Your search keyword '"Ahmed Montasser"' showing total 2 results

1. A New Generation, Multi-Sensor MLWD Device for Optimized Drilling Performance and Reservoir Insight: A Case Study, Offshore Abu Dhabi

Author

Wael Fares, Nashat Abbas, Jamal Al Nokhatha, Tim Parker, Ahmed Montasser, and Muhammad Mubeen

Abstract

Acquisition of reservoir properties measurements, high-resolution borehole images, and continuous directional surveys has historically required the deployment of multiple discrete tools. This paper details the first-time deployment of a new, integrated, multi-sensor tool, in one of the largest oil-producing reservoirs in Abu Dhabi. Deployment of the new technology helped to achieve a new record for the longest bit run with the new system. The new measurement-and-logging-while-drilling (MLWD) platform incorporates multiple sensors with significantly reduced footprint, delivering critical, high-definition measurements closer to the bit than previous technologies with modular designs. In this case study, the existing MLWD technologies were included in the drilling assembly for measurement validation and benchmarking. The new tool provided borehole size and shape measurements, and high-resolution radius and acoustic reflection-amplitude images with an axial resolution of 0.1 inches. In addition, the tool provided vibration, weight, torque, and pressure-while-drilling measurements, to help optimize the drilling parameters, and an azimuthal gamma ray sensor for formation evaluation. The new design also includes a compact directional module to provide static surveys and high-resolution continuous inclination and azimuth while drilling, facilitating wellbore placement and safe and efficient drilling by minimizing the tortuosity. The bottomhole assembly included LWD gamma ray, propagation resistivity, formation density, and neutron porosity sensors from the legacy system, along with a point-the-bit rotary steerable system and a new-generation resistivity sensor. The new system was deployed in an 8½-in. horizontal section of 14,318 ft, reaching a total depth of 25,500 ft. MD. It was the longest run of the new MLWD system globally to date. The real-time MLWD data included gamma ray and ultrasonic borehole size. Furthermore, the high-resolution radius and reflection-amplitude images captured geological features that often control the reservoir properties such as vugs, fractures, and minor faults. The radius measurements provided details of the borehole size and shape, with a three-dimensional (3D) visualization of the wellbore helping to identify borehole enlargement and breakout. In addition, the new and legacy propagation resistivity measurements matched closely. The continuous, high-definition surveys helped the drilling team to ensure smooth hole and avoid any collision risk with nearby wells. The forward plan is to continue to deploy the new generation of tools in a wider range of conditions and locations, and to add additional next-generation sensors, including higher resolution density, neutron porosity, and deep multilayer reservoir mapping sensors.

Published

2022

2. Introducing a New Logging–While–Drilling Ultrasonic Borehole Imaging Technology Using Oil–Based Mud in Mature Field, Offshore Abu Dhabi

Author

Wael Fares, Islam Khaled, Takeru Okuzawa, Yassar Goraya, Ahmet Aki, Bader Mohamed Al Dhafari, Ahmed Montasser, Ali Saee Alfelasi, Omar Al-mutwali, Muhammad Ashraf, Ahmed ElGammal, and Hocine Khemissa

Subjects

Abu dhabi, Petroleum engineering, Field (physics), Logging while drilling, Oil-based mud, Borehole, Imaging technology, Ultrasonic sensor, Submarine pipeline, Geology

Abstract

Acquisition of high-resolution images for reservoir characterization from logging-while-drilling (LWD) technologies has historically been limited to water-based mud (WBM) applications. The introduction of LWD ultrasonic technologies means high-resolution images and the associated analysis are now available in both WBM and oil-based mud (OBM) applications. This paper details the first deployments of a 4¾-in. LWD ultrasonic imaging service in a mature field, offshore Abu Dhabi, and the assessment of images in both WBM and OBM wells. The 4¾-in. ultrasonic tool combines both borehole size and shape measurements with high-resolution radius and reflection amplitude images. The ultrasonic sensor uses four transducers that operate in a pulse-echo mode. By firing simultaneously, the transducers provide a total of 2,000 travel time and reflection amplitude measurements each second, enabling the creation of high-resolution images, even at high-logging speeds. The methodology described was used to evaluate the suitability of the LWD ultrasonic measurements to enhance reservoir understanding, along with LWD azimuthal formation density and azimuthal high-resolution resistivity image measurements in WBM applications. The 4¾-in. ultrasonic borehole imaging technology was deployed while drilling with OBM/WBM to acquire ultrasonic images to capture the subtle geological features that often control the reservoir properties, but whose characterization was challenging previously due to technology limitations. The long lateral was logged with ultra-sonic imaging while drilling through Cretaceous carbonates, traversing through different layers going up and down in stratigraphy; showcasing subtle variations with complementing images that helped understand the vug distribution, bioturbation, faults, and dissolution seams, in addition to the bedding boundaries. High-resolution borehole shape analysis was performed to understand the impact of stresses on the well trajectory, made possible with the high-definition, multisector images. The resolution of the reflection amplitude images, in particular, enables identification of drilling-induced features on the surface of the borehole, highlighting the measurement's value in understanding the impact of the bottom hole assembly (BHA) on the quality of the wellbore. The travel time measurements provide detailed evaluation of the borehole size and shape, with the three-dimensional (3D) visualization of the wellbore illustrating the ability of the service to identify borehole enlargement and breakout. These findings demonstrate the suitability of the service to address wellbore stability issues in real time. This paper details the first use of the ultrasonic service in Abu Dhabi. Comparison of images from the new ultrasonic imaging service with established LWD technologies highlights the suitability of the radius and reflection amplitude images to provide enhanced formation evaluation analysis in both WBM and OBM applications. Log examples show the high-resolution images are able to identify bedding features and fractures and provide assessment of borehole size and shape for wellbore stability evaluation.

Published

2020