Halliburton‘s integrated sensor diagnostics service combines far-field and near-wellbore sensors with proven engineering practices to solve your unconventional challenges.
Integrated Sensor Diagnostics Microsite
Visit our microsite at www.Halliburton.com/ISD.
Integrated Sensor Diagnostics Video
Well and fracture spacing are two subsurface challenges that have the largest impact on net present value in large-scale field development of unconventional wells. Pinnacle’s integrated sensor diagnostics suite overcomes these challenges and more using customized sensors and engineering strategies.
Integrated Sensor Diagnostics (ISD) Brochure
Every shale formation is different, to some degree. Optimizing the asset can be a complex undertaking that involves understanding and integrating a vast scope of data to form a unified picture of the asset, from early planning through exploration and development to long-term production.
Optimizing Well Spacing
Optimizing Well SpacingHalliburton has developed tools to improve confidence in selecting well spacing strategies and to quantify the impact of well spacing on your development goals.
Integrating near-wellbore and far-field downhole sensors, such as fiber optic monitoring and microseismic mapping, provides the ability to quantify the impact of completion and fracture design on well spacing. Through our integrated service diagnostics suite, the subsurface insight gained from these sensors is combined with fracture and reservoir modeling to define a roadmap for improving pad development for optimum well spacing.
Optimizing Fracture Spacing
Optimizing Fracture Spacing Halliburton’s integrated sensor diagnostics suite helps define the best approach for optimizing fracture and completion strategies to improve fracture spacing. Fiber optic analysis has proven to be the go-to sensor for identifying fracture fluid placement by stage. Through integrated sensor diagnostics, this analysis is combined with production decline per stage and is used to calibrate fracture and reservoir models in order to develop a focused effort on optimizing fracture spacing.
Optimizing Completion Design
The Halliburton integrated sensor diagnostic suite utilizes both near wellbore and far field sensing to determine completion effectiveness. The impact as a result of completion design can then be quantified using proven engineering practices such as fracture and reservoir modeling. Cluster efficiency, isolation effectiveness, and fluid placement all drive well productivity. Capturing and improving completion design effectiveness is a key benefit to the ISD approach.
For more specifications:
http://www.halliburton.com/en-US/ps/pinnacle/integrated-sensor-diagnostics-isd.page?node-id=i2soavhn
Integrated Sensor Diagnostics Microsite
Visit our microsite at www.Halliburton.com/ISD.
Integrated Sensor Diagnostics Video
Well and fracture spacing are two subsurface challenges that have the largest impact on net present value in large-scale field development of unconventional wells. Pinnacle’s integrated sensor diagnostics suite overcomes these challenges and more using customized sensors and engineering strategies.
Integrated Sensor Diagnostics (ISD) Brochure
Every shale formation is different, to some degree. Optimizing the asset can be a complex undertaking that involves understanding and integrating a vast scope of data to form a unified picture of the asset, from early planning through exploration and development to long-term production.
Optimizing Well Spacing
Optimizing Well SpacingHalliburton has developed tools to improve confidence in selecting well spacing strategies and to quantify the impact of well spacing on your development goals.
Integrating near-wellbore and far-field downhole sensors, such as fiber optic monitoring and microseismic mapping, provides the ability to quantify the impact of completion and fracture design on well spacing. Through our integrated service diagnostics suite, the subsurface insight gained from these sensors is combined with fracture and reservoir modeling to define a roadmap for improving pad development for optimum well spacing.
Optimizing Fracture Spacing
Optimizing Fracture Spacing Halliburton’s integrated sensor diagnostics suite helps define the best approach for optimizing fracture and completion strategies to improve fracture spacing. Fiber optic analysis has proven to be the go-to sensor for identifying fracture fluid placement by stage. Through integrated sensor diagnostics, this analysis is combined with production decline per stage and is used to calibrate fracture and reservoir models in order to develop a focused effort on optimizing fracture spacing.
Optimizing Completion Design
The Halliburton integrated sensor diagnostic suite utilizes both near wellbore and far field sensing to determine completion effectiveness. The impact as a result of completion design can then be quantified using proven engineering practices such as fracture and reservoir modeling. Cluster efficiency, isolation effectiveness, and fluid placement all drive well productivity. Capturing and improving completion design effectiveness is a key benefit to the ISD approach.
For more specifications:
http://www.halliburton.com/en-US/ps/pinnacle/integrated-sensor-diagnostics-isd.page?node-id=i2soavhn
