A New Sealant System for Multilateral Junction Geometries
Abstract: This paper describes the design, development and application of a new sealant system for multilateral well junctions. The sealant system has been successfully applied in offshore multilateral well installations for North Sea operators. In recent years, the oilfield industry has shown an increasing interest in multilateral wells. Multilateral wells are an economically viable solution for many offshore operators because multilateral wells increase reservoir drainage and extend the wellhead slot… Show more
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High-Impact-Resistant Cement Allows Challenging Sidetrack in Abu Dhabi
The process of sidetracking an existing borehole with a balance cement plug has historically been time consuming and problematic for the drilling industry. The formations in the Middle East are classified as some of the most competent formations in the industry. These formations present its own challenges when attempting to sidetrack because of changes in the drilling trajectory. Historically, the operator has faced problems sidetracking in the Shilaif formations, where longer drilling time and/or numerous cement plugs are required to achieve this objective. These requirements lead to an increased in drilling costs. Traditionally, a conventional cement system with a high compressive strength is used for sidetracking purposes. However, these cement systems have low resistance to impact and shock and hence will fail through rupture when placed across the competent formations. An optimized particle sized distribution cement system, combined with engineered metallic micro ribbon technology has allowed the sidetracking to be achieved efficiently. The technology improves the durability and the resistance of the cement to load bearing capacity and fracture propagation. Further laboratary testing comparisons have confirmed the enhanced mechanical properties of this cement system. As a rule of thumb, the industry relied on the rate of penetration (ROP) as an indicator of how good a cement plug is for sidetracking purposes. It is believed that the lower the ROP is, the easier the sidetrack can be achieved. As the technology is "tougher" than the formations, the drilling bottom hole assembly (BHA) can be deflected/ sidetracked efficiently and drilling operations resumed, in a shorter period of time compared to using conventional cement systems. Introduction Setting cement plugs is an operation commonly performed while drilling the well. The objectives of the cement plugs are generally eitherplugging back an existing open hole to ensure zonal isolation orsidetracking the wellbore to change the well trajectory The process of spotting a cement plug to facilitate a sidetrack can be challenging. Problems related to this operation have been well documented in the industry 1,2,8. Some of the problems frequently encountered are:Cement plug sinking or stringing out from the wellbore while pulling out the cement tubingSoft, unset cement due to fluids contaminationExcessive wait on cement (WOC) timeLow compressive strength cement systemCement plug rupture Today as the industry is drilling more challenging wells to reach complex reservoirs, it is also faced with increasing costs associated with the drilling operations. Therefore any failures of the sidetrack cement plugs will result in job repetition, which can lead to extra rig time and costs to the operator. Many studies and advancement have been successfully made to improve the success rate of placing a sidetrack cement plug 1–3. Despite improvements in the process and better selection of proper conventional cement system, problems are still encountered while sidetracking. This is especially true in certain formations that are harder and tougher than the cement system. Therefore, there is a need for a sidetrack cement plug that exhibits greater strength and resistance compared to the conventional cement system. This paper describes a new cement system that has superior properties compared to conventional cement slurry, further optimizing the mechnical durability of the set cement. Field case histories are presented illustrating the success of the new cement system in sidetracking wells for a major operator in Abu Dhabi.
High-Impact-Resistant Cement Allows Challenging Sidetrack in Abu Dhabi
The process of sidetracking an existing borehole with a balance cement plug has historically been time consuming and problematic for the drilling industry. The formations in the Middle East are classified as some of the most competent formations in the industry. These formations present its own challenges when attempting to sidetrack because of changes in the drilling trajectory. Historically, the operator has faced problems sidetracking in the Shilaif formations, where longer drilling time and/or numerous cement plugs are required to achieve this objective. These requirements lead to an increased in drilling costs. Traditionally, a conventional cement system with a high compressive strength is used for sidetracking purposes. However, these cement systems have low resistance to impact and shock and hence will fail through rupture when placed across the competent formations. An optimized particle sized distribution cement system, combined with engineered metallic micro ribbon technology has allowed the sidetracking to be achieved efficiently. The technology improves the durability and the resistance of the cement to load bearing capacity and fracture propagation. Further laboratary testing comparisons have confirmed the enhanced mechanical properties of this cement system. As a rule of thumb, the industry relied on the rate of penetration (ROP) as an indicator of how good a cement plug is for sidetracking purposes. It is believed that the lower the ROP is, the easier the sidetrack can be achieved. As the technology is "tougher" than the formations, the drilling bottom hole assembly (BHA) can be deflected/ sidetracked efficiently and drilling operations resumed, in a shorter period of time compared to using conventional cement systems. Introduction Setting cement plugs is an operation commonly performed while drilling the well. The objectives of the cement plugs are generally eitherplugging back an existing open hole to ensure zonal isolation orsidetracking the wellbore to change the well trajectory The process of spotting a cement plug to facilitate a sidetrack can be challenging. Problems related to this operation have been well documented in the industry 1,2,8. Some of the problems frequently encountered are:Cement plug sinking or stringing out from the wellbore while pulling out the cement tubingSoft, unset cement due to fluids contaminationExcessive wait on cement (WOC) timeLow compressive strength cement systemCement plug rupture Today as the industry is drilling more challenging wells to reach complex reservoirs, it is also faced with increasing costs associated with the drilling operations. Therefore any failures of the sidetrack cement plugs will result in job repetition, which can lead to extra rig time and costs to the operator. Many studies and advancement have been successfully made to improve the success rate of placing a sidetrack cement plug 1–3. Despite improvements in the process and better selection of proper conventional cement system, problems are still encountered while sidetracking. This is especially true in certain formations that are harder and tougher than the cement system. Therefore, there is a need for a sidetrack cement plug that exhibits greater strength and resistance compared to the conventional cement system. This paper describes a new cement system that has superior properties compared to conventional cement slurry, further optimizing the mechnical durability of the set cement. Field case histories are presented illustrating the success of the new cement system in sidetracking wells for a major operator in Abu Dhabi.
Synergy Between Engineered Fibers and Lightweight Cement Slurries to Cement Depleted Formations
The production of hydrocarbons from pressure-depleted zones is becoming a common practice around the world and drives the constant development and improvement of cementing technology. This paper addresses the evolution of lightweight cement slurries to ensure zonal isolation and mechanical stability of casing in highly permeable and depleted formations. To prevent lost circulation while cementing depleted formations, a new technique has been developed based on adding inert fibers to ultralightweight slurries. During the cementing operation, the fibers create a network across the loss zone, to enable the cement to bridge off these zones and regain circulation. Also, these fibers enhance the mechanical properties of the cement as the created net provides additional stability to resist tensile stresses. This paper discusses the challenges and solutions of developing ultralightweight slurries (without foaming) that control rheology and cement properties by the interaction of fibers and cement particle size distribution. The paper addresses the synergies that cement slurries and inert fibers, with specific gravity values between 1.0 sg and 0.88 sg, bring to cement production casings in the Cantarell field of Mexico. The pay zone of the Cantarell field is a highly fractured, highly permeable, vuggy, and depleted Cretaceous formation that is typically drilled under total loss of circulation. The ability to reduce and prevent losses of slurry by adding this engineered fiber helps to ensure that the cement slurry is placed according to design to provide good zonal isolation and to permit completion of the new well. Introduction The design of the primary cementing job in the Cantarell field has been a continuous challenge to achieve a good zonal isolation along a Cretaceous formation which is considered the main producing horizon for Mexico in terms of barrels of oil produced per day. Cantarell field (Fig. 1) is the second largest producing field in the world behind Ghawar field in Saudi Arabia and was discovered in 1976. The upper reservoir is an uppermost Cretaceous brecciated dolomite, and the lowest stratigraphic reservoir in the field is a lower Cretaceous dolomitic limestone. The field is made up of a number of subfields or fault blocks, which geologically are in an overthrust structural setting. The subfields are: Akal, Chac, Kutz, and Nohoch. The field reached an early peak in production of 1.1 million B/D in April of 1981 from 40 oil wells; however, in 1994, the production was down to 890,000 B/D. One year later, in 1995, it was producing 1 million B/D because the Mexican government decided to invest in that field to raise the production level. To reach that level, the local operator built 26 new platforms, drilled many new wells, and built the largest nitrogen extraction facility capable of injecting a billion ft3/D of nitrogen to maintain reservoir pressure. Consequently, they were able to raise the oil production rate in 2001 to 2.2 million B/D. Today, the field produces 2.1 million barrels. On the other hand, analysis indicates that the gas located at the upper section of the formation zone will continue to progress in Cantarell as a result of hydrocarbon production. Thus, currently producing wells will stop producing in the future. The pace at which production will decrease will depend on the number of wells that continue to produce. Therefore, included in the stated goals for the project, based on the reservoir management policies, is the maintenance of pressure by injecting nitrogen and the closure of wells with high gas/oil ratio.
New Shock Resistant Cement Reduces the Required Time for Side-Tracking from KickOff Cement Plugs
The process of sidetracking an existing borehole with a balanced cement plug has historically been time consuming and problematic for the drilling industry.In many instances long drilling times or even multiple plugs are required to achieve the objective of sidetracking the well. These problems lead to increased drilling time and increased cost for the operator. Traditional cement slurry systems for sidetrack applications have been focused on the development of high compressive strength through reduced water content. Conventional high compressive strength cement systems exhibit low resistance to impact and low resistance to fracture propagation through the set cement. Recent developments in oil well cement system have incorporated a unique micro-ribbon technology with an optimized particle size distribution to increase the durability, load bearing capacity and resistance to fracture propagation of set cement. Field tests with these cement systems have shown substantial improvements over conventional cement slurries in terms of plug success rate and time required to achieve the objective of sidetracking the well. These improvements have resulted in significant reductions in the total cost of the operation of sidetracking wells. This paper will discuss the improved mechanical properties of these new cement systems and the success of the numerous field tests. Introduction Borehole sidetracking operations with cement plugs is a well-established and long-standing technique. This technique consists of placing a plug of cement in the borehole, allowing the cement to establish compressive strength, then using the cement plug to deflect the bit away from the current borehole starting anew open hole section. Difficulties in this operation are also well documented and long-standing [1–6]. As drilling cost increased and the level of directional drilling increased the cost associated with the failures of sidetrack cement plugs gained more attention. These problems continue to receive attention today. Many studies have been conducted to improve success rates of open hole kickoff plug placement [1–4]. Most of these studies have focused on improving portions of the workflow process associated with plug placement and slurry design methods. Others have focused on developing recommended practices for the sidetracking operation as a whole [2]. New tools have been proposed and developed to improve the placement efficiency of cement slurries [5–6] or provide mechanical alternatives to cement plugs in the open hole [6]. Much less effort has been directed toward optimizing the cement systems utilized to achieve the sidetrack. Traditionally, cement system design for sidetracking operations has focused on maximizing set cement compressive strength while optimizing other traditional properties such as pumping -time, rheology, slurry stability, fluid loss, etc. Some work has been focused on the development of cement systems that reduce the rate of penetration when drilled[7]. This work has been focused on the addition of particles with a high degree of hardness to the slurry. Reducing the rate of penetration of the slurry when drilled would seem to represent an important characteristic of aset cement system used for sidetracking operations. When properly applied, these lessons learned and the cumulative set of placement and design methodologies developed from past efforts have provided substantial rewards to the industry. However in some areas, for example regions with extremely hard formations, problems still exist even if proper placement and proper conventional slurry design are followed. This paper will outline a new cement slurry that focuses on optimizing the mechanical durability of the set cement through the implementation of optimized particle size distribution slurries with metallic micro-ribbon technology and the successful field testing of these slurries in over 25 wells. Successful implementation of this new system in sidetracking operations for a major operator in Abu Dhabi has resulted in significant improvements in the efficiency of sidetracking operations and significant cost reductions resulting from rig time saved.
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