Measuring the flow rate and pressure drawdown in a producing well while the reservoir is in steady state provides what information?

Unlock all questions

This demo includes only 20 questions. Upgrade to access hundreds of questions, flashcards, exam simulations, and disable ads.

Full question bankExam simulationsFlashcards
From $9.99Unlock all

Study for the PetroBowl Test. Enhance your knowledge with flashcards and multiple choice questions, each question comes with hints and thorough explanations. Prepare thoroughly for your exam!

Multiple Choice

Measuring the flow rate and pressure drawdown in a producing well while the reservoir is in steady state provides what information?

Explanation:
Measuring the flow rate and pressure drawdown around a producing well in steady state reveals how readily fluids move through the rock and any extra resistance near the wellbore. In steady, radial flow, the rate at which fluid enters the well depends on the formation’s ability to transmit fluids (permeability), the thickness of the reservoir, the fluid’s viscosity, and a near-wellbore skin factor that represents damage or stimulation effects. Using the observed flow rate and pressure difference between the reservoir and the well, you can solve for the effective permeability and the skin factor (often written into the radial-flow equation as a logarithmic term plus the skin). This is why the information obtained is permeability or skin. Porosity is about how much fluid the rock can store and is not directly determined from a steady-state drawdown test. Reservoir pressure generally comes from transient pressure data such as buildup tests or shut-in measurements, not from a simple steady-state drawdown. Gas saturation requires additional phase behavior and data beyond this steady-state flow measurement.

Measuring the flow rate and pressure drawdown around a producing well in steady state reveals how readily fluids move through the rock and any extra resistance near the wellbore. In steady, radial flow, the rate at which fluid enters the well depends on the formation’s ability to transmit fluids (permeability), the thickness of the reservoir, the fluid’s viscosity, and a near-wellbore skin factor that represents damage or stimulation effects. Using the observed flow rate and pressure difference between the reservoir and the well, you can solve for the effective permeability and the skin factor (often written into the radial-flow equation as a logarithmic term plus the skin). This is why the information obtained is permeability or skin.

Porosity is about how much fluid the rock can store and is not directly determined from a steady-state drawdown test. Reservoir pressure generally comes from transient pressure data such as buildup tests or shut-in measurements, not from a simple steady-state drawdown. Gas saturation requires additional phase behavior and data beyond this steady-state flow measurement.

More Multiple Choice Questions
Subscribe

Get the latest from Examzify

You can unsubscribe at any time. Read our privacy policy