RU2183271C2 - Device for breakage of monolithic objects - Google Patents

Abstract

FIELD: mining and construction engineering. SUBSTANCE: thin wire placed in vessel is melted and evaporated by supply of definite quantity of electric power to it for short period. As a result, explosive substance placed in vessel expands. Force of expansion resulting from melting and evaporating of thin metal wire makes hammer move to deliver blow against object to break it. Metal wire is installed in electrodes so that it may be moved to gap between electrodes. Device has inlet and outlet channels for supply of explosive substance to vessel and its discharge from vessel. EFFECT: higher efficiency of objects breakage due to increased breakage force. 3 cl, 5 dwg

Description

 The invention relates to a device for the destruction of monolithic objects, in which a thin metal wire (an example of a substance that melts and evaporates) very quickly melt and evaporate under the influence of electric energy supplied to it for a short period of time, and the object to be destroyed in the form of a concrete main structure rocks or slabs explode using the expansion force during evaporation caused by melting and evaporation.

 From author testimonial. SU 883389, class E 21 C 3/20, 37/18, publ. 11/23/1981 a device for the destruction of monolithic objects is known, containing a striker mounted with the possibility of moving into a vessel and striking a destructible object by impact with the surface of a destructible object, an expansion force generating unit provided in the vessel and intended to create an expansion force to force the striker to collision with the surface of the explosive object, and the said node generating expansion forces includes inserted into the vessel electrodes and a liquid explosive substance for per supply to the drummer of the expansion force generated by supplying electric energy to the electrodes, means for pressing the vessel to the object to be destroyed. However, in the case when the known device is used to destroy the object, which is a kind of plate, and the hole to be installed is not made in the object to be destroyed, and the vessel is simply placed on the surface of the object to be destroyed, then almost all the expansion force caused by the melting and evaporation of a thin mechanical wire breaks out into the air, and, therefore, a significant part of the destruction effort is not transmitted to the destructible object.

 The technical task of the present invention is to provide a device for the destruction of monolithic objects, effectively using the generated destructive force.

 The technical result of the invention was the creation of a device for the destruction of monolithic objects, most effectively using the created destructive force.

 This technical result is achieved due to the fact that in the device for the destruction of monolithic objects containing a hammer mounted with the ability to move into the vessel and strike at the destroyed object by impacting with the surface of the destroyed object, an extension force generating unit is provided in the vessel and intended to create expansion forces to force the striker to collide with the surface of the explosive object, wherein said expansion force generating unit includes inserted into the sucker electrodes and liquid explosive for transmitting to the hammer an expansion force generated by supplying electric energy to the electrodes, means for pressing the vessel against the object to be destroyed, according to the invention, thin metal wires are inserted into each electrode so that they can be pulled into the gap between the electrodes, and To transfer the expansion force to the striker, a thin metal wire can be quickly melted and vaporized by supplying electric energy to it by means of electrodes short period of time, wherein the device formed inlet for supplying the blasting substance into the vessel, an outlet channel for discharging the spent explosive substance from the container, locking means for locking the inlet and outlet channels respectively.

 Preferably, a plurality of pairs of electrodes are inserted into the vessel and a thin metal wire is inserted into each electrode so as to be able to extend into the gap between the pair of electrodes.

 Furthermore, an inclined or curved reflective surface is preferably formed in the vessel to concentrate the expansion force on the hammer.

The invention is further explained in more detail with reference to the drawings, in which:
in FIG. 1 is a cross-sectional view of a fracture apparatus made in accordance with a first embodiment of the present invention;
in FIG. 2 is an electrical diagram for supplying energy for a first embodiment of a fracture device;
in FIG. 3 is a cross-sectional view of a destruction apparatus made in accordance with a second embodiment of the present invention;
in FIG. 4 is a cross-sectional view of a destruction device made in accordance with a third embodiment of the present invention;
in FIG. 5 is a cross-sectional view of a fracture apparatus in accordance with a fourth embodiment of the present invention.

 For a more detailed description of the present invention, a first embodiment of the present invention is explained with reference to the accompanying FIGS. 1 and 5.

 The device 1 for destroying monolithic objects according to the first embodiment of the present invention is designed so that the expansion force created when a thin metal wire (for example, copper) 8 is quickly melted and evaporated by supplying electric energy to it, is transmitted through an explosive substance (water or oil) 3 so that the destructible object H1 is destroyed using the expansion force. This destruction device 1 is particularly suitable for destroying a destructible object H1 in the form of a plate.

 The destruction device 1 comprises a destruction vessel 2, which is pressed tightly against the surface of the object to be destroyed H1. This destruction vessel 2 is configured so that one end (from the side facing the explosive object H1) is open and the other end is closed, and it is provided with an expansion force generating unit A, designed to cause the thin metal wire 8 to generate the expansion force. It should be noted that the destruction vessel 2 is made of metal so that it can withstand the expansion force created by the thin metal wire 8 and the explosive 3.

 The node A for generating the expansion force is equipped with a destructive head P, which is inserted with the possibility of removal using the retainer 2c into the hole 2a made in the drum of the destruction vessel 2. The destructive head P comprises a pair of electrodes 4 inserted in the lid 2b, and a thin metal wire 8, which is connected to each other by the electrodes 4.

 In addition, the node A for generating the expansion force comprises an explosive 3 for transmitting the expansion force impactor 22 described below, when the thin metal wire 8 is quickly melted and evaporated by supplying electric energy thereto for a short period of time; an electrical circuit 9 for supplying electrical energy to a thin metal wire 8; an inlet channel 18 for inlet of the explosive substance 3 into the destruction vessel 2 and an exhaust channel 19 for discharging the spent explosive substance 3 from the destruction vessel 2.

 As shown in figure 2, the electric circuit 9 for supplying energy contains an energy source 10 connected to the output contacts 5 of the electrodes 4 wires 5A; a capacitor 13 connected in parallel with the energy source 10 and the output contacts 5; a controller 11 for charging control, which is installed between the capacitor 13 and the energy source 10 and is equipped with a charge switch (not shown) and a discharge switch 12 installed between the controller 11 and one of the output contacts 5.

 Also, the inlet channel 18 and the outlet channel 19 are placed on the other side of the destruction vessel 2 and are configured so that they can be freely opened and closed. Valves (one example of shutoff means) 20, 21, which can withstand the expansion force generated when the thin metal wire 8 is melted and vaporized, are installed on the inlet channel 18 and on the outlet channel 19, respectively.

 Drummer 22 strikes the surface of the destructible object Hl by impact. The drummer 22 is mounted with the possibility of moving into the vessel 2 for destruction on one of its sides and is shaped in such a way that it is equipped with many pointed protrusions 23 from its impact side, which it collides with the object to be destroyed H1 and an enlarged diameter part 30 having sensing pressure surface 33 made from the side of the base of the striker. A circular collar is formed in the destruction vessel 2 to limit the movement of the enlarged diameter portion 30. It should be noted that the striker 22 is made of metal so that it can withstand the shock exploded by the expansion force.

 On the other side of the destruction vessel 2, a rod 25 of the pneumatic cylinder is located (one example of pressure means; not shown) so that it can press the destruction vessel 2 against the object to be destroyed H1.

 The following is a description of the method for carrying out the destruction of the object H1 using the device 1 for destruction, made in accordance with the above description. Firstly, a predetermined number of destructive heads P is prepared by installing a pair of electrodes 4 in the lid 2b and placing between the ends of the electrodes 4 a thin metal wire 8 attached to them by welding or in some other way. The lid 2b is inserted into the hole 2a made in the drum of the destruction vessel 2 and secured using the clips 2c. Next, the destruction vessel 2 is filled with explosive 3 through the inlet channel 18, equipped with a fan 20, which is opened, and the valve 21 is closed, and after filling the valve 20 is closed. In this state, a thin metal wire is immersed in an explosive substance 3.

 Drummer 22 is pressed against one side of the destruction vessel 2, i.e. to the destructible object H1 due to the pressure created due to filling destructive substance 3 of the vessel 2 for destruction. The enlarged diameter portion 30 is guided by a guide surface 32, and the pointed protrusions 23 of the striker 22 protrude from the destruction vessel 2. When the pneumatic cylinder is activated, while guiding the rod 25 to the destruction vessel 2, the destruction vessel 2 is pressed against the surface side of the object to be destroyed H1, overcoming the pressure of the explosive substance 3. Thus, the end face of one side of the destruction vessel 2 is pressed against the surface of the destructible object H1 and at the same time, the hammer 22 is pressed against the other side of the destruction vessel 2 so that the pointed protrusions 23 are pressed against the surface of the destructible object H1.

 In this state, the electric circuit 9 for supplying energy is connected to the output contacts 4, the charge switch of the collector 11 is turned on to supply electric energy to the capacitor 13 and charge it. Then, electrical energy is supplied to the thin metal wire 8 through the electrodes 4 for a very short period of time by turning on the discharge switch 12.

 In this way, the thin metal wire 8 is quickly melted and evaporated, and the explosive 3 quickly evaporates so that an expansion force is generated at this time. Since the inlet channel 18 and the outlet channel 19 are hermetically closed by valves 20 and 21 and the destruction vessel 2 is pressed against the object to be destroyed H1 by the rod 25 of the pneumatic cylinder, the generated expansion force acts on the pressure perceiving surface 33 of the striker 22 so that the pointed protrusions 23 of the striker 22 strike on the surface of the destroyed object H1 and explode or crack it.

 After that, the rod 25 is withdrawn by depressurizing the pneumatic cylinder and the spent explosive 3 is withdrawn through the exhaust channel 19 by opening the valve 21, as a result of which the destruction vessel 2 is separated from the destructible object H1.

 When the destruction of the monolithic object is carried out constantly, the destructive head P is replaced by removing the retainer 2c, the explosive 3 is again poured into the destruction vessel 2 through the inlet channel 18 with the valve 20 open and the valve 21 closed, as in the previously mentioned case, and then valve 20 is closed. The pointed protrusions 23 of the striker 22 force a tight hold on the surface of the destructible object H1, and the rod 25 of the pneumatic cylinder forces a tight hold on the other side of the destruction vessel 2, and the destruction vessel 2 is pressed against the surface of the destruction object H1, overcoming the pressure of the explosive 3, by turning on the pneumatic cylinder and turn on the electric circuit 9 for supplying electric energy to the output contacts 5 of the electrodes 4. After that, the charge switch of the collector 11 is turned on to supply electric energy to capacitor 13 and charge it. Then, electrical energy is supplied to the thin metal wire 8 for a very short period of time by turning on the discharge switch 12. As a result, the thin metal wire 8 is quickly melted and evaporated, and the explosive 3 quickly evaporates so that an expansion force is generated at this time. Under the action of the expansion force, the pointed protrusions 23 of the striker 22 strike the surface of the destructible object H1, as a result of which the destructible object H1 is destroyed or cracked.

 It should be noted that the destruction vessel 2 and the striker 22 can be reused, as they are made of metal to withstand the shock caused by the expansion force of the thin metal wire 8 and explosive substance 3.

 As described above, in the first embodiment of the present invention, the impactor 22 is forced to strike (it is pressed tightly) with the surface of the explosive object H1 using the force of expansion of the thin metal wire 8 and explosive substance 3. After that, even if the destructible object H1 has the form of a plate, it can be destroyed due to the effective use of the expansion force of a thin metal wire 8 and explosive substance 3.

 In addition, the destruction vessel 2 and the striker 22 are made of metal to withstand the shock caused by the expansion force of the thin metal wire 8 and the explosive 3, so that they can be reused. The destructive head P also contains a pair of electrodes 4 inserted in the cover 2b, and a thin metal wire 8 is stretched between the electrodes 4. As a result, when the destruction work is carried out continuously, the destruction device 1 can be restored by simply replacing the destructive head P, which is sufficient convenient and allows to increase labor efficiency.

 Next, a second embodiment of the present invention is described with reference to figure 3. In the device 1 for the destruction of a monolithic object, made in accordance with the second embodiment of the present invention, the inlet channel 18 and the outlet channel 19 are made in the drum of the vessel 2 for destruction and are equipped with valves 20 and 21, respectively. In order to concentrate the expansion force on the hammer 22, the conical reflecting surface 35 is formed on the inner surface on the other side of the fracture vessel 2. Only one pointed protrusion 23 is also made on the impact side of the striker 22, which collides with the destructible object H1. The configuration of the destructive head P and other designs are the same as those described in the previously mentioned first embodiment, and therefore, their explanation is omitted here.

 With this configuration, the filling and discharging of the explosive 3 is performed through the inlet channel 18 and the outlet channel 19, made in the drum of the vessel 2 for destruction, respectively. When electric energy is supplied to the thin metal wire 8, the generated expansion force acts concentrated on the central part of the pressure sensing surface 33 of the hammer 22 due to the action of the conical reflecting surface 35.

 Thus, the destructible object H1 can be blown up with confidence by the striker 22.

 Each time the destruction work is completed, the destruction head P is replaced and the explosive 3 in the destruction vessel 2 is replaced. Other operations and actions are the same as in the first embodiment, and thus, their explanation is omitted here.

 Although the reflective surface 35 is made in the form of a cone in the previously mentioned second embodiment, its form is not limited to this shape, and the reflective surface can be given hemispherical or parabolic, or some other curved shape. In this case, also, the expansion force generated when electric energy is supplied to the thin metal wire 8 acts concentrated on the central part of the pressure sensing surface 33 of the striker 22 due to the action of the reflecting surface 35. Thus, the destructible object H1 can be destroyed with confidence by the striker 22.

 Next, a third embodiment of the present invention is described with reference to figure 4. In the destruction device 1, made in accordance with the present invention, the rod 25 of the pneumatic cylinder, which presses the other side of the destruction vessel 2, is hollow and the working end of the rod 25 is also used as a cover 41, which covers the hole 40 made on the other side of the vessel 2 for destruction. A plurality of pairs (three pairs are shown in the figure) of the electrodes 4 are inserted into the cover 41, and a thin metal wire 8 is stretched between the electrodes 4 of each pair, from which a destructive head is formed.

 The inlet channel 18 and the outlet channel 19 are made in the drum of the destruction vessel 2 and are provided with valves 20, 21, respectively. Also, only one pointed protrusion 23 is formed on the impact side 22, which is brought into collision with the destructible object H1. At the base of the striker 22, a larger diameter part 30 is formed, provided with a receptive surface 33. In the destruction vessel 2, a circular guide surface 32 is formed for guiding when moving the enlarged diameter part 30, and a circular bead 31 for restricting the movement of this part.

 In the fracture device 1, made in accordance with the above description, a plurality of pairs of electrodes 4 are inserted into the cover 41, and a thin metal wire is stretched between the electrodes 4 of each pair, from which the destructive heads P. are formed. Thus, the expansion force generated when electrical energy is supplied to each thin metal wire 8, more than when one thin metal wire 8 is used, and the expansion force acting on the pressure receiving surface 33 of the hammer 22 is increasing. Further, since the force by which the pointed protrusion 23 of the striker 22 is pressed against the destructible object H1 is increased, the fracture force can be increased, and the destructible object H1 can be destroyed with confidence. Each time the destruction work is completed, the destruction head P is replaced and the explosive 3 in the destruction vessel 2 is replaced.

 Next, a fourth embodiment of the present invention is described with reference to FIG. In the destruction device 1, made in accordance with the present invention, the rod 25 of the pneumatic cylinder, which presses the other side of the destruction vessel 2, is hollow and the working end of the rod 25 is also used as a cover 41, which covers the hole 40 made on the other side of the vessel 2 for destruction. A pair of electrodes 4 is inserted into the cover 41 of the destruction vessel 2, and thin metal wires 8, 8 are inserted into each of the electrodes 4 so that they can be pushed into the gap between the pointed ends of the electrodes 4. The remaining structural elements are the same as in the third embodiment, and therefore their description is omitted here.

 In the device 1 for destruction, made in accordance with the above description, the electrodes 4 are first inserted into the cover 41, and thin metal wires 8 are inserted into the corresponding electrodes 4 and then the destructive head P is ready. At this time, the tip of the thin metal wire 8 projects slightly into the gap between the electrodes 4, and the thin metal wires 8 do not contact each other.

 Next, the explosive substance 3 is poured into the vessel 2 for destruction through the inlet channel 18, while opening the valve 20 and closing the valve 21, and then closing the valve 20. At this time, thin metal wires 8 are immersed in the explosive substance 3.

 The impactor 22 is pressed against one side of the destruction vessel 2 by the pressure of the explosive 3, and the enlarged diameter portion 30 is guided by the guiding surface 32 so that the pointed protrusion 23 of the impactor 22 protrudes from the destruction vessel 2.

 In this state, the pointed protrusion 23 is forced to come into close contact with the surface of the destructible object H1, and the destruction vessel 2 is pressed against the surface of the destructible object H1, overcoming the pressure of the explosive 3 by turning on the pneumatic cylinder. Then, the striker 22 is pressed back to the other side of the destruction vessel 2, and the end surface of one side of the destruction vessel 2 is forced to press firmly against the surface of the object H1 to be destroyed. After that, the electric circuit 9 for supplying electric energy is connected to the output contacts 5 of the electrodes 4. By turning on the charging switch of the controller 11, electric energy is supplied to the capacitor 13 and charged. Alternatively, electric energy is supplied to the capacitor 13 and charged in advance, and electric energy is supplied to the thin metal wire 8 via electrodes 4 for a very short period of time by turning on the discharge switch 12. Then, a discharge occurs in the gap between the ends of the thin metal wires 8. As a result, the tips (protruding parts from each electrode) of the thin metal wires 8 quickly melt and evaporate, and the explosive 3 quickly evaporates so that expansion force is generated at this time. The generated expansion force acts on the pressure receiving surface 33 of the striker 22, and the destructible object H1 is destroyed and split by the pointed protrusion 23 of the striker 22.

 After that, the spent explosive 3 is released through the exhaust channel 19 by opening the valve 21, and the destruction vessel 2 is separated from the destructible object H1, relieving pressure in the pneumatic cylinder.

 When the destruction work is carried out continuously, the thin metal wires 8 are pushed into the gap and the explosive substance 3 is poured into the destruction vessel 2 through the inlet channel 18 and the valve 20 is opened, and the valve 21 is closed, and then the valve 20 is closed. The pointed protrusion 23 of the striker 22 is forced to come into close contact with the surface of the destructible object H1, and the destruction vessel 2 is pressed against the surface of the destructible object H1, overcoming the pressure of the explosive 3 by turning on the pneumatic cylinder.

 Since electrical energy is supplied to the thin metal wires 8 for very short periods of time, the ends of the thin metal wires 8 quickly melt and evaporate, and the explosive 3 quickly evaporates. Due to the expansion force generated at this time, the pointed protrusion 23 of the striker 22 strikes the surface of the destructible object H1 so that the destructible object H1 collapses or breaks.

 In the aforementioned fourth embodiment, the destruction work can be performed continuously by pulling the thin metal wire into the gap and by pouring the explosive 3 into the destruction vessel 2. Thus, the effectiveness of the destruction of a monolithic object can be increased.

 Although one pair of electrodes 4 is installed in the fourth embodiment, the design is not limited to such a design. As in the aforementioned third embodiment, a plurality of pairs of electrodes 4 can be inserted into the cover 41. With this configuration, thin metal wires 8 are inserted into each electrode 4 and electrical energy is supplied to each thin metal wire 8 at the same time, resulting in thin metal wires 8 and the explosive 3 expands so that the destructible object H1 is destroyed by the force of expansion. In this case, the expansion force increases so that the destructible object H1 can be destroyed with confidence.

 As described above, the present invention is applicable in the case when it is difficult to create an opening for installation in the destructible object H1, or in the case when the destruction work is very different in nature.

Claims (3)

 1. A device for the destruction of monolithic objects, containing a hammer mounted to move into a vessel and strike at the object to be destroyed by impacting with the surface of the object to be destroyed, an expansion force generating unit provided in the vessel and intended to create an expansion force to force the impactor to collide with the surface of the explosive object, and said node generating the expansion forces includes inserted electrodes in the vessel and liquid explosive to transfer to the shock the expansion force generated by supplying electric energy to the electrodes, means for pressing the vessel against the object to be destroyed, characterized in that thin metal wires are inserted into each electrode so that they can be pulled into the gap between the electrodes, and to transmit the expansion forces to the drummer a thin metal wire is configured to rapidly melt and evaporate by supplying electric energy to it by means of electrodes for a short period of time, while enes inlet for supplying the blasting substance into the vessel, an outlet channel for discharging the spent explosive substance from the container, locking means for locking the inlet and outlet channels respectively.  2. The device according to claim 1, characterized in that a plurality of pairs of electrodes are inserted into the vessel and a thin metal wire is inserted into each electrode so as to be able to extend into the gap between the pair of electrodes.  3. The device according to any one of paragraphs. 1 and 2, characterized in that an inclined or curved reflective surface is formed in the vessel to concentrate the expansion force on the hammer.

Images