SPE

Abstract The complexities of designing an effective sand control for unconsolidated gas reservoirs in a deepwater environment is exacerbated when the targeted formation sands are characterized by particle size distributions with poorly sorted and non uniform coeficients, and high fine concentrations. Managing these intricacies requires comprehensive sand retention studies developed to ascertain the effectiveness of the sand control performance of gravel and screen gauge opening combinations in the presence of selected formation sand ratios. To build a representative testing program, actual core samples from the targeted studied zones are desirable. However, for economical, technical or logistic contrains the availability of these cores is not always feasible. This paper covers a workflow to determine a synthetic Particle Size Distribution (PSD) of a targeted well in a development block where no core data is available. The data feeding the workflow is derived from wireline bore hole imagers and Non-Magnetic Resonance (NMR) logs obtained from six wells drilled in the exploration phase of the studied gas block. Results are calibrated with localized PSD from available side wall cores. Furthermore, data obtained from the process is used to interrogate sand retention testing Mastercurves built with formation samples from one of the fields in the studied block (Field I). The interrogation process takes the synthetic PSD from the targeted well and creates normalized formation testing ratios which are then compared to the results documented on the sand retention Mastercurves. This paper is intends to discuss the worklflow and results of its field application.

doi: 10.2118/209912-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209912-MS

Country:

Asia (1.00)
North America > United States (0.70)

Geophysics: Geophysics > Seismic Surveying > Borehole Seismic Surveying (0.33)

Industry: Energy > Oil & Gas > Upstream (1.00)

SPE Disciplines: Reservoir Description and Dynamics > Formation Evaluation & Management > Open hole/cased hole log analysis (1.00)

Technology:

Information Technology > Artificial Intelligence (0.49)
Information Technology > Sensing and Signal Processing > Image Processing (0.46)

Dalgit Singh, Harpreet Kaur (Weatherford Asia Pacific) | Sammat, Essam (Weatherford Asia Pacific) | Kleawyothatis, Thakornpol (Weatherford Asia Pacific) | Niracharopas, Kittikun (PTT Exploration and Production Public Company Limited) | Kiani Nassab, Kazem (PTT Exploration and Production Public Company Limited)

Gulf of Thailand 4-String Well Design Transformation Using MPD System – Cost Saving, Operational Challenges and Learnings

Abstract Gulf of Thailand (GoT) or Gulf of Siam is mainly offshore development gas wells in Thailand. Well C and well H were originally designed with GoT 4-string standard template. However, Managed Pressure Drilling (MPD) solution was then selected to save one (1) casing string provided that the maximum expected formation pressure to be within the range of 1.46-1.50SG as per geological prognosis. Both wells were drilled to plan TD with 3-casing strings as planned to result in a cost-saving from the design transformation (4-strings to 3-strings) using the MPD system. There is always a risk of lost circulation and ballooning in intermediate/high-pressure wells (Pore Pressure (PP) > 1.45SG) when drilling conventionally with 3-casing strings (instead of GoT 4-string standard design). Required high mud weight imposes an overbalance during drilling and tripping operations that exceed formation integrity at shallower depths below the 7" casing. MPD is a proven technology for maintaining Constant Bottom Hole Pressure (CBHP) that enables precise control on wellbore pressure to mitigate ballooning and kick/loss hazards, narrow margin drilling window, and formation pressure uncertainties. The 6-1/8" hole sections of both wells were drilled with the MPD technology to mitigate the loss of circulation and ballooning while drilling. MPD system worked for this project to drill the wells to TD successfully according to the plan and without any major issue. The MPD solution enabled drilling with the lowest and safest underbalanced mud weight to allow a reduction in Bottom Hole Pressure (BHP) and consequently eliminated ballooning while drilling. Surface back pressure (SBP) on connections was increased (compared to the plan) based on connection gas reading caused by pore pressure uncertainties. MPD dynamic formation integrity test (DFIT) and static pore pressure tests (PPT) have established a baseline for heavy kill mud weight estimations and displacing before tripping out of the hole. Observations and learnings from well C confirmed the study’s preliminary conclusions that the 4-strings transformation is quite challenging for PP greater than 1.55SG, and 4-string transformation is not recommended if PP exceeds 1.60SG. The wells were completed with 3-casing strings however, no NPT related to well design and MPD was encountered. The technology was proven and allowed to drill the well with 3-strings design. The solution can save some cost in intermediate pressure wells (1.46-1.54SG PP), and it is proposed for the next trials with more focus on wellbore conditioning and tripping practices.

doi: 10.2118/209911-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209911-MS

Country: Asia > Thailand (1.00)

Industry: Energy > Oil & Gas > Upstream (1.00)

SPE Disciplines:

Well Drilling > Pressure Management > Well control (1.00)
Well Drilling > Pressure Management > Managed pressure drilling (1.00)
Well Drilling > Drilling Operations (1.00)

Well Integrity Under Dynamic Stresses Using Flexible Cement Systems

Mahmood, Ahmad Abdullah (Schlumberger) | Rasheed, Hassaan (Schlumberger) | Jan, Usman Ahmed (Schlumberger) | Khan, Anum Yousuf (Schlumberger) | Salazar, Jose (Schlumberger)

As the field of well construction has advanced over the years, one feature that has remained consistent throughout is the use of Cement as a primary well barrier element. The long-lasting, impermeable nature of the cement matrix means no other material has been considered as an effective, widely-available alternate almost a century from the first cement job. What has changed however, with advancement in the the field of well integrity, is how we approach the cement job design and how certain materials can complement the role of the cement in improving hydraulic isolation. The historical cement job design only targeted a pumpable slurry reaching the desired placement interval, then the design moved to improving liquid slurry properties such as rheologies, fluid-loss and free fluid. Later, the short-term performance as the slurry transitioned through a gel phase to a set state also became an important criterion. More recently, after the renewed global focus on well integrity as learning from disasters such as Macondo, the annular cement's role as a well barrier has become a major focal area for any well construction program. 2 IADC/SPE-209910-MS This paper presents a systematic approach in designing cement systems that promise long-term well integrity starting with the root-cause identification, simulating the effect on the cement sheath, required modification of the design, and finally the application and associated results.

doi: 10.2118/209910-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209910-MS

Country:

Asia (0.70)
North America > United States > Texas (0.29)

Industry: Energy > Oil & Gas > Upstream (1.00)

SPE Disciplines:

Well Drilling > Casing and Cementing > Cement formulation (chemistry, properties) (1.00)
Well Completion > Well Integrity (1.00)

Yuankai, Xiang (Engineering Technology Research Institute, PetroChina Xinjiang Oilfield Company) | Zhou, Jianlin (PetroVulcan Energy Technology Beijing Co., Ltd) | Leiming, Cheng (Engineering Technology Research Institute, PetroChina Xinjiang Oilfield Company) | Junxiu, Ma (Engineering Technology Research Institute, PetroChina Xinjiang Oilfield Company) | Huang, Xingning (Baker Hughes) | Singjaroen, Thanapol (Baker Hughes) | Kieduppatum, Piyanuch (Baker Hughes)

Multi-Stage Length Optimization with Integrated Hydraulic Fracture Propagation and Production Simulation Technology for Horizontal Wells in Unconventional Resource

Abstract Since the tight sandstone gas reservoir which is widely distributed in China has become increasingly important in oil field with the further development of resource, it is extraordinarily meaningful for the sustainable and healthy development of China’s energy industry to explore its benefit development mode. Though great achievements have made with the wide use of the hydraulic fracturing technology, which serves as an effective process measure to increase the productivity of a single well, in the development of global unconventional oil and gas resources, there have been many technical problems exposed. A critical one is that if the fractured stage length is too long, the oil and gas resources won’t be effectively exploited, and if it is too short, the operation cost and time will be increased apparently. Therefore, it is urgently required to make plans for determining the optimal length of the fractured reservoir based on different geological features of the oil and gas reservoirs. This paper took the tight oil reservoir in Lower Wuerhe formation in study area as the research case, determined 5 fracturing stage length cases combined with the treatment status and pumping injection procedure of M oil field: Case A (40m), Case B(50m), Case C (60m), Case D (70m) and Case E(80m), and realized fully 3D coupled simulation of the hydraulic fractures in H1 well based on the 3D geomechanical modeling and 3D DFN model with considering multiple factors including stress shadow, proppant settlement and migration using the unstructured grid technology to preprocess it to improve the capacity prediction accuracy of numerical simulation. The productivity prediction results showed that the 10-year EUR (Estimated Ultimate Recovery) of a single well ranged from 35,500 tons to 48,200 tons. With the comprehensive production and fracturing operation cost being considered comprehensively, it was recommended that the optimal length of the single fractured reservoir should be 60 meters.

doi: 10.2118/209909-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209909-MS

complex reservoir, conglomerate, formation, hydraulic fracturing, integrated hydraulic fracture propagation, lower wuerhe formation, Modeling & Simulation, multi-stage length optimization, numerical simulation, permeability, pore, production simulation technology, productivity, Reservoir Characterization, sandstone, structural geology, Upstream Oil & Gas

Country: Asia > China (0.70)

Genre: Research Report (0.34)

Geologic Time: Phanerozoic (0.95)

Industry: Energy > Oil & Gas > Upstream (1.00)

Oilfield Places:

North America > United States > California > Sacramento Basin > 4 Formation (0.99)
North America > United States > Texas > Permian Basin > Yeso Formation (0.98)
North America > United States > Texas > Permian Basin > Yates Formation (0.98)
(25 more...)

SPE Disciplines:

Technology: Information Technology > Modeling & Simulation (0.83)

Pilot Deployment and Field Validation of Wellbore Strengthening Design Criteria and Enhanced Fracture Gradient in a Depleted Reservoir

Tan, Chee Phuat (PETRONAS Research Sdn Bhd) | Razak, M. Solehuddin (PETRONAS Carigali Sdn Bhd) | Zakaria, Siti Shahara (PETRONAS Carigali Sdn Bhd) | Abitalhah, Abiabhar (PETRONAS Carigali Sdn Bhd) | Wan Mohd Zainudin, Wan Nur Safawati (PETRONAS Research Sdn Bhd)

Abstract Fracture gradient enhancementtechnology has been developed for drilling mud compounds based on comprehensive large scale laboratory test data which can widen the stable mud weight window for safe and efficient drilling in depleted reservoirs. Based on the laboratory test data, correlations were developed between optimum compound particle size against Young's modulus of the rock and generated fracture width for maximising the wellbore strengthening performance of the compounds. In addition, Enhanced Fracture Gradient (EFG) concept and criteria were developed for the compounds to widen the stable mud weight window. The niche workflow developed for utilisation of the wellbore strengthening design criteria and guidelines was deployedand validated in the pilot deployment of the optimum compound particle size correlations and Enhanced Fracture Gradient criteria in two wellsfor drilling through a depleted reservoir in the Malay Basin.The enhanced fracture gradient was predicted and incorporated into the mud weight programme and mud loss contingency plan of the wells. The wells were drilled with 10 ppb of the optimum mud compounds and the concentration was monitored and maintained throughout the drilling. In the first well, the maximum ECD exceeded the in-situ fracture gradient of the depleted reservoir by 1 ppg without any losses. Following TD of the hole section, an openhole leak-off test was conducted which validated the predicted average EFG of 1.8 ppg above the in-situ fracture gradient. The predicted EFG was within 0.2-0.3 ppg from the openhole leak-off test value. In the second well, the depleted reservoir was exposed to 0.6 ppg above the in-situ fracture gradient and no losses was observed.

doi: 10.2118/209932-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209932-MS

Country:

Asia > Malaysia > South China Sea (0.25)
North America > United States > Texas (0.15)

Industry: Energy > Oil & Gas > Upstream (1.00)

Oilfield Places: Asia > Malaysia > South China Sea > Malay Basin (0.99)

SPE Disciplines:

Well Drilling > Wellbore Design > Wellbore integrity (1.00)
Well Drilling > Pressure Management > Well control (1.00)
Well Drilling > Drilling Fluids and Materials > Drilling fluid selection and formulation (chemistry, properties) (1.00)
Well Completion > Hydraulic Fracturing (1.00)

Unlock Regulatory Requirements for Drill Cuttings Waste Utilisation Pilot

Wattana, Piyarat (PTTEP) | Wondee, Jutharat (PTTEP) | Chonchirdsin, Surasak (PTTEP)

Abstract Drill cuttings waste was recycled into new use and pilot project to utilize drill cutting waste in road and construction application were carried out. This work describes strategy and best practice to engage regulator in order to unlock regulatory requirements for the pilot on drill cutting waste utilization. Characterization of drill cuttings waste was carried out and its regulatory requirements as indicated in waste management plan and EIA were investigated in parallel to the study on technical feasibility to utilize drill cuttings waste. Equally important is investigation on the rule and regulation relevant to areas and/or industries that the drill cuttings waste will be used for. These regulatory requirements must be clearly identified in an early stage of the pilot project as it will indicate necessary analytical tests to be carried out and will provide information for designing of an environmental impact assessment and monitoring program. Drill cuttings waste is classified into two groups based on type of drilling mud used. Drill cuttings from upper section of well contaminated with water-based mud, called top-hole drill cuttings, is classified as non-hazardous waste while drill cuttings from lower section of well contaminated with synthetic-based mud, called bottom-hole drill cuttings, is classified as hazardous-minor waste. Physical properties of the drill cuttings waste such as pH, conductivity, salinity, chemical properties on chloride contents as well as heavy metal contents must be analyzed and identified to be within the standard limit. These analytical results provide necessary technical information for regulator to make decision based upon in order to support the drill cuttings waste utilization pilot. Based on characteristic of road usage and potential wear and tear of the pilot recycled drill cuttings road, environmental impact assessment and monitoring program on soil, surface water, and subsurface water on areas closed to the pilot site were performed prior and after construction of the pilot road. This environmental impact assessment and monitoring program provides track record of technical analytical data which is essential supporting information for regulator's consideration and endorsement on the future modification of EIA's regulatory requirements. This work demonstrates that good understanding on classification of the drill cuttings waste, its regulatory requirements, characteristic of application the drill cuttings waste will be used for, and its relevant legislations are essential. This information indicates necessary technical analyses required to be performed in order to obtain important technical data to unlock regulatory requirements. Drill cuttings waste utilization not only save waste management cost, but also reduce environmental footprint. This approach can be applied to utilization of other type of waste as well.

doi: 10.2118/209930-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209930-MS

Country:

Asia > Thailand (0.70)
North America > United States (0.55)

Industry:

Water & Waste Management (1.00)
Materials > Chemicals > Commodity Chemicals > Petrochemicals (1.00)
Energy > Oil & Gas > Upstream (1.00)

SPE Disciplines:

Well Drilling > Drilling Fluids and Materials > Cuttings transport (1.00)
Health, Safety, Environment & Sustainability (1.00)

Abstract Shale gas reservoirs are characterized in low gas abundance, poor permeability, lower natural productivity than the lower limit of industrial oil flow, and rapid formation energy decline. At present, the technology of horizontal well drilling and staged hydraulic fracturing is widely used for the exploitation of such low-porosity and low-permeability reservoirs. The long well section of the horizontal well in the reservoir and the hydraulic fractures formed by fracturing act as the "underground expressway" for the deep gas in the reservoir to flow toward the wellbore. Their combination can greatly increase the production performance of the oil and gas resources in the reservoir. Staged multi-cluster fracturing in horizontal wells is the key technology to achieve the profitable shale gas production. The results of on-site downhole perforation imaging and distributed optical fiber temperature and acoustic monitoring show that there are obvious non-uniform liquid inflow and expansion phenomena in each cluster of fractures during the fracturing process. Relevant research results also show that factors such as the heterogeneity of the reservoir and the stress interference caused by the propagation of multiple fractures are the main causes of the non-uniform propagation of hydraulic fractures. Therefore, it is accessible to simulate the complex balanced expansion of each cluster of fractures in the fracturing section to improve the coverage of hydraulic fractures in the horizontal well section with numerical simulation methods based on the basic theory of elasticity and fracture mechanics, to reveal how the above engineering geological factors influence and control the fracture propagation. The results of the simulation of the fracturing treatment section of the deep shale gas horizontal well by the fracture propagation model are consistent with the micro-seismic monitoring results,which has obvious significance for accelerating the exploitation of difficult-to-exploit resources and guaranteeing the supply of gas resources.

doi: 10.2118/209925-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209925-MS

Country: Asia > China (0.47)

Genre: Research Report (0.68)

Geophysics: Geophysics > Seismic Surveying (1.00)

Industry: Energy > Oil & Gas > Upstream (1.00)

Oilfield Places:

Asia > China > Xinjiang Uyghur Autonomous Region > Junggar Basin > Lucaogou Formation (0.99)
Asia > China > Sichuan > Sichuan Basin (0.99)
Asia > China > Qinghai > Qaidam Basin > Qinghai Field (0.99)

SPE Disciplines:

Well Drilling > Drilling Operations > Directional drilling (1.00)
Well Completion > Hydraulic Fracturing (1.00)
Reservoir Description and Dynamics > Unconventional and Complex Reservoirs > Shale gas (1.00)
(5 more...)

Technology: Information Technology > Modeling & Simulation (0.68)

A Novel Approach to Analyze Fracture Properties Utilizing Advanced Mud Logging

Qatari, Ammar (Saudi Aramco) | Qubaisi, Khalid (Saudi Aramco) | Dsouza, Steve (Exlog) | Magnier, Caroline (Exlog)

Abstract Mud logging, in essence, is a wellsite operation that investigates, records, and analyzes measurements obtained from the circulating drilling fluid that results in the measurement of cuttings and gas. It plays a vital role in the identification of downhole geological conditions, such as hydrocarbon presence and stratigraphy along with monitoring drilling conditions, to ensure safety of operations and improve efficiency. The objective of this paper is to utilize advanced mud logging analysis characteristics to establish a workflow to potentially identify fractures along an interval. Helium is used as the correlation parameter to potentially indicate fractures along the intended formation. Advanced mud logging provides a quantitative hydrocarbon measurement from the drilling mud rather than the qualitative measurements that regular mudlogging provides. Helium is one of the major components that advanced mudlogging provides and acts as an indicator of permeability in a formation. The process starts with a novel method to utilize helium to be a correlator of fractures within a formation in terms of identification and measurements along with tracking the fracture with time. The combination between current formation imaging procedures and helium readings from mud logs is proven to be a key potential indicator to establish a fracture identification pattern. The utility of the correlated helium readings from mud logging and fractures from formation image logs is a major breakthrough into identifying formation fracture features. Tracking changes of such features in which mud logging readings are used directly as potential indicators of fractures in an anticipated well. Loss of circulation prediction and LCM designs are enhanced directly by this extra knowledge.

doi: 10.2118/209834-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209834-MS

detector, drilling contractor, drilling data acquisition, drilling measurement, fracture, helium, identification, Indicator, information, international association, mud logging, mud logging / surface measurements, Novel Approach, operation, permeability, Petroleum Engineer, property utilizing advanced mud logging, reservoir, Upstream Oil & Gas

Country:

North America > United States (0.47)
Asia > Middle East (0.28)

Industry: Energy > Oil & Gas > Upstream (1.00)

SPE Disciplines: Well Drilling > Drilling Measurement, Data Acquisition and Automation > Mud logging / surface measurements (1.00)

Technology: Information Technology (0.47)

Abstract Spontaneous imbibition is an effective method to improve the oil recovery of tight reservoirs.The development and research of nano-emulsion provide a new technical direction for improving spontaneous imbibition oil recovery (SIOR) in tight reservoirs.The salinity has a significant effect on the properties and spontaneous imbibition of nano-emulsion, but the effect on the imbibition mechanisms is still unclear.In the paper, thelower nano-emulsion system with core-shell structures, called HS-LNE,is prepared by nano-emulsion dilution method.Afterwards,the properties and imbibition mechanisms of HS-LNE under different salinitiesare studied.Firstly,the particalsize andstability of the HS-LNE system are evaluated by centrifugation and spectroscopy. What's more, the interfacial tension (IFT), wettability,and adsorption experiments under diffierent salinitiesare carried out, and the salinity influences on the physicochemical properties of the HS-LNE system is systematically analyzed.At the same time, the SIORvariationlaw of the HS-LNE system under different salinitiesis comprehensively explored through static spontaneous imbibition experiments.The experimental results show that the HS-LNE system has excellent stability at high salinity. Moreover, as the salinity increasing, the IFT of the HS-LNE system decreased, and the wettability alternationincreased.However, the adsorption on solid interfaceswas not significantly changed and SIOR reached the highest value of 50.27% at the optimal salinity (50×10mg/L). Finally, the HS-LNE system with the optimal salinity was selected for the field test forpermeability enhancement and flooding in Well Gan 128 in Jilin Oilfield. The oil production was increased by 450 t after 5 months, with an estimated validity period of 24 months and a cumulative oil production increase of 1900 t.

doi: 10.2118/209931-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209931-MS

Country: Asia > China > Jilin (0.25)

Genre: Research Report (0.34)

Industry: Energy > Oil & Gas > Upstream (1.00)

Oilfield Places: Asia > China > Jilin > Yanji Basin > Jilin Field (0.99)

SPE Disciplines:

Sakirin, Jakkawan (Rovula Thailand Company Limited) | Rapeethasanaphong, Thaniyaporn (Rovula Thailand Company Limited) | Maleewong, Parichat (PTT Exploration and Production Public Company Limited)

Aquatic Animal Monitoring System

Abstract Aquatic Animal Monitoring Systemis initiated as part of PTTEP's Ocean for Life strategy as we thrive in enhancing Ocean Health & Biodiversity Monitoring to ensure that PTTEP's offshore operations are friendly and safe to the surrounding environment and aquatic animals. The basis of the Aquatic Animal Monitoring Systemproject focuses on conservation survey and tracking of rare aquatic animals as well as marinebiodiversity. As part of the process, an underwater camera was installed on a jacket leg of PTTEP's platform to allow the video recording of underwater lives. The video footage was then analyzed by Artificial Intelligence (AI)software using an object detection method for determining the animal's categorization, then using machine learning algorithm for more accuracy. This concept can visualize aquatic animals around the platform and the surrounding environment. Moreover, the AI software can shorten the video by cutting off any non-life appearing period. Therefore, this technique can support a processor during the video analysis from the platform, contributing to a better work efficiency as it can save time, manpower, and most importantly cost. For the detection algorithm, all targets generatea large amount of data in the form of images with labels in order to train a software to memorize the target objects. The AI software was able to detect and identify nine species of aquatic animals which are fish, turtle, whale, dolphin, shark, seal, sea lion, stingray, and seahorse. With AI software in place, the video raw file can be shortened up to 85% by removing non-life periods in the original video and tracking only animal life in the video frame. This is a significant milestone for PTTEP in creating sustainable values to the ocean, which is considered as PTTEP's second home. Adopting artificial intelligence and machine learning technology to this project, it helps categorizing aquatic animal types and shorten a videofile. Moreover, it can save manpower and time.

doi: 10.2118/209933-MS

IADC/SPE Asia Pacific Drilling Technology Conference and Exhibition

SPE-209933-MS

Country: Asia > Thailand (1.00)

Industry:

Government > Regional Government > Asia Government > Thailand Government (1.00)
Energy > Oil & Gas > Upstream (1.00)

SPE Disciplines: Data Science & Engineering Analytics > Information Management and Systems > Artificial intelligence (1.00)

Technology:

Information Technology > Artificial Intelligence > Machine Learning (1.00)
Information Technology > Artificial Intelligence > Vision > Image Understanding (0.35)