KR100312349B1 - V-cut blasting method with stage advanced blasting - Google Patents

Abstract

The present invention relates to a step-by-step forward v-cart blasting method, to prevent the blasting efficiency decrease due to the poor spacing of the main core blasting, and to prevent excessive blasting vibration due to concentrated charges, Its purpose is to be able to remove the restrictions of the mill due to the increase in the size of the crushed stone. The present invention configured for this purpose is an auxiliary core hole which is formed to be symmetrically at a predetermined inclination angle with respect to the vertical line of the main surface between the main core and the main core hole, which is formed to be symmetrically at a predetermined inclination angle with respect to the free surface vertical line of the membrane surface. And drilling a vertical heart hole formed perpendicular to the center of the membrane surface between the main heart hole and the auxiliary heart hole on the same line, and having the main heart ball and the secondary heart in the same line on both sides of the same heart line of the main heart ball, the auxiliary heart ball and the vertical heart hole. Punch the ball and vertical heart hole, and load the medicine in one stage at the bottom of the main and secondary heart hole, and load the medicine in two stages in the vertical heart hole. It consists of a step-by-step configuration from deep to deep. On the other hand, perforated vertical inclined hole formed perpendicularly to the center of the inclined plane between the inclined heart hole and the inclined heart hole formed at a predetermined inclination angle with respect to the free surface vertical line of the membrane face, and inclined Drill inclined and vertical heart holes on the same line on both sides of the same and vertical heart hole, and load one step into the perforated bottom of each inclined and vertical heart hole. It may be made of a configuration.

Description

V-CUT BLASTING METHOD WITH STAGE ADVANCED BLASTING}

The present invention relates to a step-by-step progressive V-cart blasting method for performing a heart attack, and in particular, to charge / detonate a blast hole perforated in a tunnel face to drill a tunnel, prior to the explosion of all blast holes, It relates to a step-by-step v-cart blasting method that improves the blasting efficiency by improving the perforation pattern in forming the (core).

In general, a center cut is a tunnel drilling blast that drills an explosive hole at an angle to the adjacent surface of the tunnel at about the center of the drilling surface, and loads as many explosives as possible before detonating all the blasts. It is best to be located under the center of the tunnel, but it should be moved accordingly according to the result of blasting.

If you look at the form of heart, it can be divided into an angle cart and a parallel cart, and the angle cart can be divided into a V-cart, a pyramid cart, a fan cart, a draw cart, and a swing cut. Parallel carts can be further divided into Burn Cut and No Cut. The heart can be located anywhere on the free surface, but preferably slightly below the center or center of the cross section.

The heart position can be changed by the movement of the stones, explosive consumption, the number of perforations and the surrounding facilities. When drilling by jumbo, etc., the position is easier to drill than the height. When drilling by rock hammer, etc., the height of the worker is related, so the height is from 1.0m to 1.7m from the ground wall, but from 1.2m to 1.5m Many times.

If the position of the heart is as low as possible, the stone does not scatter far enough to facilitate the loading work and protect the side wall wires and pipes, but the stone is slightly larger and cut off is more likely to occur where there is a joint. . On the other hand, if the position of the heart is high, the size of the stone is small, but the flying distance is farther away. In places where there are joints, stratifications, and conveniences, it may be biased to the right or left side from the center in consideration of being easy to be broken. It may be.

The medicinal pier and armed medicinal holes are punched in the heart, and the reason for putting armed medicinals around the medicinal pill is to make the circumference of the medicinal pill more effective at blasting. The pore size of the armed pharmacy affects the excavation field per blast. The most important component to make the blasting well in the excavation duct is the size of the armed pharmacy. If you increase the respect and deepen sympathy of the armed pharmacy, you can expect a good excavation. Shorter progression means that armed pharmacy is too small for the public. At this time, when loading the first cardiac cavity adjacent to the armed pharmacy, if the charge density is too high, the opposite wall of the armed pharmacy will cause the stone to be shocked at a very high speed, and the rock fragments are filled there. Thus, the subsequent blasting will not be able to play the role of the armed pharmacy, and the complete blasting will fail. In particular, in the case of soft rock, such a phenomenon occurs, it is preferable to avoid exaggeration.

Excavation site refers to the standard of rock that is destroyed at every blasting in excavation, excavation, excavation, tunnel or horizontal tunnel excavation. In the case of blasting, excavation is shorter than fabric factory because there are 10-20cm of residual holes. The fabric mill is determined by the size of the tunnel, the working cycle, the size of the strut, the length of the rod and the blasting method.

When the explosives explode in the case of one free surface in the normal closed hole, the destruction of rock is crushed and enlarged by the impact and shock wave caused by the high-speed ejection of gas after the explosion. The next step is that the pressure of the explosive gas creates a stress distribution in the rock, causing the explosive gas to penetrate the crack created by the dynamic effect. The force that the rock withstands the tensile force is about 1/10 to 1/20 of the force that resists the compressive force, so that the fracture is performed by the tensile force.

The rock is affected by explosive detonation in three stages. The first stage starts at the detonation point, and the blast hole is expanded as the blast hole is broken. In the second stage, compressive stress waves diverge in various directions at the same speed as sound waves into the rock. If this compressive stress exceeds the tensile strength of the rock when it comes back in the opposite direction after it reaches the free surface (the surface where the rock is in contact with the outer world), the resistance line (from the blast to the free surface from the center of the charged explosive) In the distance, rocks are destroyed. The third step is that the gas released between the cracks (cracks) formed under high pressure enlarges the gap. If the distance between the loader and the free surface is calculated correctly, the rock between the loader and the free surface will break and move the rock forward. The explosive reaction is very fast in the loader, and if it expands up to 10 times the original volume of the loader in about 5 ㎳, the explosive can be considered to have worked completely and effectively.

On the other hand, the above-mentioned V-cart is a type of tongue blasting as a type of heart blasting, a method of extracting the tongue (V-type) rock by drilling the heart hole at an angle from left and right.

1 is a perforated pattern diagram of a conventional double v cart.

As shown in FIG. 1, the conventional V-cart blasting pattern is inclined at about 70 ° with respect to the free surface 1 of the membrane to laterally symmetrically or more than 1.6 m of the main core holes 10 and 10a. The perforation bottoms 12, 12a of (10, 10a) are located in a straight line, and the space between the perforation bottoms 12, 12a is within 20 cm. Inside the main core hole (10, 10a) is a secondary core hole 20, 20a having the same slope as the main core hole (10, 10a).

In the perforated V-cart as described above, the crushing of the perforated bottom part is performed very poorly after the blasting operation, excessive blasting vibration occurs due to the concentration charge, and there is a problem that the size of the crushed stone becomes too large.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a step-by-step forward V-cart blasting method to prevent the blasting efficiency decrease due to the poor spacing of the main core hole.

Another object of the present invention is to be able to prevent the excessive blast vibration caused by the concentrated charge.

In addition, another object of the present invention is to provide a step-by-step advanced V-cart blasting method that can remove the restrictions of the mill due to the increase in the size of crushed stone.

1 is a perforation pattern diagram of a conventional double v cart blasting method.

Figure 2 is a perforated pattern of the step-by-step progressive V-cart blasting method according to the present invention.

Figure 3 is a charge and detonation pattern showing a first embodiment of the step-by-step forward V Cart blasting method according to the present invention.

Figure 4 is a charge and detonation pattern showing a second embodiment of the step-by-step progressive V-cart blasting method according to the present invention.

Figure 5 is a charge and detonation pattern showing a third embodiment of the step-by-step forward V Cart blasting method according to the present invention.

Figure 6 is a charge and detonation pattern showing a fourth embodiment of the step-by-step forward V Cart blasting method according to the present invention.

7 is a charge and detonation pattern showing a fifth embodiment of the step-by-step progressive V-cart blasting method according to the present invention.

8 is a flow chart showing a step-by-step progressive V-cart blasting method according to the present invention.

** Description of symbols for the main parts of the drawing **

100. Free face 110, 110a. Referee

112, 112a. Perforation bottom 120, 120a. Assistant Heart Ball

122, 122a. Perforation bottom 130. Vertical heart hole

132. Perforation 200. Free face

210, 210a. Inclined core hole 212, 212a. Perforation

220. Vertical heart hole 222. Hole punch

S. Mage

Features of the present invention configured to achieve the above object are as follows. That is, in the step-by-step V-cart blasting method according to the present invention, the core hole drilling method is a step of puncturing the main core hole left and right symmetrically at a predetermined inclination angle with respect to the free surface vertical line of the membrane surface, the membrane surface vertically between the main core hole Perforating the auxiliary heart hole symmetrically with a predetermined inclination angle on the line and perforating the vertical heart hole perpendicular to the center of the membrane surface between the main heart hole and the auxiliary heart hole. Perforations at the same angle of inclination are appropriate. The main, secondary, and vertical cores are suitably formed in the same line. The secondary and vertical heart holes may be further formed. Spatial spacing between the vertical heart hole and the secondary heart hole at the membrane surface and the space of the secondary heart and the main heart hole It is appropriate to form at equal intervals. The vertical core hole, the main core hole, and the secondary core hole are appropriately formed so as not to be intertwined with each other. The perforated bottom of the vertical core hole can be formed deeper than the perforated bottom of the main core hole. On the other hand, the charging method in the cardiac hole drilling method configured as described above punctures the main core ball laterally symmetrically with a predetermined inclination angle with respect to the free plane vertical line of the membrane surface, and is predetermined with respect to the vertical plane line between the main core holes. Drill the auxiliary heart hole symmetrically at the angle of inclination of the core, and drill the vertical heart hole vertically to the center of the membrane between the main heart hole and the secondary heart ball, and then load the charge into the first stage at the perforation bottom of the main heart ball and the secondary heart ball. The vertical heart hole consists of two charges: the first charge loaded in the vertical heart hole is more than the charge loaded in the perforated bottom of the auxiliary heart hole. The two-tiered charges loaded below the first-tiered charges of the vertical ventilator are more likely to be loaded deeper than the ones loaded at the perforated bottom of the main ventilator. The method comprises a main core hole which is formed symmetrically at a predetermined inclination angle with respect to the free surface vertical line of the membrane surface, and an auxiliary cardiac hole which is formed symmetrically at a predetermined inclination angle with respect to the vertical surface line between the main core holes, and Perforate the vertical heart hole formed perpendicular to the center of the membrane surface between the cardiac holes on the same line, and the main heart hole, the secondary heart ball and the vertical heart hole on the same line to both sides of the same line of the main heart hole, the secondary heart ball and the vertical heart hole. To load the main medicine and the secondary cardiac hole into the first stage, and to the vertical heart hole, load the medicine into two stages, and then detonate step by step from the top to the core. The first stage and vertical auxiliary blast can be blasted at the same time, and then the second stage and vertical main blast can be blasted at the same time. However, the blast may be exploded in the following order: blast of the auxiliary heart hole, two-stage charge of the vertical heart hole, and sequential charge of the main heart ball. Charge of auxiliary heart hole drilled in the same line as the ball, one-stage charge of one vertical heart hole, charge of auxiliary heart hole drilled in the same line with one vertical heart hole, one-load of the other vertical heart hole, same as the other vertical heart hole Charge of auxiliary heart hole drilled on line, 2-stage charge of central side vertical heart hole, charge of main heart hole drilled in line with center vertical heart hole, 2-stage charge of one vertical heart hole, collinear with one vertical heart hole On cloth The blasting can be carried out step by step in the order of the charge of the main core hole, the two-stage charge of the other vertical heart hole, and the charge of the main core hole drilled on the same line as the other vertical heart hole. The method of drilling is to incline the inclined heart hole horizontally and symmetrically at a predetermined inclination angle with respect to the vertical plane of the free surface of the face, and to drill the vertical heart hole perpendicular to the center of the face between the inclined heart holes. The charge method may be loaded in each stage of the punching bottom of the ball. The detonation method in the charging method of the above-described configuration includes an inclined heart hole formed to be symmetrically symmetrically with a predetermined inclination angle with respect to the free line vertical line of the film surface; Perforate the vertical heart hole formed perpendicular to the center of the membrane surface between the inclined heart holes on the same line, and the same line on both sides of the same line between the inclined heart hole and the vertical heart hole It is composed of a single step of loading the charge into the perforated bottom of each inclined heart and vertical heart hole by drilling the oblique heart hole and vertical heart hole of the step, and then detonate step by step from the top part to the core part. After blasting, it is possible to blast the charge of the inclined heart hole.After the blast of the center vertical heart hole, the charge of the inclined heart hole drilled in the same line as the center vertical heart hole, the charge of one side vertical heart hole, and one side It is also possible to blast stepwise in the order of the charge of the inclined heart hole perforated on the same line as the vertical heart hole, the charge of the other vertical heart hole, and the charge of the inclined heart hole perforated on the same line as the other vertical heart hole. Looking at the blasting method related to the present invention for reference before explaining the advanced V-Cart method, the Vertical Crater Retreat Stage Blasting It is a method of drilling up from the bottom by using 30-40m long hole. It is high in safety and economical. Using the blasting drilled in parallel from the core to the top to the top, it is charged from the top, divided into a bottom blast and rounded up, and is blasted in sequence for each step.

Staged blasting includes the use of burn holes and the crater cut. Among them, the blasting excavation method using the crater cart is to drill the shaft by repeating the blasting only for each step after drilling through all the piercing holes, which ensures high-precision drilling and piercing. The long hole raise crater cart is based on one free surface blasting, and is usually blasted centering on the blasting hole of the five pits.

Next, V-cart is a type of cuneiform heart blast, which is a type of heart blasting, and is a method of extracting a tongue (V-type) rock by drilling the heart hole at an angle from side to side. The drilling method is generally symmetrical about the tunnel centerline, ie, V-shaped, but sometimes symmetrical about the vein.

The drilling angle is approximately 60 ° to 70 °, but the drilling bottom should be straight and the distance from the drilling bottom should be about 20cm. The characteristics of the v-cart have been the most widely used, and the deep-holes allow the perforations to be straight. However, the volume of the heart hole is not economical in some cases, and the rock of the mass is protruding to damage the prop.

V carts include the first horizontal cut, the second vertical cut, the third double cut, the fourth multi cut, and the fifth shearing cart. Shearing Cut).

First of all, the horizontal cart is suitable for rocks with developing soft stratification, the vertical cart is suitable for rocks with vertical stratification, and the double cart is also called baby cut. Is a superposition of a large number of v-carts, which is suitable for very large sections or very strong rocks, but has a disadvantage in that a large amount of explosives per m ³ is required. And a shearing cart is used for the large cross section of soft rock.

On the other hand, Figures 1 to 7 showing the step-by-step progressive V-cart blasting method according to the present invention shows a vertical excavation field in the longitudinal section. At this time, # and the numbers shown in each cardiac hole in Figures 3 to 7 represent the detonation order.

In the vertical cardiac cavity of the drawings shown in FIGS. 3 to 5, the charge loaded at the bottom of the perforation is referred to as a two-tiered charge (lower charge), and the loaded charge on the upper part is referred to as a single charge (upper charge).

Hereinafter, with reference to the accompanying drawings will be described in detail the step-by-step progressive V-cart method according to a preferred embodiment of the present invention.

2 is a perforated pattern of the step-by-step V-kart blasting method according to the present invention, Figure 3 is a charge and detonation pattern showing a first embodiment of the step-by-step V-kart blasting method according to the present invention.

As shown in Figures 2 and 3, the core ball drilled in the step-by-step V-cart blasting method according to the present invention is perforated symmetrically with a predetermined inclination angle with respect to the vertical plane of the free surface 100 of the membrane surface Secondary heart holes 120 and 120a and main heart holes 110 and 110a which are symmetrically perforated at a predetermined inclination angle with respect to the vertical plane of the free plane 100 between the foot holes 110 and 110a and the main heart holes 110 and 110a. It consists of a vertical heart hole 130 perforated vertically to the center of the membrane surface between the auxiliary heart hole (120, 120a).

In the above-described configuration, the main core holes 110 and 110a are inclined at about 70 ° with respect to the vertical plane of the free surface 100 of the membrane surface, and are drilled at a length of 1.6m or more symmetrically.

At this time, the piercing bottoms 112 and 112a of the symmetrical main foot holes 110 and 110a are positioned in a straight line, and the intervals of the piercing bottoms 112 and 112a of the symmetrical main foot holes 110 and 110a are formed within 20 cm. do.

On the other hand, the auxiliary heart hole (120, 120a) is formed between the symmetrical main heart hole (110, 110a) is inclined at the same angle as the main heart hole (110, 110a). At this time, the puncture length of the auxiliary heart hole (120, 120a) is shorter than the puncture length of the main heart hole (110, 110a), the interval between the puncture bottom (122, 122a) of the auxiliary heart hole (120, 120a) is also symmetrical 20 It is formed within cm.

In addition, the vertical heart hole 130 is vertically punched at the center between the auxiliary heart holes 120 and 120a, and the drilling bottom 132 of the vertical heart hole 130 drills the main heart holes 110 and 110a. It is formed 20 cm deeper than the bottom (112, 112a) serves to prevent the fracture of the puncture bottom (112, 112a) of the main core hole (110, 110a) during blasting.

As described above, the perforated main core holes 110 and 110a, the auxiliary core holes 120 and 120a, and the vertical core hole 130 are formed on the same line.

The main core hole 110, 110 a, the secondary core hole 120, 120 a, and the vertical core hole 130 are formed on both sides of the same line. That is, the main core hole, the secondary heart hole and the vertical heart hole of the same structure are arranged in both sides of the main core hole (110, 110a), the secondary heart hole (120, 120a) and the vertical heart hole 130 perforated on the same line .

Spatial spacing of the vertical heart hole 130 and the auxiliary heart hole (120, 120a) and the space between the auxiliary heart hole (120, 120a) and the main heart hole (110, 110a) on the same plane on the free surface 100 It is good to form.

The vertical heart hole 130, the main heart hole (110, 110a) and the auxiliary heart hole (120, 120a) is formed so as not to be in contact with each other.

On the other hand, the main heart opening (110, 110a) and the secondary heart hole (120, 120a) configured as described above is loaded with a single charge, the vertical heart hole 130 is loaded with a deck charge in two stages.

At this time, the same primer is used to detonate the main heart hole (110, 110a), the secondary heart hole (120, 120a) and the vertical heart hole 130 at the same time and the primer to be detonated stepwise from the top of the membrane surface It is ranked.

For reference, the above-mentioned deck charge (deck charge) is a kind of loading method in a cascading blasting, and if there is water, a fault or a clay layer, there is a message (rock, mixed soil, sand, etc.) between the explosive and the explosive. It is used to charge with high specific explosives.

On the other hand, in addition to the method and the method of drilling the cardiac hole as described above, it is possible to puncture the cardiac hole in the method as shown in Figures 6 and 7. 6 and 7 will be described later.

Referring to FIG. 3, the puncturing pattern of the heart blast hole according to the preferred blasting method of the present invention, and the appropriate dose and primer disparity are shown in a table as follows.

As shown in Figure 3 and Table 1, the charge of the main core hole (110, 110a) and the secondary core hole (120, 120a) is loaded in one stage in each hole perforation bottom (112, 112a, 122, 122a), close Vertical cardiac bore 130 perforated in the center of the surface is divided into two stages to charge. Primer placement of the gunpowder and secondary heart hole (120, 120a) gunpowder of the vertical heart hole 130 equal to the primer number # 0, and the core gunpowder and the main heart hole (110, 110a) of the vertical heart hole 130 ) The primer number of gunpowder is the same as the second primer. For reference, delay is a function that the explosives loaded at the blasting explode later than the regular time, and delayed primer is a primer having such a function.

After arranging as described above, the gunpowder positioned in the ceiling is first detonated, and then the gunpowder located in the core is sequentially exploded after 40 ms, that is, after 40/1000 seconds, thereby increasing the blasting vibration due to the increase in the excavation field. .

Referring to the above-described detonation method in detail, as shown in FIG. 3 as a first embodiment, the detonation of the charge is the first stage charge (upper charge) of the vertical heart hole 130 and the charge of the auxiliary heart holes 120 and 120a. At the same time to a prior detonation at the same time and then blasting in the order to simultaneously detonate the two-stage charge (bottom charge) of the vertical heart hole (130) and the main heart hole (110, 110a).

Figure 4 is a charge and detonation pattern showing a second embodiment of the step-by-step forward V Cart blasting method according to the present invention.

As shown in the second embodiment of FIG. 4, the method of detonating the charge is performed by detonating the first stage of the vertical heart hole 130 (upper medicine), and of the auxiliary heart holes 120 and 120a, the vertical heart hole 130. The two-stage charge (lower charge) and the chief puncture (110, 110a) in the order of blasting may be stepped.

5 is a charge and detonation pattern showing a third embodiment of the step-by-step forward V-cart blasting method according to the present invention.

On the other hand, as shown in the third embodiment of FIG. 5 after the blast of the first stage (upper charge) of the central side vertical heart hole 130 (secondary charge), the secondary heart hole perforated in the same line as the central side vertical heart hole 130 ( 120, 120a), one-stage charge of one side vertical heart hole 130 (upper charge), one of the secondary heart hole (120, 120a) bored in the same line as the vertical heart hole 130, the other vertical heart One-stage charge of the ball 130 (upper charge), two-stage charge of the auxiliary heart hole (120, 120a) perforated on the same line as the other vertical heart hole 130, the central side vertical heart hole (130) Lower charge), the center of the vertical cardiac hole 130, and the main cardiac hole (110, 110a) of the perforated collinear, two-level (bottom charge) of one vertical cardiac hole (130), one vertical cardiac hole (130) ) And the main cardiac hole (110, 110a) in the same line as the drill, the second stage (bottom charge) of the other vertical cardiac hole 130, the main cardiac hole (110) Only in the order of charging, 110a) Can be blasted systematically.

On the other hand, in the case of a horizontal drilling blast of the first stage (upper charge) of the center vertical vertical hole (130) after the auxiliary heart hole (120, 120a) perforated on the same line as the vertical vertical hole (130) 약, one-stage charge (upper charge) of the upper vertical heart hole 130, the charge of the auxiliary heart hole (120, 120a) perforated on the same line as the upper vertical heart hole 130, lower vertical heart hole ( 130 step 1 charge (upper charge), the lower side vertical heart hole 130 and the secondary core hole (120, 120a) of the perforated on the same line, the second side of the center vertical heart hole 130 (bottom charge) ), The main charge hole (110, 110a) of the perforations co-aligned with the vertical vertical hole 130, the two-level charge (lower charge) of the upper vertical heart hole 130, the upper vertical heart hole 130 ) And the main heart hole drilled in the same line as the main heart hole (110, 110a), two-stage charge (lower charge) of the lower vertical heart hole 130, the lower vertical heart hole 130 (110, 110a) net order Blasting each other in stages

Figure 6 is a charge and detonation pattern diagram showing a fourth embodiment of the step-by-step V-Cart blasting method according to the present invention, Figure 7 is a charge and a detonation pattern diagram showing a fifth embodiment of the step-by-step V-Cart blasting method according to the present invention Detonation pattern diagram.

The step-by-step drilling method, the charging method and the detonation method of the step-by-step V-kart blasting method according to the present invention may be as shown in Figs.

That is, as shown in FIGS. 6 and 7, the step-by-step drilling method of the step-by-step V-kart blasting method according to the present invention inclines symmetrically to the left and right symmetrically at a predetermined inclination angle with respect to the vertical plane of the free surface 200 of the membrane surface. The holes 210 and 210a are drilled, and the vertical cardiac hole 220 is drilled perpendicularly to the center of the membrane surface between the inclined core balls 210 and 210a.

As described above, the charge is loaded in one step into each of the perforated bottoms 212, 212a and 222 of the perforated oblique heart hole 210 and 210a and the vertical heart hole 220.

Meanwhile, as shown in FIG. 6, the method of detonation according to the fourth embodiment includes a sequence of blasting the charge of the vertical heart hole 220 and then of the inclined heart hole 210 and 210a.

Then, as shown in FIG. 7, after the blast of the center side vertical heart hole 220 is blasted, the side wall of the inclined heart hole 210, 210a drilled on the same line as the center side vertical heart hole 220, one side vertical. Charge of the cardiac hole 220, charge of the oblique heart ball (210, 210a) perforated on the same line as one vertical heart hole 220, charge of the other vertical heart hole 220, and the other vertical heart hole 220 It may be blasted step by step in the order of filling the oblique heart-shaped holes (210, 210a) perforated on the same line.

On the other hand, in the case of the horizontal excavation field after the blast of the center side vertical heart hole 220, the charge of the inclined heart hole 210, 210a perforated on the same line as the center side vertical heart hole 220, the upper vertical heart The charge of the ball 220, the charge of the oblique heart ball (210, 210a) perforated in the same line as the upper vertical heart hole 220, the charge of the lower vertical heart hole 220, the lower vertical heart hole 220 Blasting step by step in the order of filling the oblique heart ball (210, 210a) perforated on the same line.

Unexplained symbol S is a message made of sand and clay.

Hereinafter, a step-by-step progressive V-cart blasting method according to a preferred embodiment of the present invention will be described.

8 is a flow chart showing a step-by-step progressive V-cart blasting method according to the present invention.

As shown in FIG. 8, in step S200, the main core hole is drilled more than 1.6 m in a symmetrical direction by inclining at about 70 ° with respect to the free surface of the film. At this time, while positioning the perforated bottom of the two main gyrus in a straight line, the interval between the perforated bottom is within 20 cm. After puncturing the main heart pore in a predetermined state, the process proceeds to the next step (S210).

In step S210, the auxiliary core hole (baby hole) having the same inclination in front of the two main core holes are drilled, and when the auxiliary core holes are drilled in a predetermined state, the process proceeds to the next step (S220).

In step S220, the vertical heart hole is drilled in the center of the membrane face of both main heart holes, perpendicular to the membrane face. At this time, the perforated bottom of the vertical core hole is formed to be 20 cm deeper than the perforated bottom of the main core hole to prevent the fracture of the perforated bottom portion of the main core hole in the blasting operation. After drilling the vertical heart hole in a predetermined state, the process proceeds to the next step (S230).

In step S230, it is determined whether the puncture bottom of the vertical heart hole is drilled about 20 cm deeper than the puncture bottom of the main heart hole. As a result of the determination, if the puncture bottom of the vertical heart hole is not drilled about 20 cm deeper than the puncture bottom of the main heart hole, the process proceeds to step S220 to perform the steps below the step S220, and conversely, the puncture bottom of the vertical heart hole is the main heart hole. If the perforation of about 20 cm deeper than the perforation bottom of the proceeds to step (S240).

In step S240, the charge is loaded into the first stage of the main puncture hole and the secondary heart hole in the puncture bottom, and then the process proceeds to step S250.

In step S250, deck decking the vertical heart hole in two stages and proceeds to the next step (S260).

In step S260, using the same primer to detonate both the main and vertical ventricles at the same time, the primers are determined so that they can be detonated stepwise from the top of the membrane. After deciding the primer priority, the blasting is carried out using the primer priority to perform excavation. In other words, the blasting method is performed in the same way as in the first, second, third, fourth, and fifth embodiments shown in FIGS. 3 to 7.

When the blasting is carried out by the above-described method, it is possible to compensate for the fact that the crushing of the perforated bottom part becomes poor during the blasting operation due to the poor spacing and horizontal maintenance of the perforated bottom.

In addition, by using two-stage charge of vertical heart hole and delayed parallax of delayed primer, it is possible to minimize the blast vibration by blasting to the deep part step by step using a small amount of gunpowder and at the same time satisfies the increase of digging efficiency. You can.

Although the present invention has been described with reference to the preferred embodiments shown in the drawings, which are merely exemplary, and various modifications and equivalent other embodiments may be made by those skilled in the art.

As described above, the present invention can improve the excavation length and control the blasting vibration at the same time by improving the limitations of the fabric mill, the crushing effect of the perforated bottom part, the excessive blasting vibration, etc., which are disadvantages of the conventional V-Cart blasting method. It becomes possible.

In other words, it is possible to increase the blasting efficiency due to the puncturing error of the perforated bottom part, and to reduce the blasting vibration because it can delay the blasting of the V-cart blasting hole by the symmetrical pore blasting, and the long density of the perforated bottom part. Since it can increase the effect of increasing the excavation field.

Claims (18)

Perforating the main core hole at left and right symmetry at a predetermined inclination angle with respect to the free surface vertical line of the film surface; Perforating the auxiliary heart hole symmetrically at a predetermined inclination angle with respect to the vertical surface of the membrane between the main heart holes; And Drilling a vertical heart hole perpendicular to the center of the membrane surface between the main and secondary heart holes; Loading the charge into the first stage while loading the charge into the second stage at the base of the main and secondary assist balls; And Step-by-step progressive v-cart blasting method consisting of a step of detonating step by step from the center of the secondary heart hole, the main heart hole from the vertical heart hole. The method of claim 1, wherein the main core hole and the secondary core hole are drilled at the same inclination angle. 3. The step-by-step forward v-kart blasting method according to claim 2, wherein the main core hole, the secondary core hole and the vertical core hole are formed in the same line. The step-by-step forward v-cart blasting method according to claim 3, wherein the main core hole, the secondary core hole and the vertical core hole are further formed on both sides of the main core hole, the secondary core hole, and the vertical core hole. 5. The step-by-step V-kart blasting method according to claim 4, wherein the spaces of the vertical and secondary core holes and the spaces of the secondary and main core holes are formed at equal intervals. The method of claim 5, wherein the vertical core hole, the main core hole and the secondary core hole are formed so as not to be introduced into each other. The step-by-step forward v cart blasting method according to any one of claims 1 to 6, wherein the vertical bottom hole is drilled 20 cm deeper than the main bottom hole. delete The step-by-step forward v-kart blasting method according to claim 1, wherein the first-loaded charge loaded in the vertical heart hole is loaded deeper than the charge loaded in the perforated bottom of the auxiliary heart hole. 10. The method of claim 9, wherein the two-tiered charge loaded under the first stage of the vertical cardiac bore is loaded deeper than the charge loaded on the perforated bottom of the main cardiac cavity, but the loading density is 0.8kg / ㎥ Step-by-step forward V cart blasting method. delete delete The method according to claim 1, wherein the first step charge of the vertical heart hole and the charge of the auxiliary heart hole are simultaneously blasted simultaneously, followed by simultaneously blasting the second step charge of the vertical heart hole and the charge of the main heart hole. Step-by-step forward V cart blasting method. The method of claim 1, wherein after blasting the first stage charge of the vertical heart hole, the blast of the auxiliary heart hole, the second stage charge of the vertical heart hole and the step of the main heart hole blasting step by step Forward V Cart Blasting Method. The method of claim 1, wherein after the blast of the first stage of the center vertical heart hole blasted, the secondary cardiac hole drilled on the same line as the center side vertical heart hole, the first stage of the one vertical heart hole, the one side Charge of the secondary heart hole drilled in the same line as the vertical heart hole, one-stage charge of the other vertical heart hole, charge of the auxiliary heart hole drilled in the same line as the other vertical heart hole, 2 of the central side vertical heart hole However, the medicament charge of the main core hole punctured in the same line as the central side vertical heart hole, two-stage charge of the one vertical heart hole, the charge of the main heart hole punctured in the same line with the one vertical heart hole, the other vertical heart Step-by-step progressive v-kart blasting method characterized in that the blasting step by step in the order of the charge of the main core hole drilled in the same line with the other vertical vertical hole. delete delete delete