草古1潜山底水油藏氮气压水锥技术研究及应用

乐安油田草古 1潜山底水缝洞型碳酸盐岩稠油油藏经过多年的高效开发后 ,受底水暴性水淹影响 ,产量下滑严重 ,油藏综合开发效益日趋变差 ,针对这一问题 ,采取了对部分高含水潜力井实施氮气压水锥治理底水工艺措施 ,现场取得了较好的生产效果 ,对同类潜山灰岩油藏的开发具有参考价值。

锦州油田欢17块大凌河油层压水锥试验研究及认识

针对欢17块大凌河油藏地质与开发特点,为了进一步增加可采储量、改善油藏开发效果,对油藏地质特征进行了再认识,包括构造特征、隔夹层分布特征、储量复算等;对油藏注水开发阶段进行效果评价,总结开发效果;对底水油藏水锥起降规律进行研究,包括现在测试资料的分析研究,水锥物理模拟研究、水锥数值模拟研究等,根据不同方法预测压水锥的最佳时间。

黄沙坨油田中高含水期持续稳产配套技术研究

黄沙坨油田地质条件复杂,具有油井产量递减较大、油井含水上升快的开采特征,为了黄沙坨油田长期稳产,本次研究以黄沙坨油田近几年措施的14口井实施效果为基础,根据黄沙坨油田地质条件,把黄沙坨油田平面上分为三大类,对应不同的储层特性,提出对应的措施,为黄沙坨下步措施提出方向。

氮气吞吐技术在裂缝型碳酸盐岩油藏的应用研究

碳酸盐岩油藏多发育微裂缝、非均质性严重、天然能量低,弹性开采递减迅速的问题,常规调驱技术难以发挥有效作用。高压、大排量注入的氮气可以进入水无法进入的微裂缝,能够迅速弥补近井地带压力亏空,增强采出能力。KB油田KB6区块为受断层控制的南北向潜山油藏,KB6井位于南部构造高部位,边底水能量弱,该井区依靠天然能量开发,酸化虽然在一定程度上沟通周围孔洞缝,但能量得不到及时补充;该井累积产油量较高,阁楼油动用程度低,随着不断开采,压力下降,溶解气不断析出,弹性驱动能降低,造成目前产液量下降严重,地层能量不足。采用氮气吞吐技术,利用氮气可进入微裂缝、贾敏效应膨胀驱替等作用扩大波及体积、降低综合含水率、提高地层能量,从而达到提高采收率的目的。

注氮气提高稠油油藏开发效果的应用研究

曙光油田古潜山稠油油藏,随着稠油的开采,底水上升速度较快,该区块平均含水已经达到90%。针对稠油井区吞吐轮次高,地层压力下降幅度大,常规吞吐经济效果差。为了解决上述三大矛盾,几年来,我们根据氮气的性质及氮气来源充足,价格低的特点,先后应用在了气隔热助排、氮气控制水锥、气-水交替段塞驱工艺技术,现场应用见到了明显的效果。

氮气辅助蒸汽吞吐工艺在稠油油藏的应用

若在稠油油藏注蒸汽的同时注入氮气,将会有效地改善蒸汽吞吐效果。研究馆陶组稠油主要分布在南区及东区,油藏埋深840-960米,油层厚度10-20米,油藏边底水活跃。稠油油藏提高采收率中的注氮技术主要分为氮气辅助蒸汽吞吐、氮气压水锥以及氮气泡沫调剖技术,有效解决了蒸汽与地下原油密度差引起的重力分异作用,以及蒸汽超覆和汽窜现象,有效缓解了油层动用不均衡的开采矛盾,是提高油田采收率的经济有效方法。

Hydrodynamic deep drawing of double layered conical cups

Hydrodynamic deep drawing assisted by radial pressure is an advanced sheet forming technology with great advantages such as higher drawing ratio, good surface quality and higher dimensional accuracy. In this process, both the bottom surface and the peripheral edge of sheets are under hydrodynamic pressure, so that the forming procedure is more uniform with low failure probability. Multi-layered sheets with complex geometries could be formed more easily with this technique compared with other traditional methods. Rupture is the main irrecoverable failure form in sheet forming processes. Prediction of rupture occurrence is of great importance for determining and optimizing the proper process parameters. In this research, a theoretical model was proposed to calculate the critical rupture pressure in production of double layered conical parts with hydrodynamic deep drawing process assisted by radial pressure. The effects of other process parameters on critical rupture pressure, such as punch tip radius, drawing ratio, coefficient of friction, sheet thickness and material properties were also discussed. The proposed model was compared with finite element simulation and validated by experiments on Al1050/St13 double layered sheets, where a good agreement was found with analytical results.