RU2119045C1 - Method for completion of well - Google Patents

Abstract

FIELD: oil and gas production industry. SUBSTANCE: this is used in opening of productive beds in oil and gas wells. According to method, installed into casing string is shaped charge of explosive and installed simultaneously with it is gas-generating charge of solid fuel. Then both charges are initiated. Perforation passage is made in casing string and in surrounding productive bed together with increasing area of its filtration surface. Initiation of gas-generating charge is performed by means of shaped charge of explosive. Increasing area of filtration surface of productive bed is achieved by directing gas produced at burning of gas-generating charge into perforation passage. Application of aforesaid method ensures increase in productivity of oil and gas wells and cuts time period needed for realization of method. EFFECT: higher efficiency. 3 cl, 1 dwg

Description

 The invention relates to the mining industry and is intended for opening productive formations in oil and gas wells by creating perforation channels and fracturing in the near-wellbore zone.

 When opening productive formations in oil and gas wells, there is a problem of increasing the surface area of the filtration and increasing or maintaining at a natural level of permeability of the formation in the area of perforation channels.

 There is a known method of completing wells, which consists in making perforations using cumulative charges in the casing, cement stone and surrounding reservoir, and cumulative charges are installed in the casing of the well prior to perforation (Rifle-blasting apparatus. Reference book, edited by L.Ya. Friedlander, M., Nedra, 1990). The formation of perforation channels occurs as a result of the impact on the walls of the borehole and near-borehole zone of the formation of a cumulative jet resulting from the explosion of a blast of explosive charge.

 When introduced into the reservoir, the cumulative stream first overcomes the zone of mudding adjacent to the cement ring (the zone of formation contamination with drilling and cement mortars), the permeability of which is significantly reduced compared to the natural level. This leads to the fact that the effective filtering surface is the surface of the end (most remote) part of the perforation channel.

 The increase in the surface area of the filtration is achieved by increasing the breakdown ability of cumulative charges, which, in turn, ceteris paribus requires an increase in the mass of explosives. This increases the likelihood of destruction of the casing string and cement ring, which may entail a decrease in productivity and even the failure of the well. Another disadvantage of this method is the compaction of the walls of the formed channels, which, in turn, reduces their permeability and fluid flow. To restore the natural permeability in the area of perforation channels, additional measures are required to influence the formation.

 Another known method is described in US patent N 4673039, MKI E 21 B 43/263.

 The method consists in drilling a well, installing a casing in it, cementing the space between the casing and the wall of the well. After the cement has hardened, the well is filled with liquid, perforations are made in the casing and a gas-generating charge of solid fuel is installed in it with its subsequent initiation. When a solid fuel charge is burned, gaseous products are formed that squeeze the wellbore fluid through the perforations, causing the formation to rupture (crack) in the near-wellbore zone. The resulting cracks increase under the action of the pressure of the fluid squeezed out in them and continue to grow deep into the reservoir during the entire time the pressure pulse is applied. As a result of this process, the surface area of the filtration of perforation channels increases significantly.

 The disadvantages of this method are the application of pressure through the borehole fluid, polluting the formed filtration surface and reducing its permeability compared to the natural level, and the use of separate technologies for making perforations and creating cracks.

 These disadvantages are partially eliminated in the method described in the source Boydachenko V.N. and others. Geophysical and perforating blasting in exploration wells, M., Nedra, 1976, s.231-233 and selected for the prototype of the proposed solution.

 The method consists in installing cumulative charges in the well casing and, at the same time, powder charges with their subsequent initiation.

 Cumulative charges are initiated by an electric detonator, powder charges are initiated by an electric igniter and an igniter charge. First, cumulative charges are triggered and perforations are made in the casing, and then powder charges are ignited. During the combustion of powder charges, gaseous products are formed that squeeze the wellbore fluid through the perforations, causing a formation of a network of cracks in the formation. As a result of this process, there is a significant increase in the surface area of the filtration of perforation channels.

 The disadvantages of the prototype are the application of pressure through the borehole fluid, polluting the formed filtration surface and reducing its permeability compared to the natural level, and the placement of cumulative and powder charges spaced apart from each other in space.

The technical problem solved by the claimed method is to increase the productivity of oil and gas wells while ensuring their safety and reducing the time required for completion of the wells. The specific technical result achieved with this:
- a significant increase in the surface area of the filtration of perforation channels due to the increase in channel size and extensive crack formation in the borehole zone of the reservoir;
- maintaining the permeability of the filtration surface at a natural level or increasing it above this level;
- reducing the cost of completing wells by performing all the basic operations in one go and reducing the size of the device launched into the well by two times.

 To solve the problem in the well-known method of well completion, which includes installing a cumulative charge in the casing and simultaneously with a gas-generating charge from solid fuel with their subsequent initiation, performing a perforation channel in the casing and the surrounding reservoir, and increasing the area of its filtration surface, according to the invention the initiation of a gas-generating charge is carried out by a cumulative charge, while the increase in the surface area of the filtration of the reservoir uschestvlyayut by moving a perforation gas channel of the combustion gas generating charge. Initiation of a gas-generating charge is carried out on at least one of its surfaces: on the end, located perpendicular to the direction of the cumulative jet, on the outer side surface, on the inner surface along the axis of the charge. Together with the formed gas, at least one or in various combinations is transferred to the perforation channel: part of the gas-generating charge from solid fuel, chemical reagent, proppant elements.

The initiation of a gas-generating charge by a cumulative charge allows you to combine several technological operations in time and space:
- punching a perforation in the casing, cement stone and reservoir;
- gas-erosive cleaning of the formed channel with the ablation of a surface layer densified by a cumulative jet from its walls;
- fracture of the reservoir in the area of the perforation channel with extensive crack formation;
- fixing the formed cracks in the open form by proppant elements;
- the introduction into the perforation channel and into the fracturing zone of chemicals that increase the permeability of the filtration surface and / or composing rocks.

 In this case, the formation of the channel occurs in two stages. First, with the help of a cumulative jet, a conventional perforation channel is obtained, and then its growth and cracking of the walls occur as a result of gas erosion and compression effects of the jet of solid fuel combustion products. This significantly increases the volume (3-4 times) of the perforation channel and, consequently, the area of its walls. In addition, an additional significant increase in the surface area of the filtration occurs as a result of intense cracking in the walls of the channel and the borehole zone of the formation.

 The initiation of a gas-generating charge by a cumulative charge makes it possible to combine the cumulative stream and the gas generated during the combustion of the gas-generating charge into a single stream, which avoids contact of the formed filtration surface with the well fluid, which can significantly reduce its permeability, at all stages of the secondary opening of the reservoir until the start fluid recovery when the pressure in the well does not exceed reservoir pressure (depression mode). Thus, the permeability of the formed filtration surface remains at a level close to natural.

 When unburned solid fuel is thrown into the perforation channel, its combustion takes place in a limited volume, and at the final stage of the process, combustion products flow back into the well, which contributes to more intense gas erosion and increased pressure in the channel, especially in the peripheral zone of crack formation, compared to case when gases are thrown into the perforation channel. This significantly affects the growth of cracking. When proppant elements are used, the latter are deeply pushed into the resulting cracks and prevent them from closing after a pressure drop, which increases the duration of the existence of an extensive filtration surface. If the gas-generating charge contains a chemical reagent that increases the permeability of the filtration surface and / or the constituent rocks in the perforation zone, the latter is effectively introduced into the perforation zone of the formation and contributes to an increase in fluid flow by physicochemical action on the channel walls and formed cracks. Various options for initiating a gas-generating charge (both used individually and in different combinations) contribute to the formation of a high-speed gas flow directed along the axis of the cumulative charge into the punched perforation channel. The initiation of a gas-generating charge along the outer lateral surface also prevents lateral expansion of the combustion products. Initiation along the inner surface along the axis of the charge provides a progressive increase in the combustion zone and, therefore, a progressive law of gas evolution.

 The drawing shows a variant of the device for implementing the proposed method.

 The device contains a charge 1 blasting explosive with a cumulative lined with metal 2 recess, a shell 3, a means of initiation 4 and a gas-generating charge 5 of solid fuel. Charge 5 is made with a hole 6 along the axis for the formation and passage of a cumulative jet. Charge 5 is located directly at the base of the cumulative charge and ignites as a result of exposure to detonation products of a blasting explosive. The device is installed in the casing 7 with a cement ring 8.

 The proposed method is as follows. In the casing 7 with a cement ring 8 establish a cumulative charge 1 and a gas generating charge 5 of solid fuel, such as gunpowder. Initiate the cumulative charge. When the explosive charge is triggered, a perforation channel is formed by a cumulative jet. As a result of the impact of the products of the explosion of the explosive charge 1, the gas-generating charge 5 is ignited, and the gases formed, together with the part of the gas-generating charge that failed to burn, are released into the channel formed by the impact of the cumulative jet. The massive shell 3 thus contributes to the directed discharge of the substance of the gas-generating charge 5, creating an inert (and partially strength) backwater for the products of explosion and combustion. As a result of thermal, gas-erosion and compression effects of solid fuel combustion products formed inside the massive shell and inside the perforation channel, the surface is densely packed and contaminated from the channel walls, it is cleaned and expanded with cracking of the surrounding rock. A high pressure is maintained in the channel for a long time (compared with the time of the cumulative jet impact), which leads to the formation of extended cracks in the component rocks in the perforation zone. To prevent crack closure after pressure drop, proppant elements, such as metal balls, gravel, etc., are introduced into the perforation channel together with the gas-generating charge substance. These elements are pushed by high-pressure gas jets into the cracks and fix them in the open state. Such elements can be placed inside a massive shell or introduced into the composition of the gas-generating charge. The filtration surface formed during perforation consists of the surface of the walls of the perforation channel and the surface of the walls of cracks in the surrounding rock. To increase the permeability of the filtration surface, to prevent clogging of the pores and to increase the flow cross sections of cracks, a chemical reagent is introduced into the perforation zone together with the gas-generating charge substance. Such reagents can be placed inside a massive shell or introduced into the composition of the gas-generating charge in the form of an impurity, in capsules or granules.

The technical result of the proposed method is:
- a larger volume of perforation channels and, therefore, a large surface area of the filtration while maintaining its permeability close to natural;
- the relative simplicity and speed of the method, allowing at the same time to obtain a perforation channel and to take measures to increase well productivity (2-3 times);
- stabilization of the productive parameters of the perforation zone, ensuring the maintenance of productivity at a high level for a longer time.

Claims (5)

 1. The method of well completion, including the installation of a cumulative charge in the casing and at the same time a gas-generating charge from solid fuel with their subsequent initiation, the perforation channel in the casing and the surrounding reservoir, and the increase in the area of its filtration surface, characterized in that the initiation gas-generating charge is carried out by a cumulative charge, while the increase in the surface area of the filtration of the reservoir is carried out by moving in perforation the channel of gas generated during the combustion of a gas generating charge.  2. The method according to claim 1, characterized in that the initiation of the gas-generating charge is carried out on at least one of its surfaces: on the end, located perpendicular to the direction of the cumulative jet, on the outer side, on the inner surface along the axis of the charge.  3. The method according to claim 1, characterized in that, together with the formed gas, a part of the gas-generating charge from solid fuel is moved into the perforation channel.  4. The method according to claim 1, characterized in that together with the formed gas, a chemical reagent is transferred to the perforation channel.  5. The method according to claim 1, characterized in that together with the gas formed, proppant elements are moved into the perforation channel.