RU115061U1 - DEVICE FOR OBTAINING AXIAL CAVITY IN A BOREHOLE CHARGE OF EXPLOSIVES - Google Patents

Abstract

A device for creating an axial cavity in an explosive charge, containing a retainer, a nylon rope for lowering the device into the borehole, a hollow shell of separate sections and tendrils for centering the device in the borehole, characterized in that it contains a telescopic hollow structure of pipes with the possibility of sliding or expanding them under its own weight and fixing in a vertical position, the ends of which are closed with lids interconnected with a strong thread, while the length of this thread is less than the total length of all pipes, but not more than the length of the unfolded device, inside which it is located.

Description

The utility model relates to the mining industry, namely to the technique of blasting on the surface, and can be used for blasting using air cavities in a charge of explosives (hereinafter referred to as explosives), for example, in a downhole charge from granular or emulsion industrial BB

To create air cavities in the borehole charge, hollow devices are preliminarily placed in the borehole, and then the borehole is charged with industrial explosives. The presence of air cavities in the borehole charge changes the nature of the impact of the explosion products and creates conditions for increasing the useful use of explosive energy. The initial pressure decreases, the time of their impact on the destructible array increases. This allows you to redistribute the energy of the explosion in the direction of reducing the fraction going to the regrinding of the rock near the charge and increasing the fraction going to crushing the rock mass.

A device is known for creating an axial cavity in an explosive charge, containing separate sections made in the form of hollow cylinders with a diameter of 110 mm and a length of 2 m, the last cylinder being equipped with a plug (Well charges of explosives with an axial air cavity / V.A.Salganik, G. A. Vorotelyak, V.V. Mitrofanov, N.F. Filippov. - K.: Technika, 1986, p. 63).

The main disadvantage of the known device is the significant complexity of the formation of the borehole charge and the increase in the time of loading the explosive well, as well as its low efficiency during blasting, since as a result of filling the explosive well in separate portions, it does not ensure uniform distribution of the explosive around it.

A device is known for creating an axial cavity in an explosive charge, including a pipe with a diameter of 80 mm and a length of 12.5 m from cardboard 1 mm thick and a nylon rope for lowering the device into the well (Well charges of explosives with an axial air cavity / V.A.Salganik , G.A. Vorotelyak, V.V. Mitrofanov, N.F. Filippov. - K .: Technika, 1986, p. 58).

A disadvantage of the known device is its operational properties, since pipes, due to their large sizes, take up a lot of space, which presents certain difficulties and inconveniences during their transportation and storage. Moreover, the cardboard in such devices has low strength, while such a material well absorbs water and liquid petroleum products. In this regard, there is a high probability of spontaneous combustion of cardboard upon its contact with ammonium nitrate, especially with its solutions. At the same time, cardboard has a low combustion temperature (16,700 kJ / kg), which reduces the effectiveness of its participation in an explosive reaction when blasting rocks.

The task to which the claimed technical solution is directed is to expand the arsenal of technical means in this area, as well as to increase the usability of the device. The solution to this problem is achieved due to the fact that the device contains a telescopic sheath made of secondary aluminum pipes with the possibility of their folding or decomposition, the ends of the device are closed with covers interconnected by a strong thread inside it, and the length of this thread is less than the total length of all pipes, but not longer device length when unfolded.

As a secondary aluminum, it is supposed to use the previously used sheet aluminum for offset printing with sheet thicknesses from 150-300 microns. This aluminum has low strength (tensile strength 50-60 MPa) and hardness (170 MPa, according to Brinell), but high ductility (up to 50%). In air, aluminum is coated with a thin, durable film that protects the metal from further oxidation and corrosion.

Using a device made of aluminum together with granular and emulsion explosives allows not only to improve the explosive properties of the resulting charges due to the high heat of combustion of aluminum (8800 kJ is released during the “burning” of aluminum in water per 1 kg of products; this is 1.8 times less than with metal combustion in pure oxygen, but 1.3 times more than when burning in air), but also to increase the safety of blasting, since aluminum is resistant to the action of various types of natural waters, nitric and organic acids.

The essence of the utility model is illustrated by its images in the form of a drawing and photographs, where Fig. 1 shows a schematic drawing of a device, Fig. 2 shows an unassembled device, and Fig. 3 shows an assembled device.

The device (drawing in figure 1) contains a latch (tube) 1, which provides tension to the rope 2, connected with the top cover 3 with the antennae 4 of the telescopic shell, consisting of individual pipes 5, the last pipe of which is closed by a cover 6 with antennae 7 connected inside the device with top cover thread 8.

The length and diameter of the device is selected based on the length and diameter of the wells. Investigations in production conditions have established that these conditions correspond to a device length of 2 to 6 m and a diameter of 0.03 to 0.12 m.

The device operates as follows. Stationary device is in a folded state. In the process of loading the well with explosive, the user first lowers the device into it, while the pipes automatically come out of each other. The device is fixed by antennae in the center of the well, and with the help of a thread and a clamp, which is installed on the wellhead, remains in the unfolded state. Then, an explosive enters the well, an industrial detonator and a stemmer are lowered, i.e. downhole charge is formed. Then blasting is carried out in the usual manner.

Using a technical solution according to the utility model allows to improve the operational properties of the devices due to the possibility of their addition or decomposition and the reliability of efficient blasting of borehole charges of industrial explosives.

Claims (1)

A device for creating an axial cavity in an explosive charge, comprising a retainer, a nylon rope for lowering the device into the well, a hollow shell of separate sections and antennae for centering the device in the well, characterized in that it contains a telescopic hollow structure of pipes with the possibility of their sliding or sliding under its own weight and fixation in a vertical position, the ends of which are closed by covers interconnected by a strong thread, while the length of this thread is less than the total length of all pipes, but not more Other devices in the unfolded form, inside which it is located.