RU2119398C1 - Method for explosion cutting of hard materials and apparatus for performing the same - Google Patents

Abstract

FIELD: processes and equipment for cutting metals and other hard materials. SUBSTANCE: method comprises steps of placing elongated charge of explosive matter on one surface of cut material and initiating said charge in the form of monolythic chute with two walls symmetrical relative to symmetry plane passing through lengthwise axis of charge and mutually joined by bridge; filling chute cavity by non-gaseous inert filler; placing charge on surface of cut material by ends of its walls spaced from bridge; coinciding symmetry plane of chute-like charge with cut line and shaping ends of both walls according to surface of cut material; initiating charge at side of bridge by means of detonator arranged in symmetry plane of charge; using material with low acoustic rigidity as filler of chute cavity. EFFECT: intensification of tension stresses in cut plane of hard material. 15 cl, 7 dwg, 4 expo

Description

 The invention relates to the processing of metals by pressure and can be used for cutting metals, as well as for the fragmentation of concrete, rocks, plastics and other solid materials.

 There is a method of explosive cutting of materials with an elongated cumulative charge with a cumulative recess equipped with a metal lining (see Schekhter B. I., Shushko L.A. et al. "Study of the process of crimping the lining of an elongated cumulative charge and the formation of elements of a cumulative knife." In the journal " Physics of Combustion and Explosion (N 2, 1977, p. 244). In the known method, an elongated charge (UKZ) is used, shown in Figure 1. UKZ consists of an explosive discharge made in the form of a corner with a constant thickness of shelves inside equipped with a metal lining. The explosive charge is equipped with a detonator. UKZ is installed on the surface of the material being cut with a gap to the specified surface, the cumulative recess in this case is turned to the material being cut and the plane of charge symmetry is combined with the line of the cut being performed, after which an explosive charge is initiated by the detonator. The detonation wave front of the explosive charge forms a cumulative knife from the metal lining. When cutting materials with an elongated cumulative charge, the explosion energy is transformed into the kinetic energy of the cumulative knife, which is spent on high-speed removal of material from the cut cavity, as a result of which the cumulative charge must be changed in proportion to the volume of the cut cavity. Since the cut cavity in the cross section has the shape of an isosceles triangle with a height equal to the cut depth, the volume of the cavity is proportional to the square of the cut depth.

 The disadvantage of this method is the high energy intensity of destruction, which increases in proportion to the square of the thickness of the material being cut.

 The closest technical solution, selected as a prototype of the proposed method, is a method of cutting metals using explosive energy, according to the patent of the Russian Federation N 2013169, which includes the installation of an elongated explosive charge on the surface of the metal being cut and the subsequent initiation of a charge explosion, while previously on one of surfaces of the metal being cut perform a continuous linear incision located along the line of the cut. One of the ends of the cut is made in-depth. An elongated charge is installed on the surface of the metal being cut, opposite to the surface on which the notch is made. The initiation of a charge explosion is carried out from the end corresponding to the section of the incision with a greater depth.

 In the known method according to the patent of the Russian Federation N 2013169 apply an extended explosive charge, adopted as the closest analogue of the claimed device. The known explosive charge is made in the form of a full parallelepiped (see Fig. 2) and is equipped with a detonator. An elongated charge is placed on the metal being cut so that the longitudinal plane of charge symmetry coincides with the notch line. In the explosion of an elongated charge made in the form of a hollow parallelepiped, in the known method, one shock wave with a continuous front is excited in the metal being cut, which in the process of moving takes the form of a conical surface radially diverging from the longitudinal axis of the charge. The shock wave, reaching an incision made on the surface opposite the charge of the metal being cut, destroys the metal along the notch line.

 The method according to the patent of the Russian Federation N 2013169 reduces the energy consumption of cutting the material due to the fact that it carries out a fracture of the material without the expense of energy for the removal of material from the cutting zone. However, the method and the elongated charge used, adopted as the closest analogues, have the following disadvantage, namely: as a result of undermining the elongated charge, made in the form of a parallelepiped, weak tensile stresses arise in the cut plane due to the large dispersion of the explosion energy in a significant amount cut solid material outside the performed cut, which increases the energy intensity of destruction and reduces the explosion efficiency.

 The claimed invention has the task to strengthen the tensile stresses arising in the cut plane of the cut solid material by exciting two shock waves in the cut material that converge in the plane of the cut and interact with each other in resonance mode, which would provide a multiple increase in tensile stresses in the plane cut. The solution of this problem allows us to reduce the energy intensity of cutting solid material and thereby increase the efficiency of the explosion.

 To solve this problem, an explosive charge (BB) is used in the form of a monolithic trough with two walls connected by a jumper symmetrically located relative to the plane passing through the longitudinal axis of the charge, the trough cavity is filled with a non-gaseous inert filler, the charge is installed on the surface of the material being cut by the ends of the walls removed from the jumper, which give the shape of the aforementioned surface, while the plane of symmetry of the trough is combined with the line of the intended cut, and the initiation the charge is produced from the jumper side by means of a detonator, which is located in the said plane of symmetry.

 After the explosion is initiated, two detonation waves propagate along the walls of the trough charge, synchronized by a jumper and directly affecting the surface of the material being cut. In this case, a non-gaseous inert filler located in the charge cavity damps the action of detonation waves on the surface area of the material being cut, located between the charge walls, excluding the formation of shock waves on the indicated surface area. As a result of the direct action of two detonation fronts synchronously moving on the surface of the material being cut, two unidirectional mutually separated shock waves are excited in the material being cut, which, developing symmetrically with respect to the plane of symmetry of the charge, collide in the plane of the cut, causing resonantly increased compression in the region of the specified plane . The region of resonantly increased compression moves along the plane of the cut into the depth of the material being cut. As the region of high compression moves deeper into the material being cut beyond the region of high compression in the plane of the cut, unloading of the compressed material occurs and a biaxial tension region appears in which the maximum tensile stresses act normal to the plane of the cut, which leads to intense destruction of the material in the vicinity of the cut plane .

 Thus, a technical result is achieved, namely, tensile stresses in the plane of the cut are amplified, which ensures a reduction in the energy intensity of cutting solid material and an increase in the explosion efficiency.

 When installing a trough charge on the surface of the cut material, the ends of the longitudinal edges of both walls of the trough charge can be combined directly with the surface of the cut material.

 The solution of this problem can also be performed if a flat metal impact tape with a thickness equal to 0.03-0.1 of the thickness of the material being cut and with a width equal to the width of the charge and between the impact tape and the surface is placed between the grooved charge and the surface of the material being cut. cut material create a gap equal to 1-10 of the thickness of the shock tape, while high-density material is used as a filler in the cavity of the trough charge.

 As a result of the detonation of the charge, detonation waves directly affect the sections of the shock tape that are in contact with the ends of the longitudinal walls of the charge, as a result of which the indicated peripheral sections of the tape have a higher speed than its central part, located opposite the jumper and the filler placed in the cavity of the trench charge.

 In the process of movement of a flat shock tape in the direction of the material being cut, the velocity gradient leads to deformation of its central part, which takes the form of a vault, the concave surface of which faces the material being cut. This provides an advancing collision of the peripheral sections of the tape with the surface of the material being cut and the formation of two shock waves in it with mirror-symmetric in cross section fronts interacting with each other in the plane of the cut. The high-density material with which the cavity between the walls of the charge is filled prevents the action of detonation waves and detonation products on the central part of the shock tape, reducing its speed, and increases the duration of the high pressure on the peripheral parts of the shock tape, which is given additional speed. As a result, the collision energy of the peripheral sections of the tape with the surface of the material being cut increases and the pressure in the shock waves formed in it increases.

 Thus, a technical result is achieved, namely, a multiple increase in tensile stresses in the plane of the cut being performed due to the formation of two symmetrically converging shock waves in the material being cut. The achievement of the technical result reduces the energy intensity of destruction and increases the efficiency of the explosion.

 The use of a flat metal strip accelerated by an explosion as a generator of shock waves makes it possible to obtain a pressure in the material being cut that is significantly higher than the pressure of detonation waves of high-explosive explosives, which is an additional technical result that ensures a reduction in the energy consumption of cutting solid material.

 In the case of using cheap low-explosive explosives for manufacturing a gutter charge, a solution to this problem is achieved if a continuous layer of a high-explosive explosive with a detonation velocity greater than the detonation velocity of the gutter charge is applied to the surface of the gutter charge facing the opposite side from the ends of the longitudinal edges of both charge walls and at least 1.1 times the speed of sound propagation in the material being cut. In this case, the trough charge is initiated by means of a high-explosive explosive layer. During the explosion, the detonation front in the high-explosive HE layer moves along the cut line with a velocity greater than the detonation velocity of the gutter-shaped explosive and initiates oblique detonation waves in the walls of the latter, the lines of interaction of which with the surface of the material being cut move along the cutting line with the detonation velocity of the high-explosive explosive. If the charge is placed directly on the surface of the material being cut, and the detonation velocity of the high-explosive explosive is at least 1.1 times the speed of sound propagation in the material being cut, the energy of the explosion is dissipated by compression waves that cannot catch the contact lines of the detonation waves with the material being cut.

 Thus, an additional technical result is achieved, namely, reducing the energy dissipation of the explosion by compression waves, which increases the efficiency of the explosion and reduces the cost of cutting.

 The supersonic motion of the line of interaction of the detonation wave of the gutter-shaped charge with the material being cut is achieved if a longitudinal tube-shaped cylindrical channel is fulfilled along the length of the gutter-shaped jumper, the plane of symmetry of which in cross section coincides with the symmetry plane of the gutter-shaped charge. At the same time, a detonator is installed in one of the ends of the tubular cylindrical channel. During the trough charge in the hollow tube-shaped cylindrical channel, a strong air shock wave is generated, moving along the channel, which is ahead of the charge detonation front and initiates the explosive detonation process on the walls of this channel, which leads to the formation of oblique detonation waves in the trough charge walls. If the speed of an air shock wave in a cylindrical tube-like channel exceeds the speed of sound in the material being cut, then supersonic motion of the lines of interaction of the oblique detonation fronts of both walls of the trench charge with the material being cut is achieved. Thus, a reduction in the energy intensity of fracture is achieved when cutting materials with cheap low-blast explosives and as a result, the cost of cutting is reduced.

Before installing the elongated monolithic groove charge on the surface of the material being cut, on the indicated surface, an incision is made along the line of the cut in the form of a triangle with an acute angle at the apex of 15-60 ^o , and the depth of the cut is at least 0.05-0, 1 thickness of the cut material. When the gutter-shaped charge is detonated, the interaction of two converging shock waves in the material being cut under the notch apex occurs in the resonance mode, and the notch acts as a tensile stress concentrator and intensifies the cracking process in the plane of the cut.

 Thus, a technical result is achieved, namely, an additional increase in tensile stresses in the plane of the cut. As an inert non-gaseous filler of the cavity of the trough charge, a high-density material, for example, iron powder, is used. As an inert filler of the gutter cavity, a material with low acoustic rigidity can be used, and specifically, compressed wood pulp can be used.

 The device for explosive cutting of solid materials contains an elongated explosive charge, which is equipped with a means of initiation. To solve this problem, the elongated explosive charge is made in the form of a monolithic trench with two walls connected by a jumper symmetrically located relative to the plane passing through the longitudinal axis of the charge, while the ends of the walls remote from the jumper are located in the same plane.

 For explosive cutting of solid material, a trough charge is placed on the surface of the material being cut so that the ends of the longitudinal edges of both walls of the trough charge are facing it, and the plane of symmetry of the charge is combined with the line of the cut. The initiation of the trough charge is carried out by a detonator, which is located on the jumper in the plane of symmetry of the trough charge.

 After the explosion is initiated, two detonation waves propagate along the walls of the trough charge, synchronized by a jumper and directly affecting the surface of the material being cut. In this case, a non-gaseous inert filler located in the charge cavity damps the action of detonation waves on the surface area of the material being cut, located between the walls of the charge, excluding the direct effect of detonation waves on the specified surface area of the material being cut. As a result of the direct action of two detonation waves synchronously moving along the walls of the charge on the surface of the material being cut, two unidirectional mutually separated shock waves are excited in the material being cut, which, developing fronts that are mirror-symmetric in the cross section, collide in the plane of the cut, causing a resonantly increased compression in areas of the specified plane. The region of resonantly increased compression moves along the plane of the cut into the depth of the material being cut. As the region of high compression moves deeper into the material to be cut beyond the region of high compression in the plane of the cut, unloading of the compressed material occurs and a region of dibasic tension occurs in which the maximum tensile stresses act normal to the plane of the cut, which leads to intense destruction of the material in the vicinity of the cut plane .

 Thus, a technical result is achieved, namely, tensile stresses in the plane of the cut are amplified, which ensures a reduction in the energy intensity of cutting solid material and an increase in the explosion efficiency.

 A longitudinal groove is made in the jumper, symmetrical to the symmetry plane of the grooved charge along its entire length, in which a detonating tape made of a high-explosive explosive having a detonation speed greater than the detonation velocity of the grooved explosive and equipped with at least one slot for installing the detonator is pressed in.

 The longitudinal groove in which the detonating tape is pressed in can be made in the jumper from the side opposite to the cavity of the trough charge, which in turn is filled with a non-gaseous inert filler.

 The elongated monolithic trough charge can be made of aquanite, and the detonating tape is made of hexogen.

 An elongated monolithic trough charge can be made of TNT, and the detonating tape is made of RDX.

 The gutter-shaped charge can be made from a mixture of TNT with RDX, and in this case the detonating tape can be made from Teng.

 The gutter-shaped charge can be made of RDX, and the detonating tape is made of Teng.

 In these combinations, the principle of exceeding the detonation velocity of the explosive detonating tape over the detonation velocity of the explosive, from which the gutter-shaped charge is made, is observed.

 When an elongated monolithic grooved charge equipped with a detonating tape is detonated, the detonation front in the tape, which has an increased detonation velocity, moves along the cut line with a speed greater than the detonation velocity of the explosive grooved charge and initiates oblique detonation waves in the walls of the grooved charge, the lines of interaction of which with the surface The material being cut moves along the cutting line with the detonation speed of the high-explosive detonating belt. As a result, an additional technical result is achieved, namely, energy dissipation in the material being cut is reduced.

 In FIG. 1 shows a cross section of a trough charge located on the surface of the material being cut.

 In FIG. 2 shows a trough charge mounted on the surface of the material being cut together with the shock tape in cross section.

 In FIG. Figure 3 shows the trough charge of a low-explosive explosive with an initiating layer of a high-explosive explosive mounted on the material being cut, in cross section.

 In FIG. 4 shows a gutter-shaped charge provided with a longitudinal tube-shaped cylindrical channel in the jumper and mounted on the material being cut, in cross section.

 In FIG. 5 shows a cutting method in which a longitudinal incision is made in cross section before installing the trough charge on the surface of the material to be cut on said surface.

 In FIG. 6 shows a trough charge.

 In FIG. 7 shows a trough charge provided with a detonating tape.

 The method of explosive cutting of solid materials contains (see Fig. 1) the use of an elongated explosive charge, for example hexoplast, in the form of a monolithic groove with two walls 1 and 2 symmetrical in cross section and a jumper 3 between them, while the ends 4 and 5 of both walls 1 and 2 are directed in one direction, and the cavity of the trough charge located between the walls 1 and 2 and the jumper 3 is filled with a gaseous inert filler 6, for example, iron powder. An elongated grooved charge is mounted on the surface 7 of the material being cut 8 so that the ends 4 and 5 face the surface 7 of the material being cut 8. In this case, the plane of symmetry of the grooved charge is combined with the line of the cut being made, and the ends 7 and 5 are shaped to the surface 7 of the material being cut 8 The ends 4 and 5 of both walls 1 and 2 of the trough charge can be combined directly with the surface 7 of the material being cut 8 (Fig. 1). In the jumper 3 from the side of its outer surface 9 in the plane of symmetry of the charge, a detonator 10 is installed and the grooved charge is undermined. As a result of undermining the trough charge in the cut solid material 8, two shock waves arise, the fronts of which converge in the plane of the cut. This ensures a resonant increase in tensile stress in the plane of the cut, due to which there is a cutting of the solid material 8.

 To increase the pressure in the material being cut 8 when exposed to shock waves resulting from an explosion of an elongated charge, a metal shock tape 11 (Fig. 2) with a thickness F of 0.03-0 is placed between the grooved charge and the surface 7 of the material being cut 8 , 1 thickness G of the material being cut 8, and with a width equal to the width of the trough charge. In this case, between the shock tape 11 and the surface 7 of the material being cut 8, a gap H is created equal to (1 - 10) F - the thickness of the shock tape 11. The gap H is provided with supports 12 and 13 made, for example, of dry wood or foam. In this case, high-density material, for example, iron powder, is used as a filler 6 of the trough charge cavity. As a result of undermining the gutter-shaped charge initiated by the detonator 10, detonation waves arising in the walls 1 and 2 of the charge act directly on the sections 14 and 15 of the shock tape 11 in contact with the ends 4 and 5 of the walls 1 and 2 of the charge, as a result of which the specified peripheral sections 14 and 15 of the tape 11, a greater speed is communicated than its central part 16, located opposite the jumper 3 and the aggregate 6. This provides an advanced collision of the peripheral sections 14 and 15 of the tape 11 with the surface 7 of the cut material 8 and the formation in ma series 8 of two shock waves with mirrors symmetrically in cross section, interacting with each other in the plane of the cut and causing resonantly increased compression in the region of the specified plane and the subsequent increased tensile stress. Use as a generator of shock waves of a metal tape 11, accelerated by the explosion, can significantly increase the tensile stress in the area of the cut.

 As a high-density aggregate 6 of the trough charge cavity, a mixture of finely divided concentrate of enriched iron ore with a plasticizer, for example, epoxy resin, is also used.

 Based on the tests, it was found that the use of a shock tape 11 with a thickness of F> 0.03 G in the method is ineffective, since shock waves with high pressure but short length, which attenuate at distances, are formed as a result of the collision of the tape with surface 7 in the material being cut 8 significantly smaller than the thickness G of the material being cut 8. The use of a heavy shock tape with a thickness F> 0.1 G requires additional blast energy to accelerate the shock tape to speeds providing shock wave pressure, which is necessary imoe for cutting the material, which reduces the CPV explosion.

 When evaluating the gap H between the shock tape 11 and the surface 7 of the material being cut 8, based on the calculations, it can be concluded that the gap H is less than 1F insufficient to accelerate the tape 11 to maximum speed, and therefore is ineffective.

 A gap H larger than 10 F is not effective due to the significant consumption of kinetic energy of the shock tape to overcome the gap H.

 When using cheap low-explosive explosives, for example, aquanite, with a detonation velocity of 5.5 km / s, for both surfaces 17 and 18 of the walls 1 and 2 of the gutter charge, used in the manufacture of a monolithic trough-like charge, facing the opposite side from ends 4 and 5 (Fig. .3), and on the surface 9 of the jumper 3 adjacent to the surfaces 17 and 18, a continuous layer 10 of high-explosive explosive is applied, for example, a hexoplast having a detonation velocity of 7.5 km / s, i.e. a higher detonation velocity of the explosive from which the trough charge is made, and at least 1.1 times the speed of sound propagation in the material being cut 8. The cavity of the trough charge is filled with compressed wood pulp 6, which is a material with low acoustic rigidity. When installing the trough charge on the surface 7 of the cut solid material 8, the plane of symmetry of the charge is combined with the cut line, while the detonator 10 is installed in the layer 19 in the plane of symmetry of the trough charge.

 Thus, the trough charge is initiated through the high-explosive explosive layer 19.

 The following example relates to a method for cutting (or fragmenting) predominantly brittle solid materials, for example concrete, rocks, etc. A monolithic trough charge in this case (Fig. 4) is made of a plastic explosive, for example aquanite, having a detonation velocity of 5.5 km / s An elongated grooved charge is produced with two walls 1 and 2 mirror-mutually symmetrical in cross section and a jumper 3 between them, and a gutter-shaped charge cavity limited by walls 1 and 2 and a jumper 3 is filled with an inert filler 6, for example, material with low acoustic rigidity, such as rubber or pressed wood. In the jumper 3, a pipe-shaped cylindrical longitudinal channel 20 is made, the axis of symmetry of which is located in the plane of symmetry of the charge and at the same distance from the surfaces 9 and 21 of the jumper 3. At one end of the grooved charge, an intermediate detonator 22 is installed in the cavity of the channel 20, which is made in the form of a cylindrical charge of high-explosive explosive, for example hexogen. An axial hole is made at the outer end of the intermediate detonator 22, into which the detonator 10 is installed. The groove-shaped charge with the ends 4 and 5 of the longitudinal edges of the walls 1 and 2 is mounted on the surface 7 of the material being cut 8 and undermining.

 In the process of charge detonation, an air shock wave is formed in channel 20, which moves along channel 20. The shock wave is ahead of the detonation front of the trench charge itself and initiates the explosive detonation process on the walls of channel 20, which leads to the formation of oblique detonation waves in walls 1 and 2. The speed of the air shock wave in channel 20 exceeds the speed of sound propagation in the material being cut 8 and provides supersonic motion of the lines of interaction of oblique detonation fronts with the surface 7 of the material being cut 8. Thus, an additional technical result is achieved, namely, the energy dissipation of the shock waves in the material being cut is reduced material, which ensures a reduction in the energy intensity of fracture when cutting solid materials with low-explosive explosives and, as a result, reduces the cost of a.

The following example relates to cutting massive metal sheets, plates and structures with a thickness of more than 50 mm. A monolithic grooved charge is made from a high-explosive hexoplast explosive (Fig. 5). The cavity between the walls 1 and 2 and the jumper charge 3 is filled with compressed wood pulp 6, for example cardboard. Before installing the trough charge on the surface 7 on the specified surface along the line of the cut, for example, using an elongated cumulative charge, an incision 23 is made of depth L equal to (0.05-0.1) G - the thickness of the material being cut, with a cross-section in the form of a triangle with an acute angle α at the apex equal to 15-60 ^o . The gutter-shaped charge is established symmetrically to the lines of the cut being carried out, the ends 4 and 5 of the longitudinal edges of the walls 1 and 2 of the charge are combined with the surface 7 of the material being cut 8 and give them the shape of surface 7. On the surface 9 of the jumper 3, a detonator 10 is installed in the plane of charge symmetry and undermine.

 When the gutter charge explodes, two shock waves are formed, which interact under the apex of incision 23 in the resonance mode, which provides a multiple increase in tensile stresses acting perpendicular to the plane of the cut. A surface incision 23 with an acute angle at the apex acts as a stress concentrator, which in turn increases tensile stresses and intensifies crack formation in the plane of the cut.

 Thus, a technical result is achieved, namely an increase in tensile stresses in the plane of the cut. As a result, the energy intensity of cutting is reduced and the explosion efficiency is increased.

 The device for explosive cutting of solid material (Fig.6) contains an elongated explosive charge provided with means of initiation. The elongated charge is made in the form of a monolithic trough with two walls 1 and 2 symmetrically located relative to the plane passing through the longitudinal axis of the charge, connected by a jumper 3, while the ends 4 and 5 of the walls 1 and 2, remote from the jumper 3, are located in the same plane. As an inert non-gaseous filler 6 of the trough cavity, a material with low acoustic rigidity can be used, for example rubber, pressed wood pulp, etc. A layer 24 of a material with high adhesive properties, for example, epoxy adhesive, is applied to the ends 4 and 5 of the longitudinal edges of walls 1 and 2 .

 For explosive cutting of solid materials (Fig. 1), a trough charge is installed on the surface 7 of the material being cut 8 so that the ends 4 and 5 of the longitudinal edges of both walls 1 and 2 of the trough charge are facing, and the plane of charge symmetry is combined with the line of the cut.

 On the surface 9 of the jumper 3 in the plane of symmetry of the grooved charge, a detonator 10 is installed and undermine.

 After the explosion is initiated, two detonation waves propagate along the walls 1 and 2 of the trough charge (Fig. 1), synchronized by a jumper 3 and directly acting on the surface 7 of the material being cut 8. In this case, a non-gaseous inert filler 6 located in the plane of symmetry of the charge damps the effect of detonation waves on the surface area 7 of the material being cut 8, located between the walls 1 and 2 of the charge, excluding the direct effect of detonation waves on the specified surface area 7 times material being cut 8. As a result of the direct impact on the surface 7 of the material being cut 8 of two detonation fronts synchronously moving along the walls 1 and 2 of the charge, two unidirectional mutually separated shock waves are excited in the material being cut 8, which, when developing fronts that are mirror symmetric in the cross section, collide in the plane of the cut, causing resonantly increased compression in the region of the specified plane. The region of resonantly increased compression moves along the plane of the cut into the depth of the material being cut 8. As the region of high compression moves deep into the material of cut 8 behind the region of high compression in the plane of the cut, the compressed material 8 is unloaded and a region of biaxial tension occurs, in which the maximum tensile stresses act along normal to the plane of the cut, which leads to intense destruction of the material 8 in the vicinity of the plane of the cut.

 Thus, a technical result is achieved, namely, tensile stresses in the plane of the cut are amplified, which ensures a reduction in the energy intensity of the solid material and an increase in the explosion efficiency.

 The achievement of the technical result is also ensured if a longitudinal groove 25 is made in the jumper 3 (Fig. 7) symmetrically to the symmetry plane of the grooved charge along its entire length, in which the detonating tape 26 is made, made of a high-explosive explosive having a detonation velocity greater than the detonation velocity of the grooved charge and equipped with at least one detonator receptacle.

 The longitudinal groove in which the detonating tape is pressed in can be made in the jumper from the side opposite to the cavity of the trench charge, which in turn is filled with a non-gaseous inert filler 6.

 An elongated monolithic trough charge can be made of aquanite, and the detonating tape 26 (Fig. 7) is made of hexogen.

 An elongated monolithic trough charge can be made of TNT, and the detonating tape 26 can be made of RDX.

 The trough charge can be made of a mixture of TNT with RDX, and detonating tape 26 in this case can be made of TENA (pentaerythritol tetranitrate).

 The trough charge can be made of RDX, and the detonating tape 26 is made of TEN.

 In these combinations, the principle of exceeding the detonation velocity of the explosive detonating tape over the detonation velocity of the explosive, from which the gutter-shaped charge is made, is observed.

 When undermining the elongated monolithic groove charge (Fig. 7) equipped with detonating tape 26, the detonation front in the tape having an increased detonation speed moves along the cut line with the detonation speed of the explosive detonating tape and initiates oblique detonation waves in walls 1 and 2 of the groove charge, the lines of interaction of which with the surface 7 of the material being cut 8 move along the cut line with the detonation speed of the high-explosive detonating belt.

 As a result, an additional technical result is achieved, namely, the dispersion of the energy of the shock waves of the explosion in the material being cut is reduced.

The proposed method and device for its implementation are used to cut sheets of steel 45 with a thickness of 10 mm and dimensions in terms of 200 x 400 mm ² . The gutter-shaped charge 200 mm long (Fig. 1) with a rectangular cross-section of the cavity between walls 1 and 2 and the jumper 3 was made of plastic explosive - hexoplast. The linear charge weight was 0.2 kg of explosive per linear meter, i.e., the trough charge used in this experiment weighed 0.04 kg. A rubber cord with a rectangular cross section whose dimensions were equal to the corresponding dimensions of the section of the charge cavity was inserted into the cavity of the gutter-shaped charge without a gap as a filler 6. The gutter-shaped charge was stacked with the ends 4 and 5 of the longitudinal edges on the surface 7 of the material being cut 8, after which the plane of charge symmetry was combined with the line of the cut being made, dividing the steel sheet into 200 x 200 mm squares of equal size. The outer surface 9 of the charge was rolled around to eliminate the gaps between the ends 4 and 5 of the walls 1 and 2 and the surface 7 of the cut steel sheet 8. On the surface 9 of the jumper 3 in the plane of symmetry of the charge, a hole for the detonator capsule was made using a cylindrical template. After installing the detonator 10 in the hole of the jumper, a charge was detonated. As a result of the explosion, through cutting of the steel sheet was achieved in the plane of charge symmetry.

 In the above case, it took 0.002 kg to cut a steel sheet of steel of steel 45 with a thickness of 10 mm per 1 centimeter of cut length, and to cut a steel sheet with the same parameters as the prototype, it would take about 5 times more hexoplast.

 Thus, a technical result has been achieved, namely, tensile stress in the plane of the cut is significantly increased, due to which the energy consumption of cutting solid material is reduced and the explosion efficiency is increased.

Claims (15)

 1. A method of explosive cutting of solid materials, in which an elongated explosive charge is installed on one of the surfaces of the material being cut and its subsequent initiation is carried out, characterized in that the charge is used in the form of a monolithic groove with two symmetrically located relative to a plane passing through the longitudinal axis of the charge, the walls connected by a jumper, the cavity of the gutter is filled with a non-gaseous inert filler and installed on the surface of the material being cut by the ends of the walls k, remote from the web, which is shaped into said surface, wherein the plane of symmetry of the trough is aligned with the intended line of cut, and produce charge initiation by the jumper through the detonator, which is positioned in said plane of symmetry.  2. The method according to claim 1, characterized in that when the charge is installed on the surface of the material being cut, the ends of the walls of the gutter are in contact with said surface.  3. The method according to claim 1, characterized in that between the charge and the surface of the material being cut, a metal shock tape is placed with a thickness equal to 0.03 - 0.1 of the thickness of the material being cut, and a width equal to the width of the charge, and between the shock tape and the surface of the cut material create a gap equal to 1 to 10 thicknesses of the shock tape.  4. The method according to any one of claims 1 to 3, characterized in that a continuous layer of high-explosive explosive having a detonation velocity exceeding the detonation velocity of a charge explosive and at least 1 is applied to the surface of the charge from the side opposite the trench cavity, 1 times the speed of sound propagation in the material being cut, and the initiation of the charge is produced through the aforementioned high-explosive explosive layer.  5. The method according to any one of claims 1 to 4, characterized in that the explosive charge is performed with a longitudinal cylindrical channel along the entire length, while the axis of the channel is placed in the plane of symmetry of the charge, and the detonator is placed in the said channel from one of its ends. 6. The method according to any one of claims 1 to 5, characterized in that before installing the charge on the surface of the material being cut, the last along the line of the proposed cut is an incision with a cross section in the form of a triangle with an acute angle at the apex of 15-60 ^o , and depth of 0.05 - 0.1 of the thickness of the material being cut.  7. The method according to claim 3, characterized in that high-density material is used as an inert filler of the cavity of the gutter.  8. The method according to claim 4, characterized in that a material with low acoustic rigidity is used as an inert filler of the gutter cavity.  9. The method according to claim 8, characterized in that compressed wood pulp is used as a material with low acoustic rigidity.  10. Device for explosive cutting of solid materials, containing an elongated explosive charge and initiation means, characterized in that the charge is made in the form of a monolithic trough with two walls connected by a jumper symmetrically relative to the plane passing through the longitudinal axis of the charge, while the ends of the walls remote from the jumper are located in the same plane.  11. The device according to p. 10, characterized in that the jumper is made with a longitudinal groove located symmetrically along its length with respect to the plane of symmetry of the charge, and the initiating means is made in the form of a detonating tape of a high-explosive explosive having a detonation velocity greater than the explosive detonation velocity a charge substance having at least one socket in which a detonator is mounted.  12. The device according to claim 11, characterized in that the longitudinal groove is located on the surface of the jumper from the side opposite the cavity of the gutter.  13. The device according to any one of paragraphs.11 and 12, characterized in that the charge is made of aquanite, and the detonating tape is made of hexogen.  14. The device according to any one of paragraphs.11 and 12, characterized in that the charge is made of TNT, and the detonating tape is made of RDX.  15. The device according to any one of paragraphs.11 and 12, characterized in that the charge is made of a mixture of TNT with RDX, and the detonating tape is made of TEN.

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