Open-Hole Fluid Displacement for Carbonate Stimulation in Liner Completions

Mayer, Christian S. J.; Sau, Rajes; Shuchart, Chris E.

doi:10.2523/iptc-17490-ms

All Days 2014

DOI: 10.2523/iptc-17490-ms

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Open-Hole Fluid Displacement for Carbonate Stimulation in Liner Completions

Christian S. J. Mayer

Rajes Sau

Chris E. Shuchart

Abstract: Today, many wells in heterogeneous carbonate reservoirs throughout the Middle East and Caspian Sea area are being completed with long intervals and complex completion equipment, such as limited entry liners and inflow control devices (ICDs). Accurate modeling and understanding of fluid placement during a stimulation operation through such long complex completions can be quite challenging. In this paper, an integrated approach of modeling, experiments and computational fluid dynamics (CFD) simulations will be p… Show more

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Cited by 2 publications

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Amorphous and Nanocrystalline Dissolvable Alloys with Artificial Intelligence for Applications in Deep-Water and Unconventionals

Chen¹,

Shenoy²,

Wilkinson³

et al. 2020

Day 1 Mon, May 04, 2020

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Technology developed to harness extended reach deviated (ERD) wells for deep-water and longer laterals for unconventionals demand the use of reliable "Dissolvable Alloys". Furthermore, an economic prediction mechanism to assess the degree of dissolution of deployed dissolvable hardware is highly coveted. This is one of the bottlenecks preventing the increased adoption of dissolvables in both deep-water and multistage stimulation (MSS). DAMORPHE was founded to take advantage of recent Mechanical-Materials-Electrical (MME) innovations for development and commercialization of "Game-Changing" technologies through the selective use of amorphous and nanocrystalline dissolvable alloys with Artificial Intelligence (AI). Here we discuss a couple of applications where dissolvable materials bring enhanced functionality over traditional methods and present a case for how replacing these with intelligent materials can bring further benefits to the end users.

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Amorphous and Nanocrystalline Dissolvable Alloys with Artificial Intelligence for Applications in Deep-Water and Unconventionals

Chen¹,

Shenoy²,

Wilkinson³

et al. 2020

Day 1 Mon, May 04, 2020

View full text Add to dashboard Cite

show abstract

Accelerated Development of Pressure Balanced HPHT Dissolvable Plugged Nozzle Assemblies Through the Nippon Foundation-DeepStar Joint Ocean Innovation R&D Program for Extended Reach Deepwater Wells, Within a Short Time of Project Launch

Roy¹,

Markel²,

Wilkinson³

et al. 2021

Day 2 Tue, August 17, 2021

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To meet and sustain the increasing energy needs of a growing world economy, exploration for oil and gas will be directed to increasingly extended reaches, complex profiles and hostile environments. Progress in harnessing high-pressure high-temperature (HPHT) sour fields (environments containing hydrogen sulphide gas or H2S) and reducing the cost of extracting and refining will be highly leveraged by political and macroeconomic considerations. Motivated to harness the complex tight carbonate reservoirs in offshore Arabian Gulf, a major National Oil Company (NOC) in UAE and its partners embarked on an extensive and ambitious project to produce oil and gas from offshore artificial islands. To capture the full economic benefits of this project, operators are expected to drill farther and farther into one of the world's longest deep-water reservoirs (wells with laterals lengths beyond 40,000 feet). It has also taken them a decade of innovative technology development to be able to successfully harness these challenging deep-water assets. Among the technologies developed, one of the essential tools, a dissolvable plugged nozzle assembly (DPNA) with its ability to withstand higher pressures encountered at larger depths, while maintaining its mechanical integrity for extended times in heavy brines, enabling longer sweeps, thus service deeper wells was needed by operators. Recognizing this grand challenge, we designed and developed a pressure balanced HPHT DPN (PB-HPHT DPN) with erosion resistant Ni alloy jointly developed with a major Japanese steel and Ni alloy producer and anion-insensitive nano-BMGC plug developed by us. The PB-HPHT DPN has the following groundbreaking properties: (i) It can sustain pressures of up to 5,500 psi differential pressure (ΔP) for 48 hours when pressurized from inner diameter (ID) to outer diameter (OD), and can subsequently breakthrough on 500 psi DP pressure reversal (OD to ID) within 14 days from the start of the operations; (ii) It can be deployed in environments encompassing up-to 43% Bromide or up-to 21% Chloride brines and reaching temperatures as high as 250° F. Additionally, verification and validation (V&V) is supported by flow testing combined with Computational Fluid Dynamics (CFD). The design of the PB HPHT-DPN allows a fluid flow of up-to 0.6 bpm across the nozzle without experiencing a differential pressure increase of >2400 psi in a 4 mm DPN. In summary, the PB-HPHT DPN is a revolutionary device that will allow operators to efficiently produce oil and gas in extremely hostile environments.

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Open-Hole Fluid Displacement for Carbonate Stimulation in Liner Completions

Cited by 2 publications

References 3 publications

Amorphous and Nanocrystalline Dissolvable Alloys with Artificial Intelligence for Applications in Deep-Water and Unconventionals

Amorphous and Nanocrystalline Dissolvable Alloys with Artificial Intelligence for Applications in Deep-Water and Unconventionals

Accelerated Development of Pressure Balanced HPHT Dissolvable Plugged Nozzle Assemblies Through the Nippon Foundation-DeepStar Joint Ocean Innovation R&D Program for Extended Reach Deepwater Wells, Within a Short Time of Project Launch

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