EA020745B1 - Electrical exploration device - Google Patents

Abstract

The invention relates to electrical exploration, in particular, to methods of induced polarization (IP), and may be used to search for minerals in the explored geological cut on the basis of determination of the induced polarisation coefficient. The invention provides increased sensitivity of a device by a measured coefficient of IP. The electrical exploration device comprises a differential metre with three measuring M, N and O non-polarised point electrodes. The differential metre comprises the first and second low frequency amplifiers (LFA), a switchboard, an analogue to digital converter (ADC), the first and second random-access memories (RAM), a unit to calculate dispersion of electric potential ΔU, a subtracting device, a controlled attenuator, a unit to calculate dispersion of a difference of electric potentials, a divider, a unit of indication and a unit of control.

Description

The invention relates to the field of electrical exploration, in particular to methods of induced polarization, and can be used to search for minerals in the studied geological section based on the determination of the coefficient of induced polarization.

Known correlation electrical exploration device [ed. St. 8I No. 842682, IPC O01U 3/08, publ. 06/30/1981], consisting of a two-stage DC amplifier with conversion and a DC amplifier connected directly to the control input of the multiplication unit and through the storage and conversion units. The output of the DC amplifier with conversion is connected to the input of a two-threshold comparator, the output of which is connected to the input of the coincidence unit, which is connected to one of the outputs of the synchronizer and the timing unit. Another output of the synchronizer is connected through the switch block with the keys of the averaging block connected to the indicator. The timing unit is connected to the control input of the storage unit, and the synchronizer with the conversion unit.

The closest technical solution to the claimed one is the differential method of induced polarization of the airspace (Shaidurov G.Ya., Kozlov Yu.N., Markushin Ya.V. The differential method of extracting information about the potentials of the airspace from the Earth’s natural electromagnetic field (EEMP) B: Geophysical equipment No. 97, Krasnoyarsk, Nedra, 1991, pp. 35-41), which uses a differential meter with three non-polarizing point electrodes. Three measuring M, N, and O non-polarizing point electrodes of a two-channel differential meter, sequentially spaced on the profile axis at equal intervals, form a three-electrode measuring line ΜΟΝ oriented across the assumed strike of the ore body to be searched, and random signals χ (ΐ) and у (1 ) taken respectively from the lines of MO and ΟΝ.

The geological section is excited by an external noise field EEMP (natural electromagnetic field of the Earth) with intensity Ε (ΐ) falling parallel to the interface. Imagine the observed implementation of signals at a sample frequency ω _1, respectively, from the output of the OM and линий lines in the form χ (ί) = υ _ιΙ1χ 5Ϊη (ω; ΐ + φ _κ ); (1) y0) = 5t _p1u and (w1 + _(y p), (2) where _mx and amplitude, and _the phase p and _{x <y} p are nonstationary random variables.

Without taking into account spatial instability between χ (ΐ) and (1) there is a deterministic connection determined by the electromagnetic parameters of the geological section under study, so that _tx and _tu arise mainly due to its apparent resistance, and the phase difference Δρ = p _x -p _y - due to the potential of the VP (induced polarization).

Taking into account that the compensation methods are the most accurate, and assuming that it was possible to compensate for the difference in amplitudes ~ ^ ’" for Δφ / φχ << 1, we can obtain the average relative square of the difference between equations (1) and (2) in an approximate form:

and for a finite number η of spectral components:

Thus, algorithm (4), implemented by measuring the sum of the squares of the spectral samples of the normalized difference of the observed signals x (1) and y (1), allows you to determine the average increment of the phase difference Δφ ₁ ² arising due to the heterogeneity of the polarizability of the geological section under the MO lines and ΟΝ when moving along the observation profile. In this case, a change in the spectral composition of the EEMF field in time will only affect the absolute value of the difference Δϋ ;. The normalized value [formula (4)], taking into account the redundancy of the measured spectral components, will be more stable.

A common disadvantage of the known technical solutions is the low sensitivity due to the unsteadiness of the EEMP and, as a consequence, a sufficient variation in the readings of the parameters of the induced polarization.

The objective of the invention is to increase the sensitivity of the device according to the measured VP coefficient.

The problem is solved in that in the inventive electrical exploration device containing a differential meter with three measuring non-polarizable point electrodes, according to the invention, the differential meter contains first and second low frequency amplifiers (VLF), non-inverting inputs of which are connected respectively to measuring M and N non-polarizing point electrodes, inverting the inputs of the first and second VLF are combined and connected to a measuring Ο non-polarizable point electrode, and the outputs of the first and second

- 1,020,745

ULFs are connected respectively to the first and second signal inputs of the switch, the output of which is connected to the signal input of an analog-to-digital converter (ADC), the first random access memory (RAM), the signal input of which is connected to the first output of the two-channel ADC, the first output of the first RAM is connected to the input variance calculating block electric potential Δυ _Μ0, and the second output of the first RAM is connected to the first input of the subtractor, the second RAM, a signal input coupled to the second output of dual-channel the ADC, a controlled attenuator, the first input of which is connected to the output of the second RAM, and the output of the controlled attenuator is connected to the second input of the subtractor, an electric potential difference dispersion calculation unit, whose input is connected to the output of the subtractor, the second output of the electric potential difference dispersion calculation unit is connected a second control input of the attenuator, the divider having a first input connected to the output of the dispersion calculating unit electric potential Δυ _Μ0, and the second WMOs the divider is connected to the first output of the electric potential difference dispersion calculation unit, and an indication unit whose input is connected to the output of the divider, as well as a control unit whose first output is connected to the control input of the switch, the second output of the control unit is connected to the control input of the ADC, and the third and the fourth outputs of the control unit are connected to the control inputs of the first and second RAM, respectively.

The drawing shows a block diagram of the claimed electrical exploration device.

The electrical exploration device comprises a differential meter with three measuring M, N and O non-polarizable point electrodes. The differential meter contains the first 1! and the second 1 ₂ low-frequency amplifiers (VLF), switch 2, analog-to-digital converter (ADC) 3, the first 4 ₁ and second 4 ₂ random access memory (RAM), block 5 calculating the dispersion of the electric potential Δυ _Μ0 , subtractor 6, controllable attenuator 7, the dispersion calculation unit 8, an electrical potential difference, a divider 9, a display unit 10 and control unit 11. The non-inverting input of the first ULF 11 is connected to meter a point M non-polarizable electrode, and the second input neivertiruyuschy February ₁ connected to measure ULF N flax a point electrode. The inverting inputs of the first 1ι and second 1 ₂ VLF are combined and connected to a non-polarizing point electrode measuring O. The outputs of the first 1ι and second 1 ₂ VLF are connected respectively to the first and second signal inputs of switch 2, the output of which is connected to the signal input of the ADC 3. The signal input of the first 4 ₁ RAM is connected to the first output of the ADC 3. The first output of the first 41 RAM is connected to the input of the block 5, the variance in electric potential Δυ _Μ0, and the second output of the first RAM April ₁ is connected to the first input of the subtractor 6. The signal input of the second _{2 April} RAM connected to the second output of the ADC 3. The first input controlled attenuator 7 connected to the output of the second April ₂ OZ and the output of the controlled attenuator 7 is connected to the second input of the subtractor 6. The input of the electric potential difference dispersion calculation unit 8 is connected to the output of the subtractor 6. The second output of the electric potential difference dispersion calculation unit 8 is connected to the second input of the controlled attenuator 7. The first input of the divider 9 connected to the output unit 5 calculating the variance in electric potential Δυ _Μ0, a second input of the divider 9 is connected to a first output 8. Log display unit 10 connected to the output divides 9. A first output of the control unit 11 is connected to the control input of the switch 2, a second output connected to the control unit 11 to the control input of ADC 3, and the third and fourth outputs of the control unit 11 are connected to the control inputs of the first 41 and second RAM 42, respectively.

Electrical exploration device operates as follows.

The geological section is excited by an external EEMP noise field of intensity Ε (ΐ), falling parallel to the interface.

Three measuring M, N and O non-polarizing point electrodes of a differential meter, sequentially spaced on the axis of the profile at equal intervals, form a three-electrode measuring line Μ0Ν oriented across the geological section under study. Δυ _Μ0 and Δυ _0Ν , due to the flow of telluric currents in the studied geological section, are removed from the lines of MO and 0Ν, respectively. The signals Δυ _Μ0 and Δυ _{0Ν are} amplified in the first 1 ₁ and second 1 ₂ ULF, respectively.

The connection of a measuring O nonpolarizing point electrode to the inverting inputs of the first 1 ₁ and second 1 ₂ ULF allows you to reduce the effect of synchronous interference, in particular industrial interference of 50 Hz.

According to the control signal of control unit 11, the MO and 0Ν lines are switched by means of switch 2 with a switching frequency (. = 2 / Г, where Г, is the sampling frequency of the electric potential.

From the output of the first 1 ₁ VLF, the amplified electric potential Δυ _Μ0 through the switch 2 is fed to the input of the ADC 3. The readout of the amplified electric potential Δυ _{Μ0ι is} recorded in the memory of the first 4!

RAM Then the lines are switched, and the reference of the amplified electric potential Δυ _{0Νι is} recorded in the memory of the second 4 ₂ RAM. At the end of the measurement interval & η electrical samples

- 2 020745 potentials Δυ _ΜΟι and Δυ _ΟΝι are extracted from the memory of the first 4! and the second 4 ₂ RAM, respectively.

With the release of the first 4! RAM η samples of electric potentials Δυ _ΜΟι are fed to the input of the unit 5 _σ 2 computing the dispersion of the electric potential Δυ _Μ0 , where the dispersion value is calculated.

At the same time, η samples of electric potentials Δυ _ΜΟι arrive at the first input of the subtractor 6. From the output of the second 4 ₂ RAM, η samples of electric potentials Δυ _0Νι go to the first input of the controlled attenuator 7, where they are multiplied by a controlled coefficient K. The obtained samples ΚΔυ _ΟΝι go to the second input a subtractor 6, where the electric potential difference _Δυ ΜΟι _-ΚΔυ ΟΝι is _calculated . The electric potential difference Δυ _ΜΟι -ΚΔυ _{ΟΝι is} fed to the input of the dispersion calculation block 8 of the electric potential difference, where the dispersion σ ² σ ² is calculated. The obtained dispersion values ^Δί ' ^ιΛ And go to the first and second inputs of the divider 9, respectively, where the value of the VP coefficient is calculated from formula (5)

where η is the number of samples of the signal.

In order to minimize the difference between Δυ _ΜΟ ι and ΚΔυ _ΟΝι in amplitude, due to the unsteadiness of the EEMF, and as a consequence, the spread of the signals Δυ _ΜΟ and Δυ _ΟΝ taken from the lines of MO and ΟΝ, respectively, by means of a controlled attenuator 7, to the second input of which the dispersion value of the difference of electric potentials select the value of the controlled coefficient K from the condition:

As a result of this selection of the coefficient Κ in the absence of an ore body in the studied geological section at the input of display unit 10, the obtained value of the VP coefficient is approximately equal to zero (q _VP “0). Otherwise, the presence of an ore body in the studied geological section is judged by a nonzero value of the VP coefficient (q _VP +0).

Using this device allows you to achieve sensitivity by the coefficient of VP about 1%, compared with sensitivity by the coefficient of VP prototype about 10-30%.

Claims (1)

CLAIM An electrical exploration device comprising a differential meter with three measuring non-polarizable point electrodes, characterized in that the differential meter contains first and second low frequency amplifiers (ULF), the non-inverting inputs of which are connected respectively to the measuring M and Ν non-polarizing point electrodes, inverting inputs of the first and second ULF combined and connected to a measuring O non-polarizing point electrode, and the outputs of the first and second ULF are connected respectively but with the first and second signal inputs of the switch, the output of which is connected to the signal input of an analog-to-digital converter (ADC), the first random access memory (RAM), the signal input of which is connected to the first output of the two-channel ADC, the first output of the first RAM is connected to the input of the electric dispersion calculation unit potential Δυ _ΜΟ , and the second output of the first RAM is connected to the first input of the subtracting device, the second RAM, the signal input of which is connected to the second output of the two-channel ADC, controlled by the atten an ator, the first input of which is connected to the output of the second RAM, and the output of the controlled attenuator is connected to the second input of the subtractor, an electric potential difference dispersion calculation unit, the input of which is connected to the output of the subtractor, the second output of the electric potential difference dispersion calculation unit is connected to the second input of the controlled attenuator, the divider having a first input connected to the output of the dispersion calculating unit electric potential Δυ _ΜΟ, a second input connected to the first divider the output of the block for calculating the variance of the difference in electric potentials, and the display unit, the input of which is connected to the output of the divider, as well as the control unit, the first output of which is connected to the control input of the switch, the second output of the control unit is connected to the control input of the ADC, and the third and fourth outputs of the block control connected to the control inputs of the first and second RAM, respectively.