Understanding and Managing the Natural Self-Breaking Behaviour of Xanthan in Reservoir Drill-In, Completion and Workover Fluids

Anderson, Zhao; Ioannou, Andreas; Howard, Siv; Downs, John David

doi:10.2118/213822-ms

Cited by 3 publications

References 23 publications

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The Use of Cyclic Injection of Xanthan Solution in order to Increase the Oil Recovery Factor from Heterogeneous Terrigenous Reservoirs

Dengaev,

Maksimenko,

Ivanova

et al. 2024

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As oil reserves are depleted during the development of an oil deposit in an elastic-water-pressure mode, the water cut of the fluid gradually increases, reducing the efficiency of waterflooding and maintaining reservoir pressure by the system of injection wells. The rheological characteristics of the saturating fluid and the structure of the reservoir affect the likelihood of premature watering of production wells. To increase oil production and level the displacement front, various polymer systems, both synthetic and biological, are used to promote additional oil production from previously untapped reservoir zones. There are technologies for both constant injection of a working agent with a polymer, and a slug of a polymer solution of a certain concentration with subsequent injection of water. The purpose of this work is to assess the effect of injection of xanthan solution on the oil displacement efficiency with subsequent injection of formation water. An experimental (laboratory) study was carried out on alternating injection of xanthan and formation water solutions to increase filtration resistance in flooded filtration channels. Inhomogeneous terrigenous core samples with different fracturing and filtration-capacitive properties were selected as a physical model for carrying out the experiments. The main results of the laboratory study are the dependence of the oil recovery factor and water cut on the injected volume of formation water. It is noted that the key factor in reducing the displacement efficiency after injection of a polymer slug is the loss of polymer molecules both after adsorption on the rock and during further filtration of formation water through diffusion. As a result of the experimental study, it was revealed that changing the filtration rate can have a beneficial effect on the involvement of oilsaturated rock in the displacement process due to the sealing of watered areas when the injection pressure changes.

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The Use of Cyclic Injection of Xanthan Solution in order to Increase the Oil Recovery Factor from Heterogeneous Terrigenous Reservoirs

Dengaev,

Maksimenko,

Ivanova

et al. 2024

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Reservoir Drilling and Openhole Gravel Packing with High-Density Cesium Formate Fluids in a High-Pressure, Marginal Mud Window Environment at Martin Linge

Nilsen,

Obrestad,

Kaarigstad

et al. 2023

SPE Journal

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Summary High-density cesium/potassium (Cs/K) formate fluids were successfully utilized from reservoir drilling to upper completion installation in five productive Martin Linge high-rate gas wells. Four wells were completed with openhole gravel pack (OHGP) and one with standalone sand screens. The gravel packing operation marks what is considered to be the highest density carrier fluid OHGP successfully completed worldwide, with a specific gravity (SG) of 2.06. A complex operation under pressure and temperature conditions (745–780 bar and 135–140°C) that almost qualify as high pressure/high temperature (HP/HT), including managed pressure drilling (MPD), overbalanced screen running, and openhole gravel packing, was simplified by using the same base brine throughout the operation. Cs/K formate reservoir drilling fluid (RDF) and screen-running fluid were designed with biopolymeric additives and minimal calcium carbonate bridging particles. Clear Cs/K formate brine was chosen as gravel pack (GP) carrier fluid. The use of Cs/K formate fluids for all stages of the operation reduced the complexity of transitioning between the operational stages. In addition, the reservoir was only exposed to one filtrate without application of damaging weighting solids. The drilling fluid contributed to successful MPD and delivered wells with very good hole quality in the reservoir, which consisted of interbedded sandstone, coal stringers, and shale. The shale-stabilizing properties of concentrated formate brine–based fluids provided acceptable conditions for extended openhole time and allowed additional logging runs, including pore pressure measurements, under near-HP/HT conditions, before running the screens. One bottom-up cleanout was conducted before the screen-running fluid was circulated in and the screens installed. The spurt and seepage losses were low throughout the drilling and screen-running phases. No breaker treatment was required in any of the wells. All wells have proved to have good initial productivity and high well productivity index. The successful OHGP operations performed with the high fluid densities required in Equinor’s Martin Linge field have set a new standard for well completions in challenging high-pressure environments.

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Long-term Coreflood Testing with Biopolymers—A Laboratory Investigation Showing How Return Permeability Improves From 0 to 100 Percent by Getting a Critical Parameter Right

Howard,

2024

SPE International Conference and Exhibition on Formation Damage Control

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A series of long-term coreflood tests has shown the importance of considering the self-breaking rate of biopolymers when designing coreflood tests of low-solids and solids-free brine-based drilling and completion fluids that naturally contaminate the core plug with biopolymers during testing. The tests were conducted with a solids-free potassium formate brine–based reservoir drilling fluid, formulated with xanthan gum and starch, which when exposed to overbalanced pressure, invaded deep into the core plug. The coreflood test simulated filtrate invasion into a water-saturated formation while drilling an injection well. In this scenario the core plug was initially 100% saturated with formation water, and return permeability was measured by injecting formation water through the core in the same direction as the test fluid filtrate invasion. Testing was conducted at two temperatures, 121 and 149°C (250 and 300°F). At both test temperatures there was a very good correlation between the cleanup or permeability recovery rate of the core plug and the biopolymer self-breaking rates, which had been measured in an earlier study. Due to the low cleanup rate at the lowest temperature, this test was terminated as soon as the cleanup rate was fully established, and the testing was continued at the higher temperature until the permeability had reached close to 100% of its initial value. The initial 49-hours cleanup with formation water at 121°C (250°F) resulted in a return permeability to formation water of only 3.8%, explaining why laboratory coreflood tests with low-solids/solids-free brine-based drilling and completion fluids containing biopolymeric additives are generally unable to reproduce or predict the excellent well performance the same fluids deliver in the field after days, weeks, or months of steady clean-up. The results also give us useful insights into what to expect when such fluids are used to drill injection wells. Although the biopolymer self-breaking rate is much higher in the low-salinity injection water, it takes time for biopolymers to break down enough in the protective ionic environment of the formate brine for the filtrate to be diluted and displaced locally by the flow of injection water. The desire to reduce fluid screening and qualification costs unfortunately often means that reservoir drilling and completion fluid selection decisions are based on the results of short-term coreflood tests. This may be the correct procedure for fluids that cause permanent intractable damage from solids plugging. However, for solids-free or low-solids fluids containing self-breaking biopolymers, relying on such short-term tests can mean that the wrong fluid selection decisions are made.

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Understanding and Managing the Natural Self-Breaking Behaviour of Xanthan in Reservoir Drill-In, Completion and Workover Fluids

Cited by 3 publications

References 23 publications

The Use of Cyclic Injection of Xanthan Solution in order to Increase the Oil Recovery Factor from Heterogeneous Terrigenous Reservoirs

The Use of Cyclic Injection of Xanthan Solution in order to Increase the Oil Recovery Factor from Heterogeneous Terrigenous Reservoirs

Reservoir Drilling and Openhole Gravel Packing with High-Density Cesium Formate Fluids in a High-Pressure, Marginal Mud Window Environment at Martin Linge

Long-term Coreflood Testing with Biopolymers—A Laboratory Investigation Showing How Return Permeability Improves From 0 to 100 Percent by Getting a Critical Parameter Right

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