JP4021102B2 - Low vibration crushing method by blasting - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a technique for multistage blasting in civil engineering work such as tunnel excavation work. In particular, the present invention relates to a method for suppressing vibration due to multistage blasting.
[0002]
[Prior art]
Conventionally, there has been a crushing method by multistage blasting in which a plurality of blast holes are provided on a target surface such as a rock for excavation, and dynamite loaded in these blast holes is continuously exploded in a short time.
According to the crushing method by such multistage blasting, since the amount of explosive per hole may be small, an effect of reducing the generated vibration was obtained.
Therefore, when there is a structure or an urban area near the construction site, it has been adopted as a construction method for reducing the influence of vibration on them.
Furthermore, it is possible to generate a plurality of vibration waves having different phases by appropriately controlling the time interval of seconds for detonating each explosive and to set the peaks of the vibration waves to cancel each other.
In order to do so, it is necessary to set an appropriate explosive second interval.
[0003]
Therefore, there is a blasting method described in Japanese Patent Publication No. 7-122559 as a technique for determining an appropriate explosive second time interval.
The technique described in this publication measures the prevailing vibration frequency in advance, determines a certain detonation second time interval such that the vibration wave interferes based on the preferential vibration frequency, and uses the electrical delay electric detonator to determine the detonation second time. It is a blasting method characterized by sequentially detonating a plurality of holes at intervals of intervals.
[0004]
[Problems to be solved by the invention]
However, in the blasting method described in the above publication, the time interval for initiation is determined based on the analysis result assuming that the blasting vibration is a sine wave. It was difficult to attenuate.
[0005]
Therefore, the present invention has been made for the purpose of providing a method for determining a more effective detonation second time interval by performing a simulation using vibration waves generated at an actual construction site.
[0007]
In the low vibration crushing method by blasting according to claim 1 of the present invention, the explosive loaded in the charge hole in which only one of the four sides around the charge hole faces the slot and becomes a free surface is first After starting the test as the first test initiation and measuring and recording the first vibration wave generated, it was crushed by the first test initiation and the free surface adjacent to the charge hole and facing the slot. The explosive loaded in the charge hole where the two sides became free surfaces was experimentally detonated as the second test initiation, and the generated second vibration wave was measured and recorded. Then, from the recorded second vibration wave data, a vibration wave data group for simulation delayed at various delay time intervals is generated, and the first vibration wave data and the vibration wave for simulation at each delay second time interval are generated. Combined with data groups Performing superposition processing of dynamic wave data, extracting a combination that minimizes vibration energy of vibration wave data after superposition processing, and setting the delay second time interval to be such a combination as the initiation second time interval Yes.
[0008]
It should be noted that not only a single pilot detonation but also another charge hole under different conditions is used, and in actual multistage blasting, the delay time interval according to conditions obtained by those simulations may be adopted. Good.
In addition, as explosives to be detonated experimentally, if an explosive loaded in a charge hole in which only one of the four charge holes has a free surface by a slot is selected, the explosive second time is determined by simulation. After determining the interval, the explosive loaded in each charge hole may be detonated according to the order of the non-adjacent charge holes.
By igniting in this order that is not adjacent, each charge hole will be detonated with only one free surface, and the conditions are similar to the charge holes that were experimentally ignited. Can be used effectively.
In the low vibration crushing method by blasting according to claim 2, the vibration wave data is superposed on the number of vibration wave data used for the superposition process, and the vibration energy of the vibration wave data after the superposition process is minimized. And the number of vibration wave data and the delay second time interval used for the superposition to be such a combination are determined, and the determined delay second time interval is set as the detonation second time interval. It is characterized in that blasting is carried out in a multistage manner at intervals of the explosive seconds collectively for each number corresponding to the number obtained.
In this way, without limiting to exploding the explosives of all the charge holes at once in a row, if the energy of the vibration wave becomes smaller, the charge holes can be set at any number. By performing multistage blasting together, explosives in all charge holes may be detonated by a combination of multiple multistage blasting.
According to the third aspect of the present invention , the distance between the charging hole and the slot in the outermost row is set to a fixed distance, and the depth of each charging hole is set to be larger than the fixed distance.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Below, the low-vibration crushing method by blasting according to the present invention will be described in detail based on the drawings showing the embodiments thereof.
1 is a front view of the face of the tunnel, FIG. 2 is a cross-sectional perspective view of the face, FIG. 3 is a side cross-sectional view of the face, and FIG. 4 is a plan cross-sectional view of the face.
1, 2, 3, 4
Reference numeral 1 denotes a face to be crushed and 2 denotes a slot provided along an edge of the face 1 to be crushed.
31, 32, 33,... Are first group charge holes provided at predetermined intervals on the outermost side of the region surrounded by the slot 2 on the crushing target surface 1.
, 41, 42, 43,... Are second grouped holes provided at predetermined intervals on the inner side of the charged holes 31, 32, 33,.
In this way, the third group, the fourth group,...
Note that a> b, where a is the depth of the charge hole, b is the distance between the charge hole and the slot, c is the depth of the slot, and d is the distance between the charge holes. However, a, b, c, and d are assumed to have a constant size. For example, a = 1.5 meters, b = 0.7 meters, c = 1.7 meters, and d = 0.7 meters.
[0010]
Next, test blasting is performed to obtain vibration wave data for computer simulation. Here, as the charging hole for performing the test blasting, the charging hole 31 positioned at the corner of the face to be crushed is selected.
The charge hole 31 is a free surface because only one of the four sides faces the slot 2.
For example, a vibrometer for detecting a vibration wave is installed at a position, for example, several tens of meters away from the face. As this installation position, a specific position such as a position where an influence of vibration caused by blasting is desired to be suppressed, that is, a position of an actual structure or the like may be selected. Since the human body is more sensitive to the component in the vertical direction (Z-axis direction) than the vibration wave component in the horizontal direction (X-axis direction, Y-axis direction), the vibrometer has a component in the vertical direction (Z-axis direction). It is set to detect vibration waves.
[0011]
In the state set in this way, the charge hole 31 is loaded with a test explosive and detonated. The hatched portion in FIG. 5A is crushed. In this portion, only the slot side F1 is a free surface. This slot suppresses the propagation of vibration due to blasting.
The vibration wave generated by the explosion is detected by the vibration meter, and the change of the waveform is recorded for a predetermined time (for example, 100 mS). The recording time is set so that the amplitude becomes sufficiently small.
[0012]
Based on the vibration wave data D0 as shown in FIG. 6 obtained as described above, simulation vibration wave data groups D1 to DN as shown in FIGS. 7 and 8 are generated.
FIG. 7A shows the vibration wave data D0 and the simulation vibration wave data group D1 generated by setting the delay time interval Δt to 1 mS.
(B) of FIG. 7 is the simulation synthetic data S1 obtained by superimposing the vibration wave data D0 and the vibration wave data group D1 for simulation.
FIG. 7C shows the vibration wave data D0 and the simulation vibration wave data group D2 generated by setting the delay time interval Δt to 2 mS.
(D) of FIG. 7 is simulation synthetic data S2 obtained by superimposing the vibration wave data D0 and the vibration wave data group D2 for simulation.
FIG. 8E shows the vibration wave data D0 and the simulation vibration wave data group D3 generated by setting the delay time interval Δt to 3 mS.
(F) of FIG. 8 is simulation synthetic data S3 obtained by superimposing the vibration wave data D0 with the vibration wave data group for simulation D3.
FIG. 8G shows the vibration wave data D0 and the simulation vibration wave data group DN generated by setting the delay time interval Δt to NmS.
(H) of FIG. 8 is simulation synthetic data SN obtained by superimposing the vibration wave data D0 and the vibration wave data group for simulation DN.
The vibration wave data group for each simulation is a number corresponding to the total number of actual charge holes excluding the charge holes to be experimentally detonated.
[0013]
The respective vibration energies are calculated from the simulation composite data S1 to SN obtained as described above, the vibration energy is compared, the smallest simulation composite data is extracted, and the delay time interval Δt at that time is calculated. obtain. For example, when the vibration energy of the simulation composite data S3 is the smallest, the delay second time interval Δt = 3 mS is obtained.
[0014]
Thus, the delay time interval Δt obtained by the computer simulation process is adopted as the optimum time interval for initiation of the charge hole having only one free surface.
[0015]
Next, similarly in the charge hole 32, the test is started and the vibration wave data is recorded, and the delay time interval when the vibration energy is minimized is obtained by the computer simulation process. At this time, as shown by hatching in FIG. 5 (B), the charge hole 32 is free not only from the slot side F2 but also from the charge hole 31 side F3 due to the explosion of the charge hole 31. Therefore, two of the four sides are free. Therefore, the delayed second time interval obtained by the initiation of the charge hole 32 is adopted as the optimum second time interval for the initiation of the charge holes having two free surfaces. For example, Δt = 2 mS is adopted as the time interval for detonation seconds.
[0016]
Based on the result of the above computer simulation process, actual blasting is performed. In other words, based on the above example, the time interval for detonation after the charge hole 33 is set to 2 mS, and since the first charge hole 41 of the second group has only one free surface, the time interval for detonation time is 3 mS. Since the charge holes 42, 43,... After that are set in two directions, the time interval between the detonation seconds is set to 2 mS.
Similarly, for the third group and subsequent groups, after setting each detonation second time interval, detonation is performed and multistage blasting processing is performed.
When the vibration wave generated by the multistage blasting performed as described above was observed, the waveform was suppressed by overlapping as shown in FIG. 8A, and as shown in FIG. 9B. Furthermore, it was confirmed that the vibration wave was very similar to the simulation synthesis data S3.
[0017]
In this way, by setting the initiation time interval, the vibration wave generated by the actual multi-stage blasting is reduced in vibration energy, and is less likely to be felt by the human body. The impact on the is also reduced.
Then, after crushing the crushing target surface 1 and the face has advanced, the same crushing slot and charge hole are provided on the next crushing target surface to perform multistage blasting. The delayed second time interval obtained on the crushing target surface 1 can also be adopted as the initial second time interval.
[0018]
The vibration wave data for simulation in FIGS. 7 and 8 is generated by using the vibration wave by the first test initiation, but as shown in FIG. 10, it may be generated by using the vibration wave by the second test initiation. Good.
In this case, it is possible to simulate a situation that more closely matches the situation in the multistage blasting at the actual face, and thus an excellent simulation effect can be obtained.
In the above explanation, the test initiation was performed twice, and the data for one free surface and the data for two directions were obtained. Based on either data, the actual initiation time interval was calculated. It may be set.
In addition, when data with only one free surface is used, the actual order of multistage blasting is not to sequentially detonate adjacent charge holes, but sequentially to non-adjacent charge holes for each group. By setting to detonate, actual multistage blasting can be performed under conditions close to the simulation conditions.
[0019]
Further, as shown in FIG. 11, the number of vibration waves to be combined in the simulation process is set to a plurality, and among those combinations, the combination that minimizes the vibration energy of the vibration waves subjected to the superposition process is extracted. It may be.
In FIG.
In step 1, the number of vibration waves to be superimposed is set to the initial value (2). In step 2, the delay second time interval is set to the initial value (1 mS). Using the number of vibration waves set in step 1, the simulation energy is generated by superimposing them by shifting the delay time interval set in step 2, and the vibration energy is calculated.
In step 4, the delay second time interval is set to the next delay second time interval with reference to a preset table, and control is repeated from step 3. When processing using all the delay time intervals set in the table is completed, control is made to proceed to step 5.
In step 5, the number of vibration waves to be superimposed is set to the next number with reference to a preset table, and control is repeated from step 2. When processing using all the numbers set in the table is completed, control is made to proceed to step 6.
In step 6, all vibration energies calculated in the above processing are compared, and the delay time interval when the vibration energy is minimized and the number of vibration waves to be superimposed are determined.
In step 7, the actual multistage blasting is performed by setting the multistage blasting initiation condition based on the delay time interval thus determined and the number of vibration waves to be superimposed.
Prior to the simulation process of FIG. 11, one test initiation or two test initiations are performed, and in the simulation process of FIG. 11, a combination of these vibration wave data, or only one of them can be used.
[0020]
【The invention's effect】
According to claim 1 of the present invention, tests only one of the surrounding four sides of instrumentation Kusuriana is loaded into charge hole has a free surface facing the slot explosives as the first round of testing detonating The first vibration wave generated and measured and recorded, and then the free surface adjacent to the charge hole and facing the slot, and the free surface crushed by the first test initiation As a result, the explosive loaded in the charge hole where the two sides became free was experimentally initiated as the second test initiation, and the second vibration wave generated was measured and recorded. Generate vibration wave data group for simulation delayed from various vibration wave data at various delay time intervals, and combine the first vibration wave data and vibration wave data group for simulation at each delay second time interval. Simulation process. To apply to the actual blasting conditions, it is possible to obtain a time interval initiation seconds vibration is suppressed.
[0021]
In the low vibration crushing method by blasting according to claim 2, the vibration wave data is superposed on the number of vibration wave data used for the superposition process, and the vibration energy of the vibration wave data after the superposition process is minimized. Therefore, it is possible to adopt a combination with a smaller vibration energy of the vibration wave without limiting to explosive explosives of all charge holes at once.
And like Claim 3 , while setting the space | interval of the charging hole of an outermost row | line | column and a slot as a fixed distance, and setting the depth of each charging hole larger than the said fixed distance, Furthermore, simulation with excellent reproducibility is possible, and the effect of suppressing vibration propagation by the slot can be obtained.
[Brief description of the drawings]
FIG. 1 is a front view of a face in tunnel excavation work in an embodiment of a low vibration crushing method by blasting according to the present invention.
FIG. 2 is a vertical sectional perspective view of the face.
FIG. 3 is a side sectional view of the face.
FIG. 4 is a plan sectional view of the face.
FIG. 5 is an enlarged front view of a part of the face.
FIG. 6 is a waveform diagram of vibration waves generated experimentally.
FIG. 7 is a waveform diagram of simulation synthesis data.
FIG. 8 is a waveform diagram of simulation synthesis data.
FIG. 9 is a diagram in which an actual vibration wave waveform is compared with simulation synthesis data.
FIG. 10 is a waveform diagram of another example of simulation synthesis data.
FIG. 11 is a flowchart illustrating a procedure of another example of simulation processing.
[Explanation of symbols]
1 Face to be crushed 2 Slot
31, 32, 33, ... charge hole
41, 42, 43, ...

Claims (3)

The first time when the explosive loaded in the charge hole where only one of the four sides around the charge hole faces the slot is a free surface is experimentally initiated as the first test start. After measuring and recording the vibration wave of
The explosive loaded in the charge hole that is free on both sides by the free surface adjacent to the charge hole and facing the slot and the free surface crushed by the first test initiation. , As the second test initiation, the test oscillation was started, and the second vibration wave generated was measured and recorded,
From the recorded second vibration wave data, generate a vibration wave data group for simulation delayed by various delay seconds,
Combining the first vibration wave data and the vibration wave data group for simulation of each delay second time interval, and superimposing those vibration wave data,
Extract the combination that minimizes the vibration energy of the vibration wave data after superposition processing,
A low-vibration crushing method by blasting characterized in that the delay second time interval to be such a combination is set to the above-mentioned explosion second time interval . The number of vibration wave data used for the superposition processing is two or more, and the superposition processing of vibration wave data is performed.
Extract the combination that minimizes the vibration energy of the vibration wave data after superposition processing,
Determine the number of vibration wave data and the delay second time interval used for superposition to become such a combination,
The determined delay second time interval is the detonation second time interval,
The low-vibration crushing method by blasting according to claim 1, wherein the blasting is performed in a multistage manner at the time interval of the explosion seconds collectively for each number corresponding to the determined number . The distance between the outermost charge hole and the slot is a constant distance, and the depth of each charge hole is larger than the predetermined distance. Low vibration crushing method by blasting as described in

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