The Horizontal Automated Wing Drilling Equipment (HAWDE) machine is an enabling technology for automated drilling of large aircraft parts. HAWDE is a five axis drilling machine that operates over the upper and lower surfaces of eight wings, each more than 40 meters long and four stories tall. The machine accesses the entire A380 wing using a combination of elevators and a machine transporter that carries the machine from surface to surface. HAWDE drills holes in spars, butt splices, and rib feet in the wing box final assembly jigs for A380.
Liner hangers and liner-top packers are commonly used in the oil field in various liner applications. Unfortunately, in the traditional systems that employ "cone and slip" technology, the failure rate of the liner top packers as well as the failure of system installation has been great, impacting the ultimate cost and efficiency of the well completion. In conventional systems, mechanical equipment with multiple slips are run and set. The disadvantages of these systems include multiple leak paths, reduced radial clearance, and exposed hydraulic ports, all of which increase their potential for failures. Reasons for unsuccessful liner installations can be attributed to a number of conditions, such as:the liner cannot be run to depththe liner hanger/packer pre-setsthe setting tool failsthe setting ball cannot reach the setting tool. This paper will discuss an expandable liner system that was developed to address the shortcomings of the traditional systems. The expandable liner hanger provides a clean outer diameter to reduce preset risk and allow drilling or reaming the liner in with reduced risk of damage or hanging up. Hydraulically operated liner-hanger systems typically rely on a setting ball to plug the tubing to allow pressure activation of the liner hanger. Problems can arise if the ball is unable reach the seat due to debris or hole deviation. The new liner system combines expandable solid liner technology with an improved hydraulic setting tool that eliminates the setting ball as the primary setting method. The following discussion will include details concerning development of the design, operating procedures, and benefits of the expandable liner hanger as well as how the versatility and adaptability of the system improves its reliability. Several case histories to verify the efficiency of the new system will be discussed. Introduction Liner hangers and liner-top packers are commonly used in oilfield completions where liners are run in the well. The conventional liner-hanger system employs "cone and slip" technology. Failure of the liner-top packers as well as failure of system installation significantly impacts the ultimate cost and efficiency of the well completion.1 Many of these liner hangers are run on hydraulically operated setting tools. The typical operation requires dropping a setting ball and waiting for the ball to seat in the setting tool so that pressure can be applied. If the liner top fails, time-consuming remedial operations increase costs for equipment and services, and operational efficiency is further impacted by the delay in well completion and revenue generation. An expandable liner-hanger system that addresses some of the problems with the conventional liner-hanger systems has been developed. The system incorporates an expandable liner-hanger body with an integral packer, a tieback polishedbore receptacle, a setting-sleeve assembly, a crossover sub to connect the assembly to the liner, and a setting tool developed to eliminate the setting ball as the primary setting method. Elastomeric elements are bonded onto the hanger body. As the hanger body is expanded, the elastomeric elements are compressed in the annular space. This virtually eliminates the liner top/casing annulus and delivers liner-top pressure integrity as well as bi-directional axial load capacity. The hydraulic setting tool uses a flapper-type closure mechanism to plug the tubing and to allow pressure to be applied to the setting tool to expand the hanger body. As the hanger body is expanded, the elastomeric elements are compressed into the annular space. This virtually eliminates the liner top/casing an
As wells increase in complexity, new challenges must be addressed in order to produce hydrocarbons in the best way possible. Some wells should be cemented in two stages because of the risks of fracturing the lower zone. Running a long casing string increases the equivalent circulating density (ECD) and also increases the chance of damaging that zone, so running a liner is the best option. Cementing liners in two stages has been performed with conventional liner hangers for some time because of their capability to run an inner string and their capacity for manipulation after the hanger is set. Now, new technologies allow those treatments to be completed with expandable liner hangers (ELH). The ELH provides a premium liner top seal (Williford, Smith, 2007) and excellent tensile capabilities. They also help to improve the cement bond by allowing the movement of the string while the cement is being pumped in place. ELHs have proven to be a reliable tool (Jimenez, C., et al., 2009), and every year their popularity increases tremendously. This paper discusses the first true two-stage cement job with an ELH performed in Kazakhstan. The use of the ELH helped the operator reach total depth (TD), cement the two zones without issues, and create a premium barrier at the top of the liner.
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