已发表: 01/08/2015
已发表: 01/08/2015
To increase production in a number of onshore vertical wells, an operator in China sought to perforate approximately 820 ft [250 m] of pay zone. Reservoir pressure exceeded 17,000 psi [117.2 MPa], and downhole temperature was greater than 350 degF [176.7 degC]. To prevent killing the wells after perforating, the operation required an overbalance of 800 psi [5.5 MPa], and the completion fluid was designed with a weight of 1.87 g/cm3.
Schlumberger designed a fit-for-purpose tubing-conveyed perforating (TCP) gun system that uses the latest developments in HPHT downhole tool design. The TCP job and string configuration provided a flexible, modular, and highly reliable perforating system that could ensure successful operations and improved production for the campaign.
A 2 7⁄8-in HPHT gun was loaded with PowerJet Omega 2906 HNS shaped charges, which were picked based upon the operation's downhole specifications. The HPHT hydraulic-delay firing (HDF) head was used as the primary firing system for the operation. Specially designed for HPHT operations, the HDF head incorporates Chemraz® seals with backup rings and uses an HPHTrated sealed percussion detonator, providing reliability and efficiency in extreme conditions.
Using PURE clean perforations system software, Schlumberger engineers predicted a high dynamic underbalance (DUB) because of the reservoir's naturally high pressure and the hydrostatic pressure of the wellbore fluid. The high DUB predicted with SPAN PURE was later verified with high-speed pressure data recorded in the actual job.
SPAN Rock stressed-rock perforating analysis considered the perforation tunnels' debris volumes while predicting shaped-charge and estimated the wells' productivity index. Downhole shock was also carefully considered to ensure minimal damage to downhole tools and equipment. Further analysis helped the operator decide to perform a shoot-and-pull operation without a retrievable packer.
To date, the operator has run 12 HPHT perforating jobs without any lost time or service-quality issues, confirming the TCP confirmation's ability to reliably and consistently perform under HPHT conditions. Final production rates increased beyond what the operator initially anticipated, also confirming the performance of PowerJet Omega charges under severe downhole conditions.
Challenge: Increase production from 12 development wells in hostile HPHT reservoir while ensuring timely, efficient, and safe operations
Solution: Deploy PowerJet Omega deep-penetrating perforating shaped charges in a hydraulic-delay firing head and as modeled using SPAN Rock stressed-rock perforating analysis, which validated production estimates and calculated the level of downhole shock inherent to wells with high hydrostatic pressure to further mitigate postperforation risks
Results: Successfully perforated all 12 HPHT wells—with total reservoir gas production exceeding initial estimate—while remaining in timeline with no lost time or service-quality incidents
