RU2215725C1 - Explosive composition and charge - Google Patents

Abstract

FIELD: explosives. SUBSTANCE: invention provides explosive composition for oil-and-gas and mining industries suitable, in particular, for operations under elevated temperatures and pressures in deep wells. Composition consists of perchlorate-type oxidant, nonexplosive organic fuel, metallic fuel, and brisant explosive. Composition is used to prepare charges in the form of blasting cartridges with porosity 0.01-0.15. EFFECT: increased density and heat resistance, and lowered hygroscopicity. 8 cl, 4 ex

Description

 The invention relates to the field of explosives (BB) and their charges for the oil and gas, mining and seismic exploration and can be used for blasting in a variety of conditions, including at elevated temperatures and pressures in deep wells.

 Blasting operations are widely used in the practice of open-pit field development, when drilling wells to eliminate accidents, opening and increasing reservoir returns, and for other operations that can be carried out using explosives with less time and money than other methods (N.A. Grigoryan, D. E. Pometun, L. A. Gorbenko, S. A. Lovlya, B. L. Kaplan. Rifle and blasting in wells. M., Nedra, 1972). To break and increase the return of formations after a backache and perforation of the walls of the well, it is necessary to create local foci of high pressure. This task is performed by pressure generators (GD), equipped with compositions capable of rapid combustion with the release of a large amount of energy and a large volume of gaseous products. Compositions for wells have a number of requirements due to high temperatures and pressures in the wells, the main of which is heat resistance.

 In deep wells, you can use charges from individual explosives that are characterized by high heat resistance, for example, from a class of explosives of the nitramine type (Orlova E. Yu. Chemistry and technology of explosive explosives. 2nd ed., Revised and supplemented, - L., Chemistry, 1973), such as hexogen (Energy condensed systems. A brief encyclopedic dictionary. / Ed. By Academician B.P. Zhukov, M., Janus-K, p. 131), and for higher temperatures, HMX (ibid. , p.334), however, these explosives are very expensive, which leads to a sharp increase in the cost of work.

 Known explosive composition containing an oxidizing agent - ammonium nitrate (HA) in an amount of 66 wt.%, Combustible - 5 wt.% TNT and 5 wt.% Aluminum powder and a powerful blasting explosive, represented by hexogen, in an amount of 24 wt.%. This composition refers to industrial mixed explosives of the ammonite type (namely, rocky ammonite 1) and is widely used in explosive technology, including in holes and boreholes (L.V. Dubnov, N.S. Bakharevich, A.I. Romanov. Industrial explosives, M., Nedra, 1973, p.120).

 The known composition has good explosive and energy characteristics. The basis of this composition, like all other industrial explosives, is ammonium nitrate. The disadvantages of HA and compositions based on it are: high hygroscopicity, change in storage properties due to caking, insufficiently high density and heat resistance.

 Closest to the proposed explosive composition in terms of the qualitative composition of the components is an explosive composition consisting of 10-20 wt.% Polymer binder (e.g. polybutadiene), 5-20 wt.% Metal powder (aluminum or magnesium), 10-30 wt.% perchlorate type oxidizing agent (metal or ammonium perchlorate) and 40-55 wt.% high-power explosives (RDX or HMX) (US 3865035, 02/11/1975, C 06 C 15/00).

 This known composition (composition) has an increased explosion hazard: it is very sensitive to mechanical stress and shock wave, which increases especially when the composition contains high-power explosives of 45 wt.% And higher, which significantly limits its scope.

The closest solution in technical essence to the proposed charge is a cartridge charge of rock ammonite 1, which is a checker with a density of 1.43-1.53 g / cm ³ (L.V. Dubnov, N.S. Bakharevich, A.I. Romanov Industrial explosives, M., Nedra, 1973, pp. 121-122), which corresponds to a porosity of 0.20-0.15. Porosity of the checkers is the most important characteristic of the charge, especially when used for equipping the main engine.

 The disadvantages of the known charge are its low density and heat resistance.

 The objective of the invention is the creation of high-energy explosive composition for general use, with improved performance: reduced explosiveness, higher heat resistance and density, which will significantly expand its scope.

 The objective of the invention is the development of a charge with increased density and heat resistance, reduced hygroscopicity, which will significantly expand its scope and use this charge in various explosive devices, including explosive weapons and equipment for the main engine.

The problem is solved by the proposed explosive composition, consisting of a perchlorate type oxidizer, fuel and blasting explosive, which contains organic non-explosive fuel and metallic fuel as fuel in the following ratio of components, wt.%:
Organic Non-Explosive Fuel - 6-15
Metallic fuel - 0.1-35
High explosive - 0.1-39
Perchlorate Type Oxidant - Rest
The proposed explosive composition as an oxidizing agent of perchlorate type may contain ammonium perchlorate, potassium perchlorate or a mixture thereof.

 To reduce the cost, a certain amount of ammonium or potassium nitrate (up to 25% of the total weight of the oxidizing agent) can be added to the perchlorate oxidizing agent.

 Organic non-explosive fuel can be selected from the group: graphite, wood flour, paraffin, or a polymer selected from the series: polyethylene, polystyrene, polymethylmethacrylate, polyurethane, fluoroplast, polybutadiene, polyacrylamide, or a mixture thereof.

 As a metal fuel composition may contain powdered aluminum or its alloy with boron or with magnesium, or magnesium.

 As a blasting explosive, the composition may contain a nitro compound or explosive of the nitramine type, or a mixture thereof.

 The solution to this problem is also achieved by the proposed charge, made in the form of one or more pieces, which is made of the declared explosive composition and has a porosity of 0.01-0.15.

 The checker of the proposed charge can be placed in the shell.

 The use of perchlorate type oxidizing agents provides a high energy content of the proposed explosive composition in combination with high values of heat resistance and composition density.

 The use of organic non-explosive fuels from the list: polymer (polyethylene, polystyrene, polymethyl methacrylate, polyurethane, fluoroplastic, polybutadiene, polyacrylamide), graphite, wood flour, paraffin or mixtures thereof allows you to adjust both energy and heat resistance of the explosive composition, as well as cost and technological aspects operations of preparing the composition and charges from it and handling them.

 The type and amount of powdered metal fuel allows you to adjust the energy characteristics of the explosive composition, namely, an increase in the amount of powdered metal fuel within the stated limits increases the energy of the explosive conversion of the composition, while the density and heat resistance of the composition increase.

 The blasting explosive in the composition of the explosive mixture (within the stated limits) ensures the fulfillment of the requirements for failure-free initiation, obtaining the necessary levels of detonation velocity and critical detonation diameter and at the same time does not lead to an unacceptable increase in the sensitivity of the composition to mechanical stress and shock wave, providing sufficient explosion safety . As a blasting explosive, the proposed composition may contain nitramine type explosives (hexogen, octogen) or nitro compounds (trinitrobenzene, trinitrotoluene, hexanitrodiphenyl sulfite, hexanitrostilbene, triaminotrinitrobenzene, nitromethane, isopropyl nitrate) or mixtures thereof. As a blasting explosive in the proposed composition, explosives obtained from utilized ammunition can also be used.

 The content of individual components is dictated by the required characteristics. The declared boundary values of the content of components were determined by us taking into account thermodynamic calculations (heat of explosion, work of expansion of detonation products, gas composition, explosive force) and the results of experimental verification of the charges from the proposed explosive composition.

 The use of checkers in various kinds of explosive and shooting equipment is described in the book "Heat-resistant explosives in deep wells", M., Nedra, 1981. The charges we offer from the declared explosive composition can work in two modes of explosive transformation: detonation and explosive (convective) combustion.

 The blasting explosive content of 0.1-10% is advisable to use mainly in charges for equipping a main engine with a transformation mode in the form of explosive (convective) combustion, the content of 10-39% is mainly used for blasting operations with a detonation transformation mode.

 The density and porosity of the checker, as already mentioned, is the most important characteristic of a charge. For the most full use of the positive properties of the proposed explosive composition, it is necessary to control the porosity of the pieces made from it and have it in the required range.

 We suggest using a charge of one or more pieces of any desired configuration with reduced porosity: 0.01-0.15. These parameters of the checkers from the proposed explosive composition are selected experimentally and allow you to adjust for the proposed low-porous charge the detonation speed from 2-3 to 7.5 km / s and the speed of explosive (convective) combustion in the range of 1-100 m / s. The proposed charge provides a high completeness of combustion and a high level of gas evolution per unit time. The decrease in porosity can increase the energy concentration per unit volume of the charge.

 Charge-checker can be made by pressing, pouring or polymerization (using rubber-like binders). Checkers can have a different shape, for example, have a channel or cumulative recess. The charge can be used both in shells and without shell. A charge may consist of one or more pieces.

 Below are examples of the values of the explosive characteristics of the pieces from the compositions containing different amounts of components within the specified boundaries.

 Below are examples for charges made from the proposed compositions when used in detonation and convective combustion (KG) modes, indicating experimental values of the detonation velocity or KG and calculated energy characteristics: heat of explosion, work of expansion of products, and explosive force.

 Examples 1 and 2 correspond to the mode of detonation at values of the quantities of the components of the composition and porosity of the charge, close to the average values for the claimed interval.

Example 1
Composition 50PHA / 21A1 / 9 graphite / 20 hexogen: the heat of explosion and the work of expansion of the detonation products are 2110 kcal / kg and 2330 kcal / kg, respectively, the detonation speed is 5.6 km / s with a charge porosity of 0.1, the thermal stability threshold is 170 ^o C.

Example 2
Composition 46PKhK / 20A1 / 9 graphite / 25 octogen: the heat of explosion and the work of expansion of the detonation products are 1700 kcal / kg and 1770 kcal / kg, respectively, the detonation speed is 5.0 km / s with a charge porosity of 0.1, the thermal stability threshold is 200 ^o C.

 Examples 3 and 4 correspond to charges from compositions intended primarily for use in the KG mode.

Example 3
Composition 72PHA / 20A1 / 8 polystyrene / 0.1 RDX: at a charge porosity of 0.1 and a pressure of 1000 atm, the velocity of the KG is 10 m / s, the explosive strength is 128 t • m / kg, and the thermal stability threshold exceeds 150 ^o C.

Example 4
The stoichiometric composition is 90PHA / 10 polystyrene / 0.1 RDX: at a charge porosity of 0.1 and a pressure of 1000 atm, the velocity of the KG is 8 m / s, the strength of explosives is 118 t • m / kg, and the thermal stability threshold exceeds 140 ^o C.

For rock ammonite 1, the heat of explosion and the work of expansion of the detonation products are 1275 kcal / kg and 1750 kcal / kg, respectively, the explosive force is 105 t • m / kg, the detonation speed is 5.7 km / s with a charge porosity of 0.2, the threshold thermal stability does not exceed 120 ^o C.

 As can be seen from the comparison, the charges from the proposed composition have higher energy characteristics and heat resistance.

Claims (7)

1. An explosive composition containing a perchlorate type oxidizer, fuel and blasting explosive, characterized in that as fuel it contains organic non-explosive fuel and metallic fuel in the following ratio, wt. %:
Organic Non-Explosive Fuel - 6-15
Metallic fuel - 0.1-35
High explosive - 0.1 - 39
Perchlorate Type Oxidant - Rest
2. An explosive composition according to claim 1, characterized in that it contains ammonium perchlorate, potassium perchlorate or a mixture thereof as the perchlorate type oxidizing agent.  3. An explosive composition according to claim 1, characterized in that it additionally contains ammonium or potassium nitrate in an amount up to 25% of the total amount of oxidizing agent.  4. An explosive composition according to claim 1, characterized in that the organic non-explosive fuel is selected from the group: graphite, wood flour, paraffin or a polymer selected from the series: polyethylene, polystyrene, polyacrylamide, polymethyl methacrylate, fluoroplast, polyurethane, polybutadiene or a mixture thereof.  5. An explosive composition according to claim 1, characterized in that, as a metal fuel, it contains powdered aluminum, or its alloy with boron or with magnesium, or magnesium.  6. An explosive composition according to claim 1, characterized in that, as a blasting explosive, it contains a nitro compound or an explosive substance of a nitramine type or a mixture thereof.  7. A charge of explosive made in the form of one or more pieces, characterized in that the piece is made of explosive composition according to any one of paragraphs. 1-6 and has a porosity of 0.01-0.15.  8. The charge according to claim 7, characterized in that the checker is placed in the shell.