RU2178072C1 - Carrier-free sectional charge for formation gas-hydraulic stimulation - Google Patents

Abstract

FIELD: means for oil recovery. SUBSTANCE: carrier-free sectional charge includes ignition unit and charge sections. They are made of compositions burning in water, water-oil and acid media. Charge has one or several ignition sections for ignition of main sections, and accessories, including parts for assembly of charge sections, passing through central channel of each section, and parts tightening the sections adjacent to one another. Accessories include composite rod passed through central channel of each section. Connected to both ends of composite rod are streamlined cones - centralizers for tightening the charge sections to one another. Diameter of cones-centralizers exceeds that of charge sections. Centering rings are installed between charge sections and their diameter exceeds that of charge sections. Rings are made to preserve dynamics of charge burning. Located between lower cone-centralizer and charge sections is dispenser for withdrawal of gas flow formed in charge burning. In this case, sum of dispenser passage holes is calculated for provision of minimal load on rod and maximum action on formation. Installed between upper cone and charge sections is a spring for flexible pressing of sections and compensation for linear expansion of charge at high temperature in well. Charge sections have no protective cover to ensure burning over entire surface of charge. Configuration of central channel has developed surface of burning to provide for preset time of charge burning and pressure for hydraulic fracturing of formation. EFFECT: provided efficient stimulation of formation with its rupture without disturbance of integrity of casing and cement stone. 3 cl, 1 dwg

Description

 The invention relates to means for oil production.

 One of the rational and effective methods of influencing the borehole zone of a productive formation in order to establish a reliable hydrodynamic connection between a well and a formation is to break the formation with products of combustion of a powder charge. Under the influence of liquid and gas pressure equal to or greater than the rock, rocks are irreversibly deformed. The method of fracturing powder gases is based on the mechanical, thermal and chemical effects of gases on rocks and saturating fluids. In order to break the formation and thermogasochemical impact on its borehole zone, PGD powder generators are used. BK-100M, PGD. BK-150 and pressure accumulators ADS-5 [1].

 Known powder pressure accumulators ADS-5 and ADS-6, differing in the design of the powder charge. The powder charge of the ADS-5 is channelless. The pressure accumulator ADS-6 consists of igniting and burning powder charges. Powder charges do not have an airtight shell and are in contact with the well fluid. On the side surface of the powder charges there are diametrically opposite grooves, where a steel rope is laid, designed to assemble and lower the string of powder charges into the well. In order to protect against impacts and friction against the casing, the powder charges in the lower part are equipped with a pallet, and in the upper part, a clip. The lower clip is used to set the lower powder charge [2].

 Pressure accumulators of the type ADS are slow burning and do not create pressures exceeding the mountain pressure, but are used for thermogasochemical treatment of the formation.

 A known device for fracturing - pressure generator PGD-BK-150 [3]. The gas generator charge, consisting of several interconnected powder charge sections having a cylindrical shape with a central channel of circular cross section, is mounted on a support tube made of aluminum alloy. Threads and grooves at the ends of the support pipe allow you to connect the required number of sections of the powder charge with the help of fittings. Inside the support tubes are pyrotechnic igniters. In the lower part, the support pipe is sealed with a plug and secured with a tip; in the upper part, a single-use cable head with a support washer. In the head there is a squib, sealing parts, tip, gasket. Over the entire surface, the charge is covered with a protective coating - waterproofing composition, and on the outer side surface - with an additional coating that protects the charge from friction and impacts on the column.

 The generator operates as follows. When an electric impulse is applied through the cable, the igniter is activated, which ignites the starting igniters located in the channels of all the support pipes. The resulting combustion products of starting igniters burn through the walls of the pipes and ignite the powder charges on the surface that are in contact with the pipes.

 Using these devices does not always give a positive effect. This is due to the fact that the protective coating, connecting nodes, support pipes remain in the well, which leads to clogging of the well. With a small depth of the bottom from the perforation zone, additional cleaning of the well is necessary for re-opening the formation and installing the pump. There is a cable overlap. During the charge burning, the liquid column rises by 15-20 m, which can lead to the destruction of the casing string due to the pressure drop in the well and annulus exceeding its strength.

 As a prototype, the device PGD. BK - 100 M [4]. Unpacked sectional powder charge on a geophysical cable, including powder sections made of solid rocket fuel: one ignition section and five main charge sections installed close to each other. Each charge section has a central channel. In the ignition section of the charge, the diameter of the channel is larger than in the main sections. As an ignition section of a charge, a support tube with pyrotechnic igniters is used. In the upper part, the pipe is sealed with a cable head to which a geophysical cable is attached with two main charge sections with an upper tip attached to it. In the lower part, the pipe is sealed with a plug with a cable attached to it, on which three main charge sections are put on close to the ignition section. At the bottom of the charge there is a tip fixed with a nut. Charge burning occurs from the channel. The lateral surface of the charge has a protective coating that protects the charge from friction and impact on the column. To register the maximum pressure generated in the well by a powder generator, a crasher device is attached to the cable at a distance of 10 m from the upper end of the generator. The value of the created pressure is found according to a special table attached to each batch of crushed columns depending on the degree of compression of the column.

 The generator operates as follows. When an electric impulse is applied through the cable, the igniter is activated, which ignites the starting igniters located in the channel of the support pipe. The resulting combustion products of starting igniters burn through the walls of the pipes and ignite the ignition section of the charge. The products of combustion of the igniter charge ignite the main charges. Charge burning comes from the central channel.

 Using these devices does not always give a positive effect. This is due to the fact that the charges are collected on the geophysical cable, at the junction of the charges during their burning, overheating and rupture of the wireline cable occur, the charge sections are disconnected, which can lead to an emergency. In addition, the prototype has all the disadvantages that PGD - BK-150.

 A sectional free sectional charge for gas-hydraulic impact on the formation is proposed, including ignition unit 1, charge sections made of compositions that provide combustion in aqueous, oil-water, and acidic environments, for example, from ballistic solid propellant and equipment. One or more sections are igniter 2, and the rest, igniting from it, are the main 3. There is a groove 4 at the end of the ignition section, in which the ignition unit 1 is connected to the power wire.

 The equipment includes parts for collecting charge sections and parts for tightening sections close to each other. To collect sections of the charge using a composite rod 5 (composed of several elements). Using a composite rod allows you to collect a charge from a different number of sections and simplify the delivery of the rod to the well. The rod is passed through the central channel of each charge section. Between the charge sections, centering rings 6 are installed that are larger in diameter than the diameter of the charge sections, preventing the charge sections from moving relative to each other, and in the case of a bend of the rod in an inclined well, touch the walls of the casing. Rings are made in such a way that the dynamics of charge burning does not change. From both ends, cones-centralizers 7, 8 are attached to the rod, which compress and tighten the charge sections close to each other. Centralizer cones are streamlined to reduce the mechanical load on the bar. Their diameter exceeds the diameter of the charge sections, which allows you to protect the charge from friction and impact on the column. Between the lower cone-centralizer 7 and the charge sections is a diffuser 9 for the removal of the gas stream generated during the combustion of the charge. The sum of the bore openings of the diffuser holes is designed in such a way as to ensure a minimum load on the rod and ensure maximum impact on the formation. Between the upper cone 8 and the charge sections, a spring 10 is installed, which is designed to elasticly compress the charge sections and compensate for the linear expansion of the charge sections at high temperatures in the well. An extension rod 11 is attached to the upper part of the cone 8, which serves to reduce the turbulence of the gas flow rising upward and to reduce the heat load on the geophysical cable 12, which is connected to the device through the instrument head 13 and cable lug 14. Such an assembly ensures the integrity of the structure under mechanical and thermal loads during the combustion of the charge and its descent into the well.

 The charge sections do not have a protective coating; therefore, the charge is burned over the entire surface of the charge. The configuration of the central channel has a shape with a developed combustion surface, which provides a predetermined burning time and pressure required for hydraulic fracturing.

 A measuring unit 15 is mounted on the cable, which is used to register pressure, temperature, and charge burning time parameters, including a coupler locator for depth binding of the device’s installation location in the well.

 The ground panel includes a system to protect the charge from unauthorized initiation on the earth's surface and block ignition of the charge at atmospheric pressure.

 The device operates as follows. The device is lowered into the perforation interval. A clutch locator located in the measuring unit 15 is used for depth binding. On the operator’s command, the device is started from the ground control unit by supplying electric current through a geophysical cable 12 and through a power cable to the ignition unit 1 spiral located at the end of the ignition section of the charge. When the heating temperature of the spiral exceeds the flash point of the charge, the igniter section 2 ignites, from it - the main sections 3 adjacent to it, from which the remaining main sections of the charge ignite. Combustion occurs on the entire surface of the charge - on the outer, end and inner. According to the results of bench tests, at a hydrostatic pressure of 10 MPa, the ignition time of the entire surface of the charge does not exceed 0.1 s. With increasing hydrostatic pressure and medium temperature, the ignition time decreases. When the charge is burning, a large amount of hot gases is formed, which through the diffuser 9 fall into the casing. Hot powder gases lift the borehole column up, but since the borehole column has a large mass in the casing filled to the mouth, it acts as a packer due to inertness. Therefore, combustion occurs similarly to combustion in a confined space, which leads to a sharp increase in pressure in the casing in the processing interval. With an increase in pressure of 1.5 - 1.8 times higher than the mountain pressure (depending on the characteristics of the formation), the formation ruptures with formation of fractures in the bottom-hole zone of the formation, overflow of the borehole fluid and hot gases into the formed cracks. Hot powder gases lift the wellbore column up until their pressure is equal to hydrostatic pressure. After that, the column of liquid falls down, which is accompanied by water hammer and damped oscillations of the liquid column, increasing the effect obtained.

 Monitoring the operation of the device and evaluating its effect on the formation is carried out using continuously recorded graphs of pressure and temperature over time, which is carried out using the measuring unit 15. Information from the measuring unit enters the ground panel, which includes a system that protects the charge from unauthorized initiation on the earth surface. The charge can be ignited at a pressure several times higher than atmospheric pressure, i.e., when the charge is in the well. After the completion of work, the metal tooling rises from the well and is reused.

 Thus, the proposed charge allows, unlike many charges used when acting on the formation, to carry out gas-hydraulic treatment with fracturing, without violating the integrity of the casing and cement stone. The application of the proposed charge snap provides charge strength under mechanical and thermal loads. In addition, the equipment does not remain in the well, but can be reused. Using an extension rod reduces the effects of turbulent flow and reduces the likelihood of cable overlapping. The use of charge sections not covered by a protective layer allows the charge to ignite on all sides - from the end, the outer and the inner, which reduces the time of its combustion. The configuration of the central channel has a shape with a developed combustion surface, which provides a predetermined burning time and pressure required for hydraulic fracturing. So, with the mass of the proposed charge is half the weight of the PGD. BC. 100M, the average burning surface exceeds the average burning surface of PGD. BC. 100M 3 times and, accordingly, the burning time of the proposed charge is more than 3 times less, and the gas intake is more than 3 times more. This leads to an increase in pressure exceeding the tensile strength of rocks, the formation of cracks in them and, accordingly, an increase in effective permeability. During the charge combustion, the borehole fluid column rises to a height an order of magnitude smaller than during the combustion of PGD. BC, and the pressure in the annular space at the level of fluid rise, transmitted through the perforations, practically coincides with the pressure in the column and, therefore, eliminates the gap of the column.

 Using a measuring unit allows you to monitor the operation of the device, the burning time of the charge.

List of references
1. Rifle-blasting equipment: Handbook / L. Ya. Fridlyander, V. A. Afanasyev, L. S. Vorobyov and others; Ed. L. I am Friedlander, - 2nd ed. Re-worker. and add. - M., Nedra, 1990, Section 4. Powder generators and pressure accumulators, pp. 107-108.

 2. Rifle-blasting equipment: Handbook / L. Ya. Fridlyander, V. A. Afanasyev, L. S. Vorobyov and others; Ed. L. Ya. Fridlyander, - 2nd ed. Re-worker. and add. - M., Nedra, 1990, Section 4.2. Powder Pressure Accumulators, pp. 112-114.

 3. Rifle-blasting equipment: Handbook / L. Ya. Fridlyander, V. A. Afanasyev, L. S. Vorobyov and others; Ed. L. Ya. Fridlyander, - 2nd ed. Re-worker. and add. - M., Nedra, 1990, Section 4.1. Powder pressure generators. p. 108.

 4. Rifle-blasting equipment: Handbook / L. Ya. Fridlyander, V. A. Afanasyev, L. S. Vorobyov and others; Ed. L. Ya. Fridlyander, - 2nd ed. Re-worker. and add. - M., Nedra, 1990, Section 4.1. Powder Pressure Generators, pp. 109-112.

Claims (3)

 1. Sectional open-cell charge for gas-hydraulic treatment of the formation, including an ignition unit, charge sections made of compositions providing combustion in an aqueous, oil-water and acid environment, with one or more ignition sections for igniting the main sections, equipment with parts for collecting charge sections passed through the central channel of each section, and the parts providing the sections are pulled together close to each other, characterized in that the equipment is a composite rod through the central channel of each section, to both ends of which streamlined centralizer cones are attached to tighten and tighten the charge sections close to each other, the diameter of the centralizer cones exceeds the diameter of the charge sections, centering rings are installed between the charge sections, which exceed the diameter of the charge sections in diameter moreover, the rings are made in such a way that the dynamics of charge burning does not change, a diffuser is located between the lower cone-centralizer and the charge sections to divert the gas flow forming during combustion of the charge, and the sum of the passage openings of the diffuser is calculated in such a way as to ensure the minimum load on the rod and provide maximum impact on the formation, a spring is installed between the upper cone and the charge sections to elastic compress the sections and compensate for the linear expansion of the charge at high temperatures in the well, charge sections do not have a protective coating, for the implementation of combustion over its entire surface, the configuration of the central channel has a shape with a developed combustion surface for both baking combustion predetermined time and pressure to fracture the formation.  2. The device according to claim 1, characterized in that for registering the parameters of pressure, temperature, time of burning of the charge and reference to the depth of the installation site of the device in the well, a measuring unit is fixed on the cable.  3. The device according to p. 1, characterized in that the ground control panel includes a system for protecting the charge from unauthorized initiation on the earth's surface and blocking the ignition of the charge at atmospheric pressure.