CS268667B2 - Method of spaces volume determination,especially of underground ones - Google Patents

Abstract

The invention relates to a method for determining the spatial content of spaces, especially subterranean spaces, such as for example cavities, caverns, caves and the like. The essence of the invention resides in the fact that the volume of a medium filling the space being studied is changed by a sudden and short-lived increase or decrease in volume. In this arrangement, the pressure prevailing in the space before the change in volume is measured, as is also the pressure change which takes place as the effect of the change in spatial content, and then the desired spatial content of the space is determined by calculation from the values measured. As a result, the spatial content of spaces of any desired volume and of widely varying morphology can be determined much more accurately and cheaply than in the past.

Description

(57) This is a way of determining the volume of space, in particular underground, such as cavities, caverns, caves, corridors and the like. The principle is that the volume change of the homogeneous medium filling the examined area is made by an explosion and the volume of the space is calculated according to the formula I

V = ---- 'I

c. kde p where V is the volume of the measured space v * c is the compressibility of the medium in MPA 1, Δ V is the sudden pressure drop and Δ p is the pressure change in MPa.

CS 268 667 82

CS 268 667 B2

The invention relates to a method of detecting the volume of space, in particular groundwater, e.g. voids, caverns _c caves, tunnels and the like *

Under the Earth's surface, various cavities, such as caves, caverns, caves in the rocks and the like, have naturally formed in the past. In part, these areas can be identified by conventional methods of geological research. Cavities filled with water or hydrocarbon, which are predominantly at greater depths, are drawn to the depth of the drill during deep-drilling research; or which is observed. In the extraction of solid minerals, water bursts generally indicate that a cavern or underground cavity has been hit or hit.

Human activities have also created underground cavities in many places, such as cellars, mine corridors or passages, recesses, lines and the like, which were later left without foundation, so that their removal or disposal is only necessary now.

Naturally created or artificially created underground cavities are mostly associated with permeable rocks.

Knowledge of the size of underground cavities is important, for example, from the geological point of view, it is also important for the hydrocarbon and solid materials to be transported and mined. Therefore, those skilled in the art are constantly striving to determine the dimensions or content of these cavities.

For example, caves are mapped and their size is determined from the data and maps obtained.

Another method is to assume the drill downs that have occurred during the opening of the oil field and the interruption of flooding to the existence of caverns, but according to the data obtained, their dimensions are estimated only.

Also known is the detection of underground cavities or caverns by the geophysical method.

A method for determining the bore volume is known, in which a flushing liquid of a different density is fed to the borehole and the volume of both liquids is measured. This method can only be used if the bore can be completely filled. The disadvantage is that according to this method the volume of the cavity is not determined. Furthermore, it is virtually impossible to completely close natural cavities. many thousands of cubic meters and fill them with liquid. Underground cavities are also often associated with the atmosphere. The measurement is also inaccurate as it is performed in dynamic proportions.

However, the above-mentioned known methods can only determine the dimensions of the underground cavities very inaccurately, which does not correspond to the modern requirements, since the dimensions must be known for cavity research and mapping since the cavity under investigation can be associated with other concealed cavities. Only one cavern dimension can be determined from the depth drill, but due to the very complex morphology of the caverns, it is practically impossible to estimate its actual size. In geophysical methods, multiple reflections adversely affect measurement accuracy. Adjusting the amplitude of the transmit signal can only lead to positive results in cavities with really regular contours.

It is an object of the present invention to overcome the above-mentioned drawbacks by providing such a precise measurement method that can be used generally to measure the size of underground cavities.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a method for determining the volume of an underground cavity by which the size of an underground cavity, regardless of its shape and surface contour, can be determined much more accurately than using other methods.

This object is solved by the invention, which is based on the fact that the volume change of the homogeneous medium filling the examined area is carried out by an explosion and the volume of the space is calculated according to the formula

^V in ^{V =} c. Δ P where V is the volume of the measured space vc is the compressibility of the medium in MPa ¹ , βν is the sudden pressure drop and Д p is the pressure change in MPa.

CS 268 667 B2

The most important advantages of the method according to the invention are that by its application it is possible to determine the volume of spaces of any volume and any morphology, for example in underground cavities, much more precisely than in the known methods. The measuring devices required for carrying out the method according to the invention increase the purchase cost relatively little. The half-turn valve * shown in the examples * can be replaced, if necessary, with any known valve * suitable for the purpose. The change in volume according to the invention can also be operated with ease and with low operating costs, as shown in the examples.

The invention is illustrated in more detail by the following examples.

Example 1

In the oil field, a probe was drilled to a depth of 208 m with a casing with an inner diameter of 0.115 mm, but the probe was further excavated. By further drilling, the deep drill reached a depth of 2187 m of karst limestone, whereupon the irrigation liquid was lost. This probe could not be completed and retracted according to the state of the art and was therefore abandoned. .

Later, however, oil field mining required refinement and re-commissioning. However, even by injecting 231 m @ 2 of cement, gel and other base material, the probe failed to equip as needed and complete its execution. Therefore, the determination of the cavern area and cavity system associated with the probe has become current again, and this time the method of the invention has been performed.

A high-precision pressure measuring device was placed on the probe head and was able to report pressure changes of 1 Pa. Pressure evaluation devices with such a precise scale are known and can be used for this purpose.

Furthermore, a device, known in practice as a half-turn valve, has been placed on the probe head, the peculiarity of which is that in one rotation of the opening mechanism the valve opens only for a short time, moment or moment, and closes immediately. At the same time, the current state of the liquid detected at a depth of 132 m was measured.

Thereafter, a pressure of 0.536 MPa exerted by a pneumatic compressor was applied to the probe head, which was the first step of the preparatory operations. The pressure values given on the measuring device were recorded. Depending on the magnitude of the pressure on the probe head, the water pressure in the probe has dropped. The water level in the probe has dropped by approximately 50 m.

The volume of the respective cavity has been determined in the present case according to the invention in such a way that the opening of the half-turn cock suddenly and for a short time only expelled the air. As a result of the air bleed, the pressure at the probe head dropped by 927 Pa and this value was recorded by the measuring device. Part of the discharged air volume was filled by infiltration water into the probe, and the pressure on the probe head stabilized at a value of 541 Pa lower than the outlet pressure.

After performing these operations or measurements, the effects of adiabatic temperature changes in the system, which means the measuring instrument together with the probe, have been taken into account for calculating the cavern dimensions, since the process can be considered adiabatic due to the rate of pressure change. the hydrostatic conditions do not change to the probe, since a portion of the discharge air in the probe is occupied by the water flowing from the layer. The pressure changes observed were continuously recorded in the described case.

The size of cavern 2600 was determined according to the procedure described above.

Example 2 ‘

Oil between one refueling station on the oilfield and the main collection station was transported through a steel pipe - 6868.25 m long, with an internal diameter of 95.4 mm and a wall thickness of 6.3 mm. Along the pipeline, the high-precision measuring devices described have been provided

CS 268 667 B2 in connection with the description of example 1 with a fine scale, namely that the supply points were 1,680 m, 3,670 m and 6,870 m away from the refueling station. The volume measurement according to the invention was necessary in this case which is used to clean pipelines, between 3,670 m and 6,860 m, often stuck. In order to accurately determine where the equipment was interrupted, volume was required.

In order to carry out the method according to the invention, at the point of feeding the pipes in the refueling station, a known 288 cm @ 1 sampling vessel was connected outside the half-turn tap mentioned in the description of Example ¹ .

The outlet pressure was measured first. Then, by opening the half-turn cock, oil was suddenly discharged from the pipeline into the sampling vessel until it was completely filled. As a result of the sudden discharge, the oil pressure in the pipeline decreased by 13.963 KPa, resulting in a narrowing of the flexible pipeline. A shrinkage of 47.5 cm ¹ was found.

Pressure changes have also been observed after oil has been released. Due to the known oil pressure readability factor of 4.7 x 10 MPa, it was found that from the total pipeline volume, that is 49.1 m3 on the path between the stop of the pipe cleaner and the supply point, 38.5 m ^{1 of} pipeline was lost. volume. From this data it was possible to calculate the distance of the pipe cleaner from the supply point, which was 5 380 m.

Example 3

In the cellar of an unknown object, which is connected with its outer surface only to a limited extent, for example through a closed door, its volume could be determined by filling with a foundation.

In this case, the method according to the invention is carried out by placing a highly sensitive pressure measuring device in the cellar space as described in connection with the description of the embodiment of the method according to the invention in Example 1. The air volume increase in the cellar space was caused by a sudden opening a half-turn valve acting as an explosion of a gas cylinder containing 0,078 m ^{1 of} nitrogen at a pressure of 0,65 MPa. As a result of the detonation, the pressure in the basement under investigation increased by 530 Pa, which was disposed of by the pressure of the external atmosphere.

By the method according to the invention, the cellar air pressure before and after the explosion was measured and recorded as a change in pressure. From these data it was possible to calculate the cellar volume, which was 950 m ¹ .

The invention is particularly useful in the extraction of oil and petroleum gas.

Claims (1)

SUBJECT OF THE INVENTION Method of determining the volume of spaces, especially underground ones, such as cavities, caverns, corridors and similar natural creations, by varying the volume of the medium filling the study space by measuring the pressure values before and after the volume change Its volume is determined, characterized in that the volume change of the homogeneous medium filling the examined space is carried out by an explosion and the volume of the space is calculated according to the formula '. c. Kde p where V is the volume of the measured space in m ¹ , c is the compressibility of the medium in MPa is the sudden pressure drop а Д p is the pressure change in MPa.