SK288386B6 - Method of disconnecting a monolith from rocky massif with different structure and dividing of the monolith into sections and blocks, particularly in seismically sensitive areas, as well as the dividing of concrete blocks and device for generating gas to use this method - Google Patents

Abstract

A method of detaching a monolith from rock massif, consisting in that, depending on length and volume of the monolith (1) to be detached from rock massif (2) or concrete block (1) to be split, shot holes (3) are drilled in such massif or block with identical diameter d = 25-75 mm, identical distance between holes c = 10-25 cm, identical distance e = 10-15 cm of the outermost holes (4) from the edges (5 and 6) of the main massif (2) and identical distance k = 10-20 cm from lower plane (7) of the monolith (1) to be detached.; Next, depending on the diameter (d) and number of holes (3), prepared is the same number of identical gas-generating devices (8) having casings, made preferably of polyethylene, adapted to diameter and height of the holes and equipped with initiating device (11) provided with pyrotechnic igniter (16) equipped with electric wires (17) that is surrounded with binary mixture (12) containing 88-105 parts by weight of sodium chlorate (NaClO 3 ) and 0.8-1.5 parts by weight of iron oxide, functioning as a catalyst of burning.; Further, 7.8-13.5 parts by weight of fuel oil (19) for diesel engines is injected into the mixture by means of any commonly known method and the so prepared and tightly closed gas-generating devices (8') are placed, depending on height (H) of the shot holes (3), in at least one row on bottoms of the holes in such a way that their electric wires (17) protrude above the surface of the monolith to be detached, and further the commonly known operations are performed related to sealing the holes by means of clay, sand, or their mixture and igniting said ternary mixture initiated by initiating devices (11) and generating heat and gas with pressure amounting to 95-105 MPa resulting in detachment of monolith (1) from rock massif (2) or avalanche massif or splitting a concrete block (1).

Description

The object of the invention is a method of separating a monolith from a rock massif of various consistency and dividing monoliths into sections and blocks, particularly in seismically sensitive areas, and also splitting concrete blocks, and a gas generating device for using this method. areas, in particular in dealing with the consequences of crevasses, landslides, mud avalanches, and dealing with the consequences of emergency situations, such as earthquakes, loosening of rocks in road excavations carried out in close proximity to buildings.

BACKGROUND OF THE INVENTION

The engineering work carried out so far to prepare the area under investment requires the leveling of the terrain, excavation or slope profiling, which is very often carried out on hard soils or rocks. The use of machines for mining such terrain is very demanding and often impossible due to both the hardness of the excavation and the location of the work, especially in the case of liquidation of rock embankments or slope profiling on steep gradients. Thus, in many cases, such work is carried out using blasting operations to scrape the overburden of soil or rock, or by blasting to obtain the predicted slope profile, the disposal of large-sized rock boulders, or the disposal of rock slides resulting from landslides or rock avalanches. Rock mining is also a major problem in order to obtain stone in the form of blocks, since in this case the detonation of an explosive causes, in every environment, in addition to the positive consequences resulting in rock fragmentation, many negative phenomena and consequences such as:

- the emergence of soil shocks induced by detonation

- the occurrence of an air shock wave

- the formation of micro-cracks, the destruction of the rock block during its processing and, as a result, the loss of raw materials

- risk of scattered rock fragments

- artificial rupture or micro-cracks

Thus, carrying out such work in areas with limited exposure to paraseismic wines, the source of which may be the detonation of typical charges and explosives is substantially limited, as evidenced, inter alia, by the fact that the efficiency of these charges is demonstrated at high speed.

There is known a method of plate stone mining by drilling openings in a rock, placing in it appropriately prepared explosive charges equipped with means that cause their ignition and their slow combustion at increasing pressure, causing gas excretion and cleavage of rock from its massif. Charges produced on the basis of mercury (mercury fulminate) and lead nitride are used as explosives, and in the case of the push mode of operation of the charge, pentrite, tritol and ammonium salt, the materials being poorly resistant to moisture and temperature, as a result of which their explosive properties deteriorate significantly.

Also known are rock-separating devices containing an explosive liquid produced on the basis of ammonium, nitroesters with various additives, gunpowder and detonating cord (Szukin Ju. G and others in Przemyslowe substancje wybuchowe based on utylizowanej amunicji [Industrial explosives] based on used ammunition OSA Publishing House Nedra Russia M. 1998 pp. 54-62).

On the other hand, Ukrainian patent specification no. UA13373 discloses a method of cleaving a rock or an artificial building by drilling holes for storing explosive in the rock or an artificial building, preparing charges equipped with ignition means, installing equipped charges in the explosive openings, connecting with the ignition means with the accessory trigger igniting the charges, actuating the ignition means with further deflagration of the charges, causing cleavage of the rock while moving along the lower surface during gas evolution as a result of the combustion of the chemical compound charge in the confined space of the explosive opening. In this method, the blasting openings to be fitted to the equipped charges shall have a length of at least 0,8 m and the charges shall be located at the bottom of each of these openings equidistant to each other or parallel in several rows on the same level. a three-component gas-generating chemical composition consisting of a crystalline oxidant, a liquid hydrocarbon chemical blend, and a slow-burn deflagration powder modifier, after which the ignition means are connected and connected by electrical circuits to a charge detonation-causing device. Subsequently, the blasting openings thus provided are sealed from above by a layer of sand and clay or other material allowing the openings to be closed tightly, after which the three-component charge is ignited and burnt at increasing pressure to detonate these openings and release large amounts of gases along the firing walls. and cleaving the rock or artificial building objects over the entire surface of the loose firing orifices. This allows efficient extraction of slab stone from rock or man-made blocks on building objects, avoiding the formation of micro-cracks or stone fragments, both in the split block and throughout the massif.

From Ukrainian patent specification no. UA 13372 also discloses a rock splitting or demolition device consisting of a polymer cylindrical body enclosed on both sides by plugs placed therein with a three-component chemical composition capable of generating gases at high temperature and pressure under the influence of external factors, as well as a composition having direct contact with the mixture, and initiating the ignition of the mixture, which is connected to a direct current source via electrical conductors, wherein the chemical mixture is a crystalline oxidant, a liquid hydrocarbon mixture and a powder modifier of the combustion process in a ratio of (69.99-89.99) : (30-10): (001).

SUMMARY OF THE INVENTION

It is an object of the present invention to provide a method of separating a monolith from a rock massif of varying consistency and in the difficult geological conditions of the massif, as well as splitting the monolith into sections and blocks which will allow separation and splitting. with these charges of the deflagration process running at high linear velocity. Another object of the invention is to provide a simple and compact construction of a device for using said method, equipped with a technical means allowing rapid ignition of the surrounding chemical mixture generating a gas under a pressure of about 100 MPa which will ensure overall safety during its storage and transport. On the other hand, the technical issue requiring a solution is to develop such a compatible set of three-component chemical mixture that will not tend to deflagrate and transmit the mixture to detonation (explosion) as well as having a high sensitivity to the ignition initiation of the mixture, without the possibility of passing this combustion into a deflagration process.

In accordance with the invention, the method of separating a monolith from a rock mass of varying consistency and dividing the monoliths into sections and blocks, particularly in seismically sensitive areas, as well as splitting concrete blocks, is based on the length and volume of the monolith being separated from the rock mass; the concrete block drills bore holes with the same diameter representing 25 - 75 mm, the same distance between them representing 10 - 25 cm, the same distance of the outer holes from the edge of the main mass of 10 - 15 cm and the same distance from the lower plane of the separated monolith 10-20 cm, after which the same number of identical gas generating devices having bodies, preferably polyethylene, adapted to the diameter and height of the holes, is selected depending on the diameter of the boreholes and their number. These devices are equipped with an initiating apparatus equipped with a pyrotechnic lighter equipped with electric conductors, the lighter being surrounded by a two-component mixture containing 88-105 parts by weight of sodium chlorate (NaC10 ₃ ) and 0.8 1.5 parts by weight of iron oxide, acting as a combustion catalyst. 7.8 - 13.5 parts by weight of diesel engine diesel fuel are injected into this mixture in a known manner. The gas generating devices thus prepared and sealed are positioned at least in one row on their bottom, depending on the height of the openings for the explosive, so that their electrical conductors are pushed over the surface of the separated monolith, followed by other known sealing and sealing operations. or a mixture thereof, as well as igniting the three-component mixture initiated by heat and gas release initiators under a pressure of 95-105 MPa, causing the monolith to be separated from the rock mass or la wine mass, or to crack the concrete block. Preferably, the density of the three-component mixture is 2.0-2.5 g / cm ³ , and depending on the volume of sodium chlorate contained in the three-component mixture, the gas generating device to be placed in the borehole. - 90 minutes. It is also preferred that, for the separation of the monolith from the rock mass for each m ^{3 of} timber, depending on its type, the gas generating device comprises from 60-120 g / m ^{3 of a} three-component chemical mixture, preferably 100 g / m ^{3 of} timber. Furthermore, according to the invention, depending on the type and volume of the massif to be separated, the holes are drilled at a height of 0.7-5 m and the gas generating devices are located at one level, two or three levels, preferably at the same distances with respect to each other.

Furthermore, the essence of a gas generating device for separating a monolith from a rock mass of varying consistency and dividing monoliths into sections and blocks, used mainly in seismically sensitive areas, and also for splitting concrete blocks, is that it is coaxially placed in its polymer body during storage and transport. Initiating apparatus equipped with a pyrotechnic igniter surrounded by its two-component chemical mixture preferably containing 88-105 parts by weight of sodium chlorate (NaCIO ₃ ) and 0.8-1.5 parts by weight of iron oxide (Fe ₂ O ₃ ); a vessel comprising a diesel engine diesel fuel is loosely attached to the device and constitutes the third component of the chemical composition in an amount of 7.8-13.5 parts by weight of the total weight of the three-component chemical composition.

Further, in the condition intended to commence the operation of this apparatus, its initiating apparatus is surrounded by a three-component chemical composition comprising sodium chlorate, iron oxide and diesel fuel of an internal combustion engine having a weight to total weight ratio of 88-105: 0.8-1.5 7,8 - 13,5, the initiating device being an elastic tape provided with longitudinally placed cotton threads soaked in flammable means and connected at one end to a pyrotechnic lighter equipped with protruding outwardly electrical conductors, the tape being wound in an inseparable sleeve . It is also preferred that the complementary component of the two-component mixture consisting of sodium chlorate (NaCl 2) and iron oxide (Fe ₂ O ₃ ) is petroleum.

Tested dithermographic tests have shown that the injection of sodium chlorate and iron oxide, diesel or petroleum into the mixture does not affect the decomposition temperature of sodium chlorate in the temperature range up to 220 ° C, confirming the compatibility of these components. The placement of this mixture in the thermoplastic plastic housing does not cause this explosion from the pyrotechnic lighter, which means that it is not effective in detonation mode and the mixture of these components does not tend to turn into an explosion.

Further advantages of the method and apparatus according to the invention are that their use in variable geological conditions, in particular in seismically sensitive areas, landslides and dense installations, makes it possible to completely eliminate errors occurring in the technologies used so far, such as:

- the occurrence of an air shock wave

- risk of rock fragments

- creation of wines initiated by detonation

- formation of artificial rupture and micro-cracks

The use of the method and apparatus according to the invention causes that a rising gas pressure of about 100 MPa of the resulting combination of a targeted three-component chemical mixture causes cracking and tearing of the rock material along a straight line connecting the bored blast holes. fragments. Indeed, the pressure obtained from the gas generating devices according to the invention reaches substantially lower values than with the technologies used hitherto, which makes it possible, on the other hand, to reduce the rupture zone, the scattering of debris and to substantially reduce and eliminate the effects of paraseism wines causing shaking. On the other hand, the use in a gas-generating device of an initiating device wound from a tape equipped with cotton threads spaced all along its length and soaked with easily combustible material allows to rapidly ignite the surrounding tricomponent chemical mixture along its entire length, thereby substantially reducing its initiation time. In addition, the simple construction of this apparatus has greatly simplified its design and has made it possible to reduce the cost of manufacturing it.

The use in a gas-generating device containing as one of the three constituents a chemical mixture of iron oxide in the function of the combustion catalyst of the mixture and of cotton threads in the initiator of the device causes a substantial increase in the burning rate of the mixture and resulting from the combustion of this mixture. Furthermore, the introduction into the chemical mixture of motor oil or petroleum as its third component only prior to placing the gas generating devices in the bored blast holes eliminates the risk of ignition of these devices both during their storage and transport.

Tests and research have shown that the use of the method and apparatus according to the invention makes it possible to eliminate the risks of crevasses, the effects of landslides, eliminate the consequences of mud avalanches and adverse erosion of rivers and streams, eliminate earthquakes, eliminate or reconstruct reinforced concrete or concrete objects. building structures and prepare investment plans in seismically sensitive areas.

DETAILED DESCRIPTION OF THE INVENTION

The subject matter of the invention is explained in more detail by way of examples, and in the drawings in which the diagram shows a rock mass diagram with bored blasting holes in a perspective view, a diagram of rock mass diagram with bored blasting holes and gas generating devices disposed thereon 3 is a perspective view of a rock massif with blasting holes and gas generating devices located therein, on two levels in perspective; FIG. 4 shows a diagram of a rock massif with borehole bores and gas generating devices therein, on three levels in perspective view; gas-generating device in the form of a cylindrical casing tightly closed on both sides with longitudinal section plugs intended for storage and transport, Figure 6 gas-generating device in the form of a cylinder with a bottom, closed t FIG. 7 is an apparatus for initiating the ignition of a three-component chemical mixture which constitutes the equipment of the two gas generating devices in a state unfolded with its inner surface visible; and FIG. 8 a container which is additionally suitable for use in longitudinal section. the gas generating apparatus shown in Figures 5 and 6 comprising motor fuel for compression ignition engines, which form the third component of the chemical mixture present in the apparatus.

Example 1

Holes 3 at a height H = 700 mm, diameter d = 30 mm, at a distance of c = 10 cm therebetween, and at the distances of the outer holes 4 from the edge 5, were drilled in the separated massif 1 from the main massif 2 using known drilling equipment. and 6 of the main mass of e = 10 cm and at a distance k = 10 cm from the lower plane 7 of the massif J. separated after the opening 10 of the gas generating device 8, the body of which is made of polyethylene with s = 25 mm. Surrounded by a two-component chemical mixture 12 containing 89% by weight sodium chlorate (NaCIO ₃ ) and 1.0% by weight of iron oxide, which acts as a combustion catalyst, 10% by weight of diesel fuel was injected into the internal combustion engines so that ³ cleaved rock the weight of this mixture was 100 g. After evenly distributing the fuel within the two-component mixture and forming a three-component mixture at a ratio of 89: 1: 10, which took about 30 minutes, the gas generating device 8 was sealed with plugs 10. The gas generating devices 81 thus prepared were positioned at one level 21 on the holes of the drilled holes 3 so that the electrical conductors 17 of the initiating devices 11 protrude out of these holes, and subsequently these holes are filled - sealed - with moist clay 24. Subsequently, these conductors are connected in a known manner to a power source, the pyrotechnic lighters 16 of the gas generating devices 8, which, with the aid of their initiating devices 11, triggered the ignition of the three-component chemical mixture 12 '. contained in these plants, and the release, heat and flash combustion of this three-component mixture, which in the combustion process was converted to a gas at a pressure of 95 MPa, which, under such high pressure, converted sand with clay 24 in the openings 3. to a very hard substance which caused a blockage to exit this gas out of these openings. As a result of this blockage, the gas began to act along the length and width of the massif X to be separated along the line joining the drilled holes 3, causing the massif to break away from the massif 2 and excess pressure pushed it to a distance of about 20 cm. due to the parallel distribution in this separated mass of gas-generating devices, after its separation, its surfaces had an appearance similar to that of a diamond saw cut. As a result of these effects, it has been found that the spreading of rock fragments is considerably less than similar phenomena caused by the detonation of known charges. In addition, it has been found that the pressure and impulse caused by this detonation are substantially greater and depend on the rate of detonation, and that the pressure at the front of the detonation wave of explosives can be described by the equation:

p = qx D ^2/8, where q - is the density of the explosive, which is used in the case of a ternary mixture the value of 2.35 g / cm ³ D - a detonation velocity in m / s

It follows from this equation that the pressure obtained from the gas generating devices reaches lower values compared to known methods, which has the effect of reducing the cracking zone, minimizing the spreading of the fragments and significantly weakening the effects of para-seismic wines causing shaking of the building objects.

Example 2

In the separated massif 1 from the main massif 2, holes 3 at a height H = 2.20 m, with a diameter d = 35mm, at a distance of c = 18 cm between them, and at edge distances 4 from the edges, were drilled using known drilling equipment. 5 and 6 of a rock mass of e = 12 cm and at a distance k = 15 cm from the lower plane 7 of the separated massif T Following the opening of the plugs 10 in gas generating devices 8 having corpora made of polymeric plastic s = 30 mm Initiating apparatus 11 surrounded by a two-component chemical mixture 12 containing 88% by weight of sodium chlorate (NaCIO ₃ ) and 0.8% by weight of iron oxide acting as a combustion catalyst, 11.2% by weight of diesel contained in a separate container were injected into the mixture. 18 so that for each m ^{3 of} separated rock mass the mass of this mixture is 100 g. After uniformly distributing the fuel within the two-component mixture 12 and obtaining the three-component mixture 12 'at a ratio of 88: 0.8: 12, which lasted about 45 minutes, the gas generating devices 8J were tightly closed with a plug JO, one bottom level 21, that is to say at all bottom of the openings 3. Subsequently, these openings were backfilled and the damp sealing clay 24 at a height H1, which represents about half of their total height H, was smashed and identical in each other opening 3. the gas generating devices 8 so as to be at the same level 22, wherein all the electrical conductors 17 of the initiating devices 11 have been led to the outer surface of the massif 1 to be separated and the upper ends of these openings at H2 are covered and smashed with the same moist clay. the electric conductors 17 have been connected in a known manner to a source of electric current du, the result of which was started a pyrotechnic gas generating devices 16 81, causing further separation analogously, as shown in Example 1, in which case the combustion process ternary mixture 12 'turned-gas had a pressure of 105 psi value.

Example 3

Holes 3 at a height of H = 4.50 m, with a diameter d = 40 mm, at intervals of c = 25 cm at intervals between them, and at spacing of the outer holes 4 from edges 5 and 6 of the concrete mass with a value of e = 15 cm and at a distance k = 20 cm from the lower plane 7 of the massive. Following the opening of the plugs 10 in gas generating devices 8 having a body made of thermoplastic material with a diameter s = 35mm, equipped with an initiator 11 surrounded by a two-component chemical composition 12 containing 105 parts by weight of sodium chlorate (NaCIO ₃ ) and 1.5 parts by weight of oxide 13.5 parts by weight of diesel contained in a separate container 18 were injected into this mixture. After uniformly distributing the fuel within the two-component mixture 12 and after obtaining the three-component mixture 12 'in a ratio of 105: 1.5. : 13.5, which lasted about 60 minutes, the gas generating devices K were tightly closed with a plug W, then the devices thus prepared were placed at one lower level 21, i.e. on all the openings 3 holes. Subsequently, these openings were tightly covered and beaten with moist earthenware. a mass 24 at a height H1 which represents about 1/3 of their total height H, n Subsequently, other gas generating devices 8 were prepared in analogy, but equipped with a two-component chemical composition 12 containing 90 parts by weight of sodium chlorate (NaCl ₃ ), 1.0 part by weight of iron oxide and 9 parts by weight of diesel fuel were injected into this mixture. After evenly distributing the fuel within the two-component mixture 12 and obtaining the three-component chemical mixture 12 'in a ratio of 90: 1: 9, which took about 40 minutes, the gas generators 81 thus prepared were tightly sealed with a plug W, then placed on the second level 22 formed from the crushed sand-clay mass 24 and were buried and slaughtered at the height H2 of the apertures 3 with the same wet sand-clay mass 24 which constitutes one level 23. on which other analogous gas generating devices K as at level 22 were placed; also these openings were completely covered with the same wet sealant 24 over the entire remaining height 113 of the openings 3, which also represents about 1/3 of their total height H, all electrical conductors 17 of the initiating devices 11 being led to the outer surface of the separated block L the electrical conductors 17 have been connected in a known manner to a power source and as a result have been fired pyrotechnic lighters 16 of gas generating devices 81 causing further separation analogously to Example 1, in which case in the process of burning the three-component mixture 12 'converted into gas, its pressure was 100 MPa.

Example 4

Gas generating device 8 intended only for storage and transport

The gas generating device consists of a housing body of 25 mm diameter made of polyethylene, tightly closed on both sides with plugs 10), also made of polyethylene, in which the initiating device 11 is concentrically placed and surrounded by a two-component chemical mixture 12 composed of 89 g of sodium chlorate (NaC10 ₃ ) and 1.0 g of iron oxide (Fe ₂ O ₃ ), which acts as a combustion catalyst, the initiating device being formed by a roll of elastic tape 13 having a longitudinally disposed cotton yarn 15 soaked on its surface 14 connected to a pyrotechnic lighter 16 equipped with electrical conductors 17 which serve to connect the device to a power source not shown in the drawing, wherein the ends of the elastic tape wound into the roller 13 are permanently bonded with each other. In addition to this component of the device, the container 18 is loosely attached thereto and containing diesel fuel 19 to diesel engines or petroleum.

Example 5

A gas generating device 81 for positioning in a blasting hole

It consists of a device 8, the composition of which is described in Example 4, and a three-component chemical mixture

12 'composed of 89 g of sodium chlorate (NaC10 _3), 1.0 g of iron and injected into the container 18 from which diesel fuel to diesel engines in an amount of 19 10 g.

Example 6

The gas generating device 8 consists of a monolithic cylindrical body 20 with a bottom 20 'tightly closed on one side by a stopper K), made of polyethylene, and in it a concentrically placed initiator 11 and surrounded by a two-component chemical mixture 12 composed of 88 g sodium chlorate ( NaCIO ₃ ) and 0.8g of iron oxide (Fe ₂ O ₃ ), the initiating device 11 having the same construction as described in Example 4, and an integral part of this device is a container 18 containing diesel fuel 19 which just prior to the location of the device in the borehole 3, 1.2 g is injected into it in order to supplement the two-component mixture contained therein, thus forming a three-component mixture in a ratio of 88: 0.8: 11.2.

Example 7

Gas generating devices 81 have also been made for their placement in bore blast holes 3 with an analogous composition to that described in Example 4, but with a different chemical composition of the three-component mixture, containing 91 g of technical sodium chlorate, 1.2 g of iron oxide and 7.8 g of diesel in an aggregate ratio of 91: 1.2: 7.8.

PATENT CLAIMS

Claims (9)

1. A method of separating a monolith from a rock mass of varying consistency and dividing monoliths into sections and blocks, particularly in seismically sensitive areas, and also splitting concrete blocks, by drilling blasting holes in the massive or concrete block distributed in one row and at the same depth or depth. in several rows at a single level, preparing charges equipped with means to ignite them, installing these charges in these openings and sealing the openings with clay, sand or a mixture thereof, joining the means causing ignition of these charges and burning them, resulting in cleavage of the monolith from rock mass, characterized in that, depending on the length and volume of the separated monolith (1) from rock mass (2) or concrete block (1), bore holes (3) with the same diameter d = 25 - 75 mm are drilled , with the same distance m between them c = 10 - 25 cm, with the same distance e = 10 - 15 cm of the outer holes (4) from the edges (5 and 6) of the main massif (2) and with the same distance k = 10 - 20 cm from the lower plane (7) the same number of identical gas generating devices (8), which preferably have polyethylene bodies adapted to the diameter and height of the holes and are formed by the initiating device (1), are selected depending on the diameter (d) of the holes (3) and their amount. 11) equipped with a pyrotechnic lighter (16) equipped with electric conductors (17) surrounded by a two-component mixture (12) containing 88-105 parts by weight of sodium chlorate (NaCIO ₃ ) and 0.8-1.5 parts by weight of iron oxide which fills 7.8 - 13.5 parts by weight of diesel fuel for compression-ignition engines (19) are injected into the mixture in a known manner and gas-generating devices thus prepared and sealed. (8 ') are positioned, depending on the height (H) of the blast holes (3) in at least one row on their bottom, so that their electrical conductors (17) protrude above the surface of the separated monolith, and further known sealing operations are carried out holes with clay, sand or a mixture thereof and the ignition of this three-component mixture by initiating initiators (11) releasing heat and gas under a pressure of 95 - 105 MPa causing separation of the monolith (1) from rock mass or la wine (2) or splitting of concrete block (1) . Method according to claim 1, characterized in that the density of the three-component mixture (12 ') is 2.0 - 2.5 g / cm ³ . Method according to claim 1, characterized in that, depending on the weight of sodium chlorate present in the three-component mixture, the soaking time of the two-component mixture of the gas generating device (8) is from 30 to 90 minutes with diesel fuel. Method according to claim 1, characterized in that for separating the monolith (1) from the rock mass (2) for each m ^{3 of} woodwork, depending on its type, the gas generating device comprises from 60-120 g / m ^{3 of a} three-component chemical mixture, preferably 100 g / m ^{3 of} scrap. Method according to claim 1, characterized in that, depending on the type and volume of the massif to be separated (1), holes with a height H = 0.7 - 5 m are drilled and the gas generating devices (8 ') are located on one, two or three levels (21, 22 and 23). 6. Gas-generating device for separating monoliths from rock massif of varying consistency and dividing monoliths into sections and blocks mainly used in seismically sensitive areas and for splitting concrete blocks consisting of a polymer cylindrical body encased on both sides by a plug of three-component chemically mixed generating high temperature and pressure gases as a result of combustion thereof, having direct contact with the ignition initiating means, characterized in that during its storage and transport in its polymer body (9), an initiator (11) equipped with a pyrotechnic lighter is coaxially positioned and surrounded over its entire length with a two-component chemical mixture containing preferably 88-105 parts by weight of sodium chlorate (NaC10 ₃ ) and 0.8-1.5 parts by weight of iron oxide (Fe ₂ O ₃ ) and a vessel (18) is loosely attached to this device contained comprising a diesel fuel (19) for compression ignition engines which is the third component of the chemical composition in an amount of 7.8-13.5 parts by weight of the total weight of the three-component chemical composition (12 '). Apparatus according to claim 1, characterized in that the initiating apparatus (11) contained therein is surrounded by a three-component chemical composition (12 ') containing sodium chlorate, iron oxide and motor oil, in a state intended to start operation of the apparatus. diesel (19) for internal combustion engines by weight in relation to their total weight (88-105): (0, 8-1.5): (7.8-13.5); Apparatus according to claim 1, characterized in that its initiating device (11) comprises an elastic strip (13) provided with longitudinally disposed cotton threads (15) soaked in flammable means and connected at one end to a pyrotechnic lighter (16), provided with outwardly projecting electrical conductors (17), the tape being wound to form an integral roll. Apparatus according to claim 1, characterized in that the additional component of the binary component consisting of sodium chlorate (NaClO ₃ ) and iron oxide (Fe ₂ O ₃ ) is petroleum. 2 drawings