UA21826U - Method for cumulative-fougasse treatment of well bottom zone to form extended milling zone - Google Patents

Abstract

A method for shaped-explosive treatment of well bottom zone for formation of extended milling zone includes placement in well, in interval of possible inflow of hydrocarbons from low-porous collectors of potentially productive layer of explosive charges with initiation of those. At that with one technological operation one performs two-phase treatment and wide milling of rocks in well zone throughprovision of axial propagation of blast wave at initial initiation of brisant charges, initiation of high explosive charge component and following oxidation and transformation to explosion products of metal elements of charge construction.

Description

Description of the invention

The useful model refers to explosive robots in oil and gas wells and can be used to 2 increase the permeability of the drilling zones of wells, as well as to create conditions for the inflow and production of scattered methane from low-porosity reservoirs.

A well-known, chosen as a prototype, method of explosive treatment of wells in the interval of the productive layer due to the placement of dispersed charges of explosive substances and their detonation with ultra-short deceleration in relation to each other in order to form permeability cracks in the well, which allows increasing the total mass of the charge to 5, 84 kg due to the use of a shock wave reflector and damping elements

Declaratory patent of the United States of America Mo30919A, IPC 6 E21843/11, E21843/263, publ. Bul. Mo7, 15.12.2000). The disadvantage of this method is that it uses repeated blasting of the area of the previously performed cumulative perforation. As is known, standard high-explosive explosives provide rock crushing of about 1.0 m with 0.5 kg of charge and form a rock crushing zone with a size of no more than three to four diameters of the camouflage cavity. t In addition, the technological complexity of using the indicated method is due to the need to deliver the second charge to the zone already destroyed by the previous explosion and the insufficient length and power of the charge, which does not provide the rock crushing zone necessary for the effective inflow of scattered methane from compacted collectors.

The basis of the useful model is the task of the method of explosive treatment of wells by impacting the near-well zone with a powerful combined high-explosive charge with the simultaneous use of 70 metal structural elements as a component of the combined charge, to ensure the formation of an extensive rock crushing zone in the near-well zone, without technical limitations on length interval of the rock crushing zone followed by the opening of the explosion interval by drilling and the use of standard methods of causing a burst of scattered methane.

The task is solved by the fact that in the method of explosive processing of wells, which includes placing in 29 wells in the interval of the productive layer of charges of explosive substances and detonating them, according to a useful model, in one technological operation, two-phase processing and extensive crushing of rocks in the near-well space are carried out by ensuring axial propagation of the explosion wave during the initial initialization of explosive charges, initialization of the high-explosive component of the charge and subsequent oxidation and transformation into products of the explosion of metal elements of the charge structure. oh

To solve this problem, a combined high-explosive charge in the form of He is used in the form of a cylindrical structure, assembled on an axial pipe in a cylindrical casing made of damping elements that extinguish the axial detonation wave, and of the same type of explosive modules, consisting of a peripheral high-explosive so filler with a slowed speed detonation and excess oxygen balance, as well as segments of high-explosive charges, in the outer surface of which cumulative funnels are placed, and in the inner space there is a high-speed cylindrical rod detonator, also formed from segments, which ensures the axial propagation of the explosion wave and the initial initialization of high-explosive charges, which in turn, provide detonation of the explosive component, which ensures oxidation and transformation into products of the explosion of metal structural elements. In the zone of previously formed cumulative holes, a powerful high-explosive charge is used, which makes it possible to create large crushing zones around the wellbore, and to ensure a large radius of filtration of hydrocarbons from low-permeability reservoirs. These holes, which weaken the strength of the rock, cannot be made by well-known well technical devices of an explosive nature. In addition, the given opportunity to group a number of proposed cumulative high-explosive charges makes it possible to form single linear charges of unlimited length (100, 200 and more meters) and to form extensive zones for the influx of oil and gas into the Q15 well.

The possibility of implementing a useful model is explained in detail with the help of a drawing. - The assembly of the modules and the structure of the charge as a whole is carried out with the help of epoxy resin, which fills all the gaps of the structure, the filler of which is powdered metals and oxides, which ensures high hardness and mechanical strength of the structure. ko 50 Figure 1 shows a cumulative high-explosive module designed to create a rock crushing zone,

Ф is strung on an axial tube - 1. The high-explosive cumulative module consists of: an internal cylindrical thin-walled clip - 2, damping ring gaskets made of porous material - 3, an external cylindrical thin-walled clip - 4, assembled from half-cylinders of an axial detonator - 5, a segment of explosive charge - 6, high-explosive filler - 7, cumulative funnel closed with a protective cap - 8. Mounting gaps between 99 segments of explosive charges are filled with porous granular oxidizer. The inert high-explosive filler variant used has high mechanical strength and protects the structure from accidental impacts.

Fig. 2 shows a short-focus module of remote detonation, designed for the destruction of lock joints and reliable transmission of explosion energy through the technological gaps of threaded joints, strung on an axial bo pipe - 1. The short-focus module of remote detonation consists of: an internal cylindrical thin-walled clip - 2, damping ring gaskets - C, outer cylindrical thin-walled clip - 4, protective ring metal washer - 9, axial detonator - 5, ring detonator - 10, explosive charge - 6, high-explosive filler - 7, ring cumulative profile - 11. Transmission speed the detonation wave of the short-focus remote detonation module is selected in such a way as to ensure the transmission of the explosive wave to the pre-charge crushing zone during the formation of the discharge wave.

Fig. 3 shows an active (explosively conductive) damping module, intended for extinguishing an explosive wave in the axial direction inside the structure of a combined explosive charge, strung on the axial pipe -1. The active damping module consists of: an internal cylindrical thin-walled clip - 2, an external cylindrical thin-walled clip - 4, protective ring metal washers - 9, an axial detonator - 5, a glass fiber clip - 15, duralumin washers with an ellipsoidal profile - 13, duralumin washers with a spheroidal profile - 14, ceramic granules and powder oxidizer - 12.

Fig. 4 shows a passive (explosively non-conductive) damping module, designed for extinguishing an explosive wave in the axial direction, strung on the axial pipe -1. The passive damping module consists of 7/0 C: an internal cylindrical thin-walled clip - 2, an external cylindrical thin-walled clip - 4, protective annular metal washers - 9, duralumin washers with an ellipsoidal profile - 13, duralumin washers with a spheroidal profile - 14, ceramic granules mixed with powder oxidizer - 12. Inside the module there are four through-tube holes intended for laying detonation cords and the cable of the electric detonator (not shown in the figure). The garland of passive dampers is placed in the form of a single block, above 7/5 of the garland of cumulative high-explosive modules. The number of dampers is selected from the condition of extinguishing the explosion energy in the interval from the area of placement of charges to the bottom of the casing column.

Fig. 5 shows a cumulative funnel - 16, the zone of the inversion cone of which is enriched with oxides of heavy metals, and the zone of the support cone is enriched with AI, Mi, 2g, which ensures the exothermic reaction of the formation of intermetallics during the explosion of the high-explosive component. The inner cavity of the cumulative watering can is protected by a duralumin cap - 17.

The presence of the support surface of the cumulative funnel is due to the peculiarities of the explosive process. The assembly scheme of the cumulative watering can is shown in Fig. 1, item 8.

Fig. b6 shows a conditional version of the arrangement in a single design of the gas generator module - 24 and shown in Fig. 2 modules of removed detonation -25 (without block of damping modules and fixing packer). The assembly includes: axial pipe - 1, blind mounting washer - 20, dividing washer - 21, retarder unit ovo 7 22, lock with internal thread - 18, lock with external thread - 19, thin-walled casing - 28. Gas generator module - 24 operates with the calculated delay time from the external activator (not shown in the figure). The foam-gas mixture (shown by white arrows) actively fills the space inside the well and due to extinguishing the energy of the explosion in the vertical direction prevents hydraulic shock on the wellhead equipment and the gushing of drilling fluid through the preventer opened during the explosion. After the combustion of the gas generator filler, the initiating charge is triggered - 23 and the detonation wave spreads over the entire interval of the rod detonator - 6. The short-focus module of the extracted detonation ensures the destruction of the locking joints - 18,19 and the guaranteed detonation of the charges located below with an annular cumulative jet.

Fig. 7 shows a version of the layout in a single design: the receiving charge - 23, shown on --

Fig. 3 of the active damper - 26, shown in Fig. 1 of the cumulative high-explosive modules - 27, and shown in Fig. 2 of the removed detonation module - 25, which ensures the guaranteed spread of the explosive process in the vertical direction. The assembly includes: axial pipe - 1, blind mounting washers - 20, lock with internal thread - 18, lock with external thread - 19, thin-walled casing - 28. The external geometric parameters of the layout ensure lowering and lifting operations as well as with a standard casing pipe, at the expense of "

The presence of standard threaded connections and a through internal hole. A pressure packer (not shown in the figure) is screwed into the lock joint - 19 from the bottom of the garland of charges, which ensures fixation of the bottom of the garland when it is placed on the wellhead. The directions of the explosion are shown by black arrows. ;" Fig. 8 shows a version of the layout of the charge garland, where: fountain equipment - 29, day surface - ZO, bottom of the casing - 31, open barrel - 32, return translator and initialization control unit 7 33, gas generator module -34, upper fixing packer and explosion control unit - 35, garland of passive co-dampers - 36, garland of cumulative explosive modules, lower fixing packer - 38, support shank - 39.

The dynamics of the wave development of the explosive process is determined by the ratio of the detonation speeds of the explosive components. At the same time, the speed of detonation of the explosive substance of the detonation rod is higher than the speed

Go! detonation of the explosive charge, which, in turn, is much higher than the detonation speed of the explosive filler. 5p The presence of damping gaskets and damping modules, as well as fluid filling of the axial pipe ensures focusing of the explosion energy perpendicular to the axis of the charge.

Ф The method of using a universal combined high-explosive charge of increased power is determined based on the mining and geological conditions of the open section, the layout of the well’s engineering support, the rock crushing interval and has several implementation options. way 1. A garland of charges of the required length is lowered into the area of the open wellbore, before landing on the outcrop, on the drill pipes, the structural strength of which, taking into account the pushing force, is higher than the crushing forces of the lower part. The lower part of the garland, which ends with a fixing packer, is equipped with a shank with holes that ensure the circulation of the solution when planting in the drilling mud. in 2. Docking of the garland of charges with the drill string is carried out through a specialized reverse translator combined with a packer. The device that initiates the explosive process (explosion timer) is included in the design of the translator. 2. Through the inner space of the drill pipes, the drilling mud is squeezed out by water, until it is completely displaced from the annular space of the garland of charges. 65 Z. Then, if necessary, explosive gel of the "Irezhel" type, which has a density higher than the density of the drilling fluid and a positive oxygen balance, is pumped through the drill pipes. The calculated volume of the gel assumes complete filling of the annular space of the charges. At the same time, the explosive gel is separated from the sales liquid by means of a layer. The end of selling the gel (or turning on the packer) is fixed by a pressure jump when the layer lands on the return adapter and initiates the operation of the packer combined with the return adapter, which separates the area of charges from the internal space inside the well. In addition, the clock mechanism is triggered, which ensures the delay of the explosion for the period of time necessary for the extraction of the drill string.

As a result of the explosion, the gaseous component of the total explosion penetrates into the cumulative holes created by explosive charges and expands the rock crushing zone in the interval of the garland of combined charges. 70 4. The drill string is brought into rotation, disconnected from the garland of charges and pulled out of the well.

The decrease in the formation fluid level in the well is not replenished, which additionally protects the wellhead equipment from hydraulic shock. Until the moment of disconnection of the drill string, the clock of the explosion initiator is blocked. In the event of an emergency situation and the impossibility of freeing the drill string from the return packer, the auxiliary explosion initiator is lowered through the internal space of the drill string. 5. After the explosion, the rock crushing zone is opened by drilling, cleaned of sludge and structural elements that have not collapsed. Then standard operations are carried out to treat the zone of created artificial fracture, lower the shank equipped with a filter, induce inflow and develop the well. In the case of using a specialized cable and winch for lowering and lifting operations, an electrically controlled disconnecting device is used instead of a return translator. Detonation can be carried out from an electric 2o detonator, following a signal from the Earth's surface. In order to avoid cable entanglement, a 200-300 m long detonating cable is provided below the electric detonator, which burns completely when the fire front spreads, the branches of which are passed through channels of passive dampers. If necessary, the garland of the combined high-explosive charge includes the following liquidators: 1. An explosion initiator located in the tail packer with a delay of several months. When landing on the ground and opening the tail packer, this explosion initiator provides a delay of the explosion for several days. 2. An explosion initiator located in the main packer, which, when the packer is opened, is triggered after t calculated time, without releasing the drill string from the return packer.

In addition, an external liquidator descending on the logging cable can be used.

All initiators of the explosion have blocking systems. The transportation of the assembled module blocks is carried out in the Zone of Compliance with the rules for the transportation of explosive charges of equivalent power. When assembling module blocks directly on the well site, a specialized stand is used, located in the direction of the mine, corresponding to the direction of the well. co

In the first phase of the explosion, explosive charges form from 60 to 90 cumulative holes per linear meter, and in the second phase of the explosion, the detonation of the entire explosive substance of the combined charge provides rupture and crushing - rocks whose mechanical strength is already reduced. The length of the rock crushing interval is determined by the number of connected s in a series of cumulative-futaceous modules.

A comparative assessment of this method with similar ones allows us to draw conclusions that due to the fundamentally greater energy of explosive treatment of the wellbore space, a fundamentally larger fractured zone is created, which allows to receive industrial inflows of hydrocarbons from reservoirs that are unprofitable for operation when they are opened using standard technologies. In this way, geological objects are involved in the development of c, the research of which costs are incurred, and the exploitation is economically unprofitable due to the low flow rate of hydrocarbons. In addition, the use of explosives at the time of explosion;" components with a positive oxygen balance leads to ignition of metal elements of the charge structure (aluminum, duralumin, nickel, zirconium). The use of powder mixtures (tungsten carbide, barium nitrate, iron oxide, lead suric, ferrosilicon, aluminum powder, copper powder, calcium sulfate) in structural elements (shells of cumulative charges, docking couplings) also ensures the release of additional heat due to the formation of intermetallics, and as well as an increase in the energy of the explosion due to the reaction with formation water. Explosive combustion of structural components and high fragility of dampers not destroyed by the explosion

Go! elements will eliminate technical problems when opening the crushing zone by drilling.

From this it is clear that the wide implementation of this method can have a significant effect, especially in those cases when, due to geological prerequisites, reserves of hydrocarbon raw materials are significant, and for technical reasons their extraction

F is economically impractical. The method can also be suitable for restoring the flow of oil and gas in wells, the flow rate of which has sharply decreased due to the clogging of the wellbore pore space with paraffin and other products. with

Claims (1)

The formula of the invention The method of cumulative high-explosive processing of the near-bottom zone of the well to create an extensive zone for crushing, which includes placement in the well in the interval of a possible influx of hydrocarbons from low-porosity reservoirs of a potentially productive layer of explosive charges and their detonation, which is distinguished by the fact that two-phase processing is carried out in one technological operation and extensive crushing of rocks in the near-well space by ensuring the axial propagation of the explosion wave during the initial initialization of explosive charges, initialization of the high-explosive component of the charge and subsequent oxidation and de Conversion of metallic elements of the charge structure into explosion products.