Wireline T1 Logging

Bonnie, Ron J.M.; Akkurt, Ridvan; Al-Waheed, Hilal; Bradford, Charles; Eyvazzdeh, Ramsin Y.; Phillips, E. Craig; Aadireddy, Prabhakar; Negm, Ehab

doi:10.2118/84483-ms

Cited by 6 publications

(1 citation statement)

References 5 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Note that in the pay zone (marked by the red strip in the depth axis of both logs), the T 2 distribution contains a single peak, while the T 1 log has two (excluding the weak signals present at early times due to bound water). The stronger peak in the T 1 distribution, centered around 2 seconds is due to gas, while the peak at around 200 ms is due to mud filtrate 19 . Because of diffusion, the water and gas signals are superimposed and direct detection of gas is not possible.…”

Section: Petrophysical Requirements For Everyday-nmrmentioning

confidence: 92%

Challenges for Everyday NMR: An Operator's Perspective

Akkurt

Kersey

Zainalabedin

2006

SPE Annual Technical Conference and Exhibition

View full text Add to dashboard Cite

TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractState-of-the-art Nuclear Magnetic Resonance (NMR) applications can be classified into two categories: (1) basic applications designed for total porosity, bound water and permeability, (2) advanced applications that address hydrocarbon type, viscosity and flushed zone hydrocarbon saturation, amongst some others.An NMR log designed for basic applications -especially a T 1 log -can provide accurate porosity information in shaly sands and complex carbonates; answer questions related to reservoir quality and producibility; and easily identify gas or tar zones. Given the obvious benefits of such information for routine petrophysical analysis and timely business decisions, one would assume that NMR logging would already be an everyday phenomenon in formation evaluation. Unfortunately, NMR has yet to enter the main stream of everyday logging: it is still considered a specialty, requiring the involvement of experts from the planning to the interpretation stages.Partially due to historical reasons, but more so for cost justification and product differentiation, service companies have traditionally focused on advanced applications. Hence, despite significant advances made in all phases of the technology, concentrating on sophisticated methodologies has resulted in slow logging speeds and high costs, in addition to complex data acquisition, processing and interpretation procedures.Turning the everyday-NMR concept into a reality will require standardization of the service and proper hardware that is free of the limitations of the existing tools. The main objective of this paper is to discuss specific strategies to achieve the everyday-NMR goal for wireline and LWD logging. The proposed strategies include not only the technical requirements, but also the initiatives required from both the operators and service companies.

show abstract

Section: Petrophysical Requirements For Everyday-nmrmentioning

confidence: 92%

Challenges for Everyday NMR: An Operator's Perspective

Akkurt

Kersey

Zainalabedin

2006

SPE Annual Technical Conference and Exhibition

View full text Add to dashboard Cite

show abstract

Nuclear Magnetic Resonance Logging: While Drilling, Wireline, and Fluid Sampling

Seifert

Akkurt

Al-Dossary

et al. 2007

SPE Middle East Oil and Gas Show and Conference

View full text Add to dashboard Cite

TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractOver the past decade, results from Nuclear Magnetic Resonance (NMR), logs have added significant value to petrophysical analysis by providing total, free-fluid and bound-fluid porosities. The development of Nuclear Magnetic Resonance tools for the LWD environment allows this valuable information to become available during the drilling operation, before significant invasion, allowing timely decisions, as well as reduced borehole risk.Data from a Nuclear Magnetic Resonance Logging While Drilling tool (MRIL-WD) was acquired in a recently drilled well in Saudi Arabia. This well was extensively cored and logged. In addition to LWD NMR, wireline NMR logs (MRIL-Prime), and NMR fluid analyzers (MRILab) were also run.This paper, following a brief discussion on the operation of MRIL-WD tool, compares and contrasts the results between while-drilling and wireline NMR logs. NMR fluid properties obtained from the NMR Fluid Analyzer are also crosschecked with the log data.Obtaining Nuclear Magnetic Resonance data earlier in the drilling process will allow NMR logging to become one of the backbones of formation evaluation.

show abstract

New Integrated Applications Using T1 and T2 Modes of Magnetic Resonance in Tight Gas Reservoirs: A Case Study From Northern Mexico

Monroy-Ayala

Munoz

Rico³

et al. 2007

Latin American &Amp; Caribbean Petroleum Engineering Conference

View full text Add to dashboard Cite

Petrophysical evaluation of the tight gas reservoirs in northern Mexico presents challenges for identifying overpressured gas zones when applying conventional techniques in laminated and fine grain sand zones. This paper presents case histories in which the magnetic resonance technology was used in its new T1 mode and describes the advantages of this new logging mode over the conventional T2 mode in gas reservoirs. The paper highlights the integration of all available petrophysical data for a particular field. This integration model compares the irreducible water saturation between the newly developed models, based on magnetic resonance data after its calibration to core, conventional logs, and production tests. Our integrated approach was used to analyze the data from different wells drilled in the field and to determine the best petrophysical parameters for any interpretation. The approach used was focused on identifying the best zones to be further evaluated, considering the different responses of all available log data from each well in the field. Permeability was derived from the Coates model using the magnetic resonance data after its calibration to cores. Results were then compared to actual production. For those wells in which only standard MRI logging information was available, the model was used to calculate the permeability and compare it to actual cores. Production test results were also compared to the evaluation prognosis and used to fine tune the interpretation model. The model was then used in other wells in the area for which few conventional log data were acquired. The integrated approach used with the new MRI acquisition technique benefits the operators by helping them to better evaluate and produce laminated tight gas reservoirs. The methods developed helps with making the right decisions regarding the need to acquire additional log data, with defining intervals for testing, and determining the size of the required hydraulic fracturing for production. Introduction In overpressured tight gas reservoirs, permeability is one of the critical parameters used to characterize the reservoir and to determine the best fracture design for maximizing its gas recovery. One of the options for obtaining reliable reservoir permeability is to cut cores, using conventional methods or by using wireline rotary coring techniques, and send these rock samples to a petrophysical laboratory for permeability measurements. This is usually a single point measurement. Conversely, because permeability ranges only from 0.001 md to 0.1 md in this tight gas field, pressure tests or build-up analyses have limitations. The use of magnetic resonance to determine the irreducible water saturation and permeability using the Coates relationship (Coates, et al., 1999) is proven to be a reliable option in this type of reservoir. This relationship relates the total volume of fluids to the nonmoveable irreducible fluids in the pore space to determine the permeability. It has given good results, especially in sandstones. The original Coates relationship is expressed as follows: Equation Where: K = Permeability f = MRIL Porosity MFFI = MRI Free Fluid Volume MBVI = MRI Bulk Volume Irreducible C = Coefficient dependent on reservoir type a, b= Exponents derived from NMR core analysis Typical values for the exponents in sandstones in the Gulf of Mexico are C=20 and a, b= 2 In general, the MRI permeability should initially be used to differentiate between good quality and poor quality reservoirs in a relative fashion. After calibrating to the MRI core analysis and defining the values of "C," "a," and "b," it can be used in its absolute form. It should be closely compared to the Klinkenberg permeability (air permeability corrected for overburden) measured in the laboratory (Marschall, et al., 1999).

show abstract

Wireline T1 Logging

Cited by 6 publications

References 5 publications

Challenges for Everyday NMR: An Operator's Perspective

Challenges for Everyday NMR: An Operator's Perspective

Nuclear Magnetic Resonance Logging: While Drilling, Wireline, and Fluid Sampling

New Integrated Applications Using T1 and T2 Modes of Magnetic Resonance in Tight Gas Reservoirs: A Case Study From Northern Mexico

Contact Info

Product

Resources

About