Recommended
More Related Content
What's hot
What's hot (20)
Similar to Pulsed neutron carbon oxygen logging
Similar to Pulsed neutron carbon oxygen logging (20)
Recently uploaded
Recently uploaded (20)
Pulsed neutron carbon oxygen logging
- 1. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 1 PULSED NEUTRON C/O LOGGING ABDUL BASITH C M TECH PE
- 2. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 2 PULSED NEUTRON LOGGING • Gamma ray spectrometry measures gamma rays (counts) in time and gamma ray energies. Some elements emit gamma rays naturally; others can be bombarded with neutrons to induce gamma ray emissions. • Each element produces characteristic gamma rays of specific energies. Moreover, the number of characteristic gamma rays produced is proportional to the abundance of the element. • Naturally occurring and induced gamma rays may be counted and sorted according to energy. • This produces a gamma ray spectrum that can be processed, or decoded, to identify the elements and their concentrations. 2
- 3. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 3 3
- 4. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 4 4
- 5. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 5 5
- 6. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 6 6
- 7. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 7 7 • RST A is 4 times faster than GST. • RST B, is the only tool that can log in flowing well, Speed is same as GST. • In RST B , 2 detectors are set in an offset to axis, its helps them to increase the sensitivity of the tool. • Near detector-Borehole sensitivity. • Far detector – Formation sensitivity.
- 8. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 8 Role of RST Tool • Reservoir management. • Saturation measurement over time to understand depletion. • Water influx and Injection water breakthrough. Why RST • Can use well with tubing. • The tool is very slim. • It can be used under operating conditions. • It can work in more saline conditions. • We use the resistivity tool in the newly drilled well to understand saturation, When we use GST(gamma ray spectroscopy) or RST . 8
- 9. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 9 • When salinity of formation is less than 35000 ppm, we can use C/O. • C/O logging helps to understand relative concentration of carbon and oxygen by the gamma ray emitted by inelastic neutron scattering. • A high C/O ratio indicates oil-bearing formation, Low C/O ratio indicates water bearing formation or gas. 9
- 10. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 10 Mode of operation of c/o(inelastic capture mode) • Gate A-In elastic spectra during the burst. • B,C records capture spectra after burst. • Net elastic spectrum= Gate B- Gate A • Interpretation- by comparing data base. 10
- 11. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 11 11
- 12. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 12 • Middle east well • Both near and far detectors shows a sharp increase in at 848ft –An oil water interface in bore hole. • The bore hole oil holdup during flowing indicates that most of the oil produced from 728-750 ft. • Water saturation curve separates 770-850ft indicates oil from well bore invaded formation during shut in • When well started flowing formation water flushed out the oil from formation 12
- 13. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 13 Prudhoe bay • Reducing water cut. The left track shows the gamma ray and borehole oil holdup logs measured with the well producing, The borehole oil holdup curve shows no oil production below 1170 ft. • The right track is an ELAN Elemental Log Analysis output based on openhole and RST fluid data. It indicates oil depletion below 1170 ft. After the lower perforated interval was plugged, production increased from 220 BOPD oil with 94% water cut to 300 BOPD oil with negligible water cut. 13
- 14. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 14 14 • One potential bypassed zone, A, was identified from X280 to X291 ft. A second zone B, based on he open hole logs and a C/0 log from another service company, was proposed from X220 to X231ft. The RST log shows Zone B to contain more gas and water than Zone A. • After assessing the open hole logs and the three C/0 logs, ARCO decided to perforate Zone B. The initial production was 1000 BOPD with a 75% water cut. Production declined to 200 BOPD with more than 95% water cut in a matter of weeks. • The decline prompted ARCO to perforate Zone A, commingling production from earlier perforations. Production increased to an average of 600 BOPD and the water cut decreased to 90%. • Subsequent production logs confirm that Zone A is producing oil and gas and Zone B is producing all of the water with some oil.
- 15. School of Engineering © 2017 University of Petroleum & Energy Studies, Dehradun 15 Q & A