RU2179325C2 - Method of geological electric prospecting and gear for its realization - Google Patents

Abstract

FIELD: electric prospecting by method of induction probing of upper part of geological section. SUBSTANCE: method is predominantly applied for detection and survey of zones of tectonically disturbed rocks, for survey of construction sites, for test of condition of filled water-development works, for detection of geoelectric inhomogeneities in tested sections. In agreement with method source of electromagnetic field and receiving magnetic transducer spaced apart are employed. Intensities of magnetic field are recorded with simultaneous lift of source and field meter so placed that axis of receiving transducer is oriented perpendicular to intensity of magnetic field which excludes direct effect of radiator on meter. Measurements are conducted at several specified heights and distribution of electromagnetic field depending on height of lift determines geoelectric characteristics of tested section. EFFECT: decreased ambiguity of interpretation of obtained results with inhomogeneous structure of upper part of geological section. 2 cl, 1 dwg

Description

 The invention relates to electrical exploration by inductive sensing and can be used to study the geoelectric heterogeneity of the upper part of the section, represented by alluvial and deluvial-proluvial deposits of variable power and heterogeneities at the base of the section, emerging under thin loose deposits. The scope of primary application: engineering and geological surveys, the detection and tracing of zones of tectonically fragmented, permeable rocks, inspection of sites for engineering and civil engineering, monitoring the status of bulk hydraulic structures, etc.

 A known method of remote inductive sensing, which uses an electromagnetic field source (vertical magnetic dipole), a receiving magnetic sensor and a recorder of the amplitude components of the magnetic field [1]. During the measurements, the distance (separation) between the source of the electromagnetic field and the receiving magnetic sensor along the surface of the studied section is changed and the distribution of the electrical properties of the medium in depth is judged by the dependence of the experimental data on the separation. The disadvantage of this method is the significant distorting effect on the measurement results of geoelectric heterogeneities in the upper part of the section, located either near the source of the electromagnetic field or near the receiving magnetic sensor. This makes it difficult to interpret the results, since the theory of the method is developed for the case when the studied geological structure is modeled by a horizontally layered medium.

 Also known is the method of radar sensing (GPR), in which the geological structure is probed by sending a powerful electromagnetic high-frequency pulse to the medium and measuring the signal reflected from the internal interfaces [2]. By the delay time of the reflected signal, the depth of the reflecting object or the interface between the media is judged. A limitation in the application of the known method is the presence in the upper part of the section of highly conductive (clay, watered) formations, since the propagation velocity of electromagnetic waves depends sharply on the conductivity of the rocks of the section. Due to the distorting effect of the conductive deposits, the depth of the reflecting boundaries is determined with low accuracy. Closest to the proposed invention is a method [3], which is adopted as a prototype using a vertically spaced electromagnetic field source and a receiving magnetic sensor. In it, the source of the electromagnetic field is moved vertically, and the receiving magnetic sensor remains in a fixed position near the earth's surface (or vice versa). The amplitude of the magnetic field is recorded and, depending on the distance between the source of the electromagnetic field and the receiving magnetic sensor, the change in the electrical properties of the medium with depth is judged. The disadvantage of this method is the complexity of the practical implementation of sounding, since it is necessary to distribute the source of the electromagnetic field and the receiving magnetic sensor vertically at a distance significantly exceeding the required research depth. This height is too low for aviation applications and is difficult to achieve for a portable source of electromagnetic field and a receiving magnetic sensor. In addition, the use of ground lifting devices consisting of metal elements is unacceptable, since such elements distort the distribution of the field between the source of the electromagnetic field and the receiving magnetic sensor.

 A device for geoelectrical exploration by the method of dipole inductive profiling with a rigid mount of the electromagnetic field source and the receiving magnetic sensor on the body or wings of the aircraft [4]. The device can be used in aerial surveying geo-mapping works. The disadvantages of the device include the difficulty of compensating the electromagnetic field of the eddy currents induced in the aircraft body, and the unstable mutual position of the source of the electromagnetic field and the receiving magnetic sensor due to vibration of the body or wings of the aircraft.

 Closest to the proposed invention is a device for tracing buried pipelines [5], adopted as a prototype, in which the source of the electromagnetic field and the receiving magnetic sensor are rigidly fixed at different ends of the non-conductive frame-truss. The device is designed for shallow inductive profiling. Its design does not provide for the implementation of electromagnetic soundings.

 The purpose of the invention is to increase the efficiency of detecting geoelectric heterogeneities in the studied section and reduce the ambiguity of the interpretation of the results with the heterogeneous structure of the upper part of the section.

 This goal is achieved by the fact that in the proposed method of geoelectrical exploration and a device for its implementation, which use an electromagnetic field source and a receiving magnetic sensor, separated from each other, which consists in registering a magnetic field excited in the medium by an electromagnetic field source, and determining the geoelectric characteristics of the section, inductive sensing is carried out by simultaneously raising the source of the electromagnetic field and the receiving magnetic sensor, rigidly fixed to and at the ends of the truss frame so that the axis of the receiving magnetic sensor is oriented perpendicular to the field strength of the source of the electromagnetic field, which eliminates the direct influence of the primary field on the receiving magnetic sensor, perform measurements at several given heights and according to the distribution of the magnetic field depending on the height of the frame trusses determine the geoelectric characteristics of the studied section.

где Jo(mr) - функция Бесселя, зависящая от горизонтального разноса; f(m) - функция, зависящая от мощностей и проводимостей слоев разреза.The theory of the method and the algorithm for interpreting experimental data are based on the well-known solution to the problem of the distribution of the electromagnetic mole of a magnetic dipole in the presence of an electrically conductive horizontally layered half-space. In particular, for a dipole raised to a height h above the half-space, we have on its surface the following expression for the vector potential P:

where Jo (mr) is the Bessel function depending on the horizontal spacing; f (m) is a function depending on the powers and conductivities of the sections of the section.

If the measurement point is not on the cut surface, but at a height z, then the factor e ^-mz appears under the integral. Combining this factor with the one that contains the value of h, we obtain the initial value of the integral, replacing the value of h in it with the sum h + z.

 The calculations show that in order to achieve the same depth of study of the studied section, it is required several times lower lifting height of the frame-truss with an electromagnetic field source and a receiving magnetic sensor fixed to it than in case of raising only an electromagnetic field source or only a receiving magnetic sensor .

 For the practical implementation of the proposed method, a known device [5] is used, consisting of a rigid non-conductive frame-truss, at one end of which a source of electromagnetic field with its own power supply is fixed, and at the other end is a magnetic receiving sensor connected to a recorder located in the middle part truss frames, additionally containing a lifting device in the form of a vertical support rod, an infrared indicator of the frame lifting height, a cable, one end of which is fixed in the middle of the truss frame, and the second swarm through a system of blocks connected to the rotary mechanism.

 In FIG. 1 shows a schematic diagram of a device for implementing the proposed method, where 1 is the source of the electromagnetic field; 2 - receiving magnetic sensor; 3 - frame farm; 4 - bearing bar; 5 - cable; 6 - generator and power supply unit of an electromagnetic field source; 7 - measured block; 8 - infrared emitter of pulses of elevation mark; 9 - receiver of infrared pulses; 10 - registrar; 11 - rotary mechanism.

 When performing inductive sensing of the proposed method using a device for its implementation, the following operations are performed. The supporting rod 4 of the lifting device is installed vertically at the sounding point and this position of the rod is maintained throughout the entire measurement cycle. Using a cable 5, the frame-farm 3 is fixed at the minimum specified height from the earth's surface. Then, using the rotary device 11, rewind the cable, the frame-farm is raised above the studied section with continuous or discrete registration of the electromagnetic field strength. The elevation height is fixed according to the signals of the infrared emitter of pulses of elevation 8 received by the infrared impulse receiver 9 built into the recorder 10. All measurement results are recorded in a storage device, and after the sounding operation is completed, they are transmitted to a computer, processed, interpreted and determined by the geoelectric characteristics of the medium in paragraph sounding.

 The increase in the efficiency of detecting inhomogeneities in the upper part of the section under various geoelectric conditions by the proposed method and device for its implementation is achieved due to the fact that during the measurement the frame-farm rises with a rigidly fixed location on it of an electromagnetic field source and a receiving magnetic sensor, and the receiving magnetic axis the sensor is oriented perpendicular to the direction of the field strength of the source of the electromagnetic field. This eliminates their direct interaction, which makes it possible to increase the sensitivity of the recorder and realize higher measurement accuracy.

 The advantage of the proposed method and device for its implementation is also the fact that to achieve a given depth of study of the section requires a significantly lower height of the lifting frame-truss compared to the separation in height of the source of the electromagnetic field when placed on the earth's surface of the receiving magnetic sensor, or when raising the receiving magnetic sensor and fixing on the earth's surface the source of the electromagnetic field.

Sources used in the preparation of the application
1. Titlinov V. S., Zhuravleva R. B. Remote Inductive Sounding Technology. Yekaterinburg: UIF "Science", 1995. P.28-31.

 2. Darracot B.M., Lake M.J. An initial appraisal of ground probin radar for site investigations. - Britan Ground Engineering, 1981, April, p. 14-18.

3. Zhuravleva RB, Titlinov VS Frequency and geometrical induction sounding of layered media by an installation with vertically spaced sensors. Applied Geophysics, vol. 84. - M .: Nedra, 1976. S.124-133 (prototype)
4. Electrical exploration. Handbook of geophysics. Prince first one. - M .: Nedra, 1989.S. 418.

 5. RF patent 1746227, class G 01 V 3/08. Bull. 25, 1992 (prototype).

Claims (2)

 1. The method of geoelectrical exploration, which uses an interconnected source of an electromagnetic field and a receiving magnetic sensor, which consists in registering a magnetic field excited in the medium by a source of an electromagnetic field and determining geoelectric characteristics, characterized in that it has an electric field source and a receiving magnetic the sensor is placed at a fixed distance in a position that excludes the direct influence of the source of the electromagnetic field on the receiving magnetic sensor, and the electromagnetic Induction of the medium is carried out by lifting simultaneously the source of the electromagnetic field and the receiving magnetic sensor above the studied section with a continuous or discrete registration of the magnetic field, according to the distribution of which, depending on the height of the electromagnetic source and the receiving magnetic sensor, the geoelectric structure of the studied section is judged.  2. A device for geoelectrical exploration, containing a rigid non-conductive frame-farm, at one end of which there is an electromagnetic field source, and at the other end a receiving magnetic sensor connected to a recorder located in the middle of the frame-farm, characterized in that it has a receiving magnetic the sensor is installed so that its axis is oriented perpendicular to the direction of the field strength of the source of the electromagnetic field, and a vertical rod, infrared, are introduced to change the position of the frame-farm above the earth's surface provided a clear timer lift height farm frames, rope, one end of which is fixed in the middle of the farm-frame and second blocks through the system connected to the rotating mechanism.