Mechanic simulator fluids for clean-up operations and phases separation in vertical and horizontal wells with coiled tubing technology

This Project look for the processes simulation that take place in the oil Wells that operate the coiled tubing technique, so its workers, Company personal and anyone that wants to look these processes, can prove that consist in their cleaning methods and phase separation in these Wells, and at the same time, in what way the substances that in and out of well are controlled, show their physical features and allow that a person, without previous knowledge about the topic, may understand easily what is it injection fluid purpose by means of the C. T. in oil Wells.

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On the penetration of tubular drill pipes in horizontal oil wells

Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science ◽

10.1243/0954406041991233 ◽

2004 ◽

Vol 218 (9) ◽

pp. 1063-1081 ◽

Cited By ~ 6

Author(s):

I McCourt ◽

T Truslove ◽

J Kubie

Keyword(s):

Drill Pipe ◽

Experimental Studies ◽

Horizontal Wells ◽

Oil Wells ◽

Scale Model ◽

Coiled Tubing ◽

Frictional Forces ◽

Drill Pipes ◽

Maximum Penetration ◽

Remedial Work

To carry out remedial work in oil wells through the production tubing string, a method using a continuous length of steel tubing or coiled tubing is used. Furthermore, coiled tubing can also be used for drilling and extending existing wells. In horizontal wells, substantial frictional forces are generated which resist the motion of the tubular drill pipe as it is pushed into the well. As the penetration increases, the frictional forces arising from the contact of the tubing with the inner casing wall increase too, and the tubular pipe buckles. The buckling is initially sinusoidal but eventually transforms into helical. At this point the force required to push the tubular drill pipe rises dramatically, and the maximum penetration is then rapidly reached. To date, scale model experimental studies on horizontal wells have not reproduced the actual conditions occurring in the wells. A new experimental rig has been designed that allows for the simulation and observation of all significant parameters. An analytical model has also been developed which is in excellent agreement with the experimental data. Governing modelling parameters have been identified which suggest ways to increase the penetration of tubular drill pipes in production oil wells.

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Detecting Water Influx in Beam Pump Lifted Horizontal Wells in the Nimr Field using Temperature Measurements, Production Profiling and Concentric Coiled Tubing

10.2118/110161-ms ◽

2007 ◽

Author(s):

Michael Peter Kuchel ◽

Majid Abdullah Al-Mahrooqi ◽

Ghaliba Ali Al Hinai ◽

Harith Sakhbouri

Keyword(s):

Horizontal Wells ◽

Temperature Measurements ◽

Coiled Tubing ◽

Water Influx ◽

Beam Pump

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Challenging Catenary Coiled Tubing Thru Tubing Screen Deployment Operation Offshore Borneo

10.2118/204419-ms ◽

2021 ◽

Author(s):

Seng Wei Jong ◽

Yee Tzen Yong ◽

Yusri Azizan ◽

Richard Hampson ◽

Rudzaifi Adizamri Hj Abd Rani ◽

...

Keyword(s):

Oil Wells ◽

Well Control ◽

Coiled Tubing ◽

Open Hole ◽

Catenary System ◽

Offshore Oil ◽

Gravel Pack ◽

Emergency Measures

Abstract Production decline caused by sand ingress was observed on 2 offshore oil wells in Brunei waters. Both wells were completed with a sub-horizontal openhole gravel pack and were subsequently shut in as the produced sand would likely cause damage to the surface facilities. In an offshore environment with limited workspace, crane capacity and wells with low reservoir pressures, it was decided to intervene the wells using a catenary coiled tubing (CT) vessel. The intervention required was to clean out the sand build up in the wells and install thru-tubing (TT) sand screens along the entire gravel packed screen section. Nitrified clean out was necessary due to low reservoir pressures while using a specialized jetting nozzle to optimize turbulence and lift along the deviated section. In addition, a knockout pot was utilized to filter and accommodate the large quantity of sand returned. The long sections of screens required could not be accommodated inside the PCE stack resulting in the need for the operation to be conducted as an open hole deployment using nippleless plug and fluid weight as well control barrier. A portable modular crane was also installed to assist the deployment of long screen sections prior to RIH with CT. Further challenges that needed to be addressed were the emergency measures. As the operation was to be conducted using the catenary system, the requirement for an emergency disconnect between the vessel and platform during the long cleanout operations and open hole deployment needed to be considered as a necessary contingency. Additional shear seal BOPs, and emergency deployment bars were also prepared to ensure that the operation could be conducted safely and successfully.

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Case Study- Real Time Downhole Telemetry CCL and Tension Compression, a Differentiator for Successful Manipulation of ICD's in Horizontal Wells

10.2118/204873-ms ◽

2021 ◽

Author(s):

Usman Ahmed ◽

Zhiheng Zhang ◽

Ruben Ortega Alfonzo

Keyword(s):

Saudi Arabia ◽

Real Time ◽

Oil Recovery ◽

Horizontal Wells ◽

Differential Pressure ◽

Successful Operation ◽

Coiled Tubing ◽

Electric Line ◽

Wide Range ◽

Ict System

Abstract Horizontal well completions are often equipped with Inflow Control Devices (ICDs) to optimize flow rates across the completion for the whole length of the interval and to increase the oil recovery. The ICD technology has become useful method of optimizing production from horizontal wells in a wide range of applications. It has proved to be beneficial in horizontal water injectors and steam assisted gravity drainage wells. Traditionally the challenges related to early gas or water breakthrough were dealt with complex and costly workover/intervention operations. ICD manipulation used to be done with down-hole tractor conveyed using an electric line (e-line) cable or by utilization of a conventional coiled tubing (CT) string. Wellbore profile, high doglegs, tubular ID, drag and buoyancy forces added limitations to the e-line interventions even with the use of tractor. Utilization of conventional CT string supplement the uncertainties during shifting operations by not having the assurance of accurate depth and forces applied downhole. A field in Saudi Arabia is completed with open-hole packer with ICD completion system. The excessive production from the wells resulted in increase of water cut, hence ICD's shifting was required. As operations become more complex due to fact that there was no mean to assure that ICD is shifted as needed, it was imperative to find ways to maximize both assurance and quality performance. In this particular case, several ICD manipulating jobs were conducted in the horizontal wells. A 2-7/8-in intelligent coiled tubing (ICT) system was used to optimize the well intervention performance by providing downhole real-time feedback. The indication for the correct ICD shifting was confirmed by Casing Collar Locator (CCL) and Tension & Compression signatures. This paper will present the ICT system consists of a customized bottom-hole assembly (BHA) that transmits Tension, compression, differential pressure, temperature and casing collar locator data instantaneously to the surface via a nonintrusive tube wire installed inside the coiled tubing. The main advantages of the ICT system in this operation were: monitoring the downhole force on the shifting tool while performing ICD manipulation, differential pressure, and accurately determining depth from the casing collar locator. Based on the known estimated optimum working ranges for ICD shifting and having access to real-time downhole data, the operator could decide that required force was transmitted to BHA. This bring about saving job time while finding sleeves, efficient open and close of ICD via applying required Weight on Bit (WOB) and even providing a mean to identify ICD that had debris accumulation. The experience acquired using this method in the successful operation in Saudi Arabia yielded recommendations for future similar operations.

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Coiled Tubing: A Key Enabler for Successful Multifractured, Horizontal Wells in Recent Low-Permeability Gas Developments Offshore UK

10.2118/134935-ms ◽

2010 ◽

Cited By ~ 1

Author(s):

Brian Holland ◽

William W. Cruickshank ◽

Gerard Philip Coghlan

Keyword(s):

Horizontal Wells ◽

Low Permeability ◽

Coiled Tubing

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An Alternative Tool for Production Logging in Horizontal Wells

10.2118/204805-ms ◽

2021 ◽

Author(s):

Nadir Husein ◽

Jianhua Xu ◽

Igor Novikov ◽

Ruslan Gazizov ◽

Anton Buyanov ◽

...

Keyword(s):

Continuous Production ◽

Analytical Data ◽

Horizontal Wells ◽

Optimal Length ◽

Well Drilling ◽

Actual Distribution ◽

Well Completion ◽

Coiled Tubing ◽

Additional Equipment ◽

Getting Lost

Abstract From year to year, well drilling is becoming more technologically advanced and more complex, therefore we observe the active development of drilling technologies, well completion and production intensification. It forms the trend towards the complex well geometry and growth of the length of horizontal sections and therefore an increase of the hydraulic fracturing stages at each well. It's obvious, that oil producing companies frequently don't have proved analytical data on the actual distribution of formation fluid in the inflow profiles for some reasons. Conventional logging methods in horizontal sections require coiled tubing (CT) or downhole tractors, and the well preparation such as drilling the ball seat causing technical difficulties, risks of downhole equipment getting lost or stuck in the well. Sometimes the length of horizontal sections is too long to use conventional logging methods due to their limitations. In this regard, efficient solution of objectives related to the production and development of fields with horizontal wells is complicated due to the shortage of instruments allowing to justify the horizontal well optimal length and the number of MultiFrac stages, difficulties in evaluating the reservoir management system efficiency, etc. A new method of tracer based production profiling technologies are increasingly applied in the global oil industry. This approach benefits through excluding well intervention operations for production logging, allows continuous production profiling operations without the necessity of well shut-in, and without involving additional equipment and personal to be located at wellsite.

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Three-Phase Flow Profile Determination of A Horizontal Well in Offshore by Tracer Technology

10.4043/30991-ms ◽

2021 ◽

Author(s):

Alexander Katashov ◽

Igor Novikov ◽

Evgeny Malyavko ◽

Nadir Husein

Keyword(s):

Oil And Gas ◽

Horizontal Wells ◽

Oil And Gas Industry ◽

World Market ◽

Dynamic Mode ◽

Flow Profile ◽

Offshore Platforms ◽

Field Development ◽

Coiled Tubing ◽

Three Phase

Abstract Over the past few years, the oil and gas industry has faced a situation of high fluctuations in hydrocarbon prices on the world market. In addition, the trend for the depletion of traditional hydrocarbon reservoirs and the search for new effective solutions for the management and control of field development using horizontal and multilateral wells is still relevant. The most common method for horizontal wells testing is production logging tools (PLT) on coiled tubing (CT) or downhole tractor, which is associated with HSE risks and high cost, especially on offshore platforms, which limits the widespread use of this technology. The solution without such risks is the method of marker well monitoring, which allows obtaining information about the profile and composition of the inflow in a dynamic mode in horizontal wells without well intervention. There are several types of tracer (marker) carriers and today we will consider an approach to placing marker monitoring systems as part of a completion for three-phase oil, water and gas monitoring.

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Physical Scaling of Oil Production Rates and Ultimate Recovery from All Horizontal Wells in the Bakken Shale

Energies ◽

10.3390/en13082052 ◽

2020 ◽

Vol 13 (8) ◽

pp. 2052 ◽

Cited By ~ 2

Author(s):

Wardana Saputra ◽

Wissem Kirati ◽

Tadeusz Patzek

Keyword(s):

Petroleum Industry ◽

Oil Production ◽

Horizontal Wells ◽

Accurate Method ◽

Oil Wells ◽

Shale Oil ◽

Square Root ◽

Production Rates ◽

Time Flow ◽

Bakken Shale

A recent study by the Wall Street Journal reveals that the hydrofractured horizontal wells in shales have been producing less than the industrial forecasts with the empirical hyperbolic decline curve analysis (DCA). As an alternative to DCA, we introduce a simple, fast and accurate method of estimating ultimate recovery in oil shales. We adopt a physics-based scaling approach to analyze oil rates and ultimate recovery from 14,888 active horizontal oil wells in the Bakken shale. To predict the Estimated Ultimate Recovery (EUR), we collapse production records from individual horizontal shale oil wells onto two segments of a master curve: (1) We find that cumulative oil production from 4845 wells is still growing linearly with the square root of time; and (2) 6401 wells are already in exponential decline after approximately seven years on production. In addition, 2363 wells have discontinuous production records, because of refracturing or changes in downhole flowing pressure, and are matched with a linear combination of scaling curves superposed in time. The remaining 1279 new wells with less than 12 months on production have too few production records to allow for robust matches. These wells are scaled with the slopes of other comparable wells in the square-root-of-time flow regime. In the end, we predict that total ultimate recovery from all existing horizontal wells in Bakken will be some 4.5 billion barrels of oil. We also find that wells completed in the Middle Bakken formation, in general, produce more oil than those completed in the Upper Three Forks formation. The newly completed longer wells with larger hydrofractures have higher initial production rates, but they decline faster and have EURs similar to the cheaper old wells. There is little correlation among EUR, lateral length, and the number and size of hydrofractures. Therefore, technology may not help much in boosting production of new wells completed in the poor immature areas along the edges of the Williston Basin. Operators and policymakers may use our findings to optimize the possible futures of the Bakken shale and other plays. More importantly, the petroleum industry may adopt our physics-based method as an alternative to the overly optimistic hyperbolic DCA that yields an ‘illusory picture’ of shale oil resources.

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