RU2589156C1 - Heat-resistant detonating cord - Google Patents

Abstract

FIELD: blasting operations.

SUBSTANCE: invention relates to explosives and can be used in oil producing industry in perforating operations in wells for initiation of charges of cumulative perforators. Detonating cord contains multilayer outer shell explosive core made from a set of cylindrical tablets from heat-resistant explosive substance (es), between which tablet-separators are installed pressed from inorganic oxidising agents. Tablet-separators can be made of mixture of ammonium nitrate with aluminium powder in weight ratio of 80:20, where ammonium nitrate consists of a mixture of powder standard grain-size composition with ammonium nitrate in nano dispersed state in amount by weight of up to 25 %. In case of comparable in value of density of compact with pellets of the main charge of heat-resistant ES height (weight) of a tablet-separator is not more than 0.25 of corresponding value of a tablet of main charge.

EFFECT: introduction of tablets-separators into design of cord reduces consumption of heat-resistant powerful blasting ES and improving reliability of operation of cord in case of core soaking.

3 cl, 1 dwg, 2 tbl

Description

The invention relates to the field of blasting equipment and can be used in the oil industry when conducting shooting and blasting operations in wells to initiate charges of cumulative perforators.

Known manufactured by the domestic industry in accordance with TU 84-711-83 [1] heat-resistant detonating cords (ДШ) grades ДШТ-165, ДШТ-200, ДШУ-33. The core of these LH is made of loose heat-resistant powerful blasting explosives (BB) and is first enclosed in a filament, and then in a polymer shell with sealing caps at the ends.

The main disadvantage of cords of the DShT-165, DShT-200 and DShU-33 brands is that if the integrity of the shell, which is possible due to even minor mechanical influences, can penetrate the wellbore fluid into the core of the cord, due to capillary effects, the core will be completely saturated with liquid, which naturally leads to failure of the cords.

Closest to the proposed invention in terms of technical nature and the achieved result is heat-resistant DS brand DShTT, manufactured according to TU 84-825-79 [2]. Its core is made of pressed heat-resistant powerful blasting explosive - a set of cylindrical tablets placed inside a multilayer waterproofing shell, end to end with virtually no gaps. The ends of the cord itself are protected by sealing caps.

Due to the high density of explosive tablets that make up the core of the cord, it is less "sensitive" to jamming in violation of the integrity of the outer shell. However, when working with it at high temperatures and pressures of the well fluid, in the case of a puncture of the polymer shell, a partial washing out of the explosive from the ends of the tablets is possible, which is the reason for the failures.

The increased power of the tablet cords (the mass of explosives per 1 m LH is 45 ... 80 g / m) leads to increased consumption of expensive heat-resistant powerful blasting explosives, as well as to a large number of gaseous explosion products, a strong shock wave and, as a result, significant deformation of the punch bodies .

The technical task of the invention is to reduce the weight of the core core of an expensive heat-resistant powerful blasting explosive while improving the reliability of operation in the event of core jamming.

The solution to this problem is achieved by the fact that in the known detonating cord containing an explosive core enclosed in a multilayer outer shell made of a set of cylindrical tablets of heat-resistant powerful blasting explosives, in accordance with the invention, separator tablets are placed between the tablets of heat-resistant powerful blasting explosives compressed from inorganic oxidizing agents.

Inorganic oxidizing agents include salts of oxygen-containing acids of nitrogen - nitrates, chlorine - perchlorates, as well as permanganates, dichromates, peroxides and a number of other compounds.

Almost all inorganic oxidizing agents decompose under the influence of high temperatures with the release of gaseous oxygen, nitrogen oxides and other gases. Moreover, their specific gas formation and heat resistance are comparable, respectively, with the specific gas formation (by explosion products) of powerful blasting explosives and their heat resistance (the properties of nitrates and perchlorates are given in Table 1 below as an example).

Therefore, separator tablets made of inorganic oxidizing agents placed between tablets made of heat-resistant explosives during the transmission of the detonation pulse through the dry core of the cord will not be a passive, but an active barrier, due to which, if an individual tablet from a heat-resistant explosive in the core of the cord explodes, the detonation pulse will not simply by the mechanism of transmission through a passive barrier, and with an increase in the effect due to the high-temperature decomposition products of inorganic oxidants.

So, when heating solid nitrates, all of them, with the exception of ammonium nitrate, decompose with the release of oxygen.

Alkali metal nitrates decompose into nitrites and oxygen:

Most nitrates, from alkaline earth metals to copper, are decomposed into metal oxide, NO ₂ and oxygen:

The nitrates of the heaviest metals (AgNO ₃ and Hg (NO ₃ ) ₂ decompose to free metal, NO ₂ and oxygen:

Ammonium nitrate decomposes into gaseous components:

A typical decomposition reaction of alkali metal perchlorates proceeds according to the following mechanism:

KClO ₄ → KCl + 2O ₂ ↑

Similarly, i.e. with the release of a large number of gaseous components, decomposition reactions of permanganates, dichromates, peroxides, etc. proceed. inorganic oxidizing agents.

In the case of jamming of the core of the cord in case of damage to the outer protective sheath, the tablet separators pressed from inorganic oxidizing agents will partially dissolve, and since dissolution is carried out in a limited volume, the gap between the tablets from the heat-resistant powerful blasting explosive will eventually be filled with concentrated saline with some residual solids content, i.e. actually a water-filled explosive [4].

Thus, when initiating a crashed accident, the transfer of detonation between tablets from a heat-resistant powerful blasting explosive will occur through the “active” gap filled with a water-filled explosive.

It is known [4] that from the energy point of view, the introduction of aluminum into water-filled explosives (aquanals) is favorable. In this case, water is an oxidizing agent in relation to aluminum. The heat of reaction between water and aluminum is 8710 kJ / kg, and the oxidation of aluminum with ammonium nitrate is 9750 kJ / kg. In compositions of this type add finely dispersed aluminum powder.

From domestic varieties of powder, high detonation ability of aquanals is provided by PAK-3 and PAK-4 powder, as well as powder PAP-1 and PAP-2 grades close to them in terms of characteristics. So, the critical diameter of the aquanal containing 20% PAK-3 powder, at an explosive density of 1.2 g / cm ^3, was 5 mm [4].

Based on the analysis of the physicochemical properties of salts and nitro compounds of inorganic substances used as part of modern energy-saturated materials (Table 1), as well as the experience of using water-filled explosives in industry [4], it can be concluded that it is most expedient as a material for separator tablets placed in the core of an accident between tablets of a heat-resistant powerful blasting explosive, use ammonium nitrate with the addition of up to 20% aluminum powder. Moreover, to ensure maximum energy during the transmission of the detonation pulse, the tablet-separator should contain the maximum mass of the active substance for given geometric characteristics, i.e. have maximum density.

The studies performed on the pressing of nitrate salts showed that the maximum pressing mass in the working pressure ranges up to 200 MPa is achieved by introducing into the starting material a standard particle size distribution of up to 25% of the same substance in the nanodispersed state. So the density of the tablets of mixed ammonium nitrate was 1.68 g / cm ³ , and for the corresponding standard - 1.66 g / cm ³ . Therefore, it is advisable to use tablet separators compressed from a mixture of the starting material containing up to 25% of the nanodispersed phase in the cord construction. When pressing tablet separators from a mixture containing, along with nanosized ammonium nitrate 20% aluminum powder PAP-1, a compression density of 1.79 ... 1.80 g / cm ^{3 was} achieved.

Studies on the transfer of detonation between tablets of heat-resistant explosives, with placed between them tablets separators of ammonium nitrate with 20% aluminum powder PAP-1 were carried out according to the following method.

In a tube of heat-shrinkable plastic, tablets from the heat-resistant composition of the GFG-2 brand (a composition based on hexogen, phlegmatized with varnish, used to equip the heat-resistant DSH according to TU 84-825-79) and separator tablets from ammonium nitrate with aluminum powder (of various heights) were successively placed / mass), after which the tube was subjected to heat shrinkage, so that the tablets are closely adjacent to the ends. Then, an ED-8 electric detonator was blasted from the end of the tube in dry conditions and simulated core jamming. The core jam was simulated by piercing the tube wall at the location of the ammonium nitrate separator tablets and then placing the damaged portion of the shell in hot water (initially boiling) with a holding time of 30 minutes. The experimental results are shown in table 2.

From the above experimental data, it follows that in case of using separator tablets from a mixture of ammonium nitrate with aluminum powder, comparable in density to pressing with tablets of the main charge from a heat-resistant powerful blasting explosive (in particular, GFG-2 brand), height (weight) tablet separator should be no more than 0.25 of the corresponding indicator of the tablet main charge.

Hexogen and octogen, as well as compositions based on them [4], are currently the most used for the manufacture of various charges of industrial application as heat-resistant powerful blasting explosives.

In addition to the product of the GFG-2 brand, used for experimental purposes, which is hexogen, phlegmatized with a special varnish, mentioned above, the domestic industry also produces a number of other grades of products with both high heat resistance and close corresponding explosive characteristics (see, for example, the list given in source [5]), suitable for equipping a heat-resistant detonating cord of the proposed design. Based on hexogen - grades A-IX-1 OST V84-636-81, A-IX-2 OST V84-1067-74, RDX VDTU 75-11903-551-91, etc., based on octogen - Octogen GOST RV 1376-011-2008, Octogen highly dispersed TU 7276-841-08628424-2006, Okfol TU 7276-221-07508405-2009, etc. The choice of a specific product, of course, will be determined taking into account the specific operating conditions of the detonating cord, as well as economic opportunities.

The invention is illustrated in the schematic diagram of the design of the LH shown in FIG. one.

The heat-resistant detonating cord contains a multilayer outer shell 1 and an explosive core from a set of cylindrical tablets from a heat-resistant powerful blasting explosive 2, between which the separator tablets 3 are placed.

Upon the initiation of LH, the detonation pulse propagates through the core due to the successive blasting of the tablets from the heat-resistant powerful blasting explosive 2. If there is no jamming of the core, when a separate tablet is blown from the heat-resistant powerful blasting explosive 2 in the core of the cord, the detonation pulse will not be transmitted to the next one by the mechanism transmission through a passive barrier, and with an increase in the effect due to the high-temperature decomposition products of oxidizing salts, as well as the thermal effect of the oxidation reaction of aluminum, which are part of the tablet separator 3.

In addition, for some nitrates and oxidizing agents, an explosive pulse transmission mechanism is also possible. If the outer shell 1 is damaged and the well fluid enters the core of the cord, the tablet separators 3 partially dissolve. Because dissolution is carried out in a limited volume, the gap between the tablets from the heat-resistant powerful blasting explosive 2 is filled with concentrated saline solution with some residual solids content, i.e. actually a water-filled explosive, and the transmission of the detonation pulse is carried out by an explosive mechanism.

Thus, the introduction into the design of a heat-resistant tablet cord of tablet separators, pressed from inorganic oxidizing agents and placed between tablets from a heat-resistant powerful blasting explosive, can reduce the consumption of the latter by approximately 25%.

At the same time, the reliability of the operation of the cord in case of jamming of the core is increased, because the dissolution products of the tablet separators are a water-filled explosive.

Information sources

1. TU 84-711-83 Heat-resistant detonating cord.

2. TU 84-825-79 Detonating cords heat-resistant tablet DShTT (prototype).

3. D.I. Dementieva I.S. Kononov, R.G. Mamashev, V.A. Kharitonov. Introduction to the technology of energy-saturated materials: textbook - Biysk: Publishing House of Altai State Technical University BTI, 2009, 254 p.

4. Dubnov L.V., Bakharevich N.S., Romanov A.I. Industrial explosives. - M .: Nedra, 1988 .-- 358 p.

5. Recommendations for filling out an application for the need for explosive materials for industrial use. Ministry of Industry and Trade of the Russian Federation, 2015

Claims (3)

1. Detonating cord containing an explosive core enclosed in a multilayer outer shell made of a set of cylindrical tablets of a heat-resistant powerful blasting explosive (BB), characterized in that separator tablets pressed from inorganic oxidants are placed between tablets of a heat-resistant powerful blasting explosive. 2. Detonating cord according to claim 1, characterized in that the separator tablets are made of a mixture of ammonium nitrate with aluminum powder in a mass ratio of 80:20, while the ammonium nitrate used for pressing the separator tablets is in turn made of a mixture of standard particle size powder composition with ammonium nitrate in the nanodispersed state in an amount by weight up to 25%. 3. The detonating cord according to claim 1, characterized in that in the case of compaction densities of tablet separators with tablets of the main charge of heat-resistant powerful blasting explosive comparable in height, the height (weight) of the tablet separator is not more than 0.25 of the corresponding indicator of the tablet main charge.

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