KR101202000B1 - Blast method vibration control of multistage for blast perpendicular shaft and tunnel - Google Patents

Abstract

PURPOSE: A vibration-controlled blasting method using layered and multiple charging for blasting construction of a tunnel and a vertical shaft is provided to reduce the vibration of an expansion hole by controlling the excessive blasting vibration in the center of the charge to be similar to that of a cut hole. CONSTITUTION: A vibration-controlled blasting method using layered and multiple charging for blasting construction of a tunnel and a vertical shaft comprises the steps of: boring an auxiliary cut hole(10), a cut hole(20), a cut expansion hole(30), and an expansion hole(40) symmetrically about the center of a tunnel(1) or a vertical shaft, charging upper charges(20a,30a) and lower charges(20b,30b) in multiple stages in the cut hole and the cut expansion hole and upper and lower charges in the expansion hole, and successively blasting charges in the auxiliary cut hole, the upper charge in the cut hole, the upper charge in the cut expansion hole, the lower charge in the cut hole, the lower charge in the cut expansion hole and charge in the expansion hole, wherein the expansion hole is charged with charges at the bottom or inserted with a tube or rod to form a non-charging space.

Description

Blast METHOD VIBRATION CONTROL OF MULTISTAGE FOR BLAST PERPENDICULAR SHAFT AND TUNNEL}

The present invention relates to a vibration control blasting method of the tunnel and vertical sphere blasting work, and more particularly, to the vibration and noise of the deep hole and the expansion hole when the maximum vibration occurs when blasting a single free surface of the tunnel and vertical sphere blasting construction The present invention relates to a vibration control blasting method by multi-stage and multi-loading of tunnel and vertical sphere blasting construction.

In general, the rock excavation method for tunnels and vertical holes is determined by the size of the excavation area, the condition of the rock, and the distance to the security object. The technical improvement of these excavation methods is divided into the heart blasting method to maximize the single drilling site per blasting, the control blasting method to prevent the damage of the drilling surface, and the ground vibration and noise generated during the excavation blasting.

Conventional tunnel excavation method is divided into three steps as follows, for example, the secondary drilling hole, deep hole, deep hole expansion and expansion hole, perforation step of drilling the periphery hole, the bottom hole, etc., and It is composed of a loading step of loading the explosives and primers in the perforated holes and loading the loaded primers to detonate them with a blasting machine.

Primers used for detonation of loaded explosives use electric or non-electrical detonators detonated with delayed delays of instant or second (MS) and decisual seconds (DS). Maintain blasting in 39 ~ 41 steps, or in the case of electric primer using a multi-stage blasting machine, non-electrical primers use a surface delay primer to further blast the step.

By the way, the conventional blasting method in the loading method from the bottom of the perforated hole to continuously fill the explosive dose required for loading, and by loading one primer together to detonate the primer, there is a lot of explosive charge exploded by a single primer, the blasting vibration There is a big problem. In other words, the important steps in the process of blasting for tunnel excavation include the step of blasting the cardiac hole and the cardiac augmentation hole and the step of blasting the enlarged hole, the bottom hole, and the surrounding hole sequentially according to the drilling position.

Among them, the blasting stages of the blasting heart and the enlarged hole are the most important factors that determine the success of the blasting, and the initial blasting vibration generated during the blasting operation is the largest in all the blasting operations. Pollution occurs.

Korean Patent No. 10-0294819 has been disclosed as a technique for improving such a problem.

The conventional blasting method as described above does not need to reduce the blasting vibration generated in the augmentation hole because the vibration generated in the deep blasting hole is generated the greatest, but by controlling the vibration of the deep blasting hole in which the blasting vibration occurs the most. In Korea Patent No. 10-0294819, which is generated less than the blasting vibration of the vibration occurs in the deep hole is generated less than the vibration generated in the enlarged hole is the situation that the maximum vibration occurs in the enlarged hole, causing damage.

The present invention was developed to improve the conventional problems as described above, and the blasting vibration generated in the expansion hole when the blasting by blasting by multi-stage in the deep hole of the tunnel and vertical hole blasting construction and the magnitude of the vibration generated in the heart blasting Similarly, the purpose of the present invention is to provide a method of blasting vibration control by multi-level and multi-loading of tunnel and vertical blasting works to reduce the size of maximum vibration by more than 33%.

In order to achieve the above object, the present invention provides a blasting method for the excavation of a straight surface tunnel or vertical sphere, the left and right auxiliary vent hole, heart hole, heart enlargement hole, enlargement hole based on the center of the tunnel or the vertical sphere Perforating spaced to achieve symmetry; To charge the inside of the secondary heart hole, the heart hole, the heart enlargement hole, the enlarged hole, the multi-segment load the heart hole and the heart enlarged hole into the upper and lower charges, respectively, Multiple loading with the drug; And sequentially blasting the auxiliary heart hole, the upper mortar of the heart hole, the upper mortar of the heart enlargement hole, the lower mortar of the heart hole, the lower mortar of the heart enlargement hole, and the enlarged hole.

In addition, the present invention is to load the explosives in the bottom of the deburring section in the loading step from the bottom of the expansion to the full color before the full color, to form an unfilled space (rod) or after loading the SB (SB) explosives It provides vibration control blasting method of tunnel and vertical hole blasting work that loads explosives on top, adjusts and colors the cabinet.

In another aspect, the present invention provides a vibration control blasting method of the tunnel and vertical sphere blasting construction is formed by inserting the tube or rod in the undamaged space of the expansion hole in the loading step.

According to the vibration control blasting method by the multi-stage and multi-load of the tunnel and vertical sphere blasting construction according to the present invention configured as described above, it is loaded with a multi-stage cardiac hole and a cardiac augmentation hole, and as a column charge of the expansion hole for blasting When the explosives are filled, it forms an armless space in the middle or fills the SB explosives or rods to load the explosives in multiple, so that the blasting vibrations excessively generated in the center of the explosives can be controlled similarly to the magnitude of the blasting vibrations of the heart hole. It is possible to reduce the size of the maximum vibration of the expansion hole by more than 33%.

1 is a front view showing a perforation arrangement applied to the vibration control blasting method by the multi-stage and multi-pack of the tunnel and vertical sphere blasting construction according to the present invention.
2 is a sectional view taken along the line AA in Fig.
3 is a detailed view showing a state where the explosives are loaded in the enlarged hole according to the present invention.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings. Prior to this, terms and words used in the present specification and claims are to be interpreted in accordance with the technical idea of the present invention based on the principle that the inventor can properly define the concept of the term in order to explain his invention in the best way. It must be interpreted in terms of meaning and concept.

Hereinafter, with reference to the accompanying drawings will be described in detail the vibration control blasting method of the tunnel and vertical sphere blasting construction according to the present invention.

Vibration-controlled blasting method by the multi-stage and multi-load of the tunnel and vertical sphere blasting construction according to this embodiment, as shown in Figures 1 to 3, the auxiliary hollow hole for the excavation of the straight surface tunnel (1) or vertical sphere (10), the core hole 20, the heart enlarged hole 30, the enlarged hole 40 to the perforated spaced apart to form a left-right symmetry with respect to the center (C) of the tunnel or the secondary heart To charge the inside of the ball (10), cardiac hole (20), cardiac enlarged ball (30), enlarged ball (40), multi-loaded cardiac ball (20) and cardiac enlarged ball (30) To, the step of loading the magnification hole in the multi-load, and the secondary heart hole 10, the upper charge (20a) of the cardiac hole 20, the upper charge (30a) of the heart enlarged hole (30), cardiac hole (20) Lower swelling (20b), the heart swelling hole 30, the lower swell (30b), comprising the step of sequentially blasting the enlarged hole (40).

In the drilling step, the bottom hole 50 and the outermost hole 60 are further drilled, and the depth of each punch is drilled differently. For example, the auxiliary cardiac hole 10 forms an angle of 60 degrees with the free surface of the tunnel 1 and forms a depth of 1/2 of the cardiac hole. In addition, the cardiac hole 20 is formed to form an angle of 60 degrees with the free surface on the outside of the secondary cardiac hole (10).

In addition, in the drilling step, the vertical lines of each of the perforations 10, 20, 30, 40, 50, and 60 are formed to 45 mm.

In the explosive charge loading step, a charge (10a) is loaded at the bottom of the auxiliary cardiac hole (10), and the auxiliary cardiac hole (10) is colored to prevent the loaded medicine from being blasted (exploding in the tool direction). (10b). At this time, the auxiliary cardiac hole 10 is formed longer than the full-color (10b) section of the secondary heart hole (10) to improve the blasting effect.

In the explosive charge loading step, the charge of the cardiac cavity 20 is loaded in multiple stages, that is, the upper charge 20a and the lower charge 20b are loaded, and between the upper charge 20a and the lower charge 20b, The entrances are colored (20c, 20d). Even when loading the cardiac hole 20, the section of the upper and lower charge (20a) and the lower (20b) is formed longer than the full color (20c, 20d) section.

Heart enlargement hole 30 also consists of an upper charge (30a), a lower charge (30b), full color (30c, 30d).

Heart hole (20) and heart expansion hole (30) is a multi-stage drug consists of two upper-loading primer and lower-loading primer.

In particular, in the explosive charge loading step by reducing the amount of loading per delay of the enlarged hole 40 to prevent excessive crushing, it is multi-loaded with the upper charge (40a) and lower charge (40b) to maintain an appropriate degree of crushing.

As described above, when the expansion hole 40 is loaded, an armed section is formed between the upper and lower portions 40a and 40b to form a plurality of upper and lower portions 40a and 40b, or Fill the SB explosive (40c) or rod. And the full color 40d section is formed in the edge part of the expansion hole 40. FIG.

This, the expansion hole 40 can prevent the excessive vibration caused by the SB explosives (40c) or the rod (or armed weakness) in the central section to suppress excessive vibration, it is possible to maintain a constant degree of crushing . That is, the blasting vibration of the enlarged hole 40 may be reduced by more than 33% by reducing the dose per delay of the enlarged hole 40.

In addition, when loading the expansion hole 40, the upper charge (40a) and the lower charge (40b) section is formed longer than the SB explosive charge (40c) section.

In addition, when the expansion hole 40 is loaded, the formation of the armless section is formed by inserting a tube or a rod into the expansion hole 40.

In addition, the blasting vibration may be variously controlled by adjusting the length of the armed section or the SB explosive section 40c of the enlarged hole 40.

In the blasting step, the sequential blasting is performed in the counter-explosion state in the state where the subdivisions of the auxiliary heart hole 10, the heart hole 20, the heart enlargement hole 30, and the enlargement hole 40 are divided into multiple stages or multiple stages. After forming a free surface formed through the progressing line blasting, the bottom hole 50, the outermost hole 60 is sequentially blasted by using the free surface. At this time, the charge placed in the upper portion of the charge (20a, 30a) section is exploded with a back explosion that explodes first.

Table 1 below is an embodiment of the blasting method according to the present invention as described above.

As can be seen from Table 1 above, when the expansion hole 40 is loaded with an armless (40c) section or an SB explosive (40c) to load the charge (40a, 40b) in multiple, compared with the conventional blasting method As a result, the amount of charge (explosives) decreased.

As described above, the present invention has been described with reference to the embodiments shown in the drawings, but this is merely exemplary, and various modifications and equivalent other embodiments of the present invention may be made by those skilled in the art. I understand that it is possible. Accordingly, the true scope of the present invention should be determined by the following claims.

10: secondary heart attack hole 20: heart attack hole
30: deep hole enlargement 40: enlarged hole
50: bottom hole 60: outermost hole

Claims (3)

Drilling the auxiliary heart hole 10, the heart hole 20, the heart enlarged hole 30, and the enlarged hole 40 so as to be symmetrical with respect to the center of the tunnel or the vertical sphere; To charge the inside of the auxiliary heart hole, the heart hole, the heart enlargement hole, the enlarged hole, the heart hole and the heart enlargement hole into the upper charge (20a, 30a) and the lower charge (20b, 30b), respectively Split-loading and multi-loading the augmented hole with an upper charge (40a) and a lower charge (40b); The secondary heart hole (10), the upper charge (20a) of the heart hole, the upper charge (30a) of the heart enlarged hole, the lower charge (20b) of the heart hole, the lower charge (30b), enlarged hole of the heart enlarged hole And (40) sequentially blasting, wherein the enlarged hole is loaded with explosives in the depressed portion, forming an unfilled space or loaded SB (explosive charges) for the charge section from the deduction to full color Then, load the explosives to match and color the cabinet, and insert a tube or rod into the barrier-free space to form a barrier-free space,
In the drilling step, the auxiliary cardiac bore 10 forms an angle of 60 degrees with the free surface of the tunnel 1, and forms the depth of the auxiliary cardiac bore at 1/2 of the cardiac bore, and charges 10a. Longer than the full-color (10b) section,
In the multi-loading step, the vibration control blasting method according to the multi-load and multi-load of the tunnel and vertical sphere blasting construction, characterized in that the multi-loading in the expansion hole 40 with the upper charge (40a) and the lower charge (40b) . delete delete

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