RU2233976C1 - Method for thermochemical treatment of productive bed - Google Patents

Abstract

FIELD: oil processing industry.

SUBSTANCE: method includes feeding of combustible oxidizing compound into bed treatment area, which compound contains ammonia nitrate, urea, nitric acid, acetic acid and water, feeding of igniting material pressed in form of tablets into area of combustible oxidizing compound location, and, additionally, feeding of gunpowder charge of solid-fuel material made of ballistic gunpowder or ballistic converted artillery gunpowder, or of compound fuel containing ammonium perchlorate as oxidizer, with later extraction of bed, while charge is inserted into area of bed treatment either after feeding of combustible oxidizing material and insertion of igniting material into it, or before feeding of combustible oxidizing material and insertion of igniting material into it, or concurrently with igniting material, as which is used at least one of following row: calcium hydride, magnesium hydride, barium hydride, titanium hydride, aluminum, with amount of the latter in mixture of said hydrides 10-50% of mass, igniting material is used in amount no more than 5.0% of combustible oxidizing material mass. Combustible oxidizing material includes, in percents of mass: ammonia nitrate 30-50, urea 10-30, nitric acid 4.0-6.0, acetic acid 4.0-6.0 and water up to 100. In combustible oxidizing material no more than 10% of mass of hydrochloric acid, and with concurrent insertion of igniting material and charge the latter is placed either above, or below, or between igniting material tablets.

EFFECT: higher efficiency.

4 cl, 1 tbl

Description

The invention relates to the oil refining industry, in particular to methods for thermochemical treatment of the bottom-hole formation zone (PZP) by the combined action of a combustible-oxidative composition (GOS) on the formation, combustion initiator and powder charge, and can be used to increase permeability and recovery of the formation during oil production, gas and gas condensate, as well as for cleaning the borehole zone of the formation from asphalt and resin paraffin deposits, sand and clay particles, reducing the viscosity of oil, etc.

A known method of thermochemical treatment of a formation, including injecting into the productive zone a combustible oxidizing composition containing an aqueous solution of ammonium nitrate (ammonium nitrate) and / or ammonium hydrogen phosphate, introducing a combustion initiator into the GOS location zone, which uses an explosive charge (BB) ( RU No. 2064576 C1, E 21 B 43/24, 1996). A sufficiently long processing time (up to 130 s), the use of explosives and the complex organization of work limit the wide possibilities of using the known method.

There is a method of processing a reservoir (RU No. 2103493 C1, E 21 B 43/25, 1998), the essence of which is as follows.

In the interval of the reservoir, a powder charge is burned from a solid propellant material with chalk as a filler and a combustion stabilizer. The accumulation of pressure of the powder gases is carried out in the cavity of the Central circular channel. In it, the length and diameter are related by a ratio of 20-40: 1 with the content of the filler-stabilizer (HC) of combustion to the total mass of the central circular channel of not more than 1.5%. In the cavity of the central channel, in which the length and diameter are connected by a ratio of 40-120: 1, the content (HC) is not more than 0.6%. The pressure of the powder gases from the cavity of the Central channel is transmitted to the reservoir in the form of pressure pulses through radial channels and end surfaces. As a result of combustion in the cavity of the central circular channel, thermogasochemical, baric, and microwave waves are applied to the formation.

The known method relates to a series of methods of vibrating microwave effects on the productive layer of the reservoir with powder charges, which allows almost two times to increase the flow rate of the well.

The main disadvantage of this method is the rather high charge consumption, a long induction period, i.e. after charge initiation, only after 30 minutes in the treated zone of the formation, pressure and temperature rise, which contribute to the permeability of the formation and the influx of oil to the surface, as well as a low depth of treatment of the formation, which does not exceed 10 m

The closest analogue to the claimed method of thermochemical treatment of the bottom-hole zone of the formation, including the injection into the treatment zone of the formation of a fuel-oxidative composition containing the starting components, wt.%: Urea 18-30; nitric acid 4.0-6.0; acetic acid 4.5-5.5; potassium permanganate 0.01-0.02; carboran 0.3-3.0; water 13-18 and ammonium nitrate 38-60, then introducing into the zone of location of the fuel and oxidative composition not more than 8% by weight: GOS of a combustion initiator, compressed into tablets and containing 10-30 wt.% aluminum and 70-90 wt.% chromium oxide VI and the subsequent development of the well (RU No. 2126084, Е 21 В 43/24, 1999). The method has a sufficiently high efficiency, however, the use of carboranes in the composition of GOS makes the process more expensive and requires careful handling. In addition, the depth of the formation does not exceed 10 m

An object of the invention is to provide a method for the complex impact on the reservoir of a combustible-oxidizing composition, a combustion initiator and a powder charge, increasing the processing depth while increasing the efficiency of the process.

The stated technical problem is achieved by the fact that the method of thermochemical processing of a productive formation includes injecting a combustible oxidizing composition containing ammonium nitrate, urea, nitric acid, acetic acid and water into the treatment zone of the formation, introducing a combustible oxidizing composition compressed into tablets into the location zone a combustion initiator and optionally a powder charge of solid propellant material made from ballistic powder or from ballistic rework artillery powder, and and from a mixed fuel containing ammonium perchlorate as an oxidizing agent, the charge being introduced either after the injection of the fuel-oxidative composition and introduction of the combustion initiator, or before the injection of the fuel-oxidative composition and introduction of the initiator, or into the zone of the location of the fuel-oxidative composition with a combustion initiator, which is used as at least one of a series: calcium hydride, magnesium hydride, barium hydride, titanium hydride, aluminum, with a content of the latter in a mixture of these hydrides 10-50 wt.%, at this combustion initiator is introduced in an amount of not more than 5.0% by weight of the fuel oxidation composition. Combustion-oxidizing composition contains components in the following ratio, wt.%: Ammonium nitrate 30-50; urea 10-30; nitric acid 4.0-6.0; acetic acid 4.0-6.0 and water - up to 100. No more than 10 wt.% hydrochloric acid can be introduced into the composition of the fuel-oxidative composition, and with the simultaneous use of a combustion initiator and charge, the latter is either higher, lower, or between initiator tablets.

The combustion initiator is compressed tablets (blocks) of powders of the indicated hydrides, or a mixture of hydrides or a mixture of hydrides and aluminum, which are prepared in advance from the powders and coated with a moisture-resistant paraffin or rosin material.

The ratio of initiator components in the part of hydrides can vary from 1 to 99%, but their predominant ratio in the mixture is 50 to 50 if there are two hydrides and in equal quantities if more than two hydrides.

As a powder charge from a solid propellant material, a charge in the form of a cylindrical checker with a channel made of ballistic powder (patent RU No. 2103493 C1), or from ballistic rework artillery powder, or from mixed solid fuel containing water-soluble perchloric acid salts was used , mainly ammonium perchlorate, the crystals of which are bonded with combustible components in the form of a rubber-like binder. Charges from other fuels that are prone to vibrational combustion can also be used.

The table shows the compositions of GOS, the initiator of combustion, respectively, for each composition of GOS, which were used to refine the proposed method.

The amount of initiator for the first GOS composition is 4%, and the charge is introduced after the GOS is pumped into the treatment zone and the combustion initiator is introduced into it; for the second composition, 5%, and the charge is introduced into the treatment zone before the GOS is pumped into it and the combustion initiator is introduced; for the third composition, 3%, and the charge is introduced into the GOS location zone simultaneously with the combustion initiator, while the charge is placed above or below the combustion initiator; for the fourth composition, 2%, and the charge is introduced into the GOS location zone simultaneously with the combustion initiator, while the charge is placed between the tablets of the combustion initiator.

For convenience, using the table in its lower part indicates the methods of introducing a charge according to the examples.

For the first example, the required amount of GOS for a given well is pumped into the bottomhole formation zone through a string of tubing (tubing) in a PZP (composition 1). Then, the initiator of combustion, calcium hydride, is introduced into the GOS location zone - calcium hydride in an amount of 4% of the mass of GOS. In the treatment zone, the GOS components and the initiator interact, which leads to a thermochemical effect on the formation, and an increase in temperature and pressure. Processing PZP before the introduction of the charge prepares the formation for penetration into it of the products of combustion of the charge. Then, a charge from a mixed solid fuel containing ammonium perchlorate, the crystals of which are bonded by combustible components in the form of a rubber-like binder, is introduced into the formation treatment zone. The charge elements of mixed solid fuel are protected by a special coating that prevents the contact of crystals of ammonium perchlorate with liquid components.

After the start of the exothermic reaction caused by the contact of the GOS and the initiator, arising, for example, due to the rupture of the initiator tablets by the detonating cord, the mixture begins to heat up, the solid fuel charges ignite and burn in vibration mode.

At the same time, thermogasochemical and vibration microwave effects on the bottomhole zone are carried out and the process of GOS burning is accelerated. Hydrochloric acid is formed in the products of the combustion of charges, which acts on the PPP in the form of a vapor-gas mixture. High-temperature acid treatment of PZP, which occurs during vibrational combustion of charges, creates an additional effect on the formation, increases the processing depth to 30 m, completely frees the treatment zone of the formation from asphalt and resin-paraffin deposits, sand and clay particles, and reduces the viscosity of oil.

Due to the combined action of the above factors, intense gas evolution, additional cracking occurs. In this case, a decrease in charge mass and GOS is possible.

A similar picture is observed when using the compositions of GOS and the initiator according to example 2. In this case, first in the PZP enter a powder charge of solid propellant material made of ballistic powder (RU No. 2103493 C1), initiate its combustion.

Due to the separation of the products of the combustion of the charge and its microwave exposure to the treatment zone, the preparation of the BCP will occur. Then GOS is pumped (composition 2), a combustion initiator (a mixture of titanium hydride and magnesium hydride) is introduced. As a result of this treatment, the number of cracks increases, the water permeability of the bottomhole formation layer increases, this leads to the penetration of GOS to further distances from the well. The processing efficiency in this case increases, the GOS mass can be reduced to 20%, the depth of the formation treatment increases to 25 m, and the oil recovery increases.

With the simultaneous use of charges with an initiator (examples 3 and 4), which are introduced into the GOS location zone, the method is as follows.

The amount of GOS required for a given well is pumped into the PZP through the tubing. The required amount of combustion initiator is introduced into the GOS location zone, which is placed either above the charge or below it (example 3), or in the intervals between charges (example 4), while the charge elements are made of ballistic rework artillery powder.

In this case, the time of general processing of the formation is reduced, the mass of charge is reduced, the depth of treatment of the formation is increased to 20 m, and the yield of fluid increases.

Thus, in the end, all types of complex effects on the reservoir in accordance with the claimed combination of characteristics lead to the formation and fixation of cracks in the reservoir, the appearance of new main cracks, lower fluid viscosity, increase the permeability of the reservoir, the complete removal of asphalt and resin-paraffin deposits, sand -clay particles, an increase in oil production rate of at least 2 times, an increase in the depth of processing of the formation to 30 m, a decrease in the consumption of GOS mass and charge by 20-30%.

The proposed new method has several additional advantages.

Firstly, the claimed combination of features allows you to adjust the duration of the exothermic reactions, as a result of which the impact on the PPP is carried out at higher temperatures and pressures. This enhances the processing effect. Secondly, the use of charges burning in a vibrational mode allows for the implementation of a vibrating microwave effect on the PZP. Such an effect, in addition to the usual thermogasochemical effect, is more effective.

The proposed new technology can be used in any region of oil and gas production (including for deep wells) to stimulate the used and development of new wells.

Methods of introducing a charge according to examples

1. The charge is introduced after the GOS is pumped into the treatment zone and the combustion initiator is introduced into it.

2. The charge is introduced into the treatment zone before the GOS is pumped into it and the combustion initiator is introduced.

3. The charge is introduced into the GOS location zone simultaneously with the combustion initiator, while the charge is placed above or below the combustion initiator.

4. The charge is introduced into the GOS location zone simultaneously with the initiator of combustion, while the charge is placed between the initiator tablets.

Claims (4)

1. The method of thermochemical treatment of a productive formation, including the injection into the treatment zone of a combustible-oxidizing composition of GOS containing ammonium nitrate, urea, nitric acid, acetic acid and water, introducing a combustion initiator compressed into tablets into the GOS location zone, followed by development reservoir, characterized in that in the zone of treatment of the reservoir is additionally introduced a powder charge of solid propellant material made of ballistic gunpowder or ballistic rework artillery gunpowder, or from a mixed solid fuel containing ammonium perchlorate as an oxidizing agent, the crystals of which are bonded with combustible components in the form of a rubber-like binder, the charge being introduced either after the GOS is injected and the combustion initiator is introduced into it, or before the GOS is injected and the combustion initiator is introduced, or simultaneously with the introduction of a combustion initiator, which is used as at least one of a series: calcium hydride, magnesium hydride, barium hydride, titanium hydride, aluminum, when the content of the latter in a mixture of these hydrides 10-50 wt.%, while the initiator of combustion is introduced in an amount of not more than 5.0% by weight of GOS. 2. The method according to claim 1, characterized in that GOS contains components in the following ratio, wt.%: Ammonium nitrate 30-50, urea 10-30, nitric acid 4.0-6.0, acetic acid 4.0- 6.0 and water up to 100. 3. The method according to claim 2, characterized in that not more than 10 wt.% Hydrochloric acid is additionally introduced into the GOS. 4. The method according to any one of claims 1 to 3, characterized in that with the simultaneous introduction of the initiator of combustion and charge, the latter is placed either above or below, or between the tablets of the initiator.