RU2120031C1 - Method increasing productivity of hydrogeological wells and gear for its implementation - Google Patents

Abstract

FIELD: hydrogeology, running of artesian and hydrogeological wells of various assignment. SUBSTANCE: in correspondence with method action on zone close to filter of at least one water well is conducted by passing of heterpolar electric pulses without pauses between positive and negative pulses through zone close to filter of well. Relation of pulse durations is established constant and equal to 1. Value of pulse durations is consistently increased and decreased from t_imin to t_imax found from given relation with constant step Δt equal to 1.0-5.0 m/s after two pulses, one being positive and the other - negative, during period T_k of change of pulse duration from minimal value to maximal one and again to minimal one. Total action time should not exceed 30.0 h. Gear for implementation of method has voltage source connected by power cables to two working electrodes as minimum. Voltage source is provided with control and adjustment unit to measure and adjust parameters of output current. EFFECT: increased permeability of water stratum in zone close to filter of well and increased water inflow into filter of well as a consequence. 2 cl, 1 dwg

Description

 The invention relates to hydrogeology and can be used in the preparation and operation of artesian and hydrogeological wells to increase water loss.

 There is a method of increasing well productivity, including exposure to the filter zone of a hydrogeological well with a constant unipolar electric current to increase the porosity and permeability of the formation (SU copyright certificate N 899867, class E 21 B 43/00 of 01/23/82).

 The disadvantage of this method is its low efficiency, which in some cases, with low electrical conductivity of the formation, does not provide a noticeable result. It should be noted that the use of direct current leads to high energy consumption.

 A device for increasing the productivity of a hydrogeological well is known, which contains a constant current source connected via a cable to working electrodes (SU copyright certificate N 899867, class E 21 B 43/00 of 01/23/82).

 The disadvantages of the known device are limited functionality that does not allow to obtain a noticeable effect when using the device in the entire possible spectrum of productive formations due to the large spread of their parameters.

 A known method of increasing the productivity of a hydrogeological or artesian well, including exposure to the filter zone with direct or alternating electric current (SU copyright certificate N 1273514, class E 21 B 43/26 of 11/30/86) - prototype.

 As a disadvantage of the known method, the following can be noted. The method is aimed at increasing the permeability of the filter zone by heating water, increasing pressure in the capillaries and then increasing their cross section, which requires significant energy consumption and the use of powerful energy sources, and this is usually difficult. In this case, the formation of a vapor phase during the period of alleged uncontrolled raskolmatization is possible, which can reduce the filtering properties of the well. The possibility of vaporization requires mandatory periodic cooling by significant passive exposure between cycles of beneficial effects or laborious pumping of refrigerant. The magnitude of the electrical parameters and the cyclical effect are due only to the thermal properties of the filter zone and do not take into account its electrochemical properties, which can not only level the final result, but also lead to a decrease in productivity. The use of alternating current with a frequency of 50 Hz does not provide the opportunity to purposefully use the reactive component of the formation in a wide range of its possible useful resonant values.

 A device for increasing the productivity of a hydrogeological well is known, which contains an electric current source connected by power cables to two working electrodes. The source provides the supply to the working electrodes of direct or alternating two- and three-phase current (SU copyright certificate N 1273514, class E 21 B 43/26 from 11/30/86).

 The disadvantages of the known device should be noted limited functionality, since the structural elements do not provide the formation of pulses of electric current with a set of necessary parameters.

 The objective of the present invention is to increase the productivity of artesian and hydrogeological wells, the specific flow rate of which is either initially insufficient or significantly reduced during operation due to the clogging of pores and capillaries in the prefilter zone of the well, and the creation of a device that allows for the effects necessary for unresolution as a prefilter zone and well filter.

 The technical result of the present invention is to increase the permeability of the water reservoir in the filter zone of the well and, as a result, the increase in water flow into the filter of the well.

где
t_{i min, max} - соответственно минимальная и максимальная длительности импульсов тока;
D = B•λ_min,max ;
B - коэффициент, учитывающий отсортированность и породы, составляющей пласт, и уровень ее цементации ^*;
λ_min,max - максимальный и минимальный коэффициент анизотропии для данного пласта;
K - коэффициент пористости;
H - мощность пласта, м,
L - длина рабочего электрода, м,
C - минерализация воды в пласте, г/л.In order to achieve the indicated technical result in a method for increasing the productivity of a hydrogeological or artesian well, which includes applying an alternating electric current to the filter zone of at least one water well and extracting water and colmatants, the effect is carried out by passing through the filter zone of a water well an unipolar electric current pulse without pauses between positive and negative impulses, the ratio of the durations of which is fixed constant and p implicitly 1, and the magnitude of the pulse duration is varied during exposure, sequentially increasing and decreasing at a constant pitch equal to Δt, a range of values of t _{i min} to t _{i max:}

Where
t _{i min, max} - respectively, the minimum and maximum duration of the current pulses;
D = B • λ _{min, max} ;
B is a coefficient taking into account the sorting of both the rocks that make up the reservoir and the level of cementation ^* ;
λ _{min, max} - the maximum and minimum anisotropy coefficient for a given formation;
K is the coefficient of porosity;
H is the thickness of the reservoir, m,
L is the length of the working electrode, m
C - mineralization of water in the reservoir, g / l.

 The formation permeability zone is a medium that is very differentiated by the size of pores and capillaries, by the content of colmatant formations of natural and artificial origin, by the size of grains of rock-forming minerals, by the concentration of current carriers in its various regions, etc. Therefore, the prefilter zone of the well, which is electrically distributed inductance and capacity, can be considered within the framework of the task as an integral oscillatory circuit with its own resonant frequency, which consists of many oscillatory circuits, whose resonant properties are determined, in particular, by the above parameters and have therefore, the eigenvalues of the distributed inductance and capacitance, and hence the eigen resonant response frequencies to possible frequency electrical effects.

 Carrying out a specially selected swing of the pulse duration of electrical exposure, it is possible to consistently realize the maximum effect on individual fragments of the threshold space of the permeability zone, thereby obtaining the maximum possible final result in cleaning the pores and capillaries from collimant partitions.

The electrical parameters of the current pulses are chosen so that the effect on the collimant partitions in narrow and wide capillaries with a pulse duration equal to t _{i min} and t _{i max} , respectively, is sufficient to create electrokinetic forces that destroy these partitions. The current value is chosen such that during the exposure time there is no vaporization, which is able to block narrow capillaries by air bubbles.

 In the process of exposure, the secondary electric field is monitored, i.e. induced polarization (VP) field, by the change in the steepness of the decrease in the VP field after the end of the current pulse, by the magnitude of the kink of the transition characteristic at the boundary between positive and negative pulses, and also by a possible change in the pulse amplitude. In particular, it is possible to increase the amplitude, or alignment of the amplitude values of positive and negative impulses. In this case, the steepness of the trailing edge reaches its maximum value, and the magnitude of the fracture reaches its minimum.

где
х - расстояние до точки нулевой плотности тока, например нулевой точкой можно считать середину расстояния между рабочими электродами, м;
ρ - удельное сопротивления пласта, Ом x м;
T_p - средняя температура воды в пласте, ^oC;
T_w - время воздействия, ч;
U_w - электрическое напряжение на рабочем электроде по модулю, В.The exposure duration, as a rule, does not exceed 30 hours when the amplitude of the current pulses is determined from the relation

Where
x is the distance to the point of zero current density, for example, the zero point can be considered the middle of the distance between the working electrodes, m;
ρ - formation resistivity, Ohm x m;
T _p - the average temperature of the water in the reservoir, ^o C;
T _w - exposure time, h;
U _w is the electric voltage at the working electrode modulo V.

The value of the set period T _{k of the} change in the pulse duration (i.e., the period during which the pulse duration changes from minimum to maximum and again to minimum, with a constant discrete step Δt through two pulses, one of which is positive and the second negative) is determined taking into account the parameters of the reservoir and may be equal to
T _k = (5 - 20) • (t _{i min} + t _{i max} ), mс.

 The step size Δt of the change in the pulse duration was experimentally determined by the authors as equal to 1 - 5 ms.

 The presence of electrical resonance properties of the formation in practice is manifested by the maximum change in the controlled current parameters. In the region of infralow frequencies (with a pulse duration of 10 - 50 ms) this is a sharp increase in the steepness of the pulse fronts, in the region of higher frequencies (with a pulse duration of 1 - 10 ms), the resonance properties are manifested by a certain increase in the amplitude of the pulses transmitted through the filter zone. Moreover, the resonant responses to the action of pulses of variable duration, as a rule, are at least two in the entire exposure range from 1 to 50 ms, which allows, by changing the pulse duration according to the above regularity, to obtain the maximum possible result for the main areas of the permeability zone. The presence of a negative charge on the particles of the colmatant leads to the appearance of electrokinetic forces between them and ions moving in the formation water under the action of an applied electric voltage, the direction of these forces changes to the opposite when the polarity of the pulses changes, which ultimately leads to the "loosening" of the structure of the colmatant partitions and their decay into smaller fractions, which are then extracted with water during pumping.

 To implement the above method and obtain the specified result, a device is proposed for increasing the productivity of artesian and hydrogeological wells, containing an electric voltage source connected by power cables with at least two working electrodes, the source is made in the form of a power transformer with input terminals for connecting to a three-phase industrial AC network current, three power outputs of which are connected to three power inputs of an adjustable rectifier, two power outputs the ode of which is connected to two power inputs of a parallel thyristor inverter, two power outputs of which are connected to two power inputs of a current switch, two power outputs of which are connected through two matching elements to two output terminals to which power cables are connected, the device is also equipped with a control and monitoring unit the first control output of which is connected to the control input of an adjustable rectifier, and the second and third control outputs are connected respectively to the control inputs of pairs llelnogo thyristor inverter and the switch current and the control - measuring input of the control and monitoring unit is connected to one of the output terminals.

 As working electrodes, metal casing filters or electrically insulated filters connected through auxiliary electrodes and power cables to output terminals can be used. Auxiliary electrodes can be placed in the cavity of the open filters.

 The drawing shows a block diagram of a device for increasing the productivity of a hydrogeological well, which consists of a power reduction transformer 1 (SPT), block 2 of an adjustable rectifier (RV), block 3 of a parallel thyristor inverter (PTI), block 4 of a current switch (CT) matching elements 5, 6 (SE), control and monitoring unit 7, output terminals 8, 9 for connecting via power cables 10, 11 of working electrodes 12, 13. SPT is equipped with input terminals 14, 15, 16 for connecting to a three-phase industrial AC network 380 V, 50 g c. SPT is made according to a three-phase star-star scheme on a core common to all windings, secondary windings have taps for stepwise voltage regulation. RV is made on six thyristors connected according to the Larionov circuit, which operate in a two-sided cutoff mode, and is equipped with a filter that smooths current ripples (not shown). PTI is made on two thyristors with an output pulse transformer, the output windings of which have taps for switching the number of turns in accordance with the generated frequency and supply voltage. PTI has several inductances and capacitances for forming sequences of quasi-rectangular pulses without pauses in several frequency ranges.

The CT was performed on four thyristors and is designed to pass to the load the generated PTI pulses in one of three necessary modes:
1. bipolar pulses,
2. positive unipolar pulses,
3. negative unipolar pulses.

 BUK is designed to generate signals that control the on and off of thyristors RV, PTI and CT, as well as to measure the parameters of the output pulse current.

 The device operates as follows. The input three-phase voltage of 380 V, 50 Hz without zero is supplied through a three-phase cable to the primary windings of the power step-down transformer, the secondary windings of which provide a voltage reduction to 220 V and have taps for stepwise adjustment of this voltage, the current strength increases proportionally.

 From the SPT, the three-phase voltage is supplied to the input of the PB through the power circuits, which is assembled according to the Larionov circuit on thyristors with a smoothing filter at the output (not shown), voltage regulation is carried out within 30% of the maximum voltage. From the output of the RV, the rectified voltage is fed to the input of the PTI, at the output of which bipolar quasi-rectangular pulses are generated without pauses, which are fed through the CT and SC to the output terminals 8, 9. Then, the pulses through the power cables 10 and 11 are fed to the load terminals 12, 13, t .e. on working electrodes.

 At the first control output of the BUK, the RV is turned on and off with a cutoff depth that provides the necessary constant voltage at its output.

 By the second control output of the beech, control signals are fed to the PTI that determine the pulse duration at the PTI output, as well as the pattern by which this duration changes.

 On the third control output, the BUK controls the operation of the CT, assembled according to the bridge circuit and designed to switch the device to one of the above modes.

 The present invention was implemented on a number of wells in the Moscow region, the specific flow rate of which was significantly reduced during operation. In all cases of application of the method developed by the authors to increase the productivity of a hydrogeological well and a device for its implementation, an increase in the specific production rate and productivity of the wells to values of not less than 75% of the initial measured when putting the wells into operation was observed.

_* Dakhnov V.N. “Electrical exploration of oil and gas fields”, p. 21, Gostoptekhizdat, 1953

Claims (2)

1. A method of increasing the productivity of a hydrogeological well, which includes applying an alternating electric current to the filter zone of at least one well and extracting water and colmatants, characterized in that the effect is carried out by passing through the filter zone of a well of bipolar current pulses without pauses between positive and negative pulses, the ratio of the durations of which is fixed constant and equal to 1, and the value of the duration of the pulses is sequentially increased and decreased yut from t _imin to t _imax determined from the relation

where t _{imin, max} - respectively, the minimum and maximum duration of the current pulses;
D = B • λ _{min, max} ;
B - coefficient taking into account the sorting of the rock constituting the reservoir and the level of cementation;
λ _{min, max} - the maximum and minimum anisotropy coefficients for a given formation;
K is the coefficient of porosity;
H is the thickness of the reservoir, m;
L is the length of the electrode, m;
C - mineralization of water in the reservoir, g / l,
with a constant step Δt equal to 1 - 5 ms after two pulses, one of which is positive and the second negative, over a period T _{k of} change in pulse duration from the minimum to the maximum and again to the minimum, this period is determined from the relation
T _k = (5 - 20) • (t _imin + t _imax ), ms,
and the total exposure time is set to not exceed 30 hours  2. Device for increasing the productivity of a hydrogeological well, containing an electric voltage source connected through power cables with at least two working electrodes, characterized in that the source is made in the form of a power step-down transformer with input terminals for connection to a three-phase AC network, three power the outputs of which are connected to the three power inputs of an adjustable rectifier, the two power outputs of which are through a parallel thyristor inverter, a current commutator and the lasiry elements are connected to two output terminals, to which the power cables are connected, and is equipped with a control and monitoring unit, the first, second and third control outputs of which are connected respectively to the control inputs of an adjustable rectifier, parallel thyristor inverter and current switch, and the control and measurement input of the unit control and monitoring are connected to one of the output terminals.