RU2607668C9 - Device for treatment of bottom-hole zone - Google Patents

Abstract

FIELD: mining.

SUBSTANCE: invention relates to mining industry and intended for productive formations opening in oil and gas wells during drilling and blasting operations. Device for bottom-hole zone treatment contains hollow-carrier perforator or capsule-type perforator in casing string with cumulative and gas-generating charge of solid fuel, combined with acid reagent. Cumulative charge recess lining is fluoroplastic or other fluorine- and/or chlorine-containing polymer material. Cumulative and gas-generating charges initiation from corresponding to each charge initiation device is carried out simultaneously. Solid fuel, combined with acid reagent, is ammonium perchlorate and epoxide compound mixture in following ratio of components, wt%: ammonium perchlorate – 70–90, epoxide compound – 30–10.

EFFECT: enabling increasing efficiency of design well flow rate achievement, especially under carbonate reservoir conditions, elimination of well and its perforation channels blockage with fragments of cumulative charges sealed housing, elimination of casing pipes damage and deformation due to absence of metallic cumulative jet effect, improving acid reagent action efficiency.

3 cl, 4 dwg

Description

The invention relates to the mining industry and is intended for opening productive formations in oil and gas wells during drilling and blasting operations and to increase the productivity (flow rate) of oil and gas wells.

A device is known for processing the bottom-hole zone of a well, including an air chamber with atmospheric pressure and a length of 20-50 m, a receiving perforated metal chamber with a solid gas-generating composition placed in it - TGC, consisting of two parts, where the first part facing the air chamber is made from a combustible high-strength with low-gas separation composition — ICS, the second part of the THC is made of a thermogenerating composition, said receiving chamber is provided at its upper end with a destructible calibrated diaphragm it is connected with a coupling made with holes, with an additional receiving chamber, in which the ICS, an igniter and a calibrated polymer diaphragm are located, connected by a coupling with an additional air chamber, made in the length of 1.5-2.5 m, the ICS is made of a mixture of . %: ammonium perchlorate - 35-40, epoxy compound - a mixture of resin ED-20, plasticizer EDOS and hardener AF-2M - 65-60, and the thermogenerating composition is made from a mixture of the composition, wt. %: ammonium nitrate - 35-38, potassium permanganate - 1.0-2.8, barium nitrate - 14.0-14.5, aluminum-iron termite - 30.0-31.5, aluminum ASD-1 - 1.0 -1.5, epoxy resin ED-20 - 12.4-13.0, plasticizer EDOS - 0.5-0.7, hardener AF-2 - 1.8-2.3 - RU 2330951 C1, E21B 43 / 25,2008 g.

The disadvantages of the known device are as follows: insufficiently high combustion parameters (temperature, burning rate, amount of gaseous products) of both proposed gas generating compositions; clogging of the perforation channels and the bottomhole zone of the well with both solid combustion products of the thermogenerating composition (oxides and chlorides of manganese, iron, potassium, barium, aluminum), and fragments of the destroyed calibrated diaphragm; the need for the laborious stage of lowering and removing from the well a metal perforated chamber.

A well-known method of well completion, including the installation of a cumulative and gas-generating charge of solid fuel and an acid reagent into the casing, followed by the initiation of a gas-generating charge by a cumulative charge, performing a perforation channel in the casing and the surrounding reservoir, and transferring gas generated during combustion of the gas-generating charge into the perforation channel and then acid reagent - RU 2138623 C1, E21B 43/117, 1999

The disadvantages of the method, as well as the device that implements it, include: low efficiency to achieve the design flow rate of the well, especially in conditions of a carbonate reservoir; blockage of the well by fragments of the sealed housing of the cumulative charges and increased destruction and deformation of the casing pipes and the environment due to the blasting and high-explosive action of the explosion products and the impact of the metal cumulative jet of the charge lining when using shell-free cumulative charges (single shell leak-free cumulative perforators); clogging of perforation channels due to a metal cumulative jet of charge lining stuck in them when using case-shaped cumulative charges (case-tight sealed cumulative rotary hammers of reusable action); partial destruction of the gas-generating charge from solid fuel during its subsequent initiation due to the products of the explosive of the cumulative charge explosive, low efficiency of the acid reagent.

The closest analogue is a device that implements a method of completing a well, including installing a cumulative and gas-generating charge of solid fuel and an acid reagent in the casing followed by initiating a gas-generating charge with a cumulative charge, performing a perforation channel in the casing and the surrounding reservoir and in the gas perforation channel, generated by the combustion of a gas generating charge, and an acid reagent, while solid fuel and an acid reaction source that combine organize simultaneous movement in the perforating gas channel of the combustion gas-generating charge and an acid reagent to a solid fuel source and an acidic reagent, a mixture of ammonium perchlorate, ammonium bifluoride and an epoxy compound in the following ratio, wt. %: ammonium perchlorate - 30-45, ammonium bifluoride - 45-65, epoxy compound - 5-10, or a mixture of ammonium nitrate, ammonium bifluoride, ammonium chloride and epoxy compound in the following ratio of components, wt. %: ammonium nitrate - 30-35, ammonium bifluoride - 45-50, ammonium chloride - 17-20, epoxy compound - 3-5 - RU 2173767 C1, E21B 43/117, 2001

The disadvantages of the prototype method are the same as the above analogue, and, in addition, it also has insufficiently high combustion parameters (temperature, speed, amount of gaseous products) of both of the proposed gas-generating compositions.

The technical problem solved by the invention is to increase the efficiency of achieving the design flow rate of a well, especially in a carbonate reservoir, to prevent clogging of the well and its perforation channels with fragments of the hermetic shell of cumulative charges, the exclusion of destruction and deformation of the casing due to the absence of the impact of a metal cumulative jet; increasing the effectiveness of the acid reagent.

This problem is solved in a device for processing the bottom-hole zone of a well, comprising a casing or open-hole perforator in a casing with a cumulative and gas-generating charge of solid fuel combined with an acid reagent, the lining of the cavity of the cumulative charge is a fluoroplastic or other fluorine and / or chlorine-containing polymer material, the initiation of cumulative and gas-generating charges from the corresponding to each charge means of initiation is carried out simultaneously, and as a solid fuel, combined first with an acidic reagent, a mixture of ammonium perchlorate and an epoxy compound in the following ratio, wt. %:

ammonium perchlorate 70-90 epoxy compound 30-10

In the case of using a case perforator, to increase the efficiency of use of the device, its plugs, bushings and plugs are made of fluoroplastic or other fluorine and / or chlorine-containing polymer material; in the case of a case-free perforator, sealed cases of cumulative charges are made of the same materials.

In FIG. 1, 2 are photographs illustrating the results of experimental tests: in FIG. 1 - the size of the perforation channel when punching a steel disk-simulator with a copper cumulative funnel, in FIG. 2 - the size of the perforation channel when punching a steel disk-simulator with a fluoroplastic cumulative funnel. In FIG. 3 shows the dependence of the combustion temperature - T, K, of mixtures of the type ammonium perchlorate - epoxy resin on their composition (wt.%); in FIG. Figure 4 shows the dependence of ideal working capacity (gunpowder force) - FP, kJ / kg, of mixtures of the type ammonium perchlorate - epoxy resin on their composition (wt.%).

When processing the bottom-hole zone of the well, cumulative charges are installed in the casing, the lining of the recess of which is fluoroplastic or other fluorine and / or chlorine-containing polymer material, which forms a large amount of fluorine and / or chlorine-containing only gaseous products during the explosion. Gas-generating charges from solid fuel, combining the role of a pressure generator and an acid reagent, and cumulative charges are simultaneously initiated by separate means of initiation.

The use of separate means of initiation for the cumulative charges and the gas-generating composition of solid fuel, in contrast to the ignition of the gas-generating charge from solid fuel during its subsequent initiation due to the products of the explosive of the cumulative charge, increases the reliability of the device, reduces the number of failures due to the destruction of the gas-generating charge from solid fuel explosion products of cumulative charges, and also increases the size and length of the formed perforations channels - increases the efficiency of achieving the design flow rate of the well, by increasing the time of exposure to high pressure in the perforation channels formed by cumulative charges, taking into account the back pressure in the bottomhole zone of the well.

In this case, perforation channels in the casing and the surrounding reservoir are performed due to the movement of gas generated in the combustion of two sources of only gaseous substances into the perforation channels: a gas-generating charge of solid fuel combined with a source of acid reagent, which is used as a mixture of ammonium perchlorate and epoxy compound with the specified ratio of components, and fluoroplastic or other fluorine and / or chlorine-containing polymeric material - facing cumulative excavation charges rows forming with the explosion of a large amount of fluorine and / or chlorine-containing only gaseous products.

Polyvinyl chloride, fluoropolymers of the F4, F3, F2 type, http://www.kp.ru/guide/chto-takoe-ftoroplast.html and other types can be used.

The invention is implemented as follows.

In the casing of the well over a range of lengths of the perforated reservoir, a structure of reusable or disposable case perforator having a sealed or non-hermetic housing in which cumulative and gas-generating charges are placed, it is possible to use the design of a standard multiple case perforator, for example PK-103D, or designs of standard open-hole punch, for example, tape type PK-C65, or other designs of standard cumulative punch s.

In this case, the lining of the cumulative recesses, plugs, bushings, plugs (in the case of using case perforators), sealed cases of cumulative charges (in the case of using case-free perforators) are made of materials that form a large amount of fluorine and / or chlorine-containing only gaseous products during explosion forming solid fragments or explosion products, which reduces the clogging of the inner space of the pipe and perforation channels due to metal fragments and metal cumulative jet. One or more gas-generating charges are placed inside or outside the body of the cumulative charges (depending on the design used and the technical need, as well as the features of the well). As a solid fuel and a source of acid reagent, a mixture of ammonium perchlorate and epoxy compound is used in the following ratio of components, wt. %: ammonium perchlorate - 70-90, epoxy compound -30-10.

The epoxy compound, as an option, may consist of ED-20 epoxy and polyethylene polyamine (PEPA), in a ratio of 10: 1. Other epoxy compounds are possible.

The cumulative charges and means of igniting the gas-generating compounds are simultaneously initiated by applying voltage through the cable to the corresponding initiating means. When the cumulative charge is triggered, the formation of a strongly heated and high-pressure cumulative jet from extremely highly reactive fluorine, chlorine and / or their compounds contained in the fluoroplastic or other fluorine and / or chlorine-containing polymer material of the cumulative cavity lining destroying (“burning”) is formed shell, casing, cement ring and the space behind the cement ring. A perforation channel is formed that is not contaminated with metal. As a result of the simultaneous ignition of the gas-generating charge, the gases formed are ejected into the channel formed by the impact of the cumulative jet. As a result of the thermal, gas-erosion, and compression effects of the products of combustion of the gas-generating charge, intensive densification of the compacted and contaminated layer from the channel walls occurs, its cleaning and expansion with cracking of the surrounding rock, including due to the action of an acid agent (hydrochloric and hydrofluoric acids - HCl, HF, respectively).

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 composing rocks in the perforation zone. 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. As a result, the permeability of the filtration surface is increased, clogging of the pores is prevented, and the cross sections of cracks in the perforation zone are increased.

To confirm the operability of the device, the following experimental tests were performed:

- a comparative study of cumulative charges with shell-free, (simulated by the presence of wooden, pine shell materials of lining of cavities of cumulative charges), copper and fluoroplastic (grade F4) materials on lining of recesses on targets simulating conditions in the casing of wells;

- determination of explosive characteristics (heat, burning rate, temperature, composition of combustion products, sensitivity and the presence of a transition of combustion to detonation) of solid fuel and an acid reagent source, which was used as a mixture of ammonium perchlorate and epoxy compound in the following ratio of components, wt. %: ammonium perchlorate - 70-90, epoxy compound - 30-10.

The epoxy compound consisted of ED-20 epoxy resin and polyethylene polyamine (PEPA), in a ratio of 10: 1.

A comparative study of cumulative charges with shell-free, copper and fluoroplastic materials on targets simulating conditions in the casing of wells was carried out under the following conditions:

- explosive equipment - Plastit PVV-7 (based on a mixture of phlegmatized RDX and aluminum powder): density PVV-7 - about 1.50 g / cm ³ , heat of explosion - 1700 kcal / kg; detonation speed - about 7000 m / s;

- the geometric parameters of the cumulative recesses, the thickness, the parameters of the explosive equipment PVV-7 are the same;

- body of charges - ftoroplast F4, density - about 2200 kg / m ³ ;

- geometric dimensions of conical shaped funnels: height - 13.0 mm; diameter - 26.0 mm; thickness - 2.0 mm;

- the mass of cumulative funnels (lining), depending on the material used: non-shell (pine) - 0.5 g, copper - 15.0 g, fluoroplastic FP-4 - 3.0 g;

- witness-simulator of casing pipe - steel disks with a diameter of 150.0 mm and a thickness of 7.0 mm made of alloy steel grade X18H10T;

The blasting of charges was carried out on concrete blocks simulating carbonate rock, cumulative charges were placed directly on the surface of witnesses-steel disks located on the surface of concrete targets, which were previously filled with a layer of water-simulator of well fluid, 10.0 mm thick, at a height of about 30.0 mm, corresponding to the optimal height of the formation of the cumulative jet with the given geometric parameters of the cumulative funnels.

The initiation was carried out by standard electric-electronic detonators of the EHP type using plane-wave generators (PVG), the total mass of explosive material was about 70 g PVV-7. Photo and video recording and recording of each of the series of test results was carried out.

As a result of the experimental comparative tests, data were obtained confirming the following:

- non-shell (pine) cumulative funnels, ceteris paribus, do not provide penetration of steel casing simulator disks with a thickness of 7.0 mm, but cause their significant deformation;

- metal (copper) cumulative funnels, ceteris paribus, provide penetration of steel disks-simulators of casing 7.0 mm thick and the introduction of a cumulative jet into concrete to a depth of about 3-4 diameters of the funnel, and also cause their significant deformation. The diameter of the perforation channel is about 5-6 mm due to the effect of welding by explosion of the copper lining at the edges of the hole and jamming of the cumulative jet - FIG. one;

- fluoroplastic (F4) cumulative funnels, ceteris paribus, provide both punching steel disks-casing simulators 7.0 mm thick and the formation of perforation channels without any introduction of cumulative jet material into concrete to a depth of about 3-4 funnel diameters ( no worse than metal), and also do not completely cause deformation of steel casing pipes and without the formation of solid explosion products. The diameter of the perforation channel is about 18-20 mm, exceeds the diameter of the perforation channel of the copper lining - Fig. 2.

The use of a different name of a fluorine and / or chlorine-containing polymer material, which forms a large amount of fluorine and / or chlorine-containing only gaseous products during the explosion, for example, fluoroplastics of the type F4, F3, F2, polyvinyl chloride, taking into account the well-known high chemical the activity of acid agents (hydrochloric - HCl and hydrofluoric acids - HF), as well as the generally known minimum pressures and temperatures - des TKI-hundreds of thousands and ati 2000-3000 K, will lead to the same effect observed cumulative perforation.

The results of experimental tests confirm the operability of the device in terms of using cumulative extraction of charges of materials that form a large amount of fluorine and / or chlorine-containing only gaseous products during the explosion.

The determination of explosive characteristics (heat, burning rate, temperature, composition of combustion products, sensitivity and the presence of a transition of combustion to detonation) of solid fuel and an acid reagent source, which is used as a mixture of ammonium perchlorate and epoxy compound with the specified ratio of components, was also carried out by calculation and experimental tests of a series of charges in which the epoxy compound consisted of epoxy resin ED-20 and polyethylene polyamine (PEPA), in a ratio of 10: 1.

During the combustion of a mixture of ammonium perchlorate and an epoxy compound, which is proposed as a solid fuel and an acid reagent source, with a specified ratio of components, in the entire experimental pressure range from 0 to 1300 ati, a stable, high-velocity combustion in a turbulent mode without inclinations to a transition of the combustion mode was noted into detonation.

The following important factual data have been established, indicating that during the combustion of 1 kg of a mixture of ammonium perchlorate and an epoxy compound, which is proposed as a solid fuel and an acid reagent source, combustion parameters are achieved that significantly exceed the prototype composition, namely:

- the combustion temperature of these mixtures (depending on the composition) is from 2400 to 3600 K, which significantly exceeds the prototype composition: in FIG. 3 shows the dependence of the combustion temperature - T, K of mixtures of the type ammonium perchlorate - epoxy resin on their composition (wt.%);

- the heat of combustion of these mixtures (depending on the composition) is from about 4500 to 5200 kJ / kg, which also significantly exceeds the prototype composition;

- the maximum ideal performance (gunpowder force) during the combustion of these mixtures (depending on the composition) is up to 1134 kJ / kg, which significantly exceeds the prototype composition: in FIG. 4 shows the dependence of ideal performance (gunpowder force) - FP, kJ / kg of mixtures of the type ammonium perchlorate - epoxy resin on their composition (wt.%);

- when this mixture is burned, practically only gaseous products are formed in an amount of 760-870 l / kg (depending on the content of the epoxy compound) in the form of a mixture of СН4, HCl, H2O (g), N ₂ (in contrast to the prototype mixtures with the volume of gaseous products about 700 g / kg); in addition, during the combustion of 1 kg of this solid fuel, about 0.250-0.255 kg of an acid agent (depending on the content of the epoxy compound) is formed from this mixture — hydrochloric acid (instead of about 0.1 kg of hydrochloric acid in the prototype compositions);

- during the combustion of the mixture of ammonium perchlorate and epoxy compound, which is proposed as a solid fuel and an acid reagent source, with the indicated ratio of components, in the entire experimental pressure range from 0 to 1300 ati, steady combustion with high speeds in a turbulent mode without inclinations to the transition of the combustion mode was noted into detonation. In addition, when using a standard plastic explosive based on hexogen of the Plastit PVV-7 type (based on a mixture of phlegmatized hexogen and aluminum powder) as an equivalent charge, weighing 15-50 g, both in the contact case (without a gap) and with air gap (with a gap), with the charge diameters of this mixture from 18 to 26 mm, only its dispersion (scattering) was observed, without any characteristic signs of the explosive, cumulative and high explosive effect, which indicates safety spine and extreme insensitivity of the composition to the initial detonating impulse and impact.

The above data indicate the health and benefits of this invention compared to the prototype.

Technical effects from the use of the device are as follows:

- greater than in the prototype, the 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 process, allowing you to simultaneously get a perforation channel and take measures to increase well productivity;

- stabilization of the productive parameters of the perforation zone, ensuring the maintenance of productivity at a high level for a long time;

- reduction of the amount of contamination, clogging of the well through the use of non-metallic, forming only gaseous products of structural elements: seals, cumulative lining, bodies of cumulative charges;

- the exclusion of the destruction of the casing strings, the surrounding space, the increase in the number of perforation channels, realized by reducing the mass of the explosive cumulative charges necessary to obtain a stable cumulative effect.

Claims (4)

1. A device for processing the bottom-hole zone of a well, comprising a casing or open-hole perforator in a casing with a cumulative and gas-generating charge of solid fuel combined with an acid reagent, characterized in that the lining of the cavity of the cumulative charge is fluoroplastic or another fluorine and / or chlorine-containing polymer material, the initiation of cumulative and gas-generating charges from the corresponding means of initiation of each charge is produced simultaneously, and as a solid fuel, the combination combined with an acid reagent, use a mixture of ammonium perchlorate and epoxy compound in the following ratio of components, wt.%: ammonium perchlorate 70-90 epoxy compound 30-10 2. The device according to p. 1, characterized in that when using a casing punch, its plugs, bushings, plugs are made of fluoroplastic or other fluorine and / or chlorine-containing polymer material. 3. The device according to p. 1, characterized in that when using a die-free perforator, the sealed cases of cumulative charges are made of fluoroplastic or other fluorine and / or chlorine-containing polymer material.

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