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19: Properties of Natural Gas and Condensates II

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    Module Goal: To highlight the important properties used to characterize natural gas and condensate systems.

    Module Objective: To present the most popular models for estimating properties of natural gas and condensate systems.

    • 19.1: Heat Capacities
      This page provides an overview of constant volume (\(C_v\)) and constant pressure (\(C_p\)) heat capacities, defining their roles in thermodynamics related to internal energy and enthalpy changes. It introduces the ratio \(k = C_p/C_v\) and emphasizes that these capacities are not equal. Additionally, it discusses methods for calculating heat capacities, particularly in mixtures, and explores the thermodynamic relationship between \(C_p\) and \(C_v\).
    • 19.2: Joule-Thomson Coefficient
      Whether or not a gas cools upon expansion or compression — that is, when subjected to pressure changes — depends on the value of its Joule–Thomson coefficient. This is not only important for natural gas pipeline flow, but also for the recovery of condensate from wet natural gases.
    • 19.3: Viscosity
      Whether you are interested in flow in pipes or in porous media, one of the most important transport properties is viscosity. Fluid viscosity is a measure of its internal resistance to flow. The most commonly used unit of viscosity is the centi-poise.
    • 19.4: Action Item
      This page underscores the significance of gas metering in the natural gas industry, focusing on the necessity of accurate gas measurements. It encourages readers to evaluate which meter properties—volume, pressure, temperature, or flow rate—are most crucial for enhancing performance in various gas metering scenarios.

    This page titled 19: Properties of Natural Gas and Condensates II is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Michael Adewumi (John A. Dutton: e-Education Institute) via source content that was edited to the style and standards of the LibreTexts platform.