PRODUCTION OPTIMIZATION STRATEGY OF CERAMIC SCREENED WELL
One of the major issues dealing with high deliverability gas wells is the sand production from unconsolidated formation. Related to this issue, in order to develop shallow gas reservoirs in the Mahakam Delta, it needs a cost-effective completion solution to produce gas from multi-layered and the u...
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| Format: | Final Project |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/39879 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | One of the major issues dealing with high deliverability gas wells is the sand production from unconsolidated
formation. Related to this issue, in order to develop shallow gas reservoirs in the Mahakam Delta, it needs a
cost-effective completion solution to produce gas from multi-layered and the unconsolidated sands. Multi-Zone
Single Trip Gravel Packs (MZ-STGP) have been installed in the majority of gas wells, but they have technical
restrictions in terms of zone spacing, the number of zones, well deviations and pumping gravel cost prompted
the need to develop advanced completion technique.
Lean Six Sigma methodology helps to identify the defects of previous sand control prevention and to choose the
best feasible solution. Through Lean Six Sigma deep investigation, the cased hole ceramic sand screen has been
chosen as the best method in facing the sand problems. For simpler and quicker installation on the Tunu gas
wells, the free hanging mode is selected. The ceramic sand screen is hung at the SSD and the SSD also has been
used for gas production route. Two zones are completed using a ceramic screen, with the specification of 12
gauge slot opening (300 microns) and 10 ft screen length.
By utilizing the ceramic screen, it simplifies the completion design due to removing gravel pack stimulation as
an attempt to reduce the total well cost. In technical terms, no sand is observed on the surface during the
production phase from both zones. From an analysis, skin value are about 13 and 71 as a result of applying the
ceramic screens for zone 1 and 2, respectively. A real gas pseudo-pressure approachment is used to calculate the
skin factor. By adjusting the bottom hole pressure, the skin factor is reduced while maintaining high gas
production rate. The production optimization strategy is conducted by using the rule of thumb 40-70% of AOFP
and validated using the gas well production optimization by Dawud et al method.
For zone 1, the optimum production is in a range of 1.3 – 2.55 MMSCFD by adjusting Pwf 800 – 1,150 psia
with resulting skin value of 10 – 13. For zone 2, the optimum production can be achieved in a range of 0.96 –
1.68 MMSCFD by adjusting Pwf 1,150 – 1,600 psia with resulting skin value of 52 – 67. |
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