Applications and Derivation of a New Cased-hole Density Porosity in Shaly Sands R.C. Odom, SPE, Computalog Research, Inc.; G.P. Hogan II, SPE, Computalog Wireline Services; B.W. Crosby, SPE, Computalog Wireline Services; M.P. Archer, Chevron U.S.A., Inc. Copyright 1997, Society of Petroleum Engineers, Inc. Abstract Recently, the physical foundations and derivation of a cased-hole, density-based porosity have been developed for the Computalog PND-S pulsed neutron system. The utility of this measurement is demonstrated in applications to reservoir analysis problems in sand-shale sequences of the Gulf Coast and offshore Gulf of Mexico. This cased-hole density porosity is based on the attenuation of gamma rays produced by inelastic scattering of fast neutrons. These fast-neutron reactions create a dispersed gamma-ray source in close proximity to the accelerator, and the subsequent transport of these gamma rays is strongly affected by the density of the formation. The higher energies and larger geometric scales of this technique give it sufficient penetration to measure a cased-hole density porosity that compares favorably to the open-hole, gamma-gamma density. Applications (in combination with the cased-hole neutron porosity) include providing porosities where hole conditions make open-hole logging unviable, and in old wells where no modern porosity logs exist or the data is of questionable quality. This measurement can be utilized in cased-hole prospecting by differentiating low porosity from gas-filled porosity. Reservoir monitoring applications include: hydrocarbon typing, estimating pressure changes in gas reservoirs, and monitoring fluid level and hydrocarbon type changes. Following discussions of the derivation and possible applications, several log examples from the Gulf Coast and offshore Gulf of Mexico demonstrate the uses of the system and the correlation with the conventional open-hole density porosity. Introduction The density-neutron crossplot porosity has long been the workhorse of the log analyst. The strength of this union lies in the fact that these two porosities have roughly equal and opposite errors with respect to shale content and gas content. When these measurements are used together, a more accurate estimate of the porosity is obtained. The overlay of these porosities on the well log can be used to visually estimate the shale and fluid content of the logged formations. Traditionally, in cased-reservoir analyses, the main source of porosity is the hydrogen-based neutron porosity. The neutron radiation is capable of penetrating the well casing and cement and affecting measurable reactions in the formation. The spatial distribution of thermal neutrons (near-to-far ratio) is related to the hydrogen content of the formation. Given the assumptions that the rock matrix does not contain hydrogen and the pore fluid is water, the hydrogen content is mapped into a porosity measure. Of course, these assumptions create errors in formations with shale in the matrix and/or gas in the pore fluid. In order to have sensitivity to gas-filled porosity versus low porosity (gas vs. tight), current versions of the competitive pulsed neutron systems in the Gulf Coast market have incorporated detector counting bins during the source pulse to measure gamma rays created by inelastic scattering. The count rate during the source pulse is placed in simple ratio algorithms, and qualitative empirical relations are developed. In previous publications, it has been demonstrated that the formation density can be isolated and measured using gamma rays created from inelastic scattering of fast neutrons. This paper describes the continuous process of making this a more accurate and quantitative measurement. In the following section, we will briefly describe the unfolding processes required to measure the effects of the formation density on the received inelastic signal. Currently, the extracted density parameter undergoes a scalar mapping to normalize the well-bore effects. The normalization is facilitated by calibration checks to core data, offset wells or local sections with open-hole data. The end result is a density porosity (PN density) similar to the open-hole, gamma-gamma density porosity (OH density). In the Characterization of Measurements section that follows is a discussion of the development of a prototypical borehole compensated (BHC) algorithm. In this BHC algorithm the measurements of borehole parameters are enfolded, so that external calibration data is not required. P. 475^
Deepwater Gulf of Mexico wells are generally deep and they may incorporate casing designs that provide only a single-casing barrier between the wellbore and the formation. These aspects present unique issues and risks in regard to casing wear. The extreme depths (>30,000 ft) of many wells in the Gulf of Mexico create the potential for high side loads imparted by the drillstring to the casing, even with low doglegs (1.0°/100 ft or less) in the upper part of the well. This, combined with potentially high rotating hours, particularly on exploration wells with sidetracks, creates the potential for casing wear that exceeds allowable limits. In order to proactively manage and mitigate casing wear during drilling operations, Chevron has developed a Casing Wear Monitoring standard operating practice (SOP). Deployment and application of this SOP has proven effective. Application of this SOP indicates that casing wear can be predicted, managed, and/or mitigated with proper planning and execution. This paper illustrates a casing wear event on a Chevron well and provides an overview of the Chevron Deepwater Casing Wear Monitoring SOP. Additionally, the paper highlights some casing wear processes, well control issues, and environmental risks that are unique to deepwater wells. Application of the casing wear prediction and monitoring procedures outlined in this paper help to ensure that the integrity of the casing is maintained during drilling operations, thereby reducing the risk of a health, safety and environment event or loss of the well due to excessive casing wear.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
