Rheological properties of water-based magnetic fluid and its emulsion

Controlling the annular frictional pressure losses is important in order to drill safely with overpressure without fracturing the formation. To predict these pressure losses, however, is not straightforward. First of all, the pressure losses depend on the annulus eccentricity. Moving the drillstring to the wall generates a wider flow channel in part of the annulus which reduces the frictional pressure losses significantly. The drillstring motion itself also affects the pressure loss significantly. The drillstring rotation, even for fairly small rotation rates, creates unstable flow and sometimes turbulence in the annulus even without axial flow. Transversal motion of the drillstring creates vortices that destabilize the flow. Consequently, the annular frictional pressure loss is increased even though the drilling fluid becomes thinner because of added shear rate. Naturally, the rheological properties of the drilling fluid play an important role. These rheological properties include more properties than the viscosity as measured by API procedures. It is impossible to use the same frictional pressure loss model for water based and oil based drilling fluids even if their viscosity profile is equal because of the different ways these fluids build viscosity. Water based drilling fluids are normally constructed as a polymer solution while the oil based are combinations of emulsions and dispersions. Furthermore, within both water based and oil based drilling fluids there are functional differences. These differences may be sufficiently large to require different models for two water based drilling fluids built with different types of polymers. In addition to these phenomena washouts and tool joints will create localised pressure losses. These localised pressure losses will again be coupled with the rheological properties of the drilling fluids. In this paper, all the above mentioned phenomena and their consequences for annular pressure losses will be discussed in detail. North Sea field data is used as an example. It is not straightforward to build general annular pressure loss models. This argument is based on flow stability analysis and the consequences of using drilling fluids with different rheological properties. These different rheological properties include shear dependent viscosity, elongational viscosity and other viscoelastic properties.

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Structure of particle assembly in water-based magnetite magnetic fluid under zero applied field

Brazilian Journal of Physics ◽

10.1590/s0103-97332001000300002 ◽

2001 ◽

Vol 31 (3) ◽

pp. 347-349 ◽

Cited By ~ 2

Author(s):

B. Jeyadevan ◽

I. Nakatani ◽

H. Oka ◽

K. Tohji

Keyword(s):

Magnetic Fluid ◽

Applied Field ◽

Particle Assembly ◽

Water Based

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Comparative Analysis of the Effect of Barite and Hematite on the Rheology of Water-Based Drilling Mud

10.53902/tpe.2021.01.000508 ◽

2021 ◽

Vol 1 (2) ◽

Author(s):

Osei H

Keyword(s):

Rheological Properties ◽

Drilling Fluid ◽

Attrition Rate ◽

Drilling Mud ◽

Cleaning Efficiency ◽

Drilling Operation ◽

Water Based ◽

Petroleum Resources ◽

Drilling Muds ◽

The Impact

High demand for oil and gas has led to exploration of more petroleum resources even at remote areas. The petroleum resources are found in deeper subsurface formations and drilling into such formations requires a well-designed drilling mud with suitable rheological properties in order to avoid or reduce associated drilling problems. This is because rheological properties of drilling muds have considerable effect on the drilling operation and cleaning of the wellbore. Mud engineers therefore use mud additives to influence the properties and functions of the drilling fluid to obtain the desired drilling mud properties especially rheological properties. This study investigated and compared the impact of barite and hematite as weighting agents for water-based drilling muds and their influence on the rheology. Water-based muds of different concentrations of weighting agents (5%, 10%, 15% and 20% of the total weight of the drilling mud) were prepared and their rheological properties determined at an ambient temperature of 24ᵒC to check their impact on drilling operation. The results found hematite to produce higher mud density, plastic viscosity, gel strength and yield point when compared to barite at the same weighting concentrations. The higher performance of the hematite-based muds might be attributed to it having higher specific gravity, better particle distribution and lower particle attrition rate and more importantly being free from contaminants. The water-based muds with hematite will therefore be more promising drilling muds with higher drilling and hole cleaning efficiency than those having barite.

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Comparative experiment of enhanced heat transfer performance between water-based magnetic fluid heat pipe and ordinary water heat pipe under magnetic field

International Journal of Heat and Technology ◽

10.18280/ijht.360344 ◽

2018 ◽

Vol 36 (3) ◽

pp. 1116-1120

Author(s):

Yulin Jiao ◽

Xinhua Wang

Keyword(s):

Magnetic Field ◽

Heat Transfer ◽

Heat Pipe ◽

Magnetic Fluid ◽

Heat Transfer Performance ◽

Transfer Performance ◽

Comparative Experiment ◽

Enhanced Heat Transfer ◽

Ordinary Water ◽

Water Based

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Prediction of Formation Damage, Fluid Loss and Rheological Properties of Water Based Mud with Corn Cob

European Journal of Engineering Research and Science ◽

10.24018/ejers.2020.5.10.2203 ◽

2020 ◽

Vol 5 (10) ◽

pp. 1269-1273

Author(s):

Godwin Chukwuma Jacob Nmegbu ◽

Bright Bariakpoa Kinate ◽

Bari-Agara Bekee

Keyword(s):

Rheological Properties ◽

High Pressures ◽

Chemical Properties ◽

Analytical Models ◽

Formation Damage ◽

Fluid Loss ◽

Drilling Mud ◽

Corn Cob ◽

Core Samples ◽

Water Based

The extent of damage to formation caused by water based drilling mud containing corn cob treated with sodium hydroxide to partially replace polyanionic cellulose (PAC) as a fluid loss control additive has been studied. Core samples were obtained from a well in Niger Delta for this study with a permeameter used to force the drilling mud into core samples at high pressures. Physio-chemical properties (moisture content, cellulose and lignin) of the samples were measured and the result after treatment showed reduction. The corn cob was combined with the PAC in the ratio of 25-75%, 50-50% and 75-25% in the mud. Analyzed drilling mud rheological properties such as plastic viscosity, apparent viscosity, yield point and gel strength all decreased as percentage of corn cob increased in the combination and steadily decreased as temperature increased to 200oF. Measured fluid loss and pH of the mud showed an increase in fluid loss and pH in mud sample with 100% corn cob. The extent of formation damage was determined by the differences in the initial and final permeability of the core samples. Experimental data were used to develop analytical models that can serve as effective tool to predict fluid loss, rheological properties of the drilling mud at temperature up to 200oF and percentage formation damage at 100 psi.

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Rheological characterization of asphalt binders treated with bio sealants for pavement preservation

Canadian Journal of Civil Engineering ◽

10.1139/cjce-2017-0058 ◽

2018 ◽

Vol 45 (5) ◽

pp. 407-412

Author(s):

Debaroti Ghosh ◽

Mugurel Turos ◽

Ed Johnson ◽

Mihai Marasteanu

Keyword(s):

Rheological Properties ◽

Asphalt Binder ◽

Field Investigation ◽

Asphalt Binders ◽

Rheological Characterization ◽

Softening Effect ◽

Laboratory Findings ◽

Pavement Preservation ◽

Performance Grade ◽

Water Based

Pavement preservation is playing an increasingly significant role in maintaining our aged pavement infrastructure under severe budget constraints. One important component is the use of surface treatments based on application of sealants. Recently, a number of new products, called bio sealants, have been used to treat aging pavement surfaces. The objective of this study is to investigate rheological properties of the binders treated with these materials to understand the mechanism by which they may improve pavement performance. One plain asphalt binder and four types of sealants, two oil-based sealants, one water-based sealant, and one traditional emulsion were used in the experimental work. The results obtained using a dynamic shear rheometer and a bending beam rheometer were used to determine the changes in rheological properties and the change in performance grade. It was observed that the oil-based sealants have a significant softening effect of the control binder compared to the water-based sealants. The transverse cracking histories from field investigation were used to verify the laboratory findings.

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Development of New Models to Determine the Rheological Parameters of Water-based Drilling Fluid Using Artificial Intelligence

10.2118/204597-ms ◽

2021 ◽

Author(s):

Farqad Hadi ◽

Ali Noori ◽

Hussein Hussein ◽

Ameer Khudhair

Keyword(s):

Rheological Properties ◽

High Performance ◽

Drilling Fluid ◽

Gel Strength ◽

Solid Content ◽

Rheological Parameters ◽

Water Based ◽

Fluid Properties ◽

Drilling Operations ◽

Marsh Funnel

Abstract It is well known that drilling fluid is a key parameter for optimizing drilling operations, cleaning the hole, and managing the rig hydraulics and margins of surge and swab pressures. Although the experimental works present valid and reliable results, they are expensive and time consuming. On the other hand, continuous and regular determination of the rheological mud properties can perform its essential functions during well construction. More uncertainties in planning the drilling fluid properties meant that more challenges may be exposed during drilling operations. This study presents two predictive techniques, multiple regression analysis (MRA) and artificial neural networks (ANNs), to determine the rheological properties of water-based drilling fluid based on other simple measurable properties. While mud density (MW), marsh funnel (MF), and solid% are key input parameters in this study, the output functions or models are plastic viscosity (PV), yield point (YP), apparent viscosity (AV), and gel strength. The prediction methods were demonstrated by means of a field case in eastern Iraq, using datasets from daily drilling reports of two wells in addition to the laboratory measurements. To test the performance ability of the developed models, two error-based metrics (determination coefficient R2 and root mean square error RMSE) have been used in this study. The current results of this study support the evidence that MW, MF, and solid% are consistent indexes for the prediction of rheological properties. Both mud density and solid content have a relative-significant effect on increasing PV, YP, AV, and gel strength. However, a scattering around each fit curve is observed which proved that one rheological property alone is not sufficient to estimate other properties. The results also reveal that both MRA and ANN are conservative in estimating the fluid rheological properties, but ANN is more precise than MRA. Eight empirical mathematical models with high performance capacity have been developed in this study to determine the rheological fluid properties based on simple and quick equipment as mud balance and marsh funnel. This study presents cost-effective models to determine the rheological fluid properties for future well planning in Iraqi oil fields.

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