RU2147330C1 - Method for treating-bottom-hole zone of well bed - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: this relates to methods for isolation of well bed by using isolating components which are introduced into isolation zone to be treated. According to method, zone to be treated is filled with isolating component with subsequent introduction of isolating component into bottom-hole of bed by subjecting isolating component to pressure pulses initiated by pulse generator located in bottom-hole zone. Value of pressure pulses is higher by at least 5 MPa than pressure of hydrostatic column of liquid at depth of treatment but not higher than value of bed fracturing. Clearance between internal surface of well and generator body is not over 10 mm. Application of method allows for high efficiency of operations. EFFECT: higher efficiency. 3 cl

Description

 The invention relates to the oil and gas industry, and in particular to methods for isolating a wellbore by using insulating components introduced into the treated isolation zone.

There is a method of isolating water inflow in a well, according to which a mixture of organosilicon compounds with hydrochloric acid as a hardener is pumped into the isolation zone and the mixture is kept in the formation for the time of gelation, the gelation time being determined depending on the specific injectivity of the well by the formula: t = (21.17 - 1.26 q) ² , where - t is the gelation time (min), q is the specific injectivity of the well (m / h / MPa) (see RF patent, N 2071548, class E 21 B 33/138, 1997 .).

 As a result of the analysis of this invention, it should be noted that this method is characterized by significant component costs and a long exposure time of the mixture for gelation.

 A known method of processing the bottom-hole zone of the formation, according to which separate injection of the components of the gel-forming composition, pushing agent, selection of the pushing agent and its re-injection is carried out, moreover, as the pushing agent, a liquid is used that is not miscible with the components of the gel-forming composition and with a viscosity higher than the viscosity of the gel-forming composition, moreover, the rate of selection of the pushing agent may be less than the speed of its injection. The use as a pushing agent of a liquid that is not miscible with the components of the gel-forming composition (composition of a solution of sodium silicate, a solution of hydrochloric acid and a solution of hydrolyzed polyacrylamide), eliminates the dissolution of the components of the gel-forming composition in the pushing liquid (for example, water), increases the strength of the gel, and therefore and the screen he creates (see RF patent N 2096584, class E 21 B 33/138, 1997) - the closest analogue.

 As a result of the analysis of the known method, it should be noted that it is characterized by the duration of its implementation, a large consumption of gelling composition and pushing liquid. The method does not provide for the impact of the insulating composition only on the insulated zone.

 The objectives of the present invention are to increase the efficiency of the method by providing the impact of the pushing agent on the insulating composition only in the area of the zone of the treated wellbore, as well as reducing the consumption of components and reducing the processing time of the bottomhole zone of the wellbore.

 The tasks are solved in that in the method of processing the bottom-hole zone of the wellbore, including filling the treatment zone of the well with an insulating component and then introducing it into the bottom-hole zone of the formation, it is new that the introduction of the insulating component is carried out by exposure to pressure pulses initiated by it placed in the bottom-hole a pulse generator, and the value of the pressure pulses is at least 5.0 MPa greater than the pressure of the hydrostatic liquid column at the depth of processing, but e a quantity of the formation fracture pressure. The interval of the impact zone of pulses along the axis of the well is 1.0 - 1.5 m, and the gap between the inner surface of the well and the body of the pulse generator is no more than 10 mm, and the pulse action on the insulating component is carried out at intervals, in areas of intense water inflow. The frequency of the gas pulses generated (initiated) by the generator is set to a multiple of the frequency of the reflected gas waves in the zone between the pulse generator housing and the well wall.

 When conducting patent research, no solutions were found that are identical to the claimed, and therefore, the proposed invention meets the criterion of "novelty."

 The invention does not follow explicitly from the known technical solutions, and therefore, the proposed invention meets the criterion of "inventive step".

 We believe that the information set forth in the application materials is sufficient for the practical implementation of the invention.

 The method of processing the bottom-hole zone of the wellbore is as follows.

 A self-solidifying component is fed into a well treatment zone filled with the wellbore environment (jamming fluid), and liquid glass-based mixtures can be used as a self-curing component.

 The self-hardening component can be supplied in the treatment zone by pumping it through tubing or another known technique.

 Next, a pulse generator is lowered into the bottomhole zone. The design of the pulse generator, which can be used to implement the method, is known, it is not the subject of the invention and therefore is not disclosed in the application materials. As a pulse generator, a powder gas generator can be used.

 When the pulse generator is put in a ready state, it is initiated and the generated gas medium is exposed to the self-solidifying component, introducing it into the treatment zone of the well formation. After being introduced into the treatment zone, the self-hardening component hardens over time (depending mainly on the composition of the component), sealing the formation zone.

 To increase the efficiency of introduction into the formation, the pressure is supplied by the gas generator by successive pulses, upon initiation of each of which the gas medium captures the self-solidifying component and delivers it to the treatment zone.

 When the value of the pressure pulses is less than 5.0 MPa of the pressure of the wellbore fluid column, a part of the self-solidifying component dissolves in the wellbore fluid and does not fall into the formation treatment zone, reducing its processing efficiency.

 When the pressure pulses are large, the values of the fracture pressure, cracks can appear in the treatment zone, which significantly complicates the isolation of the formation and leads to increased gas consumption and self-curing component.

 The most effective method is carried out with an interval of the zone of influence on the formation from 1.0 to 1.5 m. When the magnitude of the zone of influence is less than 1.0 meter, an increase in the number of tripping operations will be required, which reduces the processing productivity.

 When the magnitude of the impact zone of the pulses is more than 1.5 meters, it is necessary to increase the energy of the generator, which can lead to the destruction of the rock.

 The gap between the borehole wall and the pulse generator housing must not exceed 10 mm. With a gap value exceeding 10 mm, the efficiency of gas-pulse exposure decreases when a self-hardening mixture is introduced into the isolation zone.

 In the process of exposure to pulses of gas produced by the generator and the self-solidifying mixture on the treatment zone, reflected waves propagate from the isolated interval, namely gas waves. In some cases, the reflected waves are in contact with the body of the gas generator and are again reflected in the treatment zone of the well. If the gas wave is reflected at the moment when the next pulse is applied to the treatment zone by the generator, the waves meet each other in antiphase, which weakens the pulse supplied by the gas generator. To prevent this, the frequency of the gas pulses generated by the generator must be a multiple of the frequency of the reflected gas waves in the area between the pulse generator housing and the well wall.

 Compliance with this condition can significantly increase the efficiency of the method. The frequency of the pulses is calculated in a known manner.

 The pulsed action of the generator gases, and therefore of the self-solidifying component, is carried out sequentially in zones of intense water inflow. This allows you to ensure the selectivity of the treatment during repair and insulation work in wells, which significantly increases the efficiency of the method.

Claims (4)

 1. The method of processing the bottom-hole zone of the wellbore, comprising filling the treatment zone with an insulating component and then introducing it into the bottom-hole zone of the formation, characterized in that the introduction of the insulating component is carried out by exposing it to pressure pulses initiated by a pulse generator located in the bottom-hole zone, and the value of the pulses the pressure is at least 5.0 MPa greater than the pressure of the hydrostatic column of fluid at the depth of processing, but not more than the value of the fracture pressure, and the gap between the inner surface of the well and the pulse generator housing does not exceed 10 mm.  2. The method of processing the bottom-hole zone of the wellbore according to claim 1, characterized in that the interval of the impact zone of the pulses along the axis of the well is 1.0-1.5 m.  3. The method of processing the bottom-hole zone of the wellbore according to one of claims 1 and 2, characterized in that the frequency of the gas pulses initiated by the generator is set to a multiple of the frequency of the reflected gas waves in the zone between the generator body and the inner surface of the well.  4. The method of processing the bottom-hole zone of the wellbore according to one of claims 1 to 3, characterized in that the pulsed effect on the insulating component is carried out at intervals, in zones of intense water inflow.