• 미생물학회지
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• 제54권4호
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• pp.343-353
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• 2018

이전 연구에서 우리는 RDX (hexahydro-1,3,5-trinitro-1,3,5-triazine) 분해세균 Pseudomonas sp. HK-6에서 xenobiotic reductase B를 암호화하는 xenB 유전자의 돌연변이 균주를 이용하여 RDX 스트레스에 대한 xenB 유전자의 역할에 관하여 연구를 보고하였다[Lee et al. (2015) Curr. Microbiol. 70(1): 119-127]. 본 연구에서는 Pseudomonas sp. HK-6 xenA 돌연변이 균주로 연구 범위를 확대하여 RDX 스트레스 조건에서 세포반응과 프로테옴 프로필의 변화를 분석하였다. RDX 첨가 배지에서 xenA 돌연변이 균주는 야생균주와 비교하여 RDX를 약 2배 정도 느리게 분해하였으며, RDX 스트레스 하에서 xenA 돌연변이 균주의 생장률과 생존율은 야생균주와 비교하여 낮았다. RDX 스트레스에 의한 심한 형태적 손상이 xenA 돌연변이 균주의 세포 표면에 발생하는 것이 주사전자현미경을 통해서 확인되었다. RDX 스트레스 하에서 야생균주에서 발현된 충격단백질인 DnaK 및 GroEL의 양은 배양 초기 혹은 상대적으로 낮은 RDX 농도에서는 증가하였으나, 배양시간이 길어지거나 높은 RDX 농도에서는 다소 감소하였다. 그러나 xenA 돌연변이 균주에서는 DnaK와 GroEL의 발현양은 RDX 농도가 증가함에 따라 점차 감소되었다. RT-qPCR에 의해 측정된 야생균주에서 dnaA와 groEL의 전사 수준은 RDX 스트레스가 증가된 상태에서 잘 유지되었으나, xenA 돌연변이 균주에서는 점차 감소되어 결국에는 소멸되었다. RDX 스트레스에서 xenA의 돌연변이에 의한 프로테옴 프로필의 변화를 2-DE PAGE를 통해서 관찰한 결과에 따르면 27개 단백질이 감소하고 3개가 증가한 것으로 나타났다. 이들 결과로 보아, 정상적인 xenA 유전자는 RDX 스트레스 하에서 세포의 온전한 형태 유지와 효율적인 RDX 분해 과정을 수행하기 위해서 필요하다는 것을 의미하였다.

• 한국미생물·생명공학회지
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• 제31권1호
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• pp.75-82
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• 2003

환경 오염원으로서 폭약 hexahydro-1,3,5-trinitro-1,3,5-triazine(RDX)에 대한 RDX 분해세균 Pseudomonas sp. HK-6의 세포반응과 형태변화에 대하여 조사하였다. 아치사조건의 RDX농도와 노출시간에 따른 균주 HK-6의 생존율을 분석한 결과, 이 세균의 생존율은 스트레스 충격 단백질의 생성과 비례하였다. 총세포 지방산 조성분석에서 균주 HK-6는 trypticase soy agar(TSA)에서 자랄 때 보다 RDX배지에서 자랄 때 여러 가지 종류의 지방산이 생성되거나 사라지는 것이 밝혀졌다. Anti-DnaK와 anti-GroEL을 이용하여 SDS-PAGE와 Western blot을 통한 분석으로 균주 HK-6는 70 kDa DanK와 60 kDa GroEL을 포함하는 몇가지 스트레스 충격단백질을 생성하는 것으로 밝혀졌다. RDX에 노출된 HK-6배양에서 수용성 단백질 분획에 대하여 2-D PAGE를 실시하였으며, pH 3에서 pH 10 범위에서 약 300 spots가 silver로 염색된 gel상에서 관찰되었다. 그 결과, RDX에 대한 반응으로 10여개의 spots가 현저히 유도 발현되었다. RDX(0.135mM, 12시간)에 노출된 세포는 구멍이 나타나고 표면의 불규칙적인 형태 변화가 일어나 죽게되는 것이 주사 전자현미경을 통하여 관찰되었다.

• 한국군사과학기술학회지
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• 제3권2호
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• pp.219-230
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• 2000

Plastic bonded explosive(PBX) is mainly composed of the nitramine explosives, RDX, HMX, and polymer binders. When the adhesion between nitramine crystals and binder is not particularly strong and can be failed under stress, dewetting occurs rather suddenly and this leads to a significant drop in tensile strength of explosives. Mechnical property of plastic bonded explosive depends on the surface characteristics of filler and binder. In order to design for better adhesion, an understanding of the surface properties of explosive and binder is essential. In this study, 2 kinds of RDX and 4 kinds of ethylene vinyl acetate copolymers are selected, since they are widely used in many plastic bonded explosives. The technical objective of this investigation is to calculate for the surface free energy of RDX and EVA using theory of Fowkes, van Oss, Neumann approaches and Kaelble equation and to predict the interaction between filler and binder from their surface free energies.

• 한국지하수토양환경학회지:지하수토양환경
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• 제20권6호
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• pp.73-84
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• 2015

Nine plant species were selected through vegetation survey at three military shooting ranges at northern Gyeonggi Province. Plants were germinated in normal soil and three seedlings were transplanted to a bottom sealed pot containing sandy loam soils contaminated with either RDX (291 mg/kg) or TNT (207 mg/kg). Planted, blank (without plant), and control (without explosive compound) pots were grown in triplicate at a green house for 134 days. During cultivation, transplanted plants exhibited chlorosis and necrosis in flower and leaf by explosive toxicity and stress. Only three plants, Wild soybean, Amur silver grass, Reed canary grass, survived in TNT treated pot, while seven plant species except for field penny cress and jimson weed, thrived in RDX treated pot. Appreciable amount of TNT (61.6~241.2 mg/g-D.W.) was detected only in plant roots. Up to 763.3 mg/g-D.W. along with 4-amino-2,6-dinitrotoluene, an intermediate of TNT, accumulated in the root of wild soybean. In addition, azoxy compounds, abiotic intermediates of TNT, were detected in TNT treated soils. RDX absorbed average 1,839.95 mg/kg in shoot and 204.83 mg/kg in root. Most of TNT in plant was accumulated in underground part whereas RDX was localized in aerial part. Material balance calculation showed that more than 95% of the initial TNT was removed in the planted pots whereas only 60% was removed in the blank pot. The amount of RDX removed from soil was in the order of Amur Silver Grass (51%) > Chickweed (43%) > Evening primrose (38%). Based on the results of pot cultures, Amur silver grass and Reed canary grass are selected as tolerant remedial plants for explosive toxicity.

• Journal of Welding and Joining
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• 제18권4호
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• pp.38-47
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• 2000

Characteristics of the interface between tube and tube sheet which were formed by explosive expansion and roll expansion, have been studied in the research. The results are as follows: Optimum amounts of explosives for the expansion of Alloy 600 (19.05mm and 15.88mm) were found to be RDX 3.5-8.5g/m. Because explosive expansion caused les strain hardening and increased bounding strength, characteristics of the explosively expanded were better than those of mechanically expanded. As the transition region of the explosive expansion is inactive, the resistance to the stress corrosion cracking increases by 30∼40% compared to the roll and hydraulic expansion.

• 폴리머
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• 제38권2호
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• pp.225-231
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• 2014

고분자 결합제로 vinyl acetate(VA) 함량이 각각 30, 60%인 poly(ethylene-co-vinyl acetate)(EVA)를 사용하여 고농축 복합화약 시뮬란트의 유변학적 특성을 연구하였다. 충전제로는 탄산칼슘 및 research department explosive (RDX)와 물리적 특성이 유사한 Dechlorane을 사용하였다. 회분식 용융 혼련기를 사용하여 농축 현탁계를 혼련하였는데 최대 75 v%까지 충전이 가능하였다. 동적 기계적 물성 변화를 측정한 결과 Dechlorane이 탄산칼슘보다 결합제수지와 더 높은 상호작용을 보였다. 일정 전단속도 방식과 일정 전단응력 방식의 평판-평판 레오미터를 사용하여 현탁계의 미세구조의 변화가 유변물성에 미치는 영향을 조사하였고, Krieger-Dougherty 식을 사용하여 최대 충전 부피분율 및 고유점도를 구하였다. EVA31/Dechlorane 현탁계의 최대 충전 부피분율은 약 70 v%이고, 혼련시 전단응력이 약 2000 Pa 정도 부가되는 것이 적절함을 알 수 있었다.

• 화약ㆍ발파
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• 제17권4호
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• pp.32-50
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• 1999

This study deals with interface charactristics of tube and tubesheet of the nuclear steam generator by the explosive expansion in order to take advantage of optimum expansion ratio, pull-out strength and leakage tightness and improvement of the resisitance on the stress corrosion cracking for low residual stress. The paper also show the relationship between roll, hydraulic and explosive expansion. The results obtain are as follows (1) Because of the explosive bonding is to use the high speed pressure and energy by the explosive, workability is good, bonding region is homogenous (2) Expansion ratio is 2.7%, Pull-out strength 850kg, Leakage strength $500kg/cm^2$. Clearance gap is 10~30mm in case of explosive expansion and interface structure of the tube and tubesheet is optimum condition. (3) As the transition region of the explosive expansion is inactive, the resistance of the stress corrosion cracking is increases 30~40% compare to the roll and hydraulic expansion.

• International Journal of Aeronautical and Space Sciences
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• 제16권1호
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• pp.50-63
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• 2015

Explosive bolts are one of pyrotechnic release devices, which are highly reliable and efficient for a built-in release. Among them, ridge-cut explosive bolts which utilize shock wave generated by detonation to separate bolt body produce minimal fragments, little swelling and clean breaks. In this study, separation phenomena of ridge-cut explosive bolts or ridge-cut mechanism are computationally analyzed using Hydrocodes. To analyze separation mechanism of ridge-cut explosive bolts, fluid-structure interactions with complex material modeling are essential. For modeling of high explosives (RDX and PETN), Euler elements with Jones-Wilkins-Lee E.O.S. are utilized. For Lagrange elements of bolt body structures, shock E.O.S., Johnson-Cook strength model, and principal stress failure criteria are used. From the computational analysis of the author's explosive bolt model, computational analysis framework is verified and perfected with tuned failure criteria. Practical design improvements are also suggested based on a parametric study. Some design parameters, such as explosive weights, ridge angle, and ridge position, are chosen that might affect the separation reliability; and analysis is carried out for several designs. The results of this study provide useful information to avoid unnecessary separation experiments related with design parameters.

• 화약ㆍ발파
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• 제17권4호
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• pp.18-31
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• 1999

The explosive forming has been used for many year to expand tubes into tubesheets. this process has demonstrated ability to direct carefully the energy of an explosive to expand tubes into tubesheet holes without damaging the tubesheet and without causing the excessive cold work at the tube I.D. that is normally associated with mechanical expansion. The success of explosive tube expansion provided the background for the development of the explosive tube plug. The main results are as follows : (1) The optimum explosives and explosive qualities are PETN, RDX, HMS and about 18~31gr/ft of explosive plugging in nuclear steam generator. (2) Explosive plugging's thickness is 0.9~1.8mm. If groove of 0.4 mm formed in plug outside, For the hydraulic leakage is go up, explosive plugging of formed groove are applicate tube and tubrplate. (3) Sheath is designed on the polyethylene of low density, In thermal impact test of the $430^\circ{C}$, hydraulic leakage is $300kg/cm^2$. (4) About 10~60mm oxide inclusions are existed on the space of explosive plug and tube protect to the leakage.