 to a pipe 23, which is optionally equipped with a vacuum pump 24 or with a gas measuring device 25, preferably for C0 ₂ , connected is. As can be seen from FIG. 2A, each measuring probe 20 is formed by a tube which is perforated in its front region and has a sealing cone 20a in its rear region. In the exemplary embodiment shown, the measuring probes 20 have a length of 20 cm and 10 probes 20 each form a measuring unit, the individual tubes 21 are combined to form a tube bundle. The perforation holes of the measuring probes 20 are expediently arranged in a spiral all around.

First, the measuring probes 20 are pressed or hammered into the cover or insulating layer of the dam 10 or inserted into prefabricated boreholes. The distribution of the measuring probes 20 should be as uniform as possible; the number of measuring probes 20 used depends on the particular circumstances, the "resolution" of the resulting image being better, of course, the closer the measuring probes are inserted. After the insertion of the measuring probes 20, the entire hose system with the probes connected to it are flushed with air and then evacuated. This facilitates gas entry into the probes and the further transport of the measurement gas into the measuring devices 25. After the start of the injection phase by the injection device of FIG. 1, the gas analyzes are called up individually by the probes, ie the individual solenoid valves 22 are opened in sequence and closed again. The analysis result is expediently displayed digitally. The measuring apparatus is provided with a strong diaphragm pump (not shown) which is so powerful that it can transport the gas taken up in the probes 20 via the hose lines to the measuring instruments 25. The measurement of the gas concentrations of CO ₂ , methane and propane by the measuring devices 25 is expediently carried out according to the principle of toning. Appropriate devices are available on the market. There are also various other measurement systems for sulfur dioxide. The output signals of the measuring devices 25 are expediently fed to a display device and / or a printing unit, in particular one with a graphic representation, whereby a kind of X-ray image of the dam structures is obtained and the evaluation is facilitated.

If the measuring lengths are more than 10 m, the individual hose lengths can be increased up to 7 times the. This results in a total of 70 measuring hoses, which are combined in the lower part to form a hose bundle. With a pumping and analysis time of 20 seconds each, a total of about 24 minutes. required to carry out all measurements on a hose strand. If the measuring length of a dam exceeds 70m, another measuring unit 70m long can be used as the second measuring system. With a gas injection width of 3 m on the injection side, the width of the measuring probe system on the receiving side must be about 6 m due to the side scattering effects of the gas. A total of three hose systems are required for the measurement of a 6 m wide section, which, as stated above, can be designed up to 70 m. Every hose system requires a measuring apparatus and an operator.

With smaller dams, the number of measuring points is reduced accordingly. By interconnecting the three hose systems for the 6 m wide measuring front, one can work with one measuring apparatus and with one operator. In the case of such smaller dams, the lateral displacement of the injection and measuring systems is expediently carried out on prepared, horizontally laid light metal rails.

In a second exemplary embodiment of the invention, explained with reference to FIGS. 3 and 3A, it is not the dam body itself that is checked, but rather its geological subsurface. However, this is also about exploring the permeability conditions, e.g. of porous deposits in the floodplains, which can cause the body of the dam to underflow and even cause a hydraulic break, or of rocky rocks. The permeability conditions can be investigated in the natural, untreated dam subsoil and also in the barrier layers treated with cement or other sealing materials.

In Fig. 3, 30 is a dam, in whose you tion body 31 a control passage 32 runs parallel to the longitudinal axis of the dam. From this inspection passage 32, injection bores 33 are now drilled into the dam subsurface according to the invention, namely vertically or at an angle. The boreholes 33 can be partially or completely cased, in the latter case openings at the bottom of the borehole for the injection gas to exit in the pipe wall are to be provided. Furthermore, at least one measuring bore 34 is provided for receiving the injection gases, which preferably extends vertically and is piped in its upper region. The injection bores 33 and the measuring bores 34 are used to check the dam subsoil in the manner described below. Furthermore, a barrier layer, for example a cement injection, is shown at 35 in FIG. 3, which is attached to the water side of the dam 30 and is intended to protect against undermining. An injection bore 36, which is partially piped, and measuring probes 37 on the surface of the earth are used to check this barrier layer 35. 3A, such a measuring probe 37 has a sealing cone 37a and is connected via a hose 38 with a shut-off valve 39 to a measuring device (not shown). The measuring probe 37 is inserted into a prepared bore 40.

The inspection of the dam subsoil is therefore carried out in practice with the aid of one or more injection bores 33 or 36 which are driven vertically or obliquely to a depth of 100 m into the geological subsoil. These bores 33 can also be carried out from the inspection passages 32 of the earth or stone dam 30 after completion of the construction work. The gases introduced into the cased or uncased bores 33 under pressure, preferably carbon dioxide gases or also methane, propane or sulfur dioxide, spread more or less quickly and far underground depending on the permeability of the geological layers, partly also in solution in the groundwater. The spread of these gases in depth is detected by the measuring bores 34, the depths of which essentially correspond to those of the injection bores 33. The spread of the injected gases is not only horizontal, but also to a much greater extent towards the surface of the earth. By making additional shallow measuring bores 37 to 0.8 m deep, it is possible to detect the spread and speed of gas displacement in the subsurface, even on the surface. The injected gas flows into the uncased lower part of the measuring boreholes, which were previously evacuated. The gas is collected in the piped part and fed to a measuring device for measurement via the shortest possible plastic hoses, for example in the manner described in the first exemplary embodiment. Experience has shown that the measurement results are hardly influenced by the gases present or formed in the soil, because the concentrations of the injected gases are significantly higher. Additional surface measuring probes 37 are preferably also provided. In the case of a barrier layer 35 by means of cement injections or sealing veils, the gases supplied through the injection bore 36 are prevented from spreading further horizontally in the subsurface and therefore flow after a short period of time towards the surface of the earth, where these gases can then be collected and measured. Only when the barrier layer 35 is interrupted or inadequately tight will a portion of the gases be able to continue flowing unhindered and accordingly only reach the surface after the barrier layer 35. An interruption of the barrier layer 35 is therefore noticeable in the fact that in the interruption area the measuring probes 37 located in front of the barrier layer 35 absorb significantly less gas than measuring probes in an uninterrupted, dense region of the barrier layer 35. Of course, it is also possible to use further flat measuring probes behind the barrier layer 35 and behind the dam 30 on the air side, which then measure the gas that has passed through the barrier layer 35.

A third exemplary embodiment of the invention, which relates to the detection and location of underground cavities and tectonic disturbances of the subsurface, is explained below with reference to FIG. 4. In Fig. 4, 40 is an underground cavity, 41 is a tectonic disturbance. Voncbr earth surface, an injection bore 42 leads vertically down into the cavity 40, and a plurality of flat measuring probes 43 are arranged on the earth surface.

Underground voids are created by geological processes or by mining work. The geologically determined cavities are sinkholes and caves. Mined cavities are wells, boreholes, shafts, tunnels and device lines for the extraction of raw materials. There are also underground cavities that have been created for military reasons or to protect the civilian population. The location and course of these cavities are in many cases not exactly known. This applies in particular to old mines, which are not measured with the same accuracy as today's underground lines. It is not uncommon for them to be built over due to a lack of knowledge or with insufficient security, which can subsequently lead to subsidence of the overlying soil layers or even collapse of the structures.

The method of the invention can now be used to locate such underground cavities of unknown extent and extension. Under normal rock mechanics conditions, a subsidence cone with directed and widened microstructures forms above collapsed cavities. These structures run towards the hollow body and cause a greater permeability between the underground cavity and the surface of the earth. The fact that gases can spread along such secondary structural zones is now exploited with the invention. For this purpose, 42 carbon dioxide gas or other suitable gases are injected into cavity 40. The gas, which is introduced under pressure and partly also soluble in water, spreads out laterally in the cavity 40, and with increasing pressure, gases diffuse upward over the loosened structural zones, where they are measured by the flat measuring probes 43. The gas-filled cavity 40 is thus, so to speak, using the gases on the surface of the earth. In other words, the measuring probes 43 in area A of FIG. 4 will thus take up gas, whereas the remaining measuring probes 43 remain gas-free. The design and arrangement of the flat measuring probes 43 correspond to the measuring probes 37 in FIG. 3A.

The practical way of locating underground cavities 40 is based on a preliminary investigation of the natural distribution of soil gas above a suspected cavity. The natural gas concentration associated with the formation of cavities gives raw reference values in the loosened structure of the rock about the extent of the cavity and thus a reference point for the preparation of one or more injection holes 42. The second step for the more precise location of underground cavities 40 is then carried out with the help of one or several holes made. The landing point of the bore 42 is, if possible, the cavity 40 itself or the mountains directly affected by it, which is connected to the cavity 40 via the loosened structure. The bore 42 is provisionally piped to just above the loose zones. The sample gases are injected into the cavity 40 under pressure via the head of the piping. During and after the injection, the bottom gas measurements are carried out to determine the gas contents in areas of increased permeability.

A particular advantage of the method of the invention is that, especially when carbon dioxide is selected as the injection gas, no permanent and harmful effects on rocks, floors and buildings are caused because most of the injected gas migrates quickly to the surface of the earth and only a very small part of the gas, about 0.1%, is consumed in the groundwater for the formation of carbonic acid. Carbon dioxide has the further advantage that it can be detected quickly and precisely quantitatively using simple measuring devices. The method can be used to locate cavities that are at depths of up to 200 m and deeper. The other gases mentioned also have no harmful effects, which is related to the high levels of dilution in the layers of earth and rock.

The method just described can also be used to detect tectonic disturbances in the subsurface. If the normal storage of a mountain range is disturbed by fractures (upward and downward movements, active fissures), artificial mass accumulations, such as the construction of dams and buildings or the build-up of dams, can increase the movement processes of the tectonic fractures. On the other hand, such breaks can also be the cause of uncontrolled groundwater flows.

In order to now recognize and locate such fractures 41 (FIG. 4), measurement gases are pressed in under pressure through the injection bore 42, which can be from a few meters to over 100 m deep, which spread laterally in porous layers of the substrate. When these gases reach the area of a tectonic disturbance 41, the gases rise to the surface of the earth via the permeable disturbance layer 41 and are detected by the measuring probes 43 located on the surface of the earth. The tectonic disturbance 41 forms a kind of drainage for the artificially introduced gases. The gases are measured in the same way as when locating cavities. In this case, the flat measuring probes in area B detect gas, while the measuring probes remain essentially gas-free outside this area.

In addition to the exploration of tectonic fractures and fracture systems in the area of planned dams and water storage areas, special areas of application of this method are also storage facilities for secondary gas storage in the deeper underground, natural occurrences of oil and natural gas that are disturbed by fractures, dumps, landfills and dumps, whose permeability should be examined. Furthermore, the invention is also applicable to structures made of only partially permeable material, such as concrete dams with and without iron reinforcement, which have areas of corrosion or cracking systems, the introduction of the gases taking place at appropriate points, for example from existing control bores and / or passageways. If only small amounts of gas can be passed through, then radioactive gases are particularly suitable as measurement gases, because even with the smallest amounts of gas, exact measurements can be carried out using appropriate detectors; preferably one will choose gases that are easy to activate and - for safety reasons - ensure the shortest possible half-life. Otherwise, with low permeability, gases with the lowest possible density will be chosen, for example helium, i.e. gases with great penetration ability.

Of course, not all possible uses of the invention can be exhaustively listed here; it can always be used if the presence of disturbances in the broadest sense can be inferred from the gas permeability of certain soil or rock areas.

Claims (19)

1. A method for examining the structure and permeability of earth and rock areas, characterized in that a measuring gas is introduced into the examination area at least at one injection point and, after penetrating the examination area or a partial area thereof, is again collected and measured at several measuring points, whereby from the time it takes for the measuring gas to penetrate the examination area, and the structure and permeability of the examination area are determined from the concentration of the collected measuring gas. 2. The method according to claim 1 for checking earth and rock dams, in particular for the detection and location of cracks, characterized in that the measuring gas is introduced at one point on the dam side, in particular the air side, into the dam body at several points and on the same as that of the opposite dam side, in particular the water side, and / or is collected again at measuring points on the dam crown. 3. The method according to claim 1 for checking earth and rock dams with inspection passages and / or inspection holes, in particular for the detection and location of cracks, characterized in that the measuring gas is introduced from a inspection passage and / or inspection holes from the dam body at several points and is collected again at measuring points on a dam side, in particular the water side, and / or on the dam crown. 4. The method according to claim 1 for examining the subsoil of earth and rock dams, characterized in that from the surface of the earth, adjacent to one side of the dam, or from inspection passages running in the dam from vertical or oblique injection bores in the dam bottom bored and then a measuring gas is introduced into the injection bores, and that vertical or inclined measuring bores are drilled from the surface of the earth, in particular the other side of the dam, preferably the air side, for receiving the measuring gas penetrating the dam subsurface. 5. The method according to claim 1 for locating and determining the dimensions of underground cavities, characterized in that vertical or inclined injection bores from the surface of the earth into the area of the suspected cavity, preferably into the cavity, drilled and in the injection bores a measuring gas is initiated, and that a large number of measuring points for receiving the rising measuring gas is arranged in the surface above the suspected cavity. 6. The method according to claim 1 for detecting tectonic background disturbances, in particular for locating tectonic fractures, characterized in that measuring holes are drilled from the earth's surface into the subsurface and measuring gas is introduced into the measuring holes and that on the earth's surface in the area above the suspected disturbances or Cracks a plurality of measuring points for receiving the rising measuring gas is provided. 7. The method according to any one of claims 1-6, in particular 5 or 6, characterized in that it is repeated a number of times, new injection holes being drilled on the basis of the measurement results of the preceding process step. 8. The method according to claims 4-7, characterized in that the injection and / or the measuring bores are piped and sealed in their respective head region. 9. The method according to any one of claims 1- 7, characterized ge indicates that the measuring points are combined to form a measuring field with a single detection station, at which an evaluation takes place by means of data processing. 10. The method according to any one of claims 1-9, characterized in that carbon dioxide, - gaseous hydrocarbons and / or activated, in particular radioactively activated gases are used as the measurement gas. 11. The method according to any one of claims 1-9, characterized in that different measuring gases are used, one after the other or at different injection sites. 12. The device for carrying out the method according to claim 2, characterized by an injection device (11, 12) made of tubes or frames (13, 14) connected to one another in the manner of a frame or ladder, tubular injection probes () being connected to the horizontal tubes (14) via hose lines (15). 17) and the vertical tubes (13) are connected to a sample gas source and by means of a measuring device (20, 21, 22, 23, 25) made up of a plurality of tube-like measuring probes (20) which are connected via hoses (21), solenoid valves (22 ) and a common manifold (23) are connected to a measuring device (25). 13. The apparatus according to claim 12, characterized in that a plurality of injection devices (11, 12) are provided, which are preferably connected to each other directly or via a linkage slidably or extensively. 14. The apparatus according to claim 12 or 13, characterized in that a plurality of measuring devices are provided, the measuring devices (25) being connected to a common display element and / or pressure station containing evaluation unit. 15. Device according to one of claims 12 - 14, there characterized in that the injection and / or measuring probes (17; 20) have sealing cones (17a; 20a) at their rear ends. 16. Device according to one of claims 12 - 15, characterized in that the collecting tubes (23) of the measuring device can also be connected to a vacuum pump (24). 17. Device for performing the method according to one of claims 4-7, characterized by a plurality of tubular flat measuring probes (37, 43) with sealing cones (37a) which can be inserted into prefabricated surface bores and via hose lines with a common measuring and display station are connected. 18. The method according to claim 1, characterized by its application for the investigation of structures made of gas-permeable building materials, such as concrete structures with corrosion areas and / or crack systems. 1. A method for examining the structure and the permeability of earth and rock areas by means of gases, characterized in that a measuring gas is introduced into the examination area at least at one injection point and again after penetrating the examination area or a partial area thereof at several measuring points distributed over a large area is collected and measured, the structure and the permeability of the examination area being determined from the time it takes for the measurement gas to penetrate the examination area and from the concentration of the measurement gas collected.

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