Nonisothermal Transient Flow in Natural Gas Pipeline

M. Abbaspour; K. S. Chapman

Source: Journal of Applied Mechanics:;2008:;volume( 075 ):;issue: 003::page 31018

Author:

M. Abbaspour

K. S. Chapman

DOI: 10.1115/1.2840046

Publisher: The American Society of Mechanical Engineers (ASME)

Abstract: The fully implicit finite-difference method is used to solve the continuity, momentum, and energy equations for flow within a gas pipeline. This methodology (1) incorporates the convective inertia term in the conservation of momentum equation, (2) treats the compressibility factor as a function of temperature and pressure, and (3) considers the friction factor as a function of the Reynolds number and pipe roughness. The fully implicit method representation of the equations offers the advantage of guaranteed stability for a large time step, which is very useful for gas pipeline industry. The results show that the effect of treating the gas in a nonisothermal manner is extremely necessary for pipeline flow calculation accuracies, especially for rapid transient process. It also indicates that the convective inertia term plays an important role in the gas flow analysis and cannot be neglected from the calculation.

keyword(s): Inertia (Mechanics) , Momentum , Flow (Dynamics) , Pipes , Equations , Pipelines , Pressure , Temperature , Valves AND Finite difference methods ,

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Nonisothermal Transient Flow in Natural Gas Pipeline

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contributor author	M. Abbaspour
contributor author	K. S. Chapman
date accessioned	2017-05-09T00:26:42Z
date available	2017-05-09T00:26:42Z
date copyright	May, 2008
date issued	2008
identifier issn	0021-8936
identifier other	JAMCAV-26693#031018_1.pdf
identifier uri	http://yetl.yabesh.ir/yetl/handle/yetl/137310
description abstract	The fully implicit finite-difference method is used to solve the continuity, momentum, and energy equations for flow within a gas pipeline. This methodology (1) incorporates the convective inertia term in the conservation of momentum equation, (2) treats the compressibility factor as a function of temperature and pressure, and (3) considers the friction factor as a function of the Reynolds number and pipe roughness. The fully implicit method representation of the equations offers the advantage of guaranteed stability for a large time step, which is very useful for gas pipeline industry. The results show that the effect of treating the gas in a nonisothermal manner is extremely necessary for pipeline flow calculation accuracies, especially for rapid transient process. It also indicates that the convective inertia term plays an important role in the gas flow analysis and cannot be neglected from the calculation.
publisher	The American Society of Mechanical Engineers (ASME)
title	Nonisothermal Transient Flow in Natural Gas Pipeline
type	Journal Paper
journal volume	75
journal issue	3
journal title	Journal of Applied Mechanics
identifier doi	10.1115/1.2840046
journal fristpage	31018
identifier eissn	1528-9036
keywords	Inertia (Mechanics)
keywords	Momentum
keywords	Flow (Dynamics)
keywords	Pipes
keywords	Equations
keywords	Pipelines
keywords	Pressure
keywords	Temperature
keywords	Valves AND Finite difference methods
tree	Journal of Applied Mechanics:;2008:;volume( 075 ):;issue: 003
contenttype	Fulltext

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