RU118350U1 - POWDER PRESSURE GENERATOR - Google Patents

Abstract

1. A powder pressure generator, lowered into the well on a geophysical cable, consisting of separate powder charges made in the form of cylinders connected between the top cover and the pan by a cable, in the upper and lower powder charges, incandescent coils are installed, electrically connected to the geophysical cable, characterized in that , that the composition of the powder charges includes a high-energy composite material, and the amount of high-energy composite material in individual powder charges is different. ! 2. The powder pressure generator according to claim 1, characterized in that the individual powder charges in the powder pressure generator are arranged so that the amount of high-energy composite material in the upper and lower powder charges is the same and decreases towards its middle. ! 3. The powder pressure generator according to claim 1, characterized in that the individual powder charges in the powder pressure generator are arranged so that the amount of high-energy composite material in the upper charge is maximum and decreases towards the lower charge. ! 4. Powder pressure generator according to claim 1, characterized in that nano-sized aluminum powder is used as the high-energy composite material. ! 5. A powder pressure generator according to claim 1, characterized in that the amount of high-energy composite material in individual powder charges is no more than 40% of the total mass of the powder charge. ! 6. Powder pressure generator according to claim 1, characterized in that the amount of high-energy composite material in individual powders

Description

The utility model relates to the oil and gas industry, and specifically to powder pressure generators and can be used to intensify oil and gas production caused by mechanical, thermal and physico-chemical effects on oil and gas bearing strata of solid fuel combustion products.

The well-known "Powder facing pressure generator" for housing shaped-charge perforators and implosive devices, according to the application of the Russian Federation for invention No. 2009115084, made in the form of a set of fragments fixed to the device case one after the other in a single tubular facing charge. Its fragments can be assembled from bar elements of any profile of ballistic artillery gunpowders. Fragments of the Powder facing pressure generator can be made in the form of homogeneous structures in the form of a pipe by gluing the ends of the powder elements with cold curing polymer or in the form of flexible plates by tying the powder elements with nitrocellulose or cotton tape. The disadvantage of the powder generator is the low pressure of the solid fuel combustion products.

It is known "Device for perforating wells and fracturing in the reservoir" according to the patent of the Russian Federation for invention No. 2170339. The invention relates to the oil and gas industry and, in particular, to cumulative perforators and powder pressure generators used in wells. Provides an increase in the efficiency of the perforator and an increase in the size of the channels in the columns and the creation of additional cracks in the zone adjacent to the well. The inventive device comprises a cumulative perforator with explosive charges connected to a cable cable for lowering into the well. It forms cumulative jets during detonation. There is a powder pressure generator with solid fuel elements. The solid fuel elements of the powder pressure generator are located between the explosive charges or near explosive charges in contact with them. Solid fuel elements can be located in the lower part of the device instead of the cargo or part of this cargo. In this case, the Solid fuel elements do not intersect the axis of the cumulative jets and are made of non-metallic ballistic or mixed solid rocket fuel in the form of cylinders with a central circular channel, in which the length and diameter of the central channel are related by the ratio (20 ... 40): 1. The content of the filler stabilizing combustion to the mass of the solid fuel element is not more than 1.5%. In other embodiments of the device, the length and diameter of the central channel are related by other ratios. In addition, in other embodiments, a different content of the filler stabilizer of combustion to the mass of the solid fuel element. In other embodiments, there is another arrangement of the components of the device and their implementation. The disadvantage of this device is the low efficiency of the formation.

The well-known "Method of perforation and processing of the bottomhole zone of the well and a device for its implementation" according to the patent of the Russian Federation for invention No. 2162514 Use: in the operation of oil wells. Provides perforation of a well for one descent and rise of the equipment, cleaning of the treated formation from clogging elements, and formed perforation channels in the formation from the baking crust and fracturing. SUMMARY OF THE INVENTION: a method and apparatus for its implementation include perforating a well with a cumulative perforator and implosive action immediately at the end of the perforation of the well to clean the formed perforation channels from the baking crust using an implosion chamber, the internal cavity of which is connected to the internal cavity of the perforator. After that, the thermogas generator is connected, connected to the perforator by a connecting unit, in which there is a grate with plugged holes. Hot gases of the thermogas generator enter the perforator body and, through the openings in its housing for cumulative charges, act directly on the perforation channels in the formation through preformed perforation channels. Charge characteristics, device design and operating conditions are selected such as to provide hydraulic fracturing pressure. To assess the nature of the impact and the nature of the device, it is equipped with temperature and pressure sensors, and to determine the location of the device in the well, a locator of couplings. The disadvantage of this device is the low efficiency of the impact on the oil and gas strata of the combustion products of solid fuels.

It is known "Device for opening and gas-dynamic processing of the reservoir" according to the patent of the Russian Federation for invention No. 194151. The invention relates to techniques for perforating blasting in wells and can be used for secondary opening of the borehole zone of the formation. It provides the possibility of creating an additional energy carrier, capable of generating a powerful gas stream when the cumulative charges are triggered in the well, moving behind the cumulative stream. The inventive device includes a housing shaped-charge perforator with a head with sealed side holes, cumulative charges, a tip and two sealed air chambers with atmospheric pressure. They are located at the ends of the punch. Powder charges are placed in the air chambers. Between them and the cumulative charges placed protective checkers of non-detonating mixed fuel of the elastic type. The disadvantage of this device is the low efficiency of the impact on oil and gas bearing strata.

The well-known "gas generator for solid fuel for processing oil and gas wells" according to the patent of the Russian Federation for invention No. 2311529 The invention relates to the oil and gas industry and can be used to stimulate the borehole zone of the oil and gas reservoir solid propellant charges - gas generators. Provides increased reliability and efficiency of the device, achieving a higher flow rate of oil, gas condensate and gas in wells of any orientation. The inventive device includes a tubular cylindrical charges, providing a vibrational combustion mode, an igniter charge and a load-bearing geophysical cable with fastening elements of the structure. According to the invention, when processing steeply inclined, deviated wells and horizontal wells, the geophysical cable is located inside a flexible continuous pipe repeating the direction of the well, has conductive conductors for connection to the wires of the initiating igniter unit. At the same time, a flexible continuous pipe is connected to a protective casing - a shell around the charges in the form of a perforated or non-perforated metal tubing, or made of fiberglass, using parts that tighten the charges close to each other and with it. Tubular cylindrical charges have a channel length and different diameters of these channels to provide high-frequency and low-frequency pressure pulses during the combustion of these charges. The disadvantage of this device is the low efficiency of the impact on the oil and gas strata of the combustion products of solid fuels.

The well-known "Integrated method of stimulation of wells" according to the patent of the Russian Federation for the invention No. 2282027 The method is used in the oil industry. Provides increased efficiency of stimulation of the well by enhancing the complex thermogaschemical, baric and vibro-microwave effects on the bottom-hole zone of the oil reservoir by using a powder charge without residual burning fuel fragments. The inventive method includes thermogasochemical baric and vibration microwave effects on the reservoir using a gas generator. It has a cylindrical unpacked charge with a central round channel of solid fuel material and is connected to a geophysical cable. The impact is carried out by burning this charge in the interval of the reservoir with the simultaneous accumulation of pressure of the powder gases in the cavity of its Central channel with subsequent transfer of combustion energy to the reservoir. According to the invention, in order to get rid of residual charge fragments at the end of its combustion, a charge is used with segments protruding on opposite sides of the cylindrical surface parallel to the axis of its central channel with longitudinal grooves made in them. The distance between the grooves is equal to the outer diameter of the cylindrical part of the checker. The ratio of the circumference of the checker to the base of each of the protruding segments is (6 ÷ 9) ÷ 1 The disadvantage of the invention is the low efficiency of the formation.

Known powder pressure generator according to the book Semenov Yu.V., Voitenko B.C. et al. “Testing oil and gas exploration wells in a column” Moscow, Nedra, 1983, p. 231. (prototype) A powder pressure generator consists of powder charges collected between the lid and the pan; glow plugs are electrically connected to the geophysical cable in the upper and lower powder charges , the powder charges are interconnected by a cable that runs between the protrusions made on the side surface of the powder charges. The disadvantage of this device is the lack of pressure in the interval of treatment of the reservoir due to the low burning rate of the powder charges.

The tasks of creating a utility model are: increasing the efficiency of the impact of solid fuel combustion products on oil and gas strata by increasing the burning rate of powder charges and increasing the pressure at the site of impact on the reservoir.

The solution to these problems was achieved due to the fact that the powder pressure generator, lowered into the well on a geophysical cable, consisting of separate powder charges made in the form of cylinders connected between the top cover and the pallet by a cable, incandescent spirals are installed in the upper and lower powder charges, electrically connected with a geophysical cable, the composition of the powder charges includes a high-energy composite material, and the amount of high-energy composite material in individual pores different charges. Separate powder charges in the powder pressure generator are arranged so that the amount of high-energy composite material in the upper and lower powder charge is the same and decreases towards its middle. Separate powder charges in the powder pressure generator are arranged so that the amount of high-energy composite material in the upper charge is maximum and decreases towards the lower charge. As a high-energy composite material, nano-sized aluminum powder is used. The amount of high-energy composite material in individual powder charges is not more than 40% of the total mass of the powder charge. The amount of high-energy composite material in individual powder charges located one after another differs by 2 ... 15%.

The proposed technical solution has novelty and industrial applicability, i.e. all the criteria of a utility model. The novelty of the technical solution is confirmed by patent research. Industrial applicability is due to the fact that non-deficient materials and well-known technologies are used in the manufacture of a powder pressure generator.

The essence of the utility model is illustrated in figure 1 ... 3, where:

figure 1 shows the pressure generator,

figure 2 shows the pressure distribution in the case when the reservoir is removed from the bottom,

figure 3 shows the pressure distribution in the case when the reservoir is close to the bottom.

The powder pressure generator, descends into the well on a geophysical cable 1, consists of individual, for example, five powder charges 2, 3, 4, 5, 6 made in the form of cylinders connected between the top cover 7 and the pallet 8 by a cable 9, in the upper 2 and lower 6 powder charges installed glow plugs 10, electrically connected to the geophysical cable 1, the composition of the powder charges includes high-energy composite material, and the amount of high-energy composite material in individual powder charges is different . Separate powder charges in the powder pressure generator can be arranged so that the amount of high-energy composite material in the upper and lower powder charge is the same and decreases towards its middle. For example, the percentage of high-energy composite material may be as follows for charges: 2-20%, 3-15%, 4-10%, 5-15%, 6-20%. Separate powder charges 2, 3, 4, 5, 6 in the powder the pressure generator can be arranged so that the amount of high-energy composite material in the upper charge is maximum and decreases towards the lower charge. For example, the percentage of high-energy composite material may be as follows for charges: 2-20%, 3-15%, 4-10%, 5-5%, 6-2%. As a high-energy composite material, nano-sized aluminum powder is used. The amount of high-energy composite material in individual powder charges is not more than 40% of the total mass of the powder charge. The amount of high-energy composite material in individual powder charges 2, 3, 4, 5, 6 located one after another differs by 2 ... 15%.

The powder pressure generator operates as follows. Separate powder charges 2, 3, 4, 5, 6 are collected in the necessary sequence between the top cover 7 and the pallet 8 with a cable 9. The incandescent spirals 10 are electrically connected to the geophysical cable 1. The assembly sequence depends on the removal of the reservoir from the bottom. In the case of remoteness of the reservoir from the bottom, individual powder charges in the powder pressure generator are positioned so that the amount of high-energy composite material in the upper and lower powder charge is the same and decreases towards its middle (figure 2). If the reservoir is located close to the bottom, individual powder charges in the powder pressure generator are positioned so that the amount of high-energy composite material in the upper charge is maximum and decreases towards the lower charge (Fig. 3). On the geophysical cable 1, the powder pressure generator descends into the processing interval. Then, voltage is applied to the glow plug 10 through a geophysical cable. Spirals 10 are heated and ignite the powder charges. Nano-sized aluminum, which is part of individual powder charges, significantly increases the burning rate and pressure acting on the formation. Since the amount of high-energy composite material in individual charges is different, the pressure on the reservoir will depend on its percentage in the charge. The pressure distribution 11 along the powder generator for different locations of the reservoir 12 is shown in figure 2 and figure 3. Charges with a maximum content of nano-sized aluminum create a pressure that limits the treatment area, which increases the efficiency of the remaining charges, and creates a pressure front directed towards the reservoir 12.

Application of the utility model allowed:

1. To increase the effectiveness of the impact on the oil and gas bearing strata of solid fuel combustion products.

2. Increase the burning rate of powder charges and increase the pressure in the well.

3. To increase or restore the flow properties of the adjacent rock

4. To provide thermogasochemical treatment and fracturing of oil and gas bearing strata

Claims (6)

1. The powder pressure generator, lowered into the well on a geophysical cable, consisting of separate powder charges made in the form of cylinders connected between the top cover and the pallet by a cable, glow plugs are installed in the upper and lower powder charges, electrically connected to the geophysical cable, characterized in that the composition of the powder charges includes a high-energy composite material, and the amount of high-energy composite material in individual powder charges is different. 2. The powder pressure generator according to claim 1, characterized in that the individual powder charges in the powder pressure generator are arranged so that the amount of high-energy composite material in the upper and lower powder charge is the same and decreases towards its middle. 3. The powder pressure generator according to claim 1, characterized in that the individual powder charges in the powder pressure generator are arranged so that the amount of high-energy composite material in the upper charge is maximum and decreases towards the lower charge. 4. The powder pressure generator according to claim 1, characterized in that a nanosized aluminum powder is used as a high-energy composite material. 5. The powder pressure generator according to claim 1, characterized in that the amount of high-energy composite material in individual powder charges is not more than 40% of the total mass of the powder charge. 6. The powder pressure generator according to claim 1, characterized in that the amount of high-energy composite material in individual powder charges located one after another differs by 2 ... 15%.