Smart mud to smooth the way for drilling wells

Smart mud to smooth the way for drilling wells — A model developed by KAUST researchers provides insights into how drilling muds behave within wells and could help the oil industry avoid clogged wells. Credit: Qi Liu & Carlos Santamarina

A model that simulates how drilling fluids, or muds, behave and influence the stability of oil wells has been developed by KAUST researchers. Their findings could inform new safety protocols and the design of novel drilling muds.

To ensure oil wells are safe and economically viable, it is vital to maintain their integrity. Engineers have spent decades optimizing drilling muds, which are pumped into new wells to reduce friction and keep the drill bit clean. Once in the well, the liquid element of the mud seeps into surrounding rock leaving solid particles to create a mudcake, which lines the well walls to stabilize them.

However, the behavior of drilling muds within wells is highly complex, and their efficacy depends on many factors, such as temperature, salinity and permeability, within the mud itself and in the surrounding rock. Ineffective muds can clog the well and lead to stuck pipe—an expensive and time-consuming problem for the oil industry.

KAUST's Qi Liu and Carlos Santamarina have developed a sophisticated model of mudcake formation from water-based drilling muds for the oil industry. Their model provides insights into mudcake growth and suggests ways to ensure optimal formation.

"The mudcake forms as a filtrate, similar to ground coffee in a French press, at the interface between the well and the rock," says Liu.

"Most existing mudcake models assume a sudden change between the slurry and cake phases, which is not representative," explains Liu. "Instead, we used equations that capture the gradual transition between void ratio, permeability and effective stresses to create a model that properly represents the evolution from mud slurry to mudcake."

Their results show that environmental factors including thermal, chemical and mechanical stresses play a critical role in excessive mudcake growth, along with high permeability and low mud viscosity which causes severe fluid loss within the system.

"We also found that the total force acting on the pipe increases with time," says Liu. "Therefore, our primary advice to avoid stuck pipes is to minimize time spent at a standstill. Drilling companies must also optimize mud design by taking complex downhole conditions into consideration."

The team is also working on engineered muds that allow users to monitor them directly. These include a new magnetic-sensitive mud, nanoparticle-based muds with unique properties, and stimuli-reactive muds that change properties upon request.

Explore further: Functionalized graphene oxide plays part in next-generation oil-well drilling fluids

More information: Q. Liu et al. Mudcake growth: Model and implications, Journal of Petroleum Science and Engineering (2017). DOI: 10.1016/j.petrol.2017.12.044

	Smart mud to smooth the way for drilling wells
	admin
	2018-10-02
发布年	2018
语种	英语
国家	美国
领域	地球科学
正文(英文)	A model developed by KAUST researchers provides insights into how drilling muds behave within wells and could help the oil industry avoid clogged wells. Credit: Qi Liu & Carlos Santamarina A model that simulates how drilling fluids, or muds, behave and influence the stability of oil wells has been developed by KAUST researchers. Their findings could inform new safety protocols and the design of novel drilling muds. To ensure oil wells are safe and economically viable, it is vital to maintain their integrity. Engineers have spent decades optimizing drilling muds, which are pumped into new wells to reduce friction and keep the drill bit clean. Once in the well, the liquid element of the mud seeps into surrounding rock leaving solid particles to create a mudcake, which lines the well walls to stabilize them. However, the behavior of drilling muds within wells is highly complex, and their efficacy depends on many factors, such as temperature, salinity and permeability, within the mud itself and in the surrounding rock. Ineffective muds can clog the well and lead to stuck pipe—an expensive and time-consuming problem for the oil industry. KAUST's Qi Liu and Carlos Santamarina have developed a sophisticated model of mudcake formation from water-based drilling muds for the oil industry. Their model provides insights into mudcake growth and suggests ways to ensure optimal formation. "The mudcake forms as a filtrate, similar to ground coffee in a French press, at the interface between the well and the rock," says Liu. The behavior of drilling muds within wells is highly complex, and their efficacy depends on many factors within the mud itself and in the surrounding rock. Credit: Qi Liu & Carlos Santamarina "Most existing mudcake models assume a sudden change between the slurry and cake phases, which is not representative," explains Liu. "Instead, we used equations that capture the gradual transition between void ratio, permeability and effective stresses to create a model that properly represents the evolution from mud slurry to mudcake." Their results show that environmental factors including thermal, chemical and mechanical stresses play a critical role in excessive mudcake growth, along with high permeability and low mud viscosity which causes severe fluid loss within the system. "We also found that the total force acting on the pipe increases with time," says Liu. "Therefore, our primary advice to avoid stuck pipes is to minimize time spent at a standstill. Drilling companies must also optimize mud design by taking complex downhole conditions into consideration." The team is also working on engineered muds that allow users to monitor them directly. These include a new magnetic-sensitive mud, nanoparticle-based muds with unique properties, and stimuli-reactive muds that change properties upon request. Explore further: Functionalized graphene oxide plays part in next-generation oil-well drilling fluids More information: Q. Liu et al. Mudcake growth: Model and implications, Journal of Petroleum Science and Engineering (2017). DOI: 10.1016/j.petrol.2017.12.044
URL	查看原文
来源平台	Science X network
文献类型	新闻
条目标识符	http://119.78.100.173/C666/handle/2XK7JSWQ/123427
专题	地球科学
推荐引用方式 GB/T 7714	admin. Smart mud to smooth the way for drilling wells. 2018.

您对该条目有什么异议，请向管理员反馈。
内容：
Email：	*
单位:
验证码：	刷新

您在知识库使用过程中有什么好的想法或者建议可以反馈给我们。
标题：	*
内容：
Email：	*
验证码：	刷新

条目包含的文件
条目无相关文件。

资源环境科技发展态势分析平台