Wellhead
A wellhead is the surface termination assembly of an oil, natural gas, or geothermal well, serving as the primary interface between the subsurface wellbore and above-ground production facilities to contain pressure, support tubular strings, and facilitate controlled flow of hydrocarbons. It marks the point where crude oil and/or natural gas exits the ground, with production volumes and prices often measured at this location for reporting purposes.[1][2] Key components of a wellhead include casing heads, tubing heads, hangers (such as slip or mandrel types), adapters, seals, and ports, all designed to suspend casing and tubing strings while sealing annular spaces to prevent leaks and maintain well integrity under high pressures ranging from 2,000 to 20,000 psi. These elements are manufactured to rigorous standards, primarily API Specification 6A, which ensures dimensional interchangeability, material quality, and testing protocols for safety and reliability in containing wellbore fluids and pressures.[2][3] The wellhead often integrates with a Christmas tree, an assembly of valves, spools, and fittings mounted atop it to regulate production flow, monitor pressures, and enable interventions like injection or shut-in operations.[3] Wellheads vary by application and environment: onshore versions are typically exposed and equipped for direct access, while subsea wellheads, installed on the seabed, connect to underwater production systems without vertical risers to surface platforms, supporting remote operations in offshore fields. This equipment is critical for preventing blowouts, enabling efficient resource extraction, and complying with regulatory requirements for environmental protection and worker safety in the global oil and gas industry.[4][5]Overview
Definition and Purpose
A wellhead is the surface component of an oil, gas, or geothermal well that provides the structural and pressure-containing interface for drilling and production equipment, serving as the connection between the subsurface reservoir and surface facilities.[6] According to API Specification 6A, this interface ensures the well's integrity by acting as a pressure barrier and mechanical support system rated for high-pressure environments up to 20,000 psi.[7][3] The primary purposes of a wellhead include providing suspension points and pressure seals for casing and tubing strings that extend from the well bottom to the surface, thereby maintaining wellbore stability and preventing fluid migration. It also supports blowout preventers (BOPs) during the drilling phase to enable surface pressure control and mitigate risks of uncontrolled releases, while later serving as the base for Christmas trees to manage fluid flow during production operations.[6] These functions are critical for containing reservoir pressures and ensuring safe access to the wellbore throughout its lifecycle.[7] In operational context, the wellhead terminates the casing strings at the surface, creating a sealed endpoint that facilitates monitoring, maintenance, and interventions such as wireline operations or hydraulic stimulation without compromising pressure integrity. This design aligns with industry standards like API 6A and ISO 10423, which emphasize its role in pressure regulation and structural support to uphold well control.[3][7]Importance in Oil and Gas Industry
The wellhead serves as a vital component in the oil and gas industry by providing essential well control mechanisms that prevent blowouts and uncontrolled leaks during drilling and production operations. Through integrated systems like blowout preventers (BOPs), it seals the wellbore to contain high-pressure hydrocarbons, thereby safeguarding personnel, equipment, and the surrounding environment from catastrophic releases.[8][9] This role is particularly critical in high-risk environments, where failure could lead to incidents like the Deepwater Horizon disaster, underscoring the wellhead's contribution to operational safety and regulatory compliance.[10] Economically, the wellhead enables the extraction and initial management of hydrocarbons from over 1 million active wells worldwide as of 2025, supporting a global industry that produces approximately 100 million barrels of oil equivalent per day and generates trillions in annual revenue. By facilitating reliable production flows, wellheads underpin energy supply chains that power transportation, manufacturing, and electricity generation, while the equipment market itself is valued at over $7 billion in 2024, reflecting substantial investment in infrastructure.[11] This infrastructure not only drives job creation—supporting hundreds of thousands of positions in upstream operations—but also contributes to trade balances in major producing nations like the United States and Saudi Arabia. In terms of integration, the wellhead acts as the critical interface connecting the reservoir to downstream processes, including gathering pipelines and processing facilities, where it regulates flow rates and enables real-time monitoring of pressure and production volumes.[12] This linkage ensures efficient transport of raw hydrocarbons to treatment plants for separation and purification, optimizing resource recovery and minimizing bottlenecks in the midstream sector.[13] Such connectivity is essential for maintaining the integrity of the overall production system, allowing operators to adapt to varying reservoir conditions while complying with quality standards for pipeline-grade products.History
Early Developments
The origins of wellhead technology can be traced to the 1860s in the United States oil fields of Pennsylvania, where the first commercial oil production began with Edwin Drake's well in Titusville in 1859. Early vertical wells were shallow, typically less than 100 feet deep, and employed rudimentary completion methods, including cast iron drive pipes to prevent borehole collapse and iron caps to seal the wellhead against uncontrolled flow. These simple structures sufficed for low-pressure, hand-pumped operations but offered limited safety and durability, often relying on manual plugging with rags or basic iron fittings when production ceased.[14] Key milestones in wellhead evolution occurred in the early 20th century as drilling depths increased and rotary methods gained adoption. The introduction of steel casing in the 1920s marked a significant advancement, enabling stronger, corrosion-resistant linings cemented in place to isolate formations and support the borehole, replacing fragile alternatives and facilitating safer completions. Concurrently, companies like Cameron Iron Works, founded in 1920 in Houston, Texas, pioneered standardized wellhead designs in the 1930s, incorporating forged steel components such as ring joint gaskets and bolted flanges that aligned with emerging American Petroleum Institute (API) specifications for interoperability and reliability. These designs improved assembly and pressure containment for wells reaching thousands of feet.[15][16][17] By the post-1940s period, the push for deeper drilling—driven by discoveries in fields like the Gulf of Mexico and California's Kern River—necessitated a transition from manual to pressure-rated wellhead systems capable of withstanding thousands of pounds per square inch. This shift incorporated integrated blowout preventers (BOPs) and multi-stage casing heads, enhancing control over high-pressure reservoirs and reducing blowout risks during exploration of wells exceeding 10,000 feet. Cameron Iron Works and other innovators refined these systems to meet API standards for working pressures up to 5,000 psi, laying the groundwork for modern production safety.[18]Modern Advancements
During the 1970s and 1980s, the oil and gas industry widely adopted American Petroleum Institute (API) standards for wellhead equipment, which provided uniform specifications for design, materials, and testing to improve reliability and safety across operations. API Specification 6A, first issued in 1939 but significantly revised in subsequent decades, saw key updates like the 14th edition in 1982 and the 16th edition in 1989, incorporating enhanced pressure ratings and material requirements that facilitated broader interoperability and reduced risks in high-pressure environments. Concurrently, subsea wellhead adaptations advanced offshore drilling capabilities, with early systems deployed in the North Sea; for instance, the Ekofisk field in Norway installed one of the first subsea completions in 1971, enabling remote operation without surface platforms and paving the way for deeper water exploration. By the 1990s, these adaptations evolved to include template-based wellheads and diverless installation techniques, supporting water depths up to 1,000 meters and addressing challenges like corrosion in harsh marine conditions. International developments, such as early subsea trials in the Persian Gulf, further expanded global applications. From the 2000s onward, wellhead technology integrated smart sensors for real-time monitoring of pressure, temperature, and flow, transforming operations through intelligent completion systems that allowed remote adjustments and optimized production. The deployment of such systems experienced rapid growth during the decade, exemplified by Schlumberger's InterACT and Halliburton's iAcquire technologies using fiber-optic and quartz sensors for continuous data acquisition. Modular designs emerged to accelerate installation and reduce rig time, with systems like the Cameron SOLIDrill compact wellhead, introduced around 2016, enabling reliable casing suspension and debris prevention in a single unit that cut setup durations by up to 50% in unconventional plays. Additionally, high-pressure wellhead systems rated up to 20,000 psi were developed for ultra-deep wells exceeding 30,000 feet, with pioneering subsea applications in the Gulf of Mexico starting in the early 2010s and first full 20,000 psi control stacks qualified for deepwater use by 2020, supporting high-temperature, high-pressure reservoirs. Post-2020 developments have emphasized sustainability and durability, incorporating composite materials for superior corrosion resistance in wellhead components exposed to aggressive environments like CO2-rich fluids. For example, fiber-reinforced polymer composites and advanced alloys like 904L clad plates have been applied in wellhead tubulars and fittings, demonstrating pitting resistance equivalent to or better than traditional duplex stainless steels in high-pressure gas fields, as validated in 2024 corrosion tests. AI-driven predictive maintenance has gained traction, leveraging machine learning algorithms to analyze sensor data and forecast failures, reducing unplanned downtime by 15-20% in offshore assets according to 2023-2024 industry implementations by companies like Shell. Recent industry reports from 2023 to 2025 highlight the integration of wellheads with carbon capture and storage (CCS) systems, where specialized CO2 injection wellhead equipment rated for corrosive supercritical fluids has been deployed in projects like the U.S. Gulf Coast hubs, with market growth projected at 14% CAGR through 2030 to support net-zero goals.Types
Surface Wellheads
Surface wellheads are the surface-mounted assemblies installed at the top of an oil or gas wellbore to provide structural support for casing strings and pressure containment during drilling, completion, and production operations.[19] They are primarily applied in onshore fields and fixed offshore platforms, where vertical well access is feasible and operations occur under standard atmospheric conditions, enabling reliable hydrocarbon extraction from reservoirs.[20] These systems interface with blowout preventers during drilling and support production equipment, ensuring safe pressure management in environments like shallow water or land-based sites.[21] Surface wellheads come in two main configurations: conventional stacked designs and unitized integrated assemblies. Conventional wellheads consist of modular components, such as multiple casing heads and spools, assembled in a layered stack to accommodate varying casing programs and provide flexibility for field adjustments.[19] In contrast, unitized wellheads, like the Unihead® series, integrate these elements into a single compact unit, reducing assembly time and overall profile while supporting through-bore installation for efficiency.[21] Both types are rated for working pressures from 2,000 psi to 20,000 psi and temperatures ranging from -75°F to 350°F or higher, with nominal sizes from 7-1/16 inches to 21-1/4 inches, depending on the well's requirements.[19] The advantages of surface wellheads include easier access for maintenance and interventions due to their above-ground placement, which simplifies tooling and reduces non-productive time compared to remote systems.[21] They also offer lower capital expenditure through standardized, interchangeable parts and shorter lead times, making them cost-effective for high-volume operations.[19] For instance, in the Permian Basin's onshore unconventional plays, surface wellheads have been widely deployed to support rapid drilling and production scaling, leveraging their robustness in handling high-pressure shale formations. These systems often integrate with Christmas trees for flow control, enhancing overall well integrity.[20]Subsea Wellheads
Subsea wellheads are pressure-containing components installed on the seabed to interface with drilling, completion, and testing operations for offshore deepwater oil and gas wells, serving as the primary anchor and suspension point for casing strings in environments where surface access is impractical.[22] These systems are essential for satellite or clustered well configurations, connecting to subsea Christmas trees and flowlines to enable hydrocarbon extraction from reservoirs in water depths typically exceeding 1,000 meters.[23] They often incorporate mudline suspension systems, which allow temporary well suspension during drilling phases before permanent installation of production equipment.[24] Configurations of subsea wellheads primarily include vertical and horizontal tree designs, each tailored to specific operational needs. Vertical trees position master valves above the tubing hanger for straightforward through-tubing access, commonly used in clustered developments for efficient intervention.[25] In contrast, horizontal trees, also known as spool trees, integrate valves horizontally below the tubing hanger, facilitating easier installation of electric submersible pumps and reducing stack-up height for deepwater applications.[26] Protective structures, such as foundation templates or protection covers, shield these assemblies from dropped objects, trawling, and seabed hazards, with templates often employed in multi-well setups.[22] These systems are rated for water depths up to 3,000 meters (10,000 feet) and pressures of 10,000 to 15,000 psi, accommodating extreme subsea conditions.[27][24] Key challenges in subsea wellhead deployment include corrosion from high-pressure, high-temperature environments and the need for remote operability in inaccessible locations. To address corrosion, specialized coatings and cathodic protection systems are applied, supplemented by chemical injection for long-term integrity.[22] Features like remotely operated vehicle (ROV)-accessible interfaces enable maintenance, valve actuation, and monitoring without diver intervention, enhancing safety and reliability.[22] Post-2010 examples illustrate these advancements: in the Gulf of Mexico, Hess Corporation's Tubular Bells project (2015) utilized horizontal subsea trees in approximately 1,310-meter water depths for tie-back production to a host platform.[28] More recently, Chevron's Anchor project (2024) employed vertical monobore subsea trees rated to 20,000 psi in 1,524-meter water depths, marking an industry first for high-pressure deepwater development.[29] In the North Sea, fields like those on the Norwegian Continental Shelf employed template-protected vertical trees in clustered configurations to withstand harsh currents and support extended tie-backs.[22]Components
Casing and Tubing Heads
The casing head serves as the lowermost structural component of the wellhead assembly, typically threaded or welded directly to the surface casing string to provide a secure foundation for subsequent wellhead elements.[30] It functions primarily to suspend and support the intermediate or production casing strings via dedicated hangers, while establishing an initial pressure-tight seal to isolate the casing annulus from external environments.[31] This component is engineered as a robust pressure vessel, often featuring a threaded or slip-on connection to the casing and upward-facing flanges for bolting to upper spools, ensuring axial load-bearing capacity for the weight of deeper casing sections.[32] Mounted directly above the casing head, the tubing head provides the primary suspension point for the production tubing string, utilizing tubing hangers to bear the tubing's weight and maintain alignment within the wellbore.[33] It incorporates a seal bore to prevent fluid migration in the annulus between the tubing and casing, along with side outlets that enable monitoring and access to the tubing-casing annulus for pressure gauging or fluid injection during well completion.[34] The tubing head's design typically includes flanged connections at both its base and top, facilitating integration with the overlying Christmas tree assembly for overall wellhead continuity.[35] Both casing and tubing heads incorporate packoff seals—such as O-rings or metal-to-metal seals—to achieve reliable pressure containment and prevent leaks across the annular spaces.[36] These components are commonly manufactured from high-strength forged carbon steel to withstand harsh subsurface conditions, with standard pressure ratings ranging from 5,000 psi to 10,000 psi for most conventional applications, though higher ratings up to 15,000 psi are available for high-pressure environments.[37] Flange sizes and bore diameters are standardized to match common casing and tubing dimensions, such as 7-inch or 9 5/8-inch casings, ensuring compatibility across drilling and production operations.[38]Christmas Tree
The Christmas tree is a multi-valve assembly installed atop the wellhead of a completed oil or gas well to regulate the flow of hydrocarbons, provide access for well interventions, and enable isolation of the wellbore during operations or emergencies.[39] It consists primarily of master valves for primary shutoff, wing valves for directing production flow, and swab valves for safe access during maintenance, all designed to withstand high pressures and ensure safe production control.[40] This structure adheres to industry standards such as API Specification 6A, which outlines requirements for its equipment to handle pressures up to 20,000 psi and temperatures from -50°F to 650°F.[41] Christmas trees are classified into two main types: vertical and horizontal, differing in tubing configuration and valve arrangement to suit various well environments, particularly onshore, offshore, or subsea applications. In a vertical Christmas tree, the production tubing runs through the center of the tree body, with valves stacked vertically above the tubing hanger, facilitating straightforward installation and common use in conventional land-based wells.[42] Conversely, a horizontal Christmas tree positions the production bores and valves laterally, with the tubing hanger typically located in the wellhead below, allowing easier retrieval of the tubing string for interventions without removing the entire tree—a key advantage in subsea settings where workover costs are high.[27] Both types connect to flowlines via wing outlets and incorporate chokes to regulate downstream pressure and prevent excessive flow rates.[43] Key features of Christmas trees include manual or actuated valves—often hydraulically or pneumatically operated for remote control—along with integrated pressure gauges for real-time monitoring of well conditions. The master valves, usually gate types, provide redundant shutoff capability to isolate the wellbore, while the swab valve permits wireline or tool entry without exposing the well to atmosphere. These elements ensure rapid emergency response, such as shutting in the well to contain pressure surges or leaks, thereby enhancing safety and operational reliability in production environments.[40]Accessories and Valves
Wellhead accessories encompass a range of auxiliary components attached to the wellhead assembly to facilitate monitoring, pressure management, and secondary control during drilling and production operations. These items enhance safety and operational efficiency by providing pathways for fluid circulation, pressure relief, and data acquisition without compromising the primary wellhead integrity. According to API Specification 6A, such accessories must meet stringent design, material, and testing requirements to ensure compatibility with wellhead pressures up to 20,000 psi.[41] Common accessories include kill lines, which are high-pressure pipes connecting side outlets on the blowout preventer stack or wellhead to the choke manifold, enabling controlled fluid injection to regain well control during kicks.[44] Annulus vents allow for the safe release of pressure buildup in the annular space between casing strings, preventing unintended migration of fluids or gases.[45] Gauge blocks, often integrated into the wellhead, house pressure and temperature sensors to monitor annular and tubing conditions in real-time; for instance, casing pressure gauges on the wellhead provide critical data for annular pressure readings during well control operations.[46] Valves integral to wellhead accessories include check valves, which prevent backflow of fluids into the formation or wellhead by allowing unidirectional flow, thereby maintaining pressure integrity and protecting downstream equipment.[47] Lubricator valves, typically used in wireline interventions, enable the safe insertion and retrieval of tools or plugs, such as back pressure valves, by providing a pressurized seal above the wellhead; these are often manual or hydraulic units compliant with API 6A standards for pressures up to 20,000 psi.[48] Specialized accessories feature flow tees, which incorporate integral outlets for directing flow during pumping operations, such as in rod blowout preventer setups, ensuring anti-whip stability under high loads.[49] Adapters for pump jacks or electrical submersible pumps (ESPs) provide sealed connections for mechanical or electrical interfaces, often with tapered bowls for reliable sealing at pressures from 3,000 to 5,000 psi, supporting configurations like gas lift or plunger lift.[50] Corrosion inhibitor injection ports, commonly 1/2-inch NPT fittings on ported adapters, allow precise delivery of chemicals to mitigate internal corrosion in the tubing and wellhead, as seen in toadstool-style designs rated for 5,000 to 10,000 psi.[51]Functions
During Drilling
During the drilling phase of oil and gas wells, the wellhead serves as a critical structural foundation that supports the blowout preventer (BOP) stack, enabling effective well control by providing a secure mounting base for the preventers to seal the wellbore in response to uncontrolled pressure events.[30] The casing head, a key component of the wellhead, is typically installed atop the surface casing string and features a flanged top connection that allows the BOP stack to be bolted or clamped securely, ensuring stability during rotary or directional drilling operations where high pressures and vibrations are common.[52] Another essential function of the wellhead during drilling is the suspension of casing strings as they are progressively set to stabilize the borehole and isolate formations. The casing head accommodates hangers that bear the weight of the casing, sealing annular spaces between strings while permitting continued drilling through the wellhead without interruption.[30] This suspension capability is vital for maintaining well integrity as deeper sections are drilled, with the wellhead designed to handle loads from multiple casing layers running from the surface to the target depth.[52] Additionally, the wellhead facilitates monitoring of drilling fluids and pressures through integrated outlets and side ports on the casing head, allowing for the return of drilling mud to the surface and real-time pressure checks to detect issues like kicks or losses. These outlets, often equipped with valves, enable the circulation and testing of mud returns during operations, supporting safe and efficient drilling progress.[30]During Production
During the production phase, the wellhead, particularly through its Christmas tree assembly, plays a critical role in regulating the flow of hydrocarbons from the reservoir to the surface. The Christmas tree's master valves, wing valves, and swab valves enable operators to open or shut in the well, while the choke valve—either fixed or adjustable—controls production rates by inducing a controlled pressure drop across the flow path, optimizing output and preventing issues like sand production or excessive erosion.[53] This configuration ensures safe and efficient fluid management, with the choke typically positioned on the production wing to fine-tune flow without disrupting overall well integrity.[40] The wellhead design facilitates access for well interventions, allowing maintenance and enhancement operations without requiring full disassembly of the production assembly. The swab valve at the top of the Christmas tree provides vertical access for tools such as wireline, slickline, or coiled tubing, enabling tasks like logging, perforating, or chemical treatments directly into the tubing string.[54] Similarly, the tubing hanger within the wellhead supports these interventions by securing the tubing while permitting the passage of electrical cables for equipment like electric submersible pumps, thus minimizing downtime and operational risks during production.[55] Annulus management is essential for maintaining well integrity, as the wellhead seals and monitors the annular space between the tubing and casing to detect and prevent leaks or pressure anomalies. Pressure barriers, such as annular seals and casing head valves, isolate the annulus, while monitoring ports allow for continuous pressure surveillance to avoid hazards like tubing collapse or uncontrolled fluid migration.[56] In cases of sustained casing pressure, these features enable safe bleed-off or injection operations, ensuring environmental compliance and long-term well stability throughout the production lifecycle.[57]Design and Specifications
Standards and Pressure Ratings
Wellhead equipment must conform to established industry standards to ensure safety, interchangeability, and performance in high-pressure oil and gas environments. The primary standard is API Specification 6A, 21st edition (November 2018, with addendums and errata up to Addendum 4 and Errata 6 as of November 2024), which outlines requirements for the design, materials, manufacturing, testing, and documentation of wellhead and tree equipment.[3][58] The 21st edition introduced minimum product specification level (PSL) requirements based on pressure rating and material class to ensure appropriate quality levels for different service conditions. This specification is adopted internationally through ISO 10423:2022, titled "Petroleum and natural gas industries — Drilling and production equipment — Wellhead and tree equipment," which provides equivalent guidelines with additional recommendations for global application.[59] For operations involving sour service—environments with hydrogen sulfide (H₂S) that can cause sulfide stress cracking—NACE MR0175/ISO 15156 (2021 edition) applies, specifying material selection and qualification to mitigate corrosion risks in wellhead components.[60] Pressure ratings in API Spec 6A classify wellhead equipment based on maximum rated working pressure (MRWP), ranging from 2,000 psi to 20,000 psi in standard classes: 2,000; 3,000; 5,000; 10,000; 15,000; and 20,000 psi.[3] These ratings define the equipment's capacity to contain internal pressures during drilling and production, with higher classes used in deepwater or high-pressure reservoirs. To verify integrity, equipment undergoes hydrostatic proof testing at 1.5 times the MRWP for performance levels PSL 1 through 4, with variations in hold times and additional tests depending on the PSL, ensuring a safety margin against operational stresses.[61] Temperature classes under API Spec 6A range from K to X (and Y for extreme cases), accommodating environmental variations from arctic to high-temperature conditions while maintaining structural integrity during thermal cycling. Class K covers -60°C to 82°C (-76°F to 180°F), L from -46°C to 82°C (-51°F to 180°F), and progressing to X at -18°C to 177°C (0°F to 350°F), with classes like N, P, R, S, T, U, and V filling intermediate ranges such as -46°C to 60°C for N.[2] These classifications ensure seals, elastomers, and metals perform without degradation, often requiring specialized low-temperature or high-temperature variants. Materials compliant with these standards, such as low-alloy steels, are selected to match the temperature and pressure demands.[62]Materials and Manufacturing
Wellhead components are primarily constructed from low-alloy steels, such as AISI 4130, which offers a yield strength of approximately 80,000 psi, providing the necessary strength and toughness for high-pressure applications.[63][64] In corrosive environments, such as those involving hydrogen sulfide or carbon dioxide, stainless steels like AISI 410 or 13Cr alloys are selected for their enhanced resistance to pitting, stress corrosion cracking, and sulfide stress cracking.[65][66] Non-metallic materials, including elastomeric seals made from compounds like nitrile or HNBR, are used for sealing elements to ensure fluid-tight integrity without compromising the metallic structure's load-bearing capacity.[67][68] Manufacturing begins with forging processes for critical components like casing heads and tubing heads, where billets of low-alloy steel are heated and shaped under high pressure to achieve dense, defect-free structures with superior mechanical properties.[69] Flanges and other precision parts undergo CNC machining to ensure accurate dimensions and surface finishes that meet tight tolerances for assembly and sealing.[70] Heat treatment follows, typically involving quenching and tempering to enhance hardness, tensile strength, and ductility while relieving internal stresses induced during forging and machining.[71][72] Quality assurance in wellhead fabrication adheres to API Spec 6A requirements, incorporating non-destructive testing methods such as ultrasonic testing to detect internal flaws and radiographic testing to identify surface and subsurface defects in welds and castings.[73][72] Additional inspections, including magnetic particle and liquid penetrant testing, ensure material integrity throughout the production process, with all components certified to verify compliance with pressure containment standards.[74][75]Installation and Operation
Installation Procedures
The installation of a wellhead begins after the surface casing has been run, cemented, and tested, involving the sequential assembly of components such as the casing head, hangers, seals, tubing head, and Christmas tree to ensure pressure integrity and structural support. This process adheres to industry standards like API Specification 6A, which outlines requirements for equipment design and qualification but guides installation through associated running and testing protocols.[3][19] The typical sequence for wellhead assembly proceeds as follows:- The casing head is welded or threaded to the top of the surface casing after cutting it to the required height, providing the base for subsequent components and supporting the blowout preventer (BOP) stack during further drilling.[76]
- Casing hangers and seals (such as packoffs) are installed to suspend intermediate or production casing strings, sealing annular spaces; this is often done through or under the BOP using running tools.[77]
- The tubing head (or spool) is stacked atop the casing head or spool, accepting the tubing hanger to support the production tubing string.[19]
- The Christmas tree is then installed on the tubing head, with flanges torqued to specified values using calibrated tools to secure the assembly.[77]