钻井液化学剂可生物降解性评定方法

介绍研究钻井液化学剂生物降解性的必要性及开发可生物降解钻井液的进展。阐述了常用的评定有机物生物降解性的试验方法。推荐采用BOD_5／COD_Cr比值来评定我国石油行业钻井液化学剂及油田化学剂的可生物降解性，规范石油行业生物降解研究工作，保证评定结果的可靠性和可比性。     

油气钻井作业对地下水污染治理研究＊

分析了钻井作业对地下水污染的特点、污染途径,针对性地提出了钻井作业对地下水污染的预防措施,以及污染物处理技术,其中氧化还原技术、气体抽取技术、环境生物技术主要用于有机物污染治理,SRB技术、废弃钻井液固化技术、钻井液转换为水泥浆(MTC)的固井技术可用于处理废弃钻井液。钻井引起的污染治理应以"预防为主,防治结合",切实推行清洁生产和HSE管理。     

新疆油田钻井井喷风险分级及井控管理

为了减少新疆油田钻井溢流井喷事件,杜绝井喷失控事故,在统计新疆油田影响钻井井喷风险的地质环境因素的基础上,利用模糊数学理论建立了油田基于地质环境因素的钻井井喷风险分级模型,对各个区块的钻井井喷风险程度进行了分级,结果表明南缘山前构造勘探开发区块及克拉美丽气田的钻井井控风险值最高。建议对新疆油田钻井井控进行分级管理,针对不同的钻井井喷风险等级,制定了针对性的井控对策,建议在井控设计时考虑钻井井喷风险分级设计。     

“三高”气田钻井过程硫化氢泄漏动态风险分析

传统的H2S泄漏风险分析方法不能很好地对事故发展过程进行动态分析,导致分析结果偏离实际。基于贝叶斯方法,构建了高温、高压、高含硫（“三高”）气田钻井过程中H2S泄漏的蝴蝶结模型并提出将其转化为贝叶斯网络,在事故已发生的情况下更新基本事件发生的概率。然后,假定事故后果在确定的时间段内发生的累积次数已知的条件下,更新安全屏障及事故后果发生的概率,从而完成对H2S泄漏的动态风险分析。结果表明,该方法克服了传统静态定量分析方法中的不足,可动态评估导致H2S泄漏的基本事件发生的概率和对顶事件发生的影响程度,并动态反映安全屏障和事故后果的风险变化,能为钻井过程中H2S泄漏的风险分析及防控措施提供参考。     

高突矿井大采高工作面瓦斯抽采技术及实践

为解决大采高厚煤层工作面回采期间瓦斯超限难题,应用顶板走向长钻孔中位钻孔和下临近层底板定向长钻孔等瓦斯抽采措施,对回采面瓦斯进行了多源头治理。通过对顶板走向长钻孔的抽采效果考察,确定其垂直层位为40±5 m范围、水平层位为50±10 m范围为最佳瓦斯抽采区域;中位钻孔合理的垂直层位为20 m左右,水平层位为45~50 m范围抽采效果最佳;下临近层底板定向长钻孔是拦截下部5#煤和7#煤向上部采掘空间涌出瓦斯的有效手段,其最佳的水平层位为距巷道轮廓线20 m范围,垂直层位为钻孔布置在下临近层煤层中。通过对3种不同瓦斯治理措施的综合评价考察,确定顶板走向长钻孔是治理回采面最为有效的措施,其抽采量占工作面回采期间总抽采量的79.6%,中位钻孔抽采和下临近层底板定向长钻孔抽采是回采面回采期间的辅助性措施。措施使用后,工作面上隅角瓦斯浓度保持在0.4%~0.6%之间,有效保证了工作面的安全高效回采。     

钻井平台石油污染法律问题研究——从墨西哥湾石油污染事件谈起

2010年4月20日美国路易斯安那州沿岸的一座石油钻井平台发生爆炸起火,11人死亡.底部油井漏油量从每天5千桶,到后来达2万5千至3万桶,演变成美国历来最严重的油污大灾难.海洋占整个地球表面积的71%,蕴藏着丰富的资源和能源,随着现代新科学技术的发展,海洋石油开采技术也日渐成熟,为缓解能源短缺提供了良好的解决途径,但同时也给海洋环境带来了问题.国际社会极度关注海洋油污问题,并进行了不懈的努力以减轻油污状况,改善海洋环境.本文主要考察针对海洋钻井平台的石油开采活动以及事故产生油污的相关国际国内法律文件,通过对相关法律文件的分析,揭示现有国内法律文件的不足,提出进一步完善相关法律的建议.     

苏里格气田气井现状及钻井泥浆的成分、危害

随着苏里格气田天然气探明储量的增加,气田的开发力度逐渐加大,气田开发带给当地的生态环境问题也在凸显。本文介绍了苏里格气田的现状及钻井泥浆的成分及危害,为减少环境危害提供理论依据。     

Application of Neomysis awatschensis as a standard marine toxicity test organism in China

The small mysid crustacean Neomysis awatschensis was collected in the west coast of Jiaozhou Bay, Qingdao, China in 1992 and acclimated and cultured in laboratory conditions since then. Standard acute toxicity tests using 4--6 d juvenile mysids of this species were conducted and the results were compared with Mysidopsis bahia, a standard toxicity test organism used in the US in terms of their sensitivities to reference toxins, as well as their taxonomy, morphology and geographic distributions. Because of its wide distribution along the Chinese coast, similar sensitivity to pollutants as M. bahia, short life history, small size and the ease of handling, this study intended to use N-awatschensis as one of the standard marine organisms for toxicity testing in China. The species were applied to acute toxicity evaluations of drilling fluid and its additives, organotin TPT and toxic algae, and to chronic (life cycle) toxicity assays of organotin TPT and a toxic dinofalgellate Alexandrium tamarense, respectively. Using N. awatschensis as a standard toxicity testing organism in marine pollution assment in China is suegested.     

输油管线反打孔盗油抢修施工中的HSE管理初探

笔者就长输原油管道反打孔盗油抢修施工中如何进行HSE管理提出自己的看法，建议从5个方面重点考虑，并对此5个方面中应当注意的事项一一说明。     

Natural pollution caused by the extremely acidic crater lake Kawah Ijen, East Java, Indonesia

Background. Aims and Scope Lakes developing in volcano craters can become highly acidic through the influx of volcanic gases, yielding one of the chemically most extreme natural environments on earth. The Kawah Ijen crater lake in East Java (Indonesia) has a pH 〈 0.3. It is the source of the extremely acid and metal-polluted river Banyupahit (45 km). The lake has a significant impact on the river ecosystem as well as on a densely populated area downstream, where agricultural fields are irrigated with water with a pH between 2.5 and 3.5. The chemistry of the river water seemed to have changed over the past decade and the negative effect in the irrigation area increased. A multidisciplinary approach was used to investigate the altered situation and to get insight in the water chemistry and the hydrological processes influencing these alterations. Moreover, a first investigation of the effects of the low pH on ecosystem health and human health was performed. Methods Water samples were taken at different sites along the river and in the irrigation area. Sampling for macroinvertebrates was performed at the same sites. Samples of soil and crop were taken in the irrigation area. All samples were analysed for metals (using ICP-AES) and other elements, and concentrations were compared to local and international standards. Results and Discussion The river carries a very high load of SO4, NH4, PO4, Cl, F, Fe, Cu, Pb, Zn, Al and other potentially toxic elements. Precipitation and discharge data over the period of 1980 – 2000 clearly show that the precipitation on the Ijen plateau influences water chemistry of the downstream river. Metal concentrations in the river water exceed the concentrations mentioned in Indonesian and international quality guidelines, even in the downstream river and the irrigation area. Some metal concentrations are extremely high, especially iron (up to 1600 mg/l) and aluminium (up to 3000 mg/l). The food-webs in the acidic parts of the river are highly underdeveloped. No invertebrates were present in the extremely acid water and, at pH 2.3, only chironomids were found. This also holds true for the river water with pH 3.3 in the downstream area. Agricultural soils in the irrigation area have a pH of 3.9 compared to a pH of 7.0 for soils irrigated with neutral water. Decreased yields of cultivated crops are probably caused by the use of Al containing acid irrigation water. Increased levels of metals (especially Cd, Co, Ni and Mn) are found in different foodstuffs, but still remain within acceptable ranges. Considering local residents” diets, Cd levels may lead to an increased risk for the human health. Fluoride exposure is of highest concern, with levels in drinking water exceeding guideline values and a lot of local residents suffering from dental fluorosis. Conclusions, Recommendations and Outlook In short, our data indicate that the Ijen crater lake presents a serious threat to the environment as well as human health and agricultural production.