UV and O3 are materials used in the water treatment process, and many studies have been reported to remove organic matters, contaminants, and microorganisms. In this study, we were investigated effects of Chirnomidae (Chironomus flaviplumus, Chironomus riparius), which are contamination indicator species to exposure UV and O3 for the survival rate, body color change and gene expression response. The survival rate of C. flaviplumus exposed to UV decreased to about 70% after 24 hours, and C. riparius about 50%. There was no change in the survival rate of C. flaviplumus exposed to O3, and C. riparius decreased to 95% after 10 minutes of exposure, but there was no change during the subsequent exposure time. In addition, UV and O3 exposure to the two species in body color faded in a time-dependent. In the HSP70 gene expression, C. riparius showed an increase in expression after UV exposure compared to the control group, and a significant difference was shown 12 hours after exposure (P<0.05). C. flaviplumus exposed to O3 showed a relatively low expression compared to the control group, and showed a significant difference at 10 minutes and 1 hour after exposure (P<0.05). These results reported the ecotoxicological effects on Chironomidae according to UV and O3 exposure. Therefore, the results of this study can be used as basic data to understand the effects of UV and O3, which are disinfectants used in water treatment plants, on Chirnomidae entering plants. Key words: Chironomus flaviplumus, Chironomus riparius, UV, O3, acute toxicity, survival
돌기해삼 Apostichopus japonicus는 주요 양식 대상 무척추동물로서 우리나라 연안 해역에 서 식하고 있다. 본 연구는 방류 방법에 따른 단기간의 생리학적 스트레스 정도를 평가하기 위하 여 heat shock protein 90 (HSP90) 유전자의 발현 변화를 실시간 정량적 중합효소연쇄반응법 으로 조사하였다. 어린 돌기해삼을 비닐봉지에 산소 포장하여 30분간 수송하거나 방류 해역의 간조기에 1시간 공기 중에 노출된 실험군의 HSP90 유전자 발현은 대조군의 HSP90 유전자 발현에 비하여 통계학적으로 유의미하게 증가하였다(수송 후 실험군 p=0.001; 간조기 실험군 p=0.032). 어린 돌기해삼을 방류 후 6시간까지 분석한 결과, 선상에서 씨뿌림 방식으로 방류된 6시간째의 개체 및 호스를 통과하여 수중으로 방류된 2~6시간째의 HSP90 유전자 발현율은 대 조군에 비하여 약간 감소하는 경향을 보였다(씨뿌림 실험군 p=0.069; 호스 방류군 p=0.093). 한 편, 잠수부에 의해 수중에서 방류된 어린 돌기해삼은 방류 후 시간이 경과할수록 HSP90 유전 자 발현율은 증가하는 패턴이 관찰되었다(p=0.061). 이상의 결과는 방류된 어린 돌기해삼의 단기간 스트레스 반응 연구와 효과적인 방류 방법의 개발에 HSP90 유전자 발현이 유용하게 사용될 수 있음을 시사한다.
참다슬기 아가미 조직으로부터 heat shock protein 70 유전자를 분리 · 동정하였다. 참다슬기 HSP70 cDNA의 open reading frame (ORF)는 1,917 bp로 639개의 아미노산을 암호화하여 분자 량은 약 70 kDa으로 예측되었다. 생물정보학 배열분석에 의해 HSP 유전자 기능과 관여되어 있는 3가지 주요 signature motifs와 보존된 도메인을 확인하였다. 계통학적 분석을 통하여 참 다슬기 HSP70 유전자는 왕우렁이 Pomacea canaliculate와 같은 클러스트에 포함된다는 사실을 확인하였다. 수온 및 염분 변화에 따라, 참다슬기 HSP70 mRNA 유전자 레벨은 유의적으로 증 가하였으며(p < 0.05), 이는 외부자극요인을 파악할 있는 분자생물학적 마커로서 활용될 수 있 을 것으로 사료된다.
This study investigates changes in the mechanical behaviors, especially hardness and indentation load-displacement curves, of thermal barrier coatings (TBCs) brought about by thermal shock. The TBCs on the Nickel-based bondcoat/superalloy was prepared with diameters of 25.4 mm and 600 μm thickness. The results of thermal shock cycling test from 1100 oC of the highest temperature indicate that the thermal shock do not influence on the mechanical behavior, but a continuous decrease in porosity and increase in hardness were observed after 1200 thermal shock cycles; these changes are believed to be due to sintering of thermal barrier coating materials. The results that no degradation in the indentation load-displacement curves indicate that the coating shows good thermal shock resistance up to 1200 cycles at 1100 oC in air.
This study investigates the thermal shock property of a polycrystalline diamond compact (PDC) produced by a high-pressure, high-temperature (HPHT) sintering process. Three kinds of PDCs are manufactured by the HPHT sintering process using different particle sizes of the initial diamond powders: 8-16 μm (D50 = 4.3 μm), 10-20 μm (D50 = 6.92 μm), and 12-22 μm (D50 = 8.94 μm). The microstructure observation results for the manufactured PDCs reveal that elemental Co and W are present along the interface of the diamond particles. The fractions of Co and WC in the PDC increase as the initial particle size decreases. The manufactured PDCs are subjected to thermal shock tests at two temperatures of 780oC and 830oC. The results reveal that the PDC with a smaller particle size of diamond easily produces microscale thermal cracks. This is mainly because of the abundant presence of Co and WC phases along the diamond interface and the easy formation of Co-based (CoO, Co3O4) and W-based (WO2) oxides in the PDC using smaller diamond particles. The microstructural factors for controlling the thermal shock property of PDC material are also discussed.
This study investigates the microstructure and thermal shock properties of polycrystalline diamond compact (PDC) produced by the high-temperature, high-pressure (HPHT) process. The diamond used for the investigation features a 12~22 μm- and 8~16 μm-sized main particles, and 1~2 μm-sized filler particles. The filler particle ratio is adjusted up to 5~31% to produce a mixed particle, and then the tap density is measured. The measurement finds that as the filler particle ratio increases, the tap density value continuously increases, but at 23% or greater, it reduces by a small margin. The mixed particle described above undergoes an HPHT sintering process. Observation of PDC microstructures reveals that the filler particle ratio with high tap density value increases direct bonding among diamond particles, Co distribution becomes even, and the Co and W fraction also decreases. The produced PDC undergoes thermal shock tests with two temperature conditions of 820 and 830, and the results reveals that PDC with smaller filler particle ratio and low tap density value easily produces cracks, while PDC with high tap density value that contributes in increased direct bonding along with the higher diamond content results in improved thermal shock properties.
This paper presents a method for the assesment of thermal and vibration fatigues in integral exhaust manifold/turbine housing system. Most of failures on turbine housing are observed by thermal cyclic loads. In order to predict thermal failures by finite element analysis, we considered the temperature-dependent inelastic materials and transient temperature histories based on the thermal shock test. The results showed that the plastic strains of localized critical regions such as valve seat coincided well with crack locations from an endurance test. But, some failures around neck areas of turbine housing could not predict from thermal stress analysis. These cracks were originated due to the vibration excitations near resonance frequencies within engine operating ranges. The stress results of neck areas, which divided by temperature dependent yield stresses, from harmonic analysis showd a good agreement with experimental results.
We have evaluated the role of Ag additions on the strength, fracture toughness, elastic modulus and resistance to thermal shock of (YBCO) superconductor. Addition of 10 vol.% Ag improved strength and fracture toughness, whereas, decreased elastic modulus of YBCO. In addition, YBCO-Ag composites improved resistance to thermal shock probably due to enhanced strength, fracture toughness and thermal conductivity as a result of Ag addition. It is to be noted that YBCO-Ag made by mixing with solution showed slightly higher strength, fracture toughness and resistance to thermal shock, compared to that made by mixing with metallic Ag powder. These improvements are believed to be due to the microstructure of more finely and uniformly distributed Ag particles.
PAN계 탄소섬유와 페놀수지를 이용하여 rod를 인발성형 한 후, 다른 섬유분율을 갖는 두종류의 hexagonal type 4D 프리폼을 제작하였다. 석탄계 핏치를 가압함침 탄화공정을 통하여 함침한 후 탄화와 고온열처리를 하였다. 이와 같은 공정을 반복하여 고밀도화된 4D CRFC를 제조하였다. 열충결 시험 후 새로운 크랙이 생성되었을 뿐만 아니라 기존의 크랙이 확장되었으며 이와 같은 크랙들은 공기와의 접촉면을 제공하여 중량감소를 보였다. 공기 산화 저항성을 고온열처리 공정을 거친 것이 약 20% 우수하게 나타났다. 4D CFRC의 밀도와 섬유의 분율이 높을 수록 삭마 저항성이 커지고, 삭마량은 시간에 따라 선형적으로 증가하였으며 type II가 type I보다 삭마저항성이 우수하였다. 삭마 메카니즘을 관찰한 결과 1차적으 기질의탈리가 먼저 일어난 다음 섬유가 삭마되었다.
여러가지 화학 조성을 갖는 aluminium titanate mullite복합제는 AI2O3분말을 알콜 분산용액에서 Si(OC2H5)4과 Ti(OC2H5)4의 단계적인 가수 분해로 합성되었다. Mullite함량이 20-50vol%인 소결체(1600˚C/2h)는 비교적 높은 강도와 낮은 열팽창 계수를 갖는 aluminium titanate를 개발할 수 있는 가능성을 보였다. 이와 같은 결과는 mullite로 인한 aluminium titanate의 입자 크기의 억제와 미세균열에 의하여 얻어졌다. aluminium titanate의 함량이 70-80vol% 복합재료는 우수한 열충격 저항성을 지녔으며 상온 강도는 31-45MPa이었다. 열충격 저항성, 영률, sound velocity화 열팽창 계수가 연구되었다.
In order to examine if arsenic, one of environmental stresses, contributes to hypertension as one of cardiovascular pathological factors, this study was performed in vivo and in vitro, using intacted or pithed rats and aorta ring preparation, respectively. And also the relationship between expression of heat shock protein (HSP) 90 and vasoactives-induced contractile response was elucidated.
To measure blood pressure, the carotid arterial pressure was recorded on physiograph(Grass Co. 79E) connected to strain gauge. On the other hand, contractile response of vascular ring preparation isolated from rat was determined in organ bath and was recorded on physiograph connected to isometric transducer. And HSP was detacted by Western blotting whole cell lysis.
Preganglionic nerve stimulation was increased by 26.0% in arterial pressure of rat treated with arsenic.
Vascular contractile response was monitored and HSP were measured by Western blotting of whole lysis prepared from samples exposed with 0, 0.5, 1, 2 and 4 mM of arsenic for 8 hours. The dose-vascular responses of potassium chloride were augmented by increasing dose of arsenic in the strips exposed to arsenic for 8 hours, and were not augmented for 1, 3, 5 hours. And the response of relaxation of rat aorta induced by histamine was not influenced by arsenic stress.
The increase of HSP 90 expression in rat aorta was pronounced at 8 hours after 4 mM of arsenic treatment, but HSP 60 expression was not.
Arsenic stress not only increased the expression of HSP 90 in the rat aorta, but also augmented contractions to potassium chloride.
These results indicated that arsenic stress was sufficient to induce heat shock protein 90, resulting in increased vascular contractility in rat aorta.