RU2560459C1 - Well productivity recovery method - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: method includes usage of additional well with strainer and electrode of electroconductive material placed at distance from 10m up to 100m form the first well with electrode and strainer placed in it with formation of water-bearing electroconductive formation. The wells are connected to a power supply force represented by combined direct-current generator and alternating-pulse generator. Electric current is supplied through the formed electric circuit from the power supply source to electrode and strainer of the first well, water-bearing formation, strainer and electrode of the auxiliary well for cleaning strainers from colmatant. The electrode of the first well strainer serves as anode while electrode of the auxiliary well strainer serves as cathode. Electrodes are connected additionally to the source of alternating-sign electric pulses and alternating-sign pulses are supplied to them with frequency of 20 - 100Hz for alternate change and shift of pH medium towards reduction in the strainer area. The method excludes formation of non-soluble ferroferrihydrosol complex in the water-bearing formation adjoining strainers and in strainers directly.

EFFECT: improved efficiency of treatment from deposits that promotes recovery of productivity.

1 dwg

Description

The invention relates to the field of water supply and drainage, and more specifically to cleaning the holes of the well filters from particles and substances clogging them and restoring the productivity of the wells, mainly water wells.

Typically, in a water intake or salt well, a mechanical filter is installed to clean the withdrawn water or saline from large rock particles. Mesh filters are most commonly used for this. However, during the operation of the well, the holes in the filter grid gradually overgrow and become clogged with precipitating substances and particles of water-bearing rock dissolved in water (mudding). As a result, well productivity may drop to a critical level and there is a need to clean the filter. There are various methods of cleaning filters, for example mechanical, chemical, pneumatic. However, such cleaning methods are ineffective, complex, time-consuming and expensive, lead to damage to the filter and well pipes, there are problems associated with the environment and safety.

A known method of restoring well productivity, including processing filter holes by mechanical impact (swabbing, evacuation, etc.) due to clogging with salts of substances dissolved in water and particles of water-bearing rock (mud) (V.M. Gavrilko, Alekseev BC Drill hole filters M., "Nedra", 1976, p. 344).

However, the mechanical effect for cleaning the filter openings from salts of substances dissolved in water or particles of the water-bearing rock is not effective enough because the mechanical destruction of the mud leads to the formation of cracks in the cemented salt and rock conglomerate, which reduces the filter's water holding capacity, its duty cycle and further leads to rapid colmatization. In addition, with mechanical action on the filter, there is a high risk of destruction of the water intake surface, for example, the filter mesh, which reduces the productivity of the well.

A known method of restoring well productivity, including processing filter openings with chemicals, in particular hydrochloric acid (Vorontsov V.I., Shaber GB, Intensification of the work of drainage devices during drainage of mineral deposits. - M., "Nedra", 1975, pp. . 204).

The known method of restoring well productivity is expensive, requires special acid-resistant equipment. Using acids to restore well productivity is unsafe and can lead to destruction of the well material. In addition, not all salts are soluble in acid.

There is a method of restoring well productivity, which includes placing between the filter shell electrodes - an anode and a cathode made of dissimilar materials, followed by electrochemical reactions, under the influence of which saturation of the active space with copper ions having bactericidal properties, which prevents the development of biological colmatization (A.S. USSR No. 685632 A1, IPC C02B 1/82, B01D 35/06, publ. 15.09.1979).

The disadvantage of this method is to prevent only biological mudding and the inability to completely decolmate the filter, which reduces the productivity of well recovery.

A known method of restoring well productivity, including placing an electrode of electrically conductive material inside the well and passing through the indicated electrode, the wall of the well, and an electric current filter from a connected power source to ensure that the filter is cleaned of the mud, by moving ions between the electrode and the well filter. To regenerate the filter, the water pump is turned on and off periodically, followed by the removal of slag of decomposed salts by the flow of water from the filter (AS USSR No. 850818 No. 1, IPC E03B 3/08, published July 30, 1981).

However, in the known method, when direct current is supplied, due to the interaction of iron ions with water, an insoluble complex compound ferroferrigidrosol is formed, which, in turn, clogs the filter passage openings. In addition, with a unidirectional current, the anions (OH-, O-) formed in water are attracted to the positive pole — the anode, and cations (H +, Fe ++, Fe +++, Ca ++) to the negative pole — the cathode. In a solution, when the ions move towards the electrodes under the influence of current due to the collision of oppositely charged ions, most of the energy is spent uselessly and is aimed at heating the mass of water between the electrodes. At the cathode, in this method, metals are released (mainly ferric and ferric iron compounds) contained in natural water and in the filter material, as well as free oxygen. In this case, the pH (pH value) also decreases in the cathode zone and is characterized by an acid reaction (the pH drops to 4). Subsequently, iron, oxidizing, forms a complex compound ferroferryhydrosol, which reacts with trace elements ions dissolved in natural water with the formation of insoluble salts, which does not fully restore the well productivity.

The closest technical solution, selected as a prototype, is a method of restoring well productivity, in which an electrode of electrically conductive material is placed inside the well with a filter, connected to a power source in the form of a combined direct current source and pulse generator, which is also a source of alternating electrical pulses current and direct electric current, and pass through the specified electrode, the borehole wall and the electric filter t to ensure that the filter is cleaned of colmatant, while the well wall and the filter serve as the anode, and the electrode as the cathode, and alternating electric current pulses are supplied to separate the colmatant from the filter walls and at the same time direct current to transfer cations contained in the well solution to the cathode and shear the pH of the medium is downward in the filter zone, while the precipitate formed during cleaning is removed from the well by its subsequent pumping (Patent RU No. 2318987 C2, IPC E21B 37/08, E21B 43/08, published on 04.03.2005, publ. March 10, 2008).

However, such a filter cleaning technology does not allow complete removal of colmatant in the most problematic area at the boundary between the filter surface and the water-containing rock from which water is taken, since it is located outside the interelectrode space, as a result of which the efficiency of restoration of well productivity is reduced. In addition, for the same reason, the removal of clogging sediments in the pores is not ensured, namely, the zone of this contact is the most problematic.

The task of the invention is to restore the productivity of water wells.

To solve this problem, in a method for restoring well productivity, in which an electrode of electrically conductive material is placed inside a well with a filter and connected to one of the outputs of the power source in the form of a combined constant current generator and alternating pulse generator, and the current generated during cleaning is applied sediment is removed from the well by its subsequent pumping; according to the invention, an additional well is used with a filter and an electrode from electrically conductive material located at a distance of 10 m to 100 m from the first well with the formation of a water-containing electrically conductive layer between them and connected to the second output of the power source, the electric current is supplied through the formed electric circuit from the power source to the electrode and the filter of the first well, the water-containing layer, a filter and an electrode of an additional well with cleaning filters from colmatant, while the electrode with a filter of the first well serves as an anode, and the electrode with a filter of an additional well It serves as a cathode, additionally connect a source of alternating pulses of electric current to the electrodes of two wells and supply them with a frequency of 20 to 100 Hz to alternately change and shift the pH of the medium downward in the filter zone, which prevents the formation of an insoluble complex of ferroferryhydrosol in the water-containing formation adjacent to filter and at the same time in filters with the removal of dissolved sediments by means of subsequent pumping.

Using an additional well with a filter and an electrode made of electrically conductive material installed in it and placing the well at a distance of 10 m to 100 m from the first well makes it possible for electric current to pass from one to another well through a water-containing layer enclosed between them, and, therefore, electrochemical processes in this formation, including in the zone of contact between the formation and the filter, as well as in the filters of both wells, which contributes to the full restoration of well productivity.

The location of the wells at a distance from each other from 10 m to 100 m is justified by the fact that when an electric current passes through a water-containing formation located between the wells, the electrical resistance of the formation depends on the magnitude of the current path, that is, on the distance between the wells. Colmatant dissolution efficiency depends on the current density, the value of which depends on the electrical resistance of the formation - the greater the distance between the wells, the lower the current density.

When the wells are placed at a distance of more than 100 m, the electrical resistance of the water reservoir increases sharply and to maintain the process it is necessary to increase the voltage generated by the power source, since the current density is its function, which complicates the process, primarily for safety reasons, and the recovery of well productivity is worsened .

When the wells are located at a distance of less than 10 m, the current density rises to values comparable to the short circuit mode, which can lead to the destruction of the power source on the one hand, and to the useless waste of electricity on heating water-bearing rocks, on the other hand, and recovery of well productivity does not occur.

The use of alternating current with a frequency of 20 to 100 Hz prevents the formation of ferroferrigidrosol due to alternating changes in pH in the water located in the pores of the reservoir. At frequencies above 100 Hz, the rate of change in pH is very high, which leads to a rapid change in acidity in the medium being processed and, therefore, to a slowdown in the rate of reaction of ions. At a frequency of less than 20 Hz, due to the low rate of change in pH, the likelihood of the formation of ferroferryhydrosol and the formation of insoluble precipitates increase.

The invention is illustrated in the drawing, which shows a diagram of the restoration of well productivity.

In the presented embodiment, when implementing the method, wells 1 and 2 are placed from each other at a distance of 10 m to 100 m. The electrodes are made of electrically conductive material in the form of filter columns 3 and 4, are placed in the corresponding wells 1 and 2 and are electrically connected to the filters 5 and 6. The rock section located between wells 1 and 2 forms a water-conducting electrically conductive layer 7. The power source 8 is connected to the filter columns 3 and 4. The power source 8 is a combined source in the form of a direct current source and pulse generator and is at the same time a source of alternating pulses of electric current and direct electric current. Filter column 3 with filter 5 of well 1 is used as an anode, and filter column 4 with filter 6 of well 2 is used as a cathode. The filter columns 3 and 4 of wells 1 and 2 are additionally connected to a generator of alternating impulses of the electric current of the source 8. A constant electric current from the combined power source 8 is supplied simultaneously to the filter column 3 of the well 1 with the filter 5 serving as the anode and to the filter column 4 with the filter 6 wells 2 serving as a cathode. At the same time from the power source 8 serves on both filter columns 3 and 4 with filters 5 and 6 of the corresponding wells 1 and 2 alternating current with a frequency of from 20 to 100 Hz. When alternating current pulses pass through a system formed by a power source 8, a filter column 3 with a filter 5 of a well 1, a water-containing formation 7 and a filter column 4 with a filter 6 of a well 2, an alternating change in the pH value in the water located in the pore space of the water-containing formation 7 , which leads to the electrochemical dissolution of salts, forming a clogging sediment in the reservoir 7 and at the same time in filters 5 and 6 of wells 1 and 2, respectively. The presence of direct current in the circuit leads to the movement of ions in the water-containing formation 7. In this case, the cations that make up the colmatant (mainly Fe +++, Н +, Ca ++) move to the cathode (well 2), and the anions (OH- and O-- ) move to the anode (well 1), where the pH value changes, i.e. an acidic medium is formed in the cathode region, and alkaline in the anode region. Since the porous medium of the water-containing formation 7 has the properties of a semipermeable membrane, mixing of acidic and alkaline media does not occur. In the water-containing stratum 7, the colmatating salts of a corresponding nature are dissolved. A short-term change in pH with the passage of pulses of alternating current prevents the formation of ferroferrigidrosol. The precipitate formed during purification is removed from wells 1 and 2 by subsequent pumping. A significant advantage of this method is that it can be used without shutting off the wells, provided that the filter columns are isolated from the walls of the wells, shutting them off is not required.

Example. A well with a depth of 245 m was drilled in 2001 in a water-bearing stratum represented by Cenoman-Albian medium-grained sand. Design well flow rate 24 m ³ / h. A mesh filter was installed with a galloon weaving mesh on a tubular frame with holes 2 mm in diameter, the frame duty cycle of 25%. After putting into operation, the well worked periodically. In 2010, the flow rate of the well began to decline. In 2013, it fell to 16 m ³ / h. A survey of the well showed that the decrease in flow rate was caused by chemical mucking. Decolmation was carried out by passing an electric current through the specified well and a neighboring well located at a distance of 80 m with the following parameters:

- direct current (voltage 60 V, density 6 Ohms, frequency 50 Hz);

- alternating current (voltage 70 V, current density 8 Ohms).

Processing was carried out for 72 hours.

When pumping wells, their flow rate was 26 m ³ / h.

Thus, the use of the proposed method provides an effective cleaning of the filters of two wells at the same time from deposits at relatively low material and labor costs, without the risk of damage to the filters, as well as time to restore them. In addition, the excess flow rate over the design indicates an increase in the permeability of the reservoir.

Claims (1)

A method of restoring well productivity, in which an electrode of electrically conductive material is placed inside the well with a filter and connected to one of the outputs of the power source in the form of a combined constant current generator and alternating pulse generator, and the current generated during the cleaning process, the dissolved sediment is removed from the well by its subsequent pumping, characterized in that they use an additional well with a filter and an electrode of conductive material, size It is connected at a distance of 10 m to 100 m from the first well with the formation of a water-conducting electrically conductive layer between them and connected to the second output of the power source, an electric current is supplied through the formed electric circuit from the power source to the electrode and filter of the first well, water-containing formation, filter and electrode an additional well with cleaning filters from colmatant, while the electrode with the filter of the first well serves as the anode, and the electrode with the filter of the additional well serves as the cathode, connect relative to the electrodes of two wells, a source of alternating pulses of electric current and feed them with a frequency of from 20 to 100 Hz for alternating changes and pH shifts of the medium in the direction of lowering in the filter zone, which prevents the formation of an insoluble complex of ferroferryhydrosol in the water-containing formation adjacent to the filters, and at the same time filters with the removal of dissolved sediments through subsequent pumping.