RU2169899C1 - Method for initiation of deep-hole explosive charges - Google Patents

Abstract

FIELD: blast breaking of rocks at exploitation of mineral resources. SUBSTANCE: the method consists in the fact that before placement of a detonating cartridge in the deep-hole, loops are formed in the form of a twisted spiral with closed ends into a single continuous line of sections of the detonating cartridge with a length equal to the distance of the straight-line section of the detonating cartridge in the explosive charge between the spirals, determined by formula: L = 2D_CK•V_dc/(V_dc-V_BB), where L - distance between spirals; D_CK-diameter of deep-hole explosive charge; V_dc- detonation speed of the detonating cartridge; V_BB-detonation speed of the explosive charge. The spiral coils are formed by fixation in a bundle, use is made of a spiral with 4 coils. EFFECT: enhanced efficiency of rock breaking. 2 cl, 2 tbl, 2 ex

Description

 The invention relates to blasting in the mining industry and is intended for explosive blasting of rock during the development of minerals or the construction of facilities for various purposes.

 A known method of initiating borehole charges, comprising placing a detonating cord (LH), an intermediate detonator in the charging well and supplying an initial impulse along the LH (Rzhevsky V.V. Opencast mining processes. M., Nedra, 1978, P. 91).

 However, the known solution does not provide an increase in the degree of crushing of rocks due to the multifaceted superposition of shock waves of a borehole charge.

 The closest in the set of essential features is the method of initiating borehole explosive charges, including displacing in the charging borehole LH in the form of alternating rectilinear sections and ring loops and supplying an initial impulse along the LH. Moreover, the LH loops are placed in a vertical plane and placed at the external, relatively destructible array, wall of the charge, with each loop being formed with a diameter equal to 0.5 of the diameter of the charge, with a distance between them equal to the diameter of the charge. (Patent RU 2138771, IPC F 42 D 3/04, BI N 27, 1999).

 However, this method does not sufficiently provide an increase in the efficiency of rock breaking, since the initiation of borehole charges of granular and water-filled explosives from a detonating cord often leads to failures, the output of oversized materials and a decrease in the degree of crushing of rocks.

 The main objective of the invention is to increase the efficiency of rock breaking due to the creation of a powerful initiating impulse of the imposition of detonation waves, which lead to a significant reduction in failure of downhole charges, increase the degree of crushing of rocks and increase the productivity of mining equipment.

где L - расстояние между спиралями;
D_СК - диаметр скважинного заряда ВВ,
V_ДШ - скорость детонации ДШ;
V_ВВ - скорость детонации заряда ВВ.To solve the problem in a method of initiating borehole explosive charges, which includes placing the DS in the charging well in the form of straight sections and ring loops, as well as supplying the initial impulse along the DS, the loops are formed in the form of tightly twisted turns of spirals with closed the ends into a single continuous annular line of segments of LH with a length equal to the distance of the rectilinear section of LH in the explosive charge between the spirals, which is determined by the formula;

where L is the distance between the spirals;
D _SK - the diameter of the borehole explosive charge,
V _LH - detonation velocity LH;
V _BB - detonation velocity of the explosive charge.

 The turns of the spiral are formed by fixing into a bundle, and a spiral of four turns is used.

 The implementation of the ring loops in the form of tightly twisted turns of a spiral with closed ends into a single continuous ring line of segments of the LH allows you to perform the functions of an intermediate detonator, as well as to increase the power and reliability of the initial detonation pulse of the explosive well charge.

 The closure of the ends of the DS segment into a single continuous ring line eliminates the interruption of the detonation wave in this separate spiral coil, and with it the detonation wave with a power exceeding the multiplicity of detonation waves of a separate ring loop will be formed in the beam of spiral spirals, since it does not closed in a continuous ring line located in one plane, and because the ring shock wave creating a cumulative effect will have a sector of action in different planes.

 The detonation wave, which passed through the rectilinear section of the DS before erasing, will initiate detonation at the point of contact in all the turns simultaneously in two directions. The meeting of detonation in the coils of the spiral will occur in the plane passing through the middle of the beam of coils of the spiral. At the same time, a detonation wave will form around the bundle of spiral turns in the explosive of the borehole charge. It will be created especially powerful at the point where the shock waves meet, as a result of which a very powerful detonation wave will be created with a cumulative effect in the direction normal to the plane of the spiral, thereby turning the spiral into a powerful intermediate detonator of borehole charge BB.

The maximum effect of explosive crushing of rocks by borehole charges is obtained by setting the parameters of the blast detonation wave, which provides multiple encounters in the section of the borehole explosive charge and the imposition of stress waves with a powerful destructive amplitude in the rock mass from the action of intermediate detonators-spirals. The action of stress waves in the rock mass from the meeting of powerful explosive detonation waves of the lower and upper intermediate detonator is observed along a broken line on the wall of the well starting from a point located on the straight section of the LH at a distance equal to D _SK from the lower intermediate detonator-helix. Under these conditions, the effect of superposition of shock waves, which ensures the creation of a powerful destructive amplitude, will be maximally formed.

 The second extreme point of the broken line of the shock wave meeting will be located on the opposite wall of the well on a perpendicular dropped from the first extreme point.

где V_ВВ - скорость детонации ВВ скважинного заряда, м/сек;
V_ДШ - cкорость детонации ДШ, м/сек.Thus, a shock wave meeting will be formed from two directions located on a rectilinear section of the LH at a distance equal to 2D _SC . We denote the distance between two adjacent intermediate detonators-spirals through L, then during the passage of detonation along the LH from one intermediate detonator to the second detonation along the explosive of the borehole charge, the distance will pass

where V _BB - detonation velocity of the explosive of a borehole charge, m / s;
V _DS - speed detonation DS, m / s.

Из полученного равенства

получим

Используя величину расстояния между промежуточными детонаторами-спиралями больше чем

получим на одной и той же длине скважинного заряда меньшее кoличествo промежуточных детонаторов-спиралей и вместе с этим меньше наложений ударных волн с мощной разрушительной амплитудой, что ведет к снижению степени дробления горных пород.And finally, the remaining distance between adjacent spiral detonators will be

From the resulting equality

we get

Using the distance between the intermediate detonators-spirals more than

we get a smaller number of intermediate detonators-spirals on the same length of the borehole charge and, at the same time, less overlap of shock waves with a powerful destructive amplitude, which leads to a decrease in the degree of crushing of rocks.

будем иметь частично встречное наложение ударных волн и частично догоняющее наложение ударных волн, что естественно при встречном ударе двух предметов кинетические силы складываются и при догоняющем ударе они вычитаются.When using the distance between the intermediate detonators-spirals less than

we will have a partially counterposition of shock waves and partly catch-up imposition of shock waves, which is natural when the counter impact of two objects, the kinetic forces add up and they are subtracted when catching impact.

обеспечивающая пропорциональное наложение ударных вoлн с мощной разрушительной амплитудой, создающей высокую степень дробления горных пород и высокую производительность горного оборудования (см. табл. 1).Thus, the optimal distance between the intermediate detonators-spirals will be a value equal to

providing proportional superposition of shock waves with a powerful destructive amplitude, creating a high degree of crushing of rocks and high productivity of mining equipment (see table. 1).

 The diameter of the intermediate detonator-spiral is set from the condition of the critical diameter of the explosive charge. Reducing the diameter of the spiral from the set value leads to a decrease in the force of the cumulative effect due to the small amplitude of the shock wave of the intermediate detonator, which can lead to the appearance of failures in the detonation of the borehole explosive charge.

 For the most common explosives used in well bores (granulites, granulites, see Rzhevsky V.V. Open-pit mining processes. M., Nedra, 1978, p. 86), the ratio of the diameter of the blast hole charges common in open-pit mining to the critical diameter is approximately 1: π = 3.14. The number of turns of the helix of the intermediate detonators is taken to be 4. This is the optimal number of turns based on, firstly, from practical implementation, and secondly, from ensuring the elimination of failure initiation of borehole charges and, thirdly, due to the high degree of crushing (see table . 2).

тогда упрощенный вариант расстояния между промежуточными детонаторами-спиралями составляет L=4D_ск. Заменяя D_ск= πd_сп, где d_сп - диаметр спирали, будем иметь L = 4πd_сп, а это есть условие равенства между собой расстояния между промежуточными детонаторами-спиралями и длиной отрезков ДШ, из которых формируют витки спирали промежуточного детонатора.Using the conditions of the differences in the detonation velocities of the heating element and explosives used in borehole charges (see Hanukaev A.N. Physical processes during rock breaking by an explosion. M., Nedra, 1974, p. 179, and also see Brief Guide to the Use of Grammonite 79 / 21 for blasting, Gosgortekhnadzor 1971, p. 2) we have

then a simplified version of the distance between the intermediate detonators-spirals is L = 4D _SK . Replacing D _ck = πd _cn , where d _cn is the diameter of the spiral, we will have L = 4πd _cn , and this is a condition for equality between the distances between the intermediate detonators-spirals and the length of the segments of the LH, from which the spiral coils of the intermediate detonator are formed.

 The method is as follows.

Example 1. The field of building materials is developed in an open way. Dolomite rocks of category 8 according to SNIP. Drilling and blasting operations are carried out during overburden and mining operations. Well depth - 15 m. Blasting holes are carried out by SBSh drilling rigs - 250 MN with a diameter of 269 mm. The distance between the wells in the row is 6.5 m. The distance between the rows of wells is 6.5 m. The line of least resistance along the bottom of the ledge is 7 m. The actual output of the rock mass from one well is 525 m ³ . For blasting use explosive borehole charge grammonite 79/21. As the initiator, they use LH and intermediate detonators, consisting of two TNT blocks 400 each located in the upper and lower parts of the borehole charge. Between the intermediate detonators, they are arranged in the form of alternating rectilinear sections and circular loops in a vertical plane and placed at the outer wall of the charge wall that is destructible, each loop being formed with a diameter equal to 0.5 of the diameter of the charge, with a distance between them equal to the diameter of the charge.

The bottleneck in the quarry - crushing and screening system is the screening department of the factory. Daily production of the quarry system - crushing and screening plant 1280 m ³ . The output of oversized pieces is 5%.

 Example 2. The developed field and technology are similar to those shown in example 1.

,
равным 1 метру, приклеивают клеящей лентой (скотчем или изоляционного лентой) промежуточные детонаторы-спирали из ДШ. Причем клеящей лентой делают два - три оборота вокруг прямолинейного участка ДШ, затем прикладывают промежуточный детонатор-спираль и еще делают два - три оборота, прикрепляя его так к прямолинейному участку ДШ. Предварительно заготавливают промежуточные детонаторы-спирали в виде плотно скрученных витков с замкнутыми концами в единую непрерывную кольцевую линию из отрезков ДШ длиной

,
равной 1 метру. Для этого концы отрезка ДШ замыкают клеящей лентой, сформировав из него кольцо. Далее, свернув его, делают восьмерку, а затем, соединив два кольца восьмерки друг к другу, получают плотно скрученную спираль в два оборота, на следующем этапе из нее сворачивают вторую восьмерку и получают плотно скрученную спираль диаметром

0,079 метра или 79 мм в четыре оборота и последним действием фиксируют промежуточный детонатор-спираль клеящей лентой с двух противоположных сторон с последующей подачей начального импульса по ДШ. Скорость детонации ДШ с тэновой сердцевиной составляет 7420 м/с, а скорость детонации граммонита 79/21 примерно в два раза меньше и составляет 3400 м/с.The initiator of the core charge is as follows. On a detonating cord, departing from the lower intermediate detonator made of two TNT blocks with a step determined by the formula

,
equal to 1 meter, glued with adhesive tape (scotch tape or insulation tape) intermediate detonator spirals from LH. Moreover, adhesive tape is used to make two to three turns around the rectilinear section of the DS, then an intermediate detonator-spiral is applied and another two to three turns are made, attaching it to the rectilinear section of the DS. Preliminarily prepare intermediate detonators-spirals in the form of tightly twisted turns with closed ends into a single continuous annular line of lengths of LH

,
equal to 1 meter. For this, the ends of the DS segment are closed with adhesive tape, forming a ring from it. Then, turning it, make a figure eight, and then, connecting two rings of figure eight to each other, get a tightly twisted spiral in two turns, at the next stage, turn the second eight from it and get a tightly twisted spiral with a diameter

0,079 meters or 79 mm in four turns and the last action fix the intermediate detonator-spiral with adhesive tape from two opposite sides with the subsequent supply of the initial impulse along the LH. The detonation velocity of a DW with a tena core is 7420 m / s, and the detonation velocity of grammonite 79/21 is approximately two times less and amounts to 3400 m / s.

0,000017с или 0,017 мс
Одновременно вокруг пучка витков промежуточного детoнaтopа-спирали формируется мощная детонационная волна в ВВ скважинного заряда. Особенно мощной она будет в плоскости, проходящей через середину пучка витков промежуточного детонатора-спирали в направлении по нормали, т.е. к середине окружности витков спирали.The detonation meeting in the turns of the intermediate detonator-helix will occur through

0.000017s or 0.017 ms
At the same time, a powerful detonation wave is formed around the bundle of turns of the intermediate detonator-helix in the explosive of the borehole charge. It will be especially powerful in the plane passing through the middle of the coil of turns of the intermediate detonator-spiral in the normal direction, i.e. to the middle of the circle of the spirals.

The meeting of powerful detonation in this plane will occur at a point located on the diameter drawn through the point of contact of the spiral and the straight line segment L. Half the circumference of the spiral turns is
πd _c / 2 = (3.14 • 0.079) / 2 = 0.124 m
At the moment of the detonation meeting in the spiral turns, the detonation wave along the line passing through the diameter line will be at the point
(πd _s / 2) × (3.4 / 7.42) = 0.057 m,
since the detonation velocity of the explosive of a borehole charge is almost two times less. At the remaining distance of the diameter, the detonation velocity will be the same. Then the point at which the annular meeting of the powerful detonation wave occurs, turning into a cumulative effect, will be located 0.057+ (0.079-0.057): 2 = 0.068 m on the diameter line perpendicular to the point of contact of the spiral with the rectilinear section. The time after which the cumulative effect will occur is 0.068: 3.4 = 0.02 ms from the time the detonation wave contacts the spiral.

 The time taken for the detonation wave to pass along the LH distance between two adjacent intermediate helical detonators will be 1: 7.42 = 0.135 ms. During this time, the detonation blast wave of the main borehole explosive charge from the first intermediate detonator-spiral in the direction of the second will pass a distance of 3.4 x 0.135 = 0.459 m. At the remaining distance between the intermediate detonators-spirals of the main borehole charge, exactly in the middle, the shock waves will meet borehole explosive charge at a distance (1 - 0.459): 2 + 0.459 = 0.73 m, and the distance from the point of contact of the lower spiral to the point of impact of the shock waves vertically will be 0.27 m.

The proposed method in comparison with the prototype allows to increase the degree of crushing of rocks and, as a result, to increase the productivity of the quarry - crushing and screening plant up to 1640 m ³ per day. The oversized yield from failed wells under these conditions decreased to 0.

Claims (2)

1. A method for initiating borehole charges of explosives (BB), comprising placing in a charging well a detonating cord (LH) in the form of alternating rectilinear sections and ring loops and supplying an initial impulse along the LH, characterized in that before placing the LH in the charging well, the loops are formed into in the form of tightly bonded turns of a spiral with closed ends into a single continuous annular line of segments of LH with a length equal to the distance of the rectilinear section of LH in the explosive charge between the spirals, which is determined by the formula

where L is the distance between the spirals;
D _SK - the diameter of the borehole explosive charge;
V _LH - detonation velocity LH;
V _BB - detonation velocity of the explosive charge.  2. The method according to claim 1 is characterized in that the turns of the spiral are formed by fixing into a bundle, and a spiral of four turns is used.

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