BOREHOLE PLUGGING DEVICE

Abstract

The invention relates to the field of drilling and blasting operations, and more particularly to confining gaseous explosion products in a charge cavity, and can be used in rock blasting using borehole charges. The technical result of the invention is that of reducing the specific charge of explosive per cubic metre of blasted rock mass, increasing the fragmentation of the rock mass, making it possible for explosive to be loaded into and work effectively in a borehole with excess water pressure (flooded boreholes), providing ease of use and structural simplicity, providing ease of transportation and storage since the device can be dismantled to compact dimensions, and reducing the weight of the structure. A further technical result is the possibility of using devices of a single type in boreholes of different lengths and types (flooded or non-flooded), thus making it possible for the claimed device to be used as a universal device for all types of boreholes. The above-mentioned technical result is achieved in that the claimed borehole plugging device, which is made of a pliable polymer material and has elements with a shape, the outside diameter of which is commensurate with the diameter of a borehole, and an axial internal cavity, is characterized in that it consists of a rod with a cruciform cross section, having identical dome-shaped, slotted elements fixably mounted thereon from each end.

Description

The invention refers to the sphere of drilling sod blasting operations, in particular to the confining of the gaseous explosion products in the charge cavity and can be used in rock blasting with borehole charges.

Well-known is borehole stemming with small stuff, etc. Increasing the exposure time of the blasted rock mass to the expending gaseous explosion products (B. N. Kutuzov Blasting operations. M., Nedra, 1988, p.223).

Stemming of big diameter boreholes is also known (RF Patent No. 2122178, 6 F 42 D Jan. 20, 1998) with a cylinder with internal hollow of hemispherical shape aligned with frustum, the material of which includes a salt of an alkaline earth metal (prototype). The stem is made of high-pressure polyethylene as plasticizing agent.The drawback of such structure is rather rigid external surface of the item. Since different rock types have different drillability and quality of the borehole internal surface, this leads to difficulties of the stem positioning inside the borehole. In addition, increased stem diameters require increased materiel quantities for manufacturing of one item, with a consequence of increased item price, whereas the existing methods of dye-casting and moulding do not allow for fast manufacturing of large batches of such items with high quality.The closest similar item is borehole stem (patent RU2223S84, published on May 5, 2004), made of pliable polymer material, of cylindrical shape, with OD commensurate with the borehole diameter, with axial protruded hemispherical inner cavity in conjunction with frustum, immediately adjoining the explosive charge, with a difference of the cylinder being hollow and thin wall type, thereby the above-mentioned axial inner cavity has a shape of a thin-wall funnel of the wall thickness equal to that of the cylinder walls and made of the same material, thereby the gap between the funnel and the cylinder is filled with inert material. The prototype allows for increased efficiency and reduced costs of drilling and blasting operations by confining the explosion products in the charge cavity up to the complete destruction of the rock mass.The known solutions have common problems sf complicated design, inconvenience of shipment and storage due to poor dismountabiilty to compact size pieces, relatively big weight of the stemming, poor efficiency of the borehole charge.

It Is the goal of the Invention to rectify the above-stated drawbacks by means of replacement of the currently practiced technique of borehole stemming by the subject borehole plugging device.

The technical result of the invention is that of the reduced specific charge of explosive per one cubic meter of blast rock, increased fragmentation of the rock mass, making it possible for explosive to be loaded into and work effectively in a borehole with excess water pressure (flooded boreholes), providing ease of use and structural simplicity, providing ease of transportation and storage since the device can be dismantled to compact dimensions, and reducing the weight of the structure.

A further technical result is the possibility of using devices of a single type in boreholes of different lengths and types (flooded or nan-flooded), thus making It possible for the claimed device to be used as a universal device for ail types of boreholes.

The above-mentioned technical result is achieved in that the claimed borehole plugging device, which is made of a pliable polymer material and has elements with a shape, the outside diameter of which is commensurate with the diameter of a borehole, and an axial internal cavity, is characterized in that it consists of a rod with a cruciform cross section, having identical dome-shaped slotted elements fixed mounted thereon from each end. Preferably, the dome-shaped elements contain flanges by means of which they are fixed in the dents of the rod. Preferably, the dome-shaped elements are shaped with lobes. The lobes are preferably of varying length with each long lobe between two short lobes.

Preferably, from 2 to 4 dome-shaped elements are feed on one rod. Preferably, the dome elements are shaped with symmetrical arrangement of slots.

CONCISE DESCRIPTION OF DRAWINGS

FIG. 1 shows the borehole plugging device in one of possible design variants from different points of view in 3D.

FIG. 2 shows the principle of the conjunction of the dome-shaped element on the rod. FIG. 3 shows an example of the fitting of the borehole plugging device in a borehole. FIG. 4 to FIG. 6 show measurement protocols of experimental blasting using the borehole slugging device.

In the drawings: 1—rod, 2—dome-shaped element, 3—rod dent, 4—flange of the dome-shaped element for seat on the dent, 5—ignition channel, 6—discharge channel, 7—big contact, 8—small contact.

IMPLEMENTATION OF THE INVENTION

Stemming is the process of filling with inert material of a part of the charge cavity; the inert material itself used to confine the explosive charge, to reduce the scattering range of the splitters is also called “stemming”. Stemming is used to “lock” the explosion products, to increase the efficiency of the explosion. The borehole plugging device, as stated in the claimed solution, is a replacement for the existing method of stemming.

The borehole plugging device (see FIG. 1) consists structurally of three elements: the rod (1) and at least two dome-shaped elements (2), one of which is fixed on the rod from one end and the other one on the other rod end. The cross-section of the rod is cruciform. Such solution allows for the required strength of the structure with simultaneous reduction of the material quantity for the manufacturing of the rod. Thus, the weight of the structure is less whereas the manufacturing is simplified.For fixation of the dome-shaped elements (2) the rod (1) can feature dents (3) (notches) in the places of the upper and the lower connection of the dome-shaped elements. For fixation of the dome-shaped elements (2) on the rod (1) by these dents (3), the dome-shaped elements (2) can feature flanges (4) for their retention (see FIG. 2).The rod (2) of the borehole plugging device can envisage mounting of two to four dome-shaped elements (2). Also, the rod design provides for using the borehole plugging device completely assembled within a large range of diameters. Thus the fragmentation of the rock mass in the open terrain depends on a multitude of factors, e.g., the geology, the type of the explosive utilized, the development design, the drilling equipment, on the diameters of the boreholes drilled. The operation diameters of the borehole plugging device are assigned to the borehole diameters ranging from 65 to 270 mm. The rod of the structure is unchangeable whereas the lobes get together on the rod depending on the borehole diameter.In flooded boreholes or where the borehole length exceeds 15 m, 3 to 4 dome-shaped elements with slots are mounted on the rod. These slots can also be of lobe shape, including also those symmetrical relative to the centre axis. At lobes of different length with the arrangement of each long lobs between the short ones, the slots of the structure of the borehole plugging device ensure at fitting in the borehole such structural features, which are shown in FIG. 3—fitting of the borehole plugging device in the borehole. The big contact (7) goes through the big lobe, the small contact (8) goes through the small lobe. In the slots between the lobes, there is the discharge channel (6) letting out the shock wave from the ignition channel (5).The slots, e.g. as lobes of the borehole plugging device are intended for direct contact with the borehole walls in such structure with diameters ranging from 130 to 170 mm. The small contacts (8) ensure optimal angle of attack and angle of resistance within the range of diameters 130 to 150 mm.

The big contacts (7) ensure optimal angle of attack and angle of resistance within the range of diameters 150 to 170 mm. The design of the borehole plugging device envisages channels for ignition means (5) whereas such solution protects the ignition means during the propulsion of the structure through the borehole.

The discharge channel (6) is intended for discharge of the initial pressure (piston effect). In case of a borehole with excessive water pressure, the discharge channels let the water flow but the explosive remains in the charge cavity of the borehole.

In the course of experimental tests on industrial basis in the enterprises of the mining branch, the borehole plugging device utilised in the borehole charges as stemming device, has demonstrated the following results:

• • reduced specific charge of explosive per cubic meter of blasted rock mass;
  • Increased fragmentation of the rock mass;
  • possibility of charging and full-scale operation of the explosive in a borehole with excessive water pressure (flooded boreholes).
  • comfort in use, shipment and storage due to dismantling down to compact dimensions;
  • reduced weight of the structure.

FIG. 4 to FIG. 6 shows the results of the measurement during tests of the borehole plugging device. They demonstrate that the detonation velocity in the experimental boreholes is almost the same, however slightly slower detonation is observed in boreholes with the borehole plugging device.

Claims

1. Borehole plugging device is made of pliable polymer material and features shaped elements the outer diameter of which is commensurate with the borehole diameter, with an axial inner cavity consisting of a rod with cruciform cross-section, on both ends of which uniform dome-shaped elements with slots can be fixed.

2. Borehole plugging device similar to that of pos. 1 with a difference that the dome-shaped elements feature flanges by means of which and a retainer they are fixed in the dents formed in the rod.

3. Borehole plugging device similar to that of pos. 1 with a difference that the dome-shaped elements have lobe form.

4. Borehole plugging device similar to that of pos. 3 with a difference that the lobes are of varying length with arrangement of each long lobe between the shorter ones.

5. Borehole plugging device similar to that of pos. 1 with a difference that there are 2 to 4 dome-shaped elements fixed on the rod.

6. Borehole plugging device similar to any of pos. from 1 to 5 with a difference that the dome-shaped elements feature symmetrical arrangement of the slots.