南海高温高压气藏机械防砂筛管动态腐蚀评价实验研究

机械防砂筛管腐蚀寿命评价及筛管评价优选对于高温高压气藏尤为重要,目前以静态金属挂片腐蚀实验为主要手段的筛管腐蚀评价难以适应气藏的动态生产条件。针对该问题,利用防砂筛管动态腐蚀评价系统,基于南海某高温高压气藏温度、压力和流体条件,对典型的机械防砂筛管的基管、挡砂介质(多层滤网、烧结纤维、绕丝筛板、泡沫金属镍)和外保护罩组件进行了动态腐蚀评价实验。结果表明:典型高温高压气藏条件下,N80钢基管为中度腐蚀,深度腐蚀速率为0. 073 8 mm/a,316L钢多层滤网挡砂介质为轻度腐蚀,深度腐蚀速率为0. 017 4mm/a,304钢外保护罩腐蚀程度介于两者之间,深度腐蚀速率为0. 029 3 mm/a;筛管各组件的质量腐蚀速率随CO2分压增大而加快,三者的质量腐蚀速率在CO2分压超过7. 0 MPa后差异更明显;各组件质量腐蚀速率随温度升高先上升后下降,在温度为120~140℃时达到最高质量腐蚀速率;水气比增加会加快腐蚀。多层滤网、绕丝筛板、烧结纤维和泡沫金属镍4种典型的挡砂介质的深度腐蚀速率分别为0. 017 4、0. 030 6、0. 010 5、0. 005 8 mm/a,差异明显。延长筛管腐蚀寿命的主要途径为选择合适的筛管类型和介质类型、优化筛管结构参数、改变外保护罩和基管的材料等。动态腐蚀寿命评价方法为不同油气储层的机械防砂筛管及井下工具的腐蚀评价和寿命预测提供了更加可靠的手段。

深井套管在CO_(2)环境中腐蚀规律研究

CO_(2)溶于水有极强的腐蚀性,在油田中导致套管发生腐蚀,降低井筒完整性。蓬莱油田是典型的高CO_(2)腐蚀性油田,井底温度与压力要高于其他油田。现利用CO_(2)动态腐蚀实验仪器模拟套管的腐蚀环境,采用控制单一因素改变的方式分别研究CO_(2)腐蚀与温度、CO_(2)分压、时间、电位差和砂之间的关系。结果表明:碳钢在某个温度区间内升高温度后在二氧化碳水溶液中的腐蚀速度加快;随CO_(2)分压的升高,腐蚀速率急剧增大,然后趋于稳定;与电偶腐蚀相比,油井含砂对腐蚀影响更大,1Cr材料对出砂敏感。增加CO_(2)分压后腐蚀电流密度呈先上升再下降趋势;随着温度的升高,油套管钢的腐蚀电位一直减小,腐蚀电流密度先增大后减小。

旅大油田A井液控管线腐蚀分析及管材优选

旅大油田A井为稠油热采井,注350℃高温高压蒸汽,井下监测设备液控管线腐蚀严重。通过扫描电子显微镜(SEM)以及电子能谱分析(EDS)对现场液控管线腐蚀试样进行分析,对采出液水样进行离子及腐蚀性气体成分分析,得出该管线腐蚀主要原因是在高温、高压和高矿化度条件下的H_(2)S腐蚀,并伴有氯离子腐蚀和少量CO_(2)腐蚀。在模拟现场温度、压力和介质条件下,挑选316L、Inconel 625、P110、9Cr1Mo材质的试片,进行动态模拟腐蚀实验,用失重法对4种材料的腐蚀性能进行了评价。结果表明,在稠油热采环境中,Inconel 625材料抗温耐蚀效果最优.

页岩气田集输管线CO_(2)腐蚀因素及缓蚀剂评价分析

CO_(2)作为页岩气伴生气,是某含CO_(2)页岩气开发过程中导致管材腐蚀的重要因素之一。为了控制该页岩气田集输管线的CO_(2)腐蚀问题,明确页岩气田集输管线CO_(2)的腐蚀规律,保证该气田安全平稳地运行生产,首先通过动态腐蚀挂片实验分析了温度、CO_(2)分压、气体流速和Cl^(-)浓度对CO_(2)腐蚀的影响,并通过腐蚀失重法评价了四种缓蚀剂的缓蚀效果,结果表明,影响该页岩气田发生CO_(2)腐蚀的主要因素为CO_(2)分压、流速以及Cl^(-)浓度,加注150 mg/L的羟乙基两性咪唑啉缓蚀剂,对控制页岩气田集输管线腐蚀有最佳的效果。

Analytic model of non-uniform corrosion induced cracking of reinforced concrete structure

In order to perfectly reflect the dynamic corrosion of reinforced concrete (RC) cover in practical engineering,an analytic model of non-uniform corrosion induced cracking was presented based on the elastic-plastic fracture mechanics theory.Comparisons with the published experimental data show that the predictions given by the present model are in good agreement with the results both for natural exposed experiments and short-time indoor tests (the best difference is about 2.7%).Also it obviously provides much better precision than those models under the assumption of uniform corrosion (the maximal improved precision is about 48%).Therefore,it is pointed out that the so-called uniform corrosion models to describe the cover cracking of RC should be adopted cautiously.Finally,the influences of thickness of local rusty layer around the reinforcing steel bar on the critical corrosion-induced crack indexes were investigated.It is found that the thickness of local rusty layer has great effect on the critical mass loss of reinforcing steel,threshold expansion pressure,and time to cover cracking.For local rusty layer thickness with a size of a=0.5 mm,the time to cover cracking will increase by about one times when a/b (a,semi-minor axis;b,semi-major axis) changes from 0.1 to 1 mm.