• Explosives and Blasting
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• v.40 no.4
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• pp.47-56
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• 2022

It was designed as the mechanical excavation mass method on 176m because the safety thing is located around the site. But low-vibration blasting using an electronic detonator was proposed to improve constructability and economy. As a result of the suggestion blasting, both blasting noise and vibration were safe within the allowable limit, confirming the applicability of low-vibration blasting using an electronic detonator to the section. And compared with the mechanical mass excavation method, an economic evaluation was conducted about the section, and it was evaluated that there was an economic advantage as the construction period was reduced by 88 days.

• Explosives and Blasting
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• v.13 no.3
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• pp.66-68
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• 1995

14세기 우리나라 최초로 화약을 만들어 왜적을 물리쳤다는 최무선, 원나라에서 온 사신으로부터 화약기술을 배워 당시 불꽃놀에나 쓰던 화약을 폭발무기로 개발한 뒤 화통도감을 설치했다. 지난 4월 과학의 달에 이달의 인물로 뽑혔던 최무선을 재조명해본다.

• Explosives and Blasting
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• v.21 no.3
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• pp.73-80
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• 2003

암반발파에 사용하고 있는 전기식 뇌관과 비전기식 연결뇌관 및 번치 커넥터(Bunch connector), 점화구, 에멀젼류 폭약이 지상에서 기폭 될 때 발생하는 소음을 비교 분석하였다. 에멀젼류 폭약의 폭발소음과 화공품의 기폭소음에 대한 추정식을 도출하였다. 에멀젼류 폭약의 폭발 소음 예측은 반대수 자승근 환산식, 번치 커넥터, 전기식 뇌관 및 비전기식 연결뇌관 및 점화구는 전대수식이 적합한 것으로 판단된다. 소음원으로부터 동일한 거리에서의 소음은 점화구, 비전기식 연결뇌관, 전기식 뇌관 및 번치 커넥터 순으로 높았다. 소음원으로부터 약20∼30m거리의 범위에서 번치 커넥터의 기폭소음은 에멀젼류 폭약 0.250kg의 폭발소음보다 약15.6∼20.2dB(A) 낮고, 비전기식 연결뇌관 보다 약13.5∼16.0dB(A) 높고, 전기식 뇌관 보다는 약6.5∼7.5dB(A) 높게 됨을 알 수 있었다. 점화구는 약20m 거리에서 약 7dB(A)이하 이었다. 에멀젼류 폭약의 폭발과 번치 커넥터의 기폭소음에 미치는 주(主)소음원은 에멀젼류 폭약의 약량과 번치 커넥터의 도폭선임을 확인하였다.

• Korean Journal of Fisheries and Aquatic Sciences
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• v.33 no.4
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• pp.348-355
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• 2000

This paper described the relationship between the behavior of the Israeli carp, Cyprinus carpio and the environmental noise level due to the dynamite explosion work. The experiment was conducted in the cage ($L10{\times}W4{\times}D4 m$) of aquaculture located at Chungjoo Lake, Chechon, in 1997. The fish trajectory was obtained by the telemetry system in which a pulsed ultrasonic pinger ($50 kHz, {\phi}16{\times}L70 mm$) attached to the fish was tracked three dimensionally, and the underwater noise levels were measured. The results of the study were as follows: 1. The underwater noise levels in the normal blasting measured at a distance of 400 m from the source of noise increased by $40 dB (re 1 {\mu}Pa)$ compared to the levels before explosion. The dominant frequency and the increased power spectrum level of the underwater noise by the explosion work were $75 to 100 Hz and 22.9 to 35.3 dB$, respectively. 2. The underwater noise levels in the test blasting measured at a distance of 350 m from the source of noise increased by average $49.5 dB (re 1 {\mu}Pa)$compared to the levels before explosion. 3. The swimming area of the fish was reduced with the time after explosion, and after more than one hour the fish represented the similar swimming area and behavior to the status of right before explosion. 4, The swimming depth layer of the fish was most of the case at the sea surface less than 1,0 m except during explosion or right after of it. But the fish swam downward when an external stimulus like the explosion noise was given to the fish. 5. The average swimming speeds of the fish before, during and after the works were about 1.2 times, 1.9 times and 1.0 times of the body length, respectively, and the speed of the fish with explosion was faster 1.6 times than the speed without of that. Consequently, the explosion noise levels measured by this study were sufficiently high to affect the fish, and the heavy shock by the explosion works could produce a considerable unfavorable effects to the fish.

• Journal of Korean Tunnelling and Underground Space Association
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• v.10 no.3
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• pp.207-219
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• 2008

In urban areas, it is very often to excavate ground adjacent to existing structures for the construction of new buildings. Deformation and vibration induced by such construction activities may cause damages to the existing structures and petitions from citizens. To secure safety of the existing structures, particularly of tunnels, establishment of general guidelines on vibration have been crucial concerns, although some institutions have their own guidelines which are not generally accepted. This study aims establishing guidelines for tunnel safety due to blast-induced vibration. Numerical methods are adopted for this study. Blast load equation proposed by International Society of Explosive Engineers (2000) is used to decide detonation pressure. Analysis models were obtained from the construction cases of Seoul Metros. By performing dynamic numerical analysis, vibration velocity of an existing tunnel is evaluated. The numerical results are verified by comparing with the field measurement data obtained in excavation sites adjacent to an existing tunnel. Based on the results vibration safety zone is proposed. Influence circle for vibration velocity is drawn and the area not exceeding the allowable vibration velocity is established.

• Journal of the Korean Geotechnical Society
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• v.40 no.2
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• pp.7-17
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• 2024

Vibrations were measured at the surface of a GTX-A site to assess the impact of blasting on underground tunneling. A numerical analysis was conducted using the same ground and blast conditions as those at the site, accompanied by a comparative analysis of other GTX-A sites. This analysis determined the maximum vibration velocity at regular intervals directly above the blasting point at each site. The results were compared with domestic and international vibration standards to establish the vibration measurement range. The specified vibration measurement locations in domestic regulations—"measuring from the closest part of the structure's foundation to the blasting source, and if conditions make it impossible, measuring from the nearest surface to it"—were evaluated. Furthermore, this study underscores the significance of considering the tunnel drilling depth and soil conditions when selecting a vibration measurement location.

• Explosives and Blasting
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• v.21 no.1
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• pp.85-94
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• 2003

발파후에 2차연소 또는 폭발(이하, 2차연소라 한다. )이 일어났다는 사실은 폭약이 폭발후에 어떤 가연성가스가 발생하고 그 가연성가스가 잔존하는 폭발열 또는 기타의 점화원에 의해 연소되었음을 의미한다. 폭약이 폭발하였을 때, 발생 가능한 가연성물질은 유리탄소, 일산화탄소, 수소 등으로 추정할 수 있는데 실험결과에서는 가연성물질의 주성분이 수소인 것으로 나타났다. 본 연구에서는 에멀존계 함수폭약이 산소평형, 알루미늄함량, 알루미늄형태와 크기 그리고 포장지의 두께에 따라 수소가 발생되는 양을 가스크로마토그라피를 이용하여 측정하였다. 상기의 열거한 요인들은 모두 수소발생량과 관계가 있는데, 이중에서도 가장 중요한 요인은 산소평형과 알루미늄의 함량인 것으로 나타났다. 한 예로 알루미늄이 15%가 포함되고 산소평형이 -10인 에멀존계 함수폭약은 폭발후에 19.4%의 수소를 함유하고 있는 후가스를 발생시켰으며 이 가스를 포집하여 공기중에 방출시키면서 성냥불을 가까이 하였더니 연소가 되었다. 따라서 에너지를 높이기 위하여 알루미늄의 함량을 높이고 산소평형을 지나치게 마이너스로 설계한다면, 2차연소는 언제든지 발생할 가능성이 있다고 판단된다. 알루미늄의 함량을 가능한 적게, 산소평형을 가능한 0에 가깝게 설계해야 만이 2차연소 현상을 방지할 수 있을 것이며 ㄸ한 최적의 설계뿐만이 아니라 정확한 제조와 품질검사도 2차연소 현상을 방지하는데 중요한 몫을 할 것으로 판단된다.

• Explosives and Blasting
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• v.28 no.1
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• pp.40-54
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• 2010

The messer shield method applys mainly to a tunnel with small cross-section of a weathered soil or weathered rock district and is fulfilled mostly by man-power excavation. but in case that hard rock exposes on tunnel face, incredible is an application of the rock-splitting method using a hydraulic power or a blasting method. This study represents the case of a blasting method which can control to be practiced by the minimum charges of 125 g an initial vibration occurring at the cut instead of the rock-splitting method, even though water pipe and gas pipe are closely adjacent.

• Explosives and Blasting
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• v.30 no.1
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• pp.37-51
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• 2012

In this case of "Seongnam~Yeoju double-lanes railroad construction", there were safety facilities which were concerned about damages from vibration and noise. In the project design stage, the rock-splitter method was designed to prevent them. The electronic blasting was considered to improve construction speed and economic value as an alternative tunnelling method, complying with the site's vibration criteria(cowhouse : 0.09cm/sec, residence : 0.2cm/sec). In the environment evaluation report of the eDev, tunnel electronic blasting systems, the blasting pollutions can be managed by the electronic blasting method. The results were successfully conducted with high speed construction without any damages to adjacent facilities.

• Explosives and Blasting
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• v.20 no.1
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• pp.25-34
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• 2002

일반적으로 도심지에서 터널 시공을 위한 암반굴착 작업은 주변 보안물건에 대해 직접적인 피해를 유발시킬 수 있는 공해요소인 진동을 허용기준값 이하로 제어할 수 있으면서 상대적으로 시공성과 경제성이 뛰어난 공법으로 수행되어야 한다. 본 사례에서는 각내의 대표적인 문화시설인 예술의 전당 하부를 통과하는 우면산 터널 공사현장에서 암반굴착공법으로 고려한 TTM 장비를 이용한 기계굴착, 플라즈마 공법, 유압장비를 이용한 할암공법, 겔파쇄 공법, 미진동파쇄기를 이용한 공법, 진동제어발파공법에 대한 현장 적용성을 시험시공 등을 통해 평가한 내용과 결과를 제시하였다. 비록 각 도심지 터널의 현장 상황이나 주변 여건에 따라 이 현장에서의 시험시공 내용이나 적용 결과를 그대로 적용할 수는 없겠지만, 진동제어 암반굴착 공법에 대한 시험시공이나 선정 과정에 이 사례연구가 개략적인 참고자료로 활용될 수 있을 것이다.