UA65043A - A method for producing the charge of slurry explosive, a water-containing liquid (variants) and a slurry explosive - Google Patents

Abstract

A method for producing the charge of slurry explosive consisting in addition of water-containing liquid being mix aqueous solution of oxidizing and combustion agents to the ammonium and saltpeter explosive, mixing the mentioned component substances composition at the ambient temperature up to obtaining the finished water-containing substance and forming the charge of an explosive. The water-containing liquid, an unsaturated by concentration of substances, and at the temperature of dry explosive and temperatures of components in mixing being added, and mixing process is performed in the period of time up to equalization of the mention substances composition temperature with the ambient temperature.

Description

Description of the invention

The invention relates to mining, namely, to blasting in quarries, in particular to methods 2 of manufacturing explosives (BP) directly at the place of use, before their placement in wells, including in polyethylene sleeves.

There are known methods of making a water-containing charge and BP for its implementation (1, 2), in which water filling is carried out by mixing dry components with water or oxidizing solutions. The water-containing BP is manufactured beforehand, as a rule, in stationary conditions and transported to the place of explosion in a ready-made form 70, where the charge is manufactured. The stability of the composition in these BPs is ensured by the creation of a high viscosity of the liquid phase.

When implementing this method, mechanized charging is problematic, since the ready-made water-filled BP with a low water content, especially if it contains thickeners, has reduced flowability.

In addition, water filling of BP at the place of its preparation leads to the need to transport a larger amount of dangerous cargo, as water increases the total mass of BP. This reduces the safety of work.

Charges from BP are known, which are made immediately before placing them in the charging cavity by mixing a hot saturated solution of oxidizing substances - ifzanites, aquatols, as well as oxidizing and combustible substances - carbatols with dry substances |ZI.

To stabilize the composition of BP in the process of crystallization, during its cooling, thickening components are introduced into the composition of these BPs. However, in practice, with significant time intervals of storage of charges in the finished form due to the action of various factors, such as the influence of sign-changing temperature changes, rock impurities, insufficient technological properties of thickening components, etc. precipitation of salt crystals and stratification of charges occurs, which sharply reduces the effectiveness of the explosion of such charges.

There is a known method of making a charge based on a cold saturated solution of ammonium nitrate |4). In it, immediately before the formation of the charge, the solution is mixed with dry BP. "

There is also a known method of manufacturing BP and BP charge on the basis of a cold water-containing liquid, as well as the composition of this liquid, adopted by us as a prototype of IB). In the first |4| and the second |5) variants of BP manufacture and charge formation, the probability of sedimentation and charge stratification is lower than in the case of hot solutions.

However, when the temperature of the substance drops below the saturation temperature of the solution, this phenomenon will occur. at

Such a decrease is possible when the solution is added to a cold dry BP or when substances are mixed, or when the obtained substance is placed in the charge at temperatures lower than the temperature of the solution. These methods do not take into account the phenomenon of sedimentation and do not consider measures to reduce it or completely eliminate it. In addition, the ratio of substances in the water-containing liquid (solution) in these variants is significantly different from the stoichiometric one, and this liquid has a relatively low energy potential. This requires changing the composition of the dry BP, to which this liquid is added, when the liquid content in the BP composition is changed. Due to the relatively low energy saturation of the liquid, the water-containing BP also has a reduced energy potential, which will drop sharply if the ratio of the liquid content in the BP is disturbed or when this liquid is stratified due to sedimentation during saturation. In addition, the storage of a saturated solution without its crystallization in technological operations that precede its addition is problematic, especially if BP is produced in the conditions of a pit, C 70 immediately before the formation of well charges. c The technical task of the invention is to develop a method of forming a charge, water-containing liquid and water-containing

Из» BP, which ensure an increase in the effectiveness of the action of the charge of water-containing BP due to a decrease in the intensity of sedimentation, as well as an increase in the energy properties and balance of the water-containing liquid.

The problem is solved by the fact that in the known method of manufacturing a charge of a water-containing explosive substance, which consists in adding a water-containing liquid, which is a mixed aqueous solution of oxidizing and combustible substances, to a dry ammonia-nitrite explosive substance, mixing the specified component composition of substances at 4! ambient temperature before obtaining the finished water-containing substance and the formation of the charge of the explosive substance, add a water-containing liquid, which is not saturated in substance concentration, at the temperature of the dry explosive substance and the temperatures of the components during mixing, and the mixing process is carried out in the 20th period of time until the temperature of the specified composition of substances with ambient temperature. c» In this case, the charge of the explosive substance is formed immediately after mixing the component composition of the substances until the temperature of the finished explosive substance equalizes with the ambient temperature.

At the same time, before making the charge and/or in the process of adding liquid to the explosive substance and mixing the components, they are placed in a cooled environment. in. At the same time, the mixing of substances is carried out in the period of time from the beginning of the addition of water-containing liquid to the explosive substance until the end of the decrease in the temperature of the resulting mixture.

At the same time, the mixing of substances is carried out during the time of adding a water-containing liquid to the dry explosive substance. 60 At the same time, the aqueous mixed solution of substances includes substances that form eutectic mixtures with ammonium nitrate, for example nitrates of alkali metals or urea.

At the same time, the water-containing explosive substance is thickened by additional introduction of a thickening component into the mixed aqueous solution of substances and/or into the dry explosive substance.

In this case, the thickening component is introduced before mixing the substances. because the thickening component is introduced in the process of mixing substances.

At the same time, the water-containing liquid is added in a volume smaller than the total volume of open pores in the dry explosive.

At the same time, the water-containing liquid is added in a volume equal to or greater than the total volume of open pores in the dry explosive.

At the same time, the charge is formed by placing a ready-made water-containing explosive in the charging cavity, for example, in a well or shell.

At the same time, the water-containing explosive substance is placed in the charging cavity in a stream.

At the same time, the water-containing explosive substance is placed in the charging cavity in portions. 70 At the same time, the water-containing liquid is added to the dry explosive immediately before the formation of the charge, and at the same time, its amount is changed as the charge is formed.

At the same time, the amount of liquid added to the dry explosive is changed discretely.

At the same time, the amount of liquid added to the dry explosive is changed continuously.

At the same time, the amount of liquid added to the dry explosive is reduced.

At the same time, the amount of liquid added to the dry explosive is increased.

At the same time, the amount of liquid added to the dry explosive is changed alternately, decreasing and increasing.

At the same time, as the water-containing explosive substance is placed in the charging cavity, the charge is separated by impermeable bridges.

At the same time, the charge is formed from separate parts pressed together, in which the water-containing explosive substance is placed in individual closed shells.

The problem is also solved by the fact that the water-containing BP includes a water-containing liquid, which includes ammonium nitrate, alkali metal nitrate, for example, sodium nitrate, a water-soluble combustible substance and water, and these substances are contained in a ratio close to stoichiometric at this composition, because by mass: ammonium nitrate 15.0-50.0 « alkali metal nitrate, for example sodium nitrate 10.0-30.0 water-soluble combustible substance 5.0-20.0 water the rest. in addition, mono-, di-, triethylene glycol, glycerol, ethyl, methyl alcohols, urea or all of them together in any combination and ratio are used as a fuel.

The problem is also solved by the fact that the water-containing BP includes a water-containing liquid, which includes ammonium nitrate, alkali metal nitrate, for example, sodium nitrate, a water-soluble combustible substance, additives and water, and these substances are contained in a ratio close to stoichiometric at such composition, 95 by mass: with ammonium nitrate 15.0-50.0 alkali metal nitrate, for example sodium nitrate 10.0-30.0 water-soluble combustible substance 5.0-20.0 « additives 0.05-3, 0 s 70 water rest. 8 z" At the same time, mono-, di-, triethylene glycol, glycerin, ethyl, methyl alcohol, urea or their combination in any combination and ratio are used as a combustible substance.

At the same time, one or more surface-active substances, such as sodium stearate or oleic acid, as well as a thickening component, are used as additives separately or together in any ratio.

Me which includes a gelling agent, such as guar gum or polyacrylamide, and a cross-linking agent, such as aluminum potassium alum, or no cross-linking agent.

The problem is also solved by the fact that in a water-containing explosive substance containing a water-containing liquid and a dry explosive mixture, the explosive mixture as a basis contains ammonium nitrate, liquid fuel, solid organic combustible substance, individual explosive substance, or gunpowder, or silicon , or a metallic combustible substance, or both of them together in any combination, and the components of a water-containing explosive substance are used in the following proportions, 95 by mass: a water-containing liquid based on at least one oxidizer and at least one combustible substance in the ratio shenny, close to 5.0-35.0 556 stoichiometric dry explosive mixture based on ammonium nitrate, liquid fuel, solid organic fuel, individual explosive residue

P" substance, or gunpowder, or silicon, or metallic combustible substance, or their combination in any ratio

At the same time, the water-containing explosive contains a water-containing liquid, which includes ammonium nitrate, nitrate of a base metal, for example, sodium nitrate, a water-soluble combustible substance and water, and the specified substances are contained in a ratio close to stoichiometric with this composition, 9% by mass: nitrate ammonium 15.0-50.0 alkali metal nitrate, for example sodium nitrate 10.0-30.0 water-soluble combustible substance 5.0-20.0 bo water the rest.

At the same time, the water-containing explosive contains a water-containing liquid, which includes ammonium nitrate, alkali metal nitrate, for example sodium nitrate, a water-soluble combustible substance, additives and water, and the specified substances are contained in a ratio close to stoichiometric with this composition, because by mass: ammonium nitrate 15.0-50.0 alkali metal nitrate, for example sodium nitrate 10.0-30.0 water-soluble combustible substance 5.0-20.0 additives 0.05-3.0 water the rest.

At the same time, the dry explosive mixture contains 95 by mass: an individual explosive substance, or gunpowder, or silicon, or a metallic combustible substance, or both of them together in any ratio 3.0-20.0 solid organic combustible substance 0.3-5 .0 liquid fuel 0.5-4.0 ammonium nitrate the rest.

At the same time, the dry explosive mixture additionally contains 95% by weight: an individual explosive substance, or gunpowder, or silicon, or a metallic combustible substance, or both of them together in any ratio 3.0-20.0 solid organic combustible substance 0.3- 5.0 liquid fuel 0.5-4.0 thickening component 0.05-3.0 ammonium nitrate the rest. "

At the same time, the dry explosive mixture additionally contains a swelling component, a porous component, a phlegmatizing agent, and additives in 95% by weight: individual explosive substance, or gunpowder, or silicon, or metallic combustible substance, or all of them together in any ratio of 3.0 -20.0 solid organic fuel 0.3-5.0 - liquid fuel 0.5-4.0 o swelling component 0.3-3.0 porous component 0.3-5.0 it) phlegmatizing agent 0, 1-5.0 (Te) additives 0.05-3.0 ammonium nitrate the rest.

At the same time, as an individual explosive, a water-containing explosive contains TNT, or phlegmatized hexane, or both together, or explosive mixtures - products of ammunition disposal. з с At the same time, as gunpowder, it contains ground or crushed ballistic gunpowder, or granulated or crushed pyroxylin gunpowder, or both in various combinations. At the same time, it contains aluminum, or ferrosilicon, or silicocalcium, or siliceous aluminum as a metallic fuel.

At the same time, as a solid organic substance, it contains stone or charcoal, or soot, or rubber, or

F them together in any combinations.

At the same time, as a liquid fuel, it contains a liquid petroleum product, for example, diesel fuel or a mixture of petroleum products. At the same time, as a swelling component, it contains an organic swelling component, for example, wood flour, or cereal flour, or bran, or clay, or all of them together in any combination. At the same time, as a porous component, it contains expanded perlite, or fly ash, or glass microcapsules, or foam plastic, or both of them in any combination.

At the same time, as a phlegmatizing component, it contains glycerin, or talc, or aluminum hydrochloride, or urea, or they are combined in any combination.

At the same time, as additives, one or more surfactants and a thickening component are used separately or together in any ratio. » At the same time, stearates of alkali metals, such as sodium, and fatty acids, such as oleic acid, are used as surfactants.

At the same time, as a thickening component, guar gum or polyacrylamide and a crosslinking agent are used, for example, aluminum potassium alum or ferric salts, or without a crosslinking agent.

At the same time, crystalline, or granulated, or crushed, or ground, dense or porous ammonium nitrate is used.

The effectiveness of the distinguishing feature of mixing the component composition of substances and obtaining a ready-to-moment equalization of the temperature of this composition with the ambient temperature d5 is determined by the factors acting at the same time. At different temperatures of the liquid and dry BP practically during the mixing process, their temperature equalizes and becomes constant at all points of the mixed mass. At the same time, if the solution was saturated at the temperature of its combination with dry BP, it remains saturated until the end of the mixing process. However, its concentration can be significantly reduced. This will happen when the temperature of the solution drops and when leveling, if it was higher than the temperature of dry BP. "Excess" in concentration at the temperature of mixing, the substance of the solution crystallizes and precipitates. At the end of the mixing process, this sediment will gradually sink into the lower layers of the BP volume.

The limiting concentration of a substance in a solution at which it can precipitate during mixing is the saturation concentration at the mixing temperature. In this case, during mixing, after the equalization of the difference in the initial temperatures of the mixed substances, dissolution processes in the mixed medium will not occur and the temperature will stabilize.

When an unsaturated liquid is added to the dry BP after equalization of temperatures, the process of dissolution of ammonium nitrate continues, which gradually slows down, and the temperature of the composition drops to a lower value, which depends on the concentration of substances in the solution. The less saturated the solution, the greater the drop in temperature.

If at the same time the external conditions for the production of BP do not change, then upon reaching the minimum value /5 of the temperature and the concentration of the formed solution in the composition of the water-containing BP approaching saturated, the temperature of the mixture slowly rises to equalize with the ambient temperature. At the same time, sediment is not formed. With long-term storage of the substance and temperature fluctuations, precipitation of crystallized salts is possible.

If the detonation temperature of water-containing BP is lower than the storage temperature of the finished water-containing 2o substance, BP delamination occurs. Therefore, in this case, the lower the concentration of the solution of the substances before combining and mixing with the dry substance and the faster, after the maximum decrease in temperature, the substance is given the temperature at which it will explode, the less likely it is to form a precipitate and stratify the water-containing BP. Therefore, the mixing process should be carried out during the period of lowering the temperature of the mixture, and the ready BP should be immediately placed and stored in conditions where its explosion will take place. c It is advisable to reduce the concentration of the initial solution to a certain limit, despite the associated decrease in the probability of precipitation. This is due, first of all, to an increase in the water content in the composition of BP and a decrease in its energy indicators. The logical lower limit of the concentration of substances of the original solution is its saturation concentration at the detonation temperature. In this case, in the process of manufacturing BP with the dissolution of ammonium nitrate, the lowest temperature, if the change in the content of salts in the solution is not taken into account, will not be lower than the temperature of detonation, since in this case the dissolution of substances and the accompanying decrease in temperature will stop. When placing such a substance for storage under the conditions of its explosion, it will not delaminate due to sedimentation. In the case of mixing such a solution with a dry component of water-containing BP at the temperature of its detonation, the temperature of the mixture will not drop and precipitation will not be observed. at

An additional factor in increasing the homogeneity of the charge composition is the difference in the processes of transition of soluble substances into solution with uniform and non-uniform distribution of components in the volume of mixtures. With an uneven ratio of dry BP and liquid, this process will occur with an accelerated, up to complete, transition to a solution of soluble components at some points and almost complete preservation of the initial structure of dry BP in other points of the volume of the mixture. At the same time, in the first points, solid insoluble "combustible substances, which remained without direct contact with the oxidizer, will be concentrated. At the same time, liquid insoluble in water will coagulate and settle on undissolved, primarily combustible particles. petroleum products released from dissolved oxidizer particles, in particular ammonium nitrate, especially porous. and This will lead to the formation of coarse-grained structures with combustible substances. In addition, it is possible that part of the soluble particles will pass into the solution completely, while other soluble particles will dissolve in a smaller

Measures, that is, will also be larger on average. When mixing, large particles can be again

He" are evenly distributed, but will remain enlarged in size, significantly worsening the detonation and energy characteristics of the BP. On the contrary, mixing at earlier stages of the dissolution process leads to a more uniform dissolution of particles in all points of the volume and a more uniform change in the structure of dry BP for the better with a decrease in the size of soluble particles, usually oxidants. A uniform decrease of 50% in the size of the oxidizing particles will lead to an increase in the uniformity and intensity of contact between combustible and oxidizing substances, which increases the detonation characteristics and energy output of the reactor. Therefore, the dissolution process with 4) reduction of the particle size of the elements that dissolve, with timely mixing and equalization of the composition of the substance in the volume, is an important technological element that improves the technical properties of BP. This additionally justifies the expediency of using unsaturated liquid solutions in the production of water-containing BPs.

The figures show the temperature regimes for mixing specific variants of the declared liquid and dry BP. The composition of the liquid includes, wt. 9o: ammonium nitrate 28; sodium nitrate 25; in ethylene glycol 11; water 36.

VR includes, mass. 905: ferrosilicon 4.0; b5 fossil coal 2.0;

diesel fuel 2.4; guar gum 0.6; ammonium nitrate 81.0. , , 2, nya p. . ,

Fig. 1 shows the dependence of the temperature of the mixture on time at the initial temperature of the liquid, dry BP and the environment, which is equal to 2770.

In fig. 2 shows the dependence of the temperature of the mixture on time at the temperature of the liquid - 57C, dry BP and environment - 27"C (dependency 7), as well as at the temperature of dry BP and surrounding /o0 Environment, which is equal to 5"7C (dependency 2).

Comparative characteristics of the water-containing liquid according to the prototype and the claimed variant are given in the table.

The data in this table confirm significantly higher energy characteristics of the claimed liquid and closer to the stoichiometric ratio of the components.

Close to the stoichiometric ratio of the components is the ratio in which the addition of 75% water-containing liquid to the dry BP does not deteriorate its operational performance within the limits of permissible deviations. 2 pirate 31010300 m

002800 9230

Zyratamonyu 10013000 7730

Diesel pile 25 | 502 zv Etlentyut 10201009 68

Peramo 1110118 250812 «

Vr 001 o| 3155 not with her about

For example, for a dry BP with an oxygen balance of 1.095, the liquid compositions given in the table when adding them in t) 35 in the amount of 26.Omas.95 are: the liquid according to the prototype is not close to the stoichiometric ratio of components, but the declared one is close. Thus, the resulting composition when using liquid according to the prototype will have an oxygen balance of 12.82, and according to the proposed version - minus 0.1. In the first case, there will be a sharp qualitative and quantitative change in the gas composition of detonation products for the worse.

Specific variants of the method of manufacturing a charge of BP, water-containing liquid and explosive substances have no special features. They can be used in stationary conditions for the production of BP charges - from c cartridges, as well as in more typical conditions for the manufacture of borehole BP charges in quarries with the help of mobile mixing units. :z» Sources of information 1. Pat. USSR Mo537624, СО6ЕВ31/28 2. Pat. RF Mo2147567, СО6ЕВ31/42

FO Z. Krsyn R.S., Domnychev V.N. Modern explosive substances of local preparation. -

Dnipropetrovsk: Science and Education, 1998. -140p. o 4. Seinov N.P., Valiev B.S. The technology of charging irrigation wells with waterproof explosives about substances / In book. Explosive case, Mo89/46. - M.: Nedra, 1986. - P.204-215. 5. Pat. USA Mo4693765, СО6В 36/30 iz 50 s»

Claims (45)

The formula of the invention 1. The method of manufacturing a charge of a water-containing explosive substance, which consists in adding a water-containing liquid, which is a mixed aqueous solution of oxidizing and inflammable substances, to a dry ammonia-nitrite explosive substance, mixing the specified component composition of substances at ambient temperature to obtain a ready water-containing substance and formation of an explosive charge, which differs in that a water-containing liquid is added, unsaturated in terms of substance concentration, at the temperature of the dry explosive substance and the temperatures of the components during mixing, and the mixing process is carried out during the time period until the temperature of the specified composition of substances equals the temperature of the environment. 2. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which is characterized by the fact that the charge of an explosive substance is formed immediately after mixing the component composition of the substances until the temperature of the finished explosive substance is equal to the ambient temperature. 65 3. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which differs in that before the manufacture of the charge and/or during the process of adding liquid to the explosive substance and mixing the components, they are placed in a cooled environment. 4. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which is characterized by the fact that the mixing of substances is carried out in the period of time from the beginning of the addition of water-containing liquid to the explosive substance until the end of the decrease in the temperature of the formed mixture. 5. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which is characterized by the fact that the mixing of substances is carried out during the time of adding the water-containing liquid to the dry explosive substance. 6. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which differs in that the aqueous 70 mixed solution of substances includes substances that form eutectic mixtures with ammonium nitrate, for example nitrates of alkali metals or urea. 7. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which is characterized by the fact that the water-containing explosive substance is thickened by additional introduction of a thickening component into the mixed aqueous solution of substances and/or into the dry explosive substance. 8. The method of manufacturing a charge of a water-containing explosive substance according to claims 1 and 7, which differs in that the thickening component is introduced before mixing the substances. 9. The method of manufacturing a charge of a water-containing explosive substance according to claims 1 and 7, which differs in that the thickening component is introduced during the mixing process. 10. The method of manufacturing a charge of water-containing explosive substance according to claim 1, which differs in that the water-containing liquid is added in a volume smaller than the total volume of open pores in the dry explosive substance. 11. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which is characterized by the fact that the water-containing liquid is added in a volume equal to or greater than the total volume of open pores in the dry explosive substance. 12. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which differs in that the charge is formed by placing a ready-made water-containing explosive substance in a charging cavity, for example, in a well or casing. " 13. The method of manufacturing a charge of a water-containing explosive substance according to claims 1 and 12, which differs in that the water-containing explosive substance is placed in the charging cavity by a stream. 14. The method of manufacturing a charge of a water-containing explosive substance according to claims 1 and 12, which differs in that the water-containing explosive substance is placed in the charging cavity in portions. 15. The method of manufacturing a charge of a water-containing explosive substance according to claim 1, which differs in that - a water-containing liquid is added to the dry explosive substance immediately before the formation of the charge and at the same time its quantity is changed as the charge is formed. 16. The method of manufacturing a charge of a water-containing explosive substance according to claims 1, 12 and 15, which differs in that the amount of liquid added to the dry explosive substance is changed discretely. co 17. The method of manufacturing a charge of a water-containing explosive substance according to claims 1, 12 and 15, which is characterized by the fact that the amount of liquid added to the dry explosive substance is changed continuously. 18. The method of manufacturing a charge of a water-containing explosive substance according to claims 1, 12 and 15, which is characterized by the fact that the amount of liquid added to the dry explosive substance is reduced. " 19. The method of manufacturing a charge of a water-containing explosive substance according to claims 1, 12 and 15, which differs in that -plv) with the amount of liquid added to the dry explosive substance is increased. . 20. The method of manufacturing a charge of a water-containing explosive substance according to claims 1, 12 and 15, which is characterized by the fact that the amount of liquid added to the dry explosive substance is changed alternately, decreasing and increasing. 21. The method of manufacturing a charge of a water-containing explosive substance according to claims 1 and 12, which differs in that when the water-containing explosive substance is placed in the charging cavity, the charge is separated by impermeable bridges. 22. The method of manufacturing a charge of a water-containing explosive according to claims 1, 12 and 21, which is characterized by the fact that the charge is formed from individual parts pressed together, in which the water-containing explosive is placed in individual closed shells. 23. A water-containing liquid, including ammonium nitrate, alkali metal nitrate, for example, sodium nitrate, a water-soluble combustible substance and water, which is characterized by the fact that these substances are contained in 4) a ratio close to stoichiometric with this composition, 95 by mass: ammonium nitrate 15.0-50.0 5B alkali metal nitrate, for example, sodium nitrate 10.0-30.0 water-soluble combustible substance 5.0-20.0 in" water the rest. 24. Water-containing liquid according to claim 23, which is characterized by the fact that mono-, di-, triethylene glycol, glycerin, ethyl, methyl alcohol, urea or their combination in any combination and ratio are used as a combustible substance. 25. A water-containing liquid, including ammonium nitrate, alkali metal nitrate, for example, sodium nitrate, a water-soluble combustible substance, additives and water, which is distinguished by the fact that the specified substances are contained in a ratio close to stoichiometric at such a composition, 95 by mass : for ammonium nitrate 15.0-50.0 alkali metal nitrate, for example, sodium nitrate 10.0-30.0 water-soluble combustible substance 5.0-20.0 additives 0.05-3.0 water the rest. 26. Water-containing liquid according to claim 25, which is characterized by the fact that mono-, di-, triethylene glycol, glycerin, ethyl, methyl alcohol, urea or their combination in any combination and ratio are used as a fuel. 70 27. Water-containing liquid according to claim 25, which is characterized by the fact that as additives are used separately or together in any ratio one or more surface-active substances, for example, sodium stearate or oleic acid, as well as a thickening component, which includes a gel-forming substance, such as guar gum or polyacrylamide, and a crosslinking agent, such as potassium alum, or without a crosslinking agent. 28. A water-containing explosive substance containing a water-containing liquid and a dry explosive mixture, which differs from 5. WHEREAS the explosive mixture as a basis contains ammonium nitrate, liquid fuel, solid organic combustible substance, individual explosive substance or gunpowder, or silicon, or metallic combustible substance, or both together in any combination, and the components of the water-containing explosive substance are used in such ratios, Cho by mass: water-containing liquid based on at least one oxidizer and at least one combustible substance in a ratio close to 5.0-35.0 stoichiometric dry explosive mixture based on ammonium nitrate, liquid fuel, solid organic combustible substance , individual explosive residue. substance, or gunpowder, or silicon, or metallic combustible matter, or their combination in any ratio 29. A water-containing explosive according to claim 28, which differs in that it includes a water-containing liquid according to claim 23. 30. A water-containing explosive according to claim 28, which differs in that it includes a water-containing liquid according to claim 25. 31. Water-containing explosive according to claim 28, which is characterized by the fact that the dry explosive mixture contains 905% by mass: an individual explosive or powder, or silicon, or a metallic combustible substance, or both of them in any ratio of C, 0- 20.0 so solid organic fuel 0.3-5.0 liquid fuel 0.5-4.0 ammonium nitrate the rest. at 32. Water-containing explosive according to claim 28, which is characterized by the fact that the dry explosive mixture additionally contains M in 9% by weight: individual explosive, or gunpowder, or silicon, or metallic combustible, or both of them in any ratio 3 .0-20.0 solid organic fuel 0.3-5.0 liquid fuel 0.5-4.0 « 20 thickening component 0.05-3.0 with ammonium nitrate the rest. "with 33. Water-containing explosive according to claim 28, which is characterized by the fact that the dry explosive mixture additionally contains a swelling component, a porous component, a phlegmatizing agent and additives in 95% by mass: an individual explosive or gunpowder, or silicon, or a metallic combustible, or their together in any ratio C.0-20.0 Me solid organic fuel 0.3-5.0 (9! liquid fuel 0.5-4.0 swelling component 0.3-3.0 o porous component 0 .3-5.0 s" 50 phlegmatizing agent 0.1-5.0 additives 0.05-3.0 s" ammonium nitrate the rest. 34. A water-containing explosive substance according to claims 28, 31, 32, 33, which differs in that, as an individual explosive substance, the water-containing explosive substance contains phlegmatized TNT or hexane, or both of them, or non-explosive mixtures - ammunition disposal products. 35. A water-containing explosive substance according to claims 28, 31, 32, 33, which differs in that, as a powder, it contains ground or crushed ballistic powder, or granular or crushed pyroxylin powder, or both of them in various combinations. 60 36. A water-containing explosive according to claims 28, 31, 32, 33, which differs in that it contains aluminum or ferrosilicon, or silicocalcium, or siliceous aluminum as a metallic combustible substance. 37. A water-containing explosive according to claims 28, 31, 32, 33, which differs in that as a solid organic substance it contains coal or charcoal, or soot, or rubber, or both of them in any combination. 38. A water-containing explosive according to claim 28, 31, 32, 33, which differs in that, as a liquid fuel, it contains a liquid petroleum product, for example, diesel fuel or a mixture of petroleum products. 39. A water-containing explosive according to claims 28, 33, which is characterized in that as a swelling component it contains an organic swelling component, such as wood flour or cereal flour, or bran, or clay, or both together in any combination. 40. Water-containing explosive according to claims 28, 33, which is characterized by the fact that as a porous component it contains expanded perlite or fly ash, or glass microcapsules, or foam plastic, or both of them in any combination. 41. Water-containing explosive according to claims 28, 33, which is characterized by the fact that as a phlegmatizing component it contains glycerin or talc, or aluminum hydroxochloride, or urea, or both of them in any 7/0 combination. 42. Water-containing explosive according to claims 28, 33, which is characterized by the fact that one or more surface-active substances and a thickening component are used as additives separately or together in any ratio. 43. A water-containing explosive according to claims 28, 33 and 42, which differs in that as surface-active /5 substances stearates of alkali metals, for example, sodium, and fatty acids, for example, oleic, are used. 44. A water-containing explosive according to claims 28, 31, 32, 33 and 42, which is characterized by the fact that guar gum or polyacrylamide and a crosslinking agent, for example, aluminum potassium alum or ferric salts, or without a crosslinking agent are used as a thickening component. 45. Water-containing explosive according to claim 28, 31, 32, 33, which is characterized by the fact that crystalline or granular, or crushed, or ground, dense or porous ammonium nitrate is used. " Ge) "I (av) I c) (Se) - a (e)) 1 (av) t» Fe bo b5