RU2471622C2 - Armored chamber for grinding used tires - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to processing of industrial wastes. Armored chamber comprises housing. Housing bottom accommodates means to discharge tire grinding solid products. Armored chamber comprises also means to house tires, means to accommodate and blast explosive charge, and means to remove blast gaseous products. Note here that housing top peripheral part is shaped to circular flute directed inward and connected with housing lateral shell ring and port rings. Note also that shock wave cowl is fitted on port cover inner surface with working surface primarily, shaped to cone to smoothly conjugate with circular flute working surface.

EFFECT: decreased specific metal input, higher resistance to blast effects.

5 cl, 2 dwg

Description

The invention relates to the processing of industrial waste and can be used in the manufacture of armored chambers for grinding worn tires using explosive materials to produce rubber crumb and cord metal.

A known method of processing worn-out tires with metal cord using mechanical grinding using a machine equipped with two parallel shafts rotating towards each other, on which milling cutters equipped with replaceable cutting elements are fixed (patent RU 2125908). When grinding tires with metal cord using such a device, a significant amount of electricity is consumed and there is a need to periodically stop the process to readjust equipment and replace cutting elements. This significantly limits the performance of such equipment and reduces the profitability of the technology.

A well-known armored camera, the body of which is made in the form of two truncated conical shells interconnected by wide bases, the smaller base of the conical shells are interconnected by an external pipe that forms a looped working volume of the armored chamber (patent RU 2057014). The upper part of the pipeline is removable for loading worn-out tires and explosive charge into the armored chamber, and on the lower stationary part of the pipeline there is a hatch for unloading products obtained by grinding the tires by explosion. Using the well-known armored camera, the explosive circulation process of grinding tires is implemented, in which it is possible to significantly reduce the effect of the blast wave on the body of the armored camera due to the peculiarities of its geometry. However, the need to use an external pipeline with movable elements in the design significantly complicates the design of the armored chamber, increases the likelihood of depressurization of the working volume during an explosion, and also significantly increases the metal consumption and dimensions of the armored chamber.

Closest to the claimed armored camera is a device for destroying worn-out tires, comprising an armored camera, an upper hatch with a cover for loading and placing tires therein, means for placing and detonating explosives, means for removing gaseous explosion products and a hatch for unloading tire grinding products (patent RU No. 2184035). The design of this device allows for efficient grinding of tires due to a certain ratio of the size of the armored camera and the package of tires, as well as the choice of charge power. A disadvantage of the known device is that during the explosion of the hatch for loading tires and other parts of the body of the armored camera, which are oriented normal to the direction of movement of the blast wave, experience high shock loads. This nature of the shock load is due to the geometric shape of the explosive charge and the main direction of the shock wave (upward axis) in the initial phase of the explosion. This leads to the need to increase the thickness of the loading hatch and the walls of the hull, increases the likelihood of depressurization of the armored chamber, reduces the grinding performance and significantly limits its use for large-diameter tires.

The aim of the invention is to reduce the specific metal consumption of the armored camera, increasing its resistance to explosion, increasing the grinding performance and expanding the possibility of its use for grinding large diameter tires. This goal is achieved due to the technical result achieved using the claimed invention, which is to reduce the pressure of the shock wave when acting on the inner surface of the body of the armored camera in the axial direction.

The technical result is achieved by the fact that in the known armored chamber for grinding worn-out tires (comprising a body, in the upper central part of which there is a hatch with a cover for loading tires and charge, and in the lower conical part of the body there is a means for unloading solid products of grinding tires; means for placement tires, means for placing and detonating the explosive charge and means for removing gaseous products of the explosion) the upper peripheral part of the body is made in the form of a reversed inside the annular trough, which is connected to the lateral sidewall of the housing and a sidewall of the hatch on the internal surface of the hatch cover is mounted fairing blast wave, the working surface of which is made mainly conical shape and smoothly joined with the working surface of the grinding ring.

In a particular embodiment of the armored camera, the fairing is made in the form of a conical shell with a taper angle of 30 ° to 90 °, connected to the manhole cover using a cylindrical shell mounted concentrically with respect to the manhole shell.

In another particular embodiment, the armored chambers of the annular groove are made of several sections interconnected by welding, made of bent plates or pipe fragments.

In another particular embodiment of the invention, the annular groove of the housing is made of N sections interconnected by welding, the side shell of the housing is also made of N plate sections welded together, each section of the side shell is connected by welding to the adjacent section of the groove, and the number N is selected at least 6.

In another particular embodiment of the invention, the lower conical part of the casing is also made of N plate sections welded together, each section being welded with an adjacent side shell section.

The essence of the invention lies in the fact that the claimed combination of essential features of the device of the armored camera allows you to create conditions under which the impact of the shock wave in the axial direction on the cover of the loading hatch and the walls of the armored camera is significantly weakened. This is achieved due to the fact that with the declared geometric shape of the armored camera, the impact of the shock wave and explosion products on its body does not cause the formation of high values of the explosion parameters that are realized when the shock wave is normal to the wall of the armored camera. In the claimed design, the impact of a shock wave on the working surface of the fairing and on the smooth working surface of the annular groove occurs at fairly sharp angles with the formation of a circulation flow of explosion products parallel to the working surfaces of the armored chamber. Due to the geometric features of the implementation of these elements of the body of the armored camera and the nature of their interaction with the shock wave and explosion products, a significant reduction in the impact load on the most vulnerable elements of the armored camera, in particular on the manhole cover, is provided. This allows you to reduce the thickness of the loading hatch, the walls of the armored chamber, significantly reduce the material consumption of the armored chamber without reducing its explosion resistance and improve the quality of sealing.

Figure 1 presents a General view of the armored camera in cross section.

Figure 2 presents a top view.

Figure 1 presents a General view of the armored camera in cross section. In the upper central part of the housing (1) there is a hatch made in the form of a shell (2), a cover (3), a locking device (4) and a seal (5). In the lower conical part (20) of the housing (1) there is a hatch for unloading solid products of grinding tires, which is made in the form of a shell (6), a cover (7), a locking device (8) and a seal (9). Inside the armored camera is placed a tool for placing tires (10), which is made in the form of several brackets (11). Along the axis of the housing (1) and the tire package (10), an explosive charge (12) is placed, which is equipped with a means for its placement (13) and means for undermining it (14). A means (15) for removing gaseous explosion products is connected to the armored camera.

The upper peripheral part of the housing (1) is made in the form of an inwardly facing annular groove (16), which is connected by welding to the side shell of the housing (1) and to the shell (2) of the hatch. A blast wave fairing is installed on the inner surface of the hatch cover (3), which is made in the form of a conical shell (17) attached to the hatch cover (3) using a cylindrical shell (18) installed concentrically and with a gap relative to the shell (2) of the hatch . The working surface of the conical shell (17) smoothly mates with the working surface of the annular groove (16) and is made with a taper angle from 30 ° to 90 °.

The annular groove (16) can be made of several sections interconnected by welding, made of curved plates or pipe fragments. Figure 2 presents an embodiment of the armored camera, in which the annular groove (16) consists of 8 sections interconnected by welding. In this case, the side shell of the housing (1) should also be made of 8 plate sections interconnected by welding, each of which is welded with the adjacent section of the gutter (16). The octagonal shape of the side shell of the body (1) in this case determines the most appropriate form of the lower conical part of the body (1) in the form of 8 plate sections welded together, each of which is welded with the adjacent plate section of the side shell of the body (1). The number of sections (N) for the manufacture of hull elements depends on the size of the armored camera and on the technological capabilities of welding from thick-walled sheet metal. When the value of N is less than 6, the efficiency of using the working volume of the armored chamber decreases and the stress concentration increases when exposed to an explosion in the welds of the joints of the sections of the body of the armored chamber.

In accordance with the invention, the annular groove, the side shell and the lower part of the body of the armored camera can be made of another geometric shape with the achievement of the technical result described above. In particular, the side shell of the housing can be made in the form of a cylindrical shell, and the lower part of the chamber in the form of a truncated conical shell.

The armored camera works as follows. With the lid (3) open, a packet of pre-cooled tires (10) is loaded into the armored chamber through the loading hatch and mounted on brackets (11). An explosive charge (12) is introduced, equipped with a means for detonating it (14), and it is suspended inside the tire package along the axis of the housing (1) and the tire package (10) using means (13) made in the form of stretch marks. To neutralize harmful gases and cool the explosion products, a layer of water (19) or an aqueous solution is placed in an airtight shell on the outer surface of the charge. Covers (3) and (7) are closed and sealed with locking devices (4) and (8) using seals (5) and (9).

In the initial phase of the explosion, when the charge (12) is initiated by means (14), the detonation wave moves from the upper end of the charge (12) to its lower end. The resulting shock wave and gaseous explosion products move from the point of charge initiation in the direction opposite to the direction of propagation of the detonation wave, i.e. in the direction of the apex of the fairing cone (17). The shock wave and gaseous products of the explosion act on the fairing (17) at an angle to its working surface and are reflected from it without the formation of a shock load, which is typical for the impact of a shock wave normal to the surface of the obstacle. The shock wave and gaseous products of the explosion move along the working surface of the fairing (17), and then along the working surface of the annular groove smoothly conjugated with it (16). Since the shock wave falls on the working surface of the fairing (17) and on the working surface of the annular groove (16) at an angle of 30-90 °, the load on the upper part of the body of the armored camera (1) is reduced several times in comparison with the prototype, in which the shock wave on the top hatch cover runs normal, i.e. at an angle of 0 °.

After the interaction of the shock wave and the gaseous products of the explosion with the fairing (17) and the annular groove (16), a flow is formed in the direction of movement along the tangent to the side shell of the housing (1) of the armored chamber and further in the direction of the lower conical part of the housing (1). With such an impact of the shock wave and explosion products on the side shell of the housing (1), the parameters of the shock loads are significantly reduced. Then the shock wave is reflected from the lower conical part of the body (1) and the cover (7) of the discharge hatch and moves upward in the direction of the cowl (17) and the annular groove (16). Thus, at the initial phase of the explosion, an internal circulation of the shock wave and explosion products is formed in the armored chamber when they move from top to bottom tangential to the inner surface of the body of the armored chamber and from bottom to top in its center.

Under the action of the explosion on the tires (10), they expand in the radial direction until stresses and strains corresponding to the conditions of their destruction and the formation of the primary products of their destruction are reached. In this case, the tire destruction products interact with the circulation flow of the shock wave and gaseous explosion products formed at the initial phase of the explosion, which leads to their additional grinding.

Under the action of a charge explosion (12), the water layer located on its surface breaks up into finely dispersed fractions, which move together with the shock wave and heated gaseous products of the explosion to the surface of the tires (10). The finely dispersed fractions of water having a high heat capacity cool the explosion products and reduce the thermal effect of the explosion on tire grinding products to safe values (10), and also significantly reduce the concentration of harmful gases (CO and NO) that are present in gaseous products of the explosion.

After completion of the process of explosive grinding of tires using the device (15), the static component of the pressure of the gaseous explosion products is removed and the working volume of the armored chamber is aspirated. Then open the unloading hatch (7) and unload the product of grinding tires from the lower conical part (20) of the body of the armored camera.

The claimed invention significantly reduces the parameters of the impact of the shock wave on the most vulnerable elements of the wall of the armored chamber. This allows, without a significant increase in the metal consumption of the hull and while maintaining its high resistance to explosion, to significantly increase the working volume of the armored camera and expand the possibilities of its use. With the greatest effect, the inventive armored camera can be used for grinding typical tires with high grinding performance, as well as for grinding large diameter tires.

Claims (5)

1. Armored camera for grinding worn tires, comprising a housing in the upper central part of which a hatch with a cover for loading tires is made, and in the lower conical part of the housing there is a means for unloading solid products of grinding tires, means for placing tires, means for accommodating and undermining the charge explosive and means for removing gaseous products of the explosion, characterized in that the upper peripheral part of the body is made in the form of an inwardly facing annular groove, which is connected with a side shell of the body and with a shell of the hatch, a blast cowl is installed on the inner surface of the hatch cover, the working surface of which is predominantly conical in shape and smoothly interfaced with the working surface of the annular groove. 2. The armored chamber according to claim 1, characterized in that the fairing is made in the form of a conical shell with a taper angle of 30 ° to 90 °, which is mounted on the hatch with a cylindrical shell mounted concentrically relative to the shell of the hatch. 3. The armored chamber according to claim 1, characterized in that the annular groove is made of several sections interconnected by welding in the form of bent plate blanks or pipe fragments. 4. The armored chamber according to claim 3, characterized in that the annular groove is made of N sections welded together, the side shell of the body is also made of N plate sections connected to each other by welding, each section of the side shell is connected by welding to the adjacent section of the ring gutters, and the number N is chosen at least 6. 5. The armored chamber according to claim 4, characterized in that the lower conical part of the body is made of N plate sections connected to each other by welding, each section being connected by welding to the adjacent side shell section of the body.

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