During most hydraulic fracturing operations, coiled tubing (CT) is used as a contingency option for well cleanup in the case of sand screenout. An alternative improvised solution is presented introducing a single-shot circulating valve into the frac string to help minimize additional resources related to CT procedures, thus reducing costs and enhancing operational performance. The tool is positioned above the retrievable frac packer to provide circulation capability to reverse out proppant sand without well intervention activities. Setup, operating procedures, concept evaluation, and performance of the single-shot circulating valve used to reverse proppant sand from the frac string are discussed. A single-shot circulating valve in the frac string provides additional liquid flow pass for recovering excess sand inside the frac string to the surface. Intensive laboratory testing was performed to evaluate tool function in worst-case scenarios of a highly deviated well with proppant sand packed above the circulating ports. During field operations, activated pressure tolerance was defined by incorporating rupture-disk reliability and temperature decrement effects during hydraulic fracturing to help ensure the operating pressure did not impair the fracturing operation or well integrity. Lastly, a cleanout procedure was meticulously planned to help prevent pipe sticking situations caused by sand fallout in the annulus. The single-shot circulating valve, typically deployed during drillstem testing (DST) operations, proved successful circulating out the proppant-sand column packed inside the tool during both laboratory testing and field operations. With precise hydrostatic pressure calculations, the burst pressure was reliable, meaning no premature activation occurred, and the rupture-disk burst within the designed surface pressure tolerance of ±400 psi. During reverse circulation, pumping pressure was maintained within an acceptable range (the maximum pumping rate across the circulating ports was 8 bbl/min) and no visual tool damage occurred. Deploying comprehensive engineering and operating procedures (e.g., defining the operating envelope to maintain a higher casing pressure than drillpipe pressure), the frac string and retrievable downhole frac packer were free of sand and successfully retrieved, even during a screenout scenario. Based on the success of the prolonged two-year fracturing operations, the proposed approach is appropriate for fracturing using a single-shot circulating valve as the primary contingency equipment during screenout, replacing CT intervention for this application. This alternative method resulted in improved safety and operational efficiency by eliminating on-rig CT operations when screenout pressure is trapped in the string in addition to significant cost savings attributed to eliminating the extra standby resources of a CT package. This innovative approach, which applies functions of a downhole well-testing tool during hydraulic fracturing, requires both circumspect engineering consideration to define a proper operating envelope and comprehensive operational procedures to help mitigate operational risks.
Depletion of shallow water oil reserves and growing energy demands have required exploration and development to extend into deepwater resources. Ever-changing environments in deepwater offshore locations present new challenges and require cutting-edge well-testing technology as well as advancements in cost optimization and operational safety. This paper introduces a successful system integration test (SIT) in preparation for the first deepwater well test in Vietnam on a dynamic positioning vessel in 1117 m water depth for a 3764 m deep well. It was the first time both a real-time acoustic controlled well-testing system and an electrohydraulic (EH) controlled subsea safety system were to be deployed. The acoustically controlled well-testing system eliminated the use of electric lines to obtain real-time accurate reservoir information and minimized the use of annulus pressure to operate downhole tools. The EH-controlled subsea safety system introduced superior safety measures for emergency situations requiring less rig time. The full system included the following: EH-controlled subsea safety system that uses the speed of EH actuation to perform emergency well shut-in and landing string secure disconnectAcoustically operated combined tester valve and circulating valveAcoustically triggered downhole samplersReal-time acquisition of reservoir pressure and temperature dataReal-time monitoring of downhole valve statusReal-time monitoring of seabed pressure and temperature data During the SIT, the EH-controlled subsea safety system demonstrated an emergency shut-in including disconnecting the landing string in 8 seconds. Additionally, the acoustically controlled well-testing system demonstrated real-time acquisition of downhole pressure and temperature data, operated and monitored the status of downhole valves, and acoustically activated bottomhole samplers. Although the tool string was not deployed offshore because of dry holes, the success of the SIT validated the ability of this combined system to provide high performance, high safety levels, and high quality standards. This combined system would not only allow the operator to make immediate and accurate decisions to achieve intended well-test objectives, but also would provide effective safety measures in emergency situations in less rig time. The successful SIT should encourage exploration expansion in deepwater environments in the near future when solutions are available for additional challenges facing operators.
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