A Method of Evaluating Drilling Fluid’s Dynamic Adhesiveness
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摘要: 大部分传统钻井液润滑测试仪只考虑金属界面的相互作用,忽略了钻具与钻井液、钻井液泥饼、井壁间黏滞力对润滑效果的影响,导致润滑剂的润滑性能评价结果与现场实际表现不一致。通过模拟钻井中钻具与井壁、钻具与钻井液及泥饼间的相互作用,设计了一套钻井液动态黏滞性能测试仪。实验结果表明,钻井液动态黏滞性能测试仪操作简单,可评价不同压力、转速条件下的扭矩变化,评价结果准确、重复性高,能有效预防井下卡钻事故的发生。Abstract: Most of the traditional drilling fluid lubricity testers only consider the interaction between the interfaces of metals, and omit the effects of the adhesiveness between the drilling tools and drilling fluid, mud cakes and borehole walls on the lubricity of the drilling fluid, causing an inconformity between the evaluation results and the actual field performance of a lubricant. By simulating the interaction between the drilling tool and the borehole wall, the drilling tool and the drilling fluid as well as the drilling tool and the mud cake, a drilling fluid’s dynamic adhesiveness tester was developed. Experimental results show that the drilling fluid’s dynamic adhesiveness tester is easy to operate, and can be used to evaluate torque fluctuations under different pressures and rotational speeds. The results of the evaluation with this tester are accurate and highly repeatable, and can be used to effectively prevent stuck pipe accidents from occurring.
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Key words:
- Frictional resistance /
- Lubricity /
- Lubricity tester /
- Adhesiveness
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图 1 钻井液动态黏滞性能测试仪结构
1-记录仪、2-旋转开关、3-制动开关、4-直线开关、5-旋转控制器、6-直线控制器、7-压力控制器、8-转速1、9-转速2、10-转速3、11-旋转停止、12-直线开启、13-上升开关、14-下降开关、15-直线停止、16-控制面板、17-防护罩、18-扭矩传感器、19-旋转轴、20-旋转摩擦盘、21-沙盘、22-泥饼、23-密封圈、24-球面轴承、25-底座、26-压力传感器连接处、27-压力传感器与弹簧连接处、28-压力传感器、29-弹簧、30-升降螺杆、31-升降螺母、32-风机、33-固定轴(4根)、34-上固定板、35-直线轴承4个、36-滑杆、37-下固定板、38-台面、39-风机面板、40-橡胶脚、41-螺杆、步进电机连接器、42-步进电机
表 1 钻井液黏滞性能测试仪主要技术指标
序号 名称 技术参数 1 最大工作压力 147 N(15 kgf) 2 最大转速 1000 r/min 3 测量分辨率 0.1 N·m 4 综合测量误差 <1.5‰ 5 沙盘直径 6.3 cm 6 沙盘厚度 0.635 cm 7 有效沙盘直径 4.5 cm 
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表 2 3%CX300润滑剂在聚合物水基钻井液中的润滑性能
聚合物体系 扭矩 润滑系数降低率/% 空白 21.0/19.5/14.0/17.0 3%CX300 8/13/9/10 59.85/30.35/36.84/43.62
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