• Title/Summary/Keyword: Electric Detonator

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Review of Delay Time of Electric Detonator and Blast Design Using the Sequential Blasting Machine (지발뇌관의 시차와 다단발파에 대한 고찰)

  • 두준기
    • Explosives and Blasting
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    • v.18 no.4
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    • pp.29-42
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    • 2000
  • 발파에 사용하는 지발뇌관의 정확한 지연초시클 알지 못하면 발파진동제어 발파에서 허용진동값을 초과하여 실패하는 경우가 많다. 발파공의 지발단차를 설계함에 있어서 지발뇌관 사이의 실제 기폭초시가 8 ms를 초과하도록 기폭초시를 배열하기 위해서는 지발뇌관 자체의 지발초시 오차가 발파에 어떠한 영향을 미치는 가를 면밀하게 검토하여 발파진동을 제어할 수 있도록 지발뇌관 실제 초시에 의해 순차적으로 기폭될 수 있는 지발시차로 발파를 설계해야 한다. 지발뇌관의 제조기준과 명목상의 호칭 초시 및 실제 초시 등이 어떤 특징을 나타내며 발파를 설계할 때에는 어떤 초시를 기준하여 설계해야 진동제어를 실현할 수 있는 가를 알아보고, 국내의 전기 지발뇌관과 다단발파기를 이용한 발파설계 사례는 어떤 종류가 있으며, 다단발파 구역의 회로분할과 분할구역에 대하여 지발뇌관 및 다단발파기에 의한 지연시차 배열은 어떻게 조합해야 올바른 진동제어 발파가 될 수 있는 지를 검토한다. 지발뇌관의 실제 초시를 고려하지 않은 발파에서 설계시의 허용기준과 관계없이 과대한 발파진동이 발생되어 공해가 발생되므로 지발뇌관의 실제 초시를 기준하여 중복초시와 적정한 초시간격이 유지될 수 있도록 설계하는 기술이 필요하다.

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A Case Study of the Underwater Blasting Using Emulsion Explosives (에멀젼폭약을 사용한 수중발파 사례)

  • An, Bong-Do;Lee, Ik-Joo;Heo, The-Moon
    • Explosives and Blasting
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    • v.25 no.2
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    • pp.71-78
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    • 2007
  • In many cases of underwater blasting in South Korea, the special blasting is mainly used for deepening harbor, installing gas pipes, or well blasting to build a bridge. The procedure of well blasting is almost same with shaft blasting, but the difference is that water is filled in before blasting. In case of deepening blasting under water, the first step like drilling, arranging explosives, and wire connection is done on a barge, then the next step such as charging and tamping is accomplished under water by expert divers. Therefore, underwater blasting needs precise and exact plan before blasting. In this paper, authors would like to introduce a case of underwater blasting for deepening the Busan new port with emulsion explosives and non-electric detonators in order to get some of 8,500TEU out sized container vessels entered into the port and to make safe. Considering environment and vibration, the blasting was controlled to minimized the damage to the lighthouse nearby. It will be great help to many other blasting sites where emulsion explosives and non-electric detonators are used for underwater blasting through this case.

Underwater Blasting for Removing Todo Island in the Sea of Pusan Newport by Using Bulk Emulsion Explosives and Non-electric Detonators (벌크 에멀젼 폭약과 비전기뇌관을 이용한 부산신항 토도 제거 수중발파)

  • An, Bong-Do;Kim, Gab-Soo;Lee, Soo-Hyung;Jung, Byung-Youl;Lim, Dae-Kyu
    • Explosives and Blasting
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    • v.38 no.4
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    • pp.37-45
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    • 2020
  • Todo was an uninhabited island located in the sea of Pusan Newport. It was a small island with the height of 32 m above sea level, and its area including the submerged part was approximately 24,400 ㎡. Unfortunately, the island was located exactly in the middle of the narrow entrance way to the North and South Container Wharfs of Pusan Newport so that a number of ships had to turn quickly to avoid collision with the island, which frequently caused collisions with other ships or cranes. To avoid such a danger and make the water way wider and deeper, the Ministry of Oceans and Fisheries decided to remove the island. This was believed to make even super-large vessels operate safely in the sea of Pusan Newport so that the competitiveness of the port could be highly enhanced. This paper describes in detail the whole process of the removing work, which was the first case of successful underwater blasting operation using bulk emulsion explosives and non-electric detonators to remove a whole island in South Korea.

Considerations on the Safety of Electric Caps Based on Measured Electrical Resistivity of Rock Samples (암석의 전기비저항 측정을 통한 전기뇌관의 사용 안전성 검토)

  • Choi, Byung-Hee;Ryu, Chang-Ha;Shin, Seung-Wook;Kim, Soo-Lo
    • Explosives and Blasting
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    • v.34 no.4
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    • pp.19-27
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    • 2016
  • Much care should be taken when electric caps are used in blast site than when non-electric initiation systems are used. This is because electric caps can cause premature firing or misfires if stray currents of high magnitude flow into the blasting circuit. If the rock has higher electrical conductivity or lower electrical resistivity, such risks will be increased because the rock will provide more passages for the stray currents to flow into the blasting circuit. In this study, several rock samples obtained at a blast site were tested for electrical resistivity to decide whether electric caps could be used or not in the site. The measured electrical resistivity was $39{\sim}47{\Omega}{\cdot}m$ for the rock samples that had a higher content of metal sulfides. Contrary, the resistivity was $15000{\sim}21000{\Omega}{\cdot}m$ for ordinary rocks. Especially, in the case of the rock of electric resistivity of $39{\Omega}{\cdot}m$, only 2-V electric potential enables a stray current to flow through the rock of 1-m length, which can cause the premature firing of a detonator whose initiation current is 0.4 A. This result shows that electric initiation system should not be used in the site because rocks containing much amount of metal sulfides are widely distributed there.

Study on the Dynamic Response Characteristics of Impact Force Sensors Based on the Strain Gage Measurement Principle (변형률 게이지 측정원리를 이용한 충격하중 측정 센서의 동적응답 특성에 관한 연구)

  • Ahn, Jung-Lyang;Kim, Seung-Kon;Sung, Nak-Hoon;Song, Young-Soo;Cho, Sang-Ho
    • Explosives and Blasting
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    • v.29 no.1
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    • pp.41-47
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    • 2011
  • In order to estimate blast damage zone and control rock fragmentation in blasting, it is important to obtain information regarding blast hole pressure. In this study, drop impact tests of acrylic, aluminium, steel sensors were performed to investigate the dynamic response characterizations of the sensors through the strain signals. As a result, the strain signals obtained from the steel sensors showed less sensitivity to impact force level and experienced small changes with various length of the sensors. The steel sensors were applied to measure the impact force of an electric detonator.

A Case Study of Underwater Blasting (수중발파 사례 연구)

  • 정민수;박종호;송영석
    • Explosives and Blasting
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    • v.22 no.3
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    • pp.57-64
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    • 2004
  • There are two major types of underwater blasting at Korea, bridges and harbor construction work. Pier blasting for lay the foundation bridges construction is used dry excavation working (drilling and charging) after pump out water and then fire pump in water that is same as bench blasting. In contrast, underwater blasting for harbor construction and increase of harbor load depth is used to barge with digging equipment that is in oder to drilling on the surface and blasting work(charge, hook-up) under water. Thus, there are need to special concern such as charge method and hook-up method different from tunnel blasting work and bench blasting work. If do not use special concern breaks out dead pressure and mis fire because of there are so many difficult condition such as water pressure, obstruct field of vision. In this study underwater blasting at Busan Harbor Construction have consider with special concern that is plastic pipe charge method used to MegaMITE I and specialized buoy hook- up method make far initial system detonate on the surface used to TLD. The results is designed blast pattern charge per delay effect an inspection of verify between predict velocity and measure velocity. minimized break out mis fire consideration charge method, hook up method. According to result best underwater blasting design is 105mm drilling dia, MeGAMITE II, HiNLL Plus(non electric detonator).