RU2046286C1 - Method of destruction of large-sized solidified waste of blast-furnace and steelmaking processes - Google Patents

Abstract

FIELD: destruction of solids, mainly of large-sized solidified waste of blast-furnace and steelmaking processes. SUBSTANCE: axisymmetric shaped charge forms a striker with a mean diameter of 0.01 to 0.1 of the diameter of solid to be destructed and minimum speed of working member within 2000 to 4000 m/s. The striker acts on solid to be destructed in the axis of symmetry on the side of the hemispherical surface. Shaped charge has a casing which can be made of plastic, explosive charge, funnel with an angle of splay of 60 to 120 deg. Funnel thickness is 0.01 to 0.05 of the casing diameter, charge can have a lens assembly. The casing can have a cylindrical-conical shape with an angle of splay equal to that of the funnel. The distance between the funnel and conical part makes up 10 to 40 funnel thicknesses. The funnel can be made of aluminium or steel. EFFECT: enhanced efficiency. 8 cl, 8 dwg

Description

 The invention relates to blasting and can be used in the destruction of solids, mainly bulky solidified blast furnace and steelmaking waste.

 The existing technology for blast furnace production involves casting slag formed in the furnace into bucket trolleys, in which it is transported for dumping to special dumps. During casting, cast iron partially enters the ladles, which, settling at the bottom, solidifies, forming a continuous mass of cake weighing 15-20 tons, repeating the inner surface of the ladle with a hemisphere of radius 1.5 m, the height of which varies depending on the amount of cast iron that has entered the ladle and is 1-1.5 m. Korzh, as a rule, is heterogeneous and consists of cast iron located on the periphery of the hemisphere, and slag in its center. There are cakes, almost entirely consisting of cast iron.

 At present, blast furnace waste is being processed that has accumulated over decades in dumps. Cakes go for remelting in order to obtain cast iron from them. At the same time, there is a problem of the destruction of cake layers in the dump area into parts, ensuring their convenient transportation to the remelting site without the use of hoisting and heavy vehicles.

A known method of destruction of solid rocks, including the formation of a high-speed impactor with an axisymmetric cumulative charge and the impact of the impactor on the destructible body [1]
Known cumulative charge for the destruction of solid rocks, containing a housing, the explosive charge placed in it with a recess and a conical funnel [2]
A disadvantage of the known method and device is the insufficiently high efficiency of the destruction of hard rocks.

 The aim of the invention is to increase the destruction efficiency of large solidified solid waste blast furnace and steelmaking.

The goal is achieved due to the fact that in the method of destroying large-sized solidified wastes of blast furnace and steelmaking, including the formation of a high-speed drummer with an axisymmetric cumulative charge and the impact of the drummer on the destructible body, a high-speed drummer is formed with an average diameter of the drummer equal to 0.01-0.1 of the diameter of the destructible body, with a length of 0.2-0.7 of its height, with a minimum speed of the working part of 2000-4000 m / s, and also due to the fact that the effect is carried out from the axis of symmetry of the destructible body with on the side of the hemispherical surface, and also due to the fact that in the cumulative charge containing the housing, the explosive charge placed in it with a recess and a conical funnel, the thickness of the funnel is 0.01-0.05 of the diameter of the body, and the angle of the funnel solution is 60 -120 ^about , while the charge length is 0.5-1.6 of its diameter, also due to the fact that the cumulative charge body is cylindrical, the funnel is mounted on the side of the cylindrical part of the body, and the angle of the conical part of the body is equal to the angle of the solution funnels the distance between the funnel and the conical part of the body is 10-40 thicknesses of the funnel. At the same time, a lens assembly is installed at the end of the cumulative charge opposite the funnel, the housing is made of plastic, and the funnel is made of aluminum or steel.

 In FIG. 1-8 shows a diagram of the destruction of solidified waste and the design of cumulative charges.

The destruction of bulky hardened waste blast furnace and steel production is as follows (see Fig. 1-5). An axisymmetric cumulative charge 1 is made, which is mounted on a stand at a distance from the destructible body 2 and undermined, for example, by an electric detonator 3 (Fig. 1). A high-speed hammer 4 is formed, the average diameter of which is d, and the length l (meaning the diameter and length of the working part of the hammer). The minimum speed of the working part of the striker 2000-4000 m / s (Fig. 2). A high-speed hammer 4 acts on the destructible body 2, as a result, a high pressure zone a arises on the contact surface of the hammer (cumulative jet) 4 and the destructible body 2, where the pressure is about 10 ⁶ atm (Fig. 3). A powerful shock wave b propagates from the zone of high pressure a along the destructible body 2, which, after reflection from the free surface, causes the destruction of the body 2 by loading with a tensile stress r equal to the pressure difference in the reflected b and shock waves b (Figs. 3, 4). Moreover, from the hole formed by the striker immediately after the passage of the high pressure zone a, another rarefaction wave k propagates, forming tensile stresses d (Figs. 3, 4). The rarefaction waves b and k with tensile stresses d and d (Fig. 5) are encountered, after which tensile stresses double e. In the zone of doubling stresses e, as a rule, the body is destroyed. Deviations from this rule occur due to numerous internal defects.

 When exposed to a destructible body along its axis of symmetry, the load distribution inside it will be symmetrical, which will lead to uniform destruction.

 For the formation of a high-speed projectile (cumulative jet), a cumulative charge is used (Fig. 6-8). After the triggering means of initiation, for example, an electric detonator 5, the detonation wave propagates directly through the cumulative charge 2 (Fig. 6) or through the lens unit 4, and then through the cumulative charge 2 (Fig. 8). After this, the detonation wave acts on the funnel 3, forming a high-speed shock element (cumulative stream) from it, and on the housing 1, causing it to crush, and an overpressure zone forms around the blast site.

 The axisymmetric cumulative charge forms a high-speed shock element (cumulative jet), moving at a speed of 2000-10000 m / s depending on the material of the funnel and the design parameters of the cumulative charge. This allows you to provide, when interacting with a destructible body, pressures that exceed the dynamic tensile strength of its material. Thus, the introduction of a high-speed impactor into a destructible body is similar to the introduction of a cumulative jet into an obstacle, that is, it takes place according to hydrodynamic laws, which determines the lower limit of the velocity of the formed impactor (minimum speed of the working part) within 2000-4000 m / s depending on the material of the funnel (for copper ≈2500 m / s; for aluminum ≈3500 m / s, for steel ≈3000 m / s). The working part is understood to mean the part of the drummer involved in the destruction of the body, along with the non-working part formed from the funnel zone lying near its larger base and having a speed less than the minimum specified limit. The length of the non-working part of the drummer is insignificant.

 The diameter of the striker determines the size of the compression zone in the destructible body, which is equal to 2-20 diameters of the striker, depending on its density rate. The size of the compression zone determines the intensity of loading the body. Consequently, the diameter of the striker depends on the dimensions of the destructible body, its density and strength, as well as on the density and speed of the striker. Obviously, large diameters (about 0.05 diameters of the destructible body) are used for impactors made of materials with low density (aluminum), and less (about 0.01) for materials with high density (copper, tungsten, etc.), since the lower the impactor density, the lower the pressure in the compression zone, and vice versa.

 The length of the striker determines the depth of its penetration into the destructible body, while the penetration depth depends on the density of the striker material and the velocity distribution along it, since the cumulative jet of the striker stretches during movement under the action of a velocity gradient. The penetration depth determines the nature of loading destructible. If the penetration depth is small, there will be no destruction of the body from the side opposite to the cumulative charge, which will result in large parts requiring additional destruction. Based on the foregoing, the striker is selected taking into account the degree of crushing of the destructible body of the striker material and the velocity gradient along it and is 0.2 of its height for strikers made of materials with high density (tungsten, copper, etc.) and destructible bodies of small dimensions and 0.7 of its height for drummers from a material with low density and destructible bodies of large dimensions.

 Thus, by varying the diameter of the impactor and its length, it is possible to ensure the destruction of large-sized solidified waste from blast furnace and steelmaking of any size.

 Since bulky waste from blast-furnace and steel-making production, as a rule, has the shape of the bottom of the trolleys into which the slag merges, that is, the shape of a hemisphere, when exposed to its axis of symmetry, the most uniform loading of the destructible body occurs, which leads to the formation of the largest number of pieces on which it is destroyed, while their masses will be naturally minimal.

 The distance from the destructible body, on which the cumulative charge is installed, can vary from 1 to 10 diameters of the cumulative charge, depending on the parameters of the projectile (velocity gradient, diameter and the ratio of the diameter of the projectile to its length), while the minimum distance is determined from the conditions for the formation of the projectile with the necessary parameters, since the formation of the projectile continues during its movement, and the maximum condition for maintaining the integrity of the projectile (in the process of movement of the projectile is possible its destruction under ystviem velocity gradient).

A cumulative charge is used to form a high-speed projectile with the following parameters. Since the ratio of the diameter of the destructible body (determines the diameter of the projectile) to its height (determines the length of the projectile of a cumulative jet) is quite large 2-10, the ratio of the diameter of the projectile to its working length (minimum working length 2000-4000 m / s) is also quite large and ranges from 1 to 0.1, taking into account the choice of parameters of the drummer and its length from the ratios given in the claims. Such jets shaped charges are formed with an angle of from 60 to ^120, wherein the funnel angle of ^about 60 formed solution cumulative jet diameter ratio of 0.1 to the working length, and from funnel with an angle of ^about 120 "shock core" with a ratio diameter to length ≈1.

 If the angle of the funnel mainly determines the ratio of the diameter of the striker to its length, then the thickness of the funnel determines the diameter of the striker, it must be borne in mind that an increase in the diameter of the striker or its density leads to a decrease in its speed, the minimum value of which is specified in the modes of the destruction method. Therefore, an increase in the diameter of the hammer or its density (mass) must be compensated. This is achieved by increasing the diameter of the body of the cumulative charge. Thus, the ratio of the thickness of the funnel to the diameter of the charge is determined taking into account the required diameter of the striker and its speed and is 0.01 for strikers from a material with high density (tungsten, lead, etc.) and 0.05 for strikers from materials with a small density (aluminum).

The length of the charge is determined from the predetermined conditions provide options impactor depends mainly on the angle of the funnel and the solution lies in the range from 0.5 to craters with corners ¹²⁰ solution to 1.6 with an angle for funnel ⁶⁰ solution.

 Important from the point of view of the cost of the work is the mass of the explosive of the cumulative charge, which not only directly determines the cost of the cumulative charge, but also determines the cost of its isolation during the work and the cost of transportation to the place of destruction through the radius of the danger zone.

 The minimum explosive mass is provided by cumulative charges having a cylindrical shape. A cone cuts off a part of the charge that is not involved in the formation of a high-speed projectile. When the angle of the conical part of the body is equal to the angle of the cladding, the mass of the explosive charge will be minimal, providing the necessary parameters of the striker. The distance between the funnel and the conical part of the body is determined from the condition of ensuring the necessary speed of the hammer and, depending on the density of the material of the funnel and its thickness, is 40-10 thicknesses of the funnel.

 The installation of the lens unit, providing a converging front of the detonation wave, increases the energy of the projectile while maintaining the total mass of the explosive charge.

 The housing of the cumulative charge made of plastic, providing fastening of the details of the cumulative charge, does not give fragments when it is detonated, turning into dust when it is detonated, and since the cumulative jet formed from the funnel moves in the direction of the destructible body and is trapped by it, the cumulative charge can be blown on open areas without using special traps of fragments.

 Copper is widely used in cumulative charges, but it has a high cost of up to 50% of the cost of the cumulative charge; therefore, aluminum, having good ductility under dynamic loading and low density, and steel for short impactors, having low ductility under dynamic loading and high density.

 Thus, the use of the proposed solution will allow, at low cost and high productivity, to destroy large-sized solidified waste from blast furnace and steelmaking into parts convenient for transportation to the place of their smelting.

Claims (8)

 1. A method of destroying large-sized solidified wastes of a blast furnace and steelmaking, including the formation of a high-speed impactor with an axisymmetric cumulative charge and the impact of the impactor on the destructible body, characterized in that the impactor is formed with an average diameter and length equal to 0.01 0.1 times the diameter of the destructible body and 0.2 0.7 the height of the destructible body at a minimum speed of the working part 2000 4000 m / s.  2. The method according to p. 1, characterized in that the effect is carried out along the symmetry axis of the destructible body from the hemispherical surface. 3. The cumulative charge containing the housing, the explosive charge placed in it with a recess and a conical funnel, characterized in that the funnel is made with a thickness equal to 0.01 0.05 case diameter and a solution angle of 60 120 ^o , and the charge is made in length equal to 0.5 1.6 of its diameter.  4. The charge according to claim 3, characterized in that the housing is cylindrical with a cone angle equal to the angle of the funnel solution, while the funnel is placed on the side of the cylindrical part, and the distance between the funnel and the conical part is 10 40 thicknesses of the funnel.  5. The charge according to claim 3, characterized in that it is equipped with a lens assembly located at the end opposite the funnel.  6. The charge according to claim 3, characterized in that the housing is made of plastic.  7. The charge according to claim 3, characterized in that the funnel is made of aluminum.  8. The charge according to claim 3, characterized in that the funnel is made of steel.

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