Evaluation and optimization of water-salt based drilling fluids for slim-hole wells in one of Iranian central oil fields

IF 2.6 Q3 ENERGY & FUELS
Iman Jafarifar , Babak Karimi Dehkordi , Hassan Abbasi , Mahin Schaffie , Mohammad Ranjbar
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引用次数: 7

Abstract

Slim-hole drilling in oil and gas industry has been developed extensively in recent years. Drilling fluid, in addition to providing appropriate rheological properties should produce a low annular pressure loss (APL) gradient while drilling. During slim-hole drilling, drilling mud hydraulics is an important concern, because due to reduced annular clearance, pressure loss can occur in drill pipe and annulus considerably. In this research, water based drilling muds were selected for the experimental work due to its low price, simple preparation and easy access to the required water. The research includes development and testing of water-salt based fluids. In this study, sixty-five samples of fluids were analyzed for their rheological parameters, the were considered using three various case study gas field wellbore configurations 6 1/8, 5 7/8 and 4 1/8 inch for their calculate APL gradients. Each composition was evaluated by the Power-Law and Bingham Plastic models and results of both models were compared. Choose of optimum fluids is based on suitable rheological properties, minimum annular pressure losses and maximum fluid transport ratio. Also, the effect of high temperature (180°F) on frictional pressure losses was studied. For an optimal formulation at high temperature from a well with distinct configuration 6 1/8 inch had an APL gradient of 0.149 psi/ft compared to 0.176 psi/ft at atmospheric condition. It was found that effect of high temperature on drilling fluids behavior is affirmative. On the other hand, the observed effect of high temperature on Power-Law fluids greater than Bingham Plastic fluids. Fluids with xanthan, in spite of high cutting carrying capacity and due to high viscosity have exhibited high frictional pressure loss. However, for some fluids, the annular pressure loss increased at high temperature due to green starch fermentation.

伊朗某中部油田小井水盐基钻井液评价与优化
近年来,小井眼钻井在油气工业中得到了广泛的发展。钻井液除了提供适当的流变特性外,还应在钻井时产生较低的环空压力损失(APL)梯度。在小井眼钻井过程中,钻井泥浆的水力学是一个重要的问题,因为由于环空间隙的减小,钻杆和环空的压力损失可能会很大。本研究选择水基钻井液作为实验材料,因为水基钻井液价格低廉,制备简单,且容易获得所需的水。这项研究包括开发和测试水盐基流体。在这项研究中,研究人员分析了65种流体样品的流变参数,并考虑了三种不同的案例研究气田井筒配置,分别为6 1/ 8,5 7/8和4 1/8英寸,以计算APL梯度。采用幂律模型和宾汉姆塑性模型对每种成分进行了评价,并对两种模型的结果进行了比较。最佳流体的选择是基于合适的流变特性、最小的环空压力损失和最大的流体输送比。同时,研究了高温(180°F)对摩擦压力损失的影响。对于具有不同配置的高温井而言,6 1/8英寸的APL梯度为0.149 psi/ft,而大气条件下的APL梯度为0.176 psi/ft。结果表明,高温对钻井液性能的影响是肯定的。另一方面,高温对幂律流体的影响大于宾汉姆塑性流体。尽管含有黄原胶的流体具有很高的切削承载能力,但由于其高粘度,其摩擦压力损失也很高。然而,对于某些液体,由于绿色淀粉的发酵,在高温下,环空压力损失增加。
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CiteScore
5.50
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