On the Modeling and Control of Coupled Multi-Loop Thermosyphons

Yan Wu

On the Modeling and Control of Coupled Multi-Loop Thermosyphons

Mathematical Sciences

Research output: Contribution to book or proceeding › Chapter

Abstract

This paper presents a one-dimensional model for natural convection in coupled multi-loop thermosyphons. The physical model is governed by a system of Navier-Stokes equations, which are reduced to coupled systems of Lorenz equations via the Galerkin method. The simulations reveal different stages of flow of the Rayleigh number increases, e.g., from heat conduction, steady convective flow, to chaotic time-dependent flow. The control objective is either stabilized the flow in each loop at one its equilibrium points or track a reference signal in the chaotic range of the Rayleigh number. The controller design is based on proportional and integral (PI) control principles. The design can be easily implemented because the feedback state is measurable.

Original language	American English
Title of host publication	Applications of Mathematics and Computer Engineering: Proceedings of the American Conference on Applied Mathematics
State	Published - Jan 29 2011

Disciplines

Mathematics

Keywords

Chaos
Lorenze equations
Navier-Stokes Equations
Perturbation
Proportional-integral control
Termosyphon
jacobian

Cite this

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title = "On the Modeling and Control of Coupled Multi-Loop Thermosyphons",

abstract = " This paper presents a one-dimensional model for natural convection in coupled multi-loop thermosyphons. The physical model is governed by a system of Navier-Stokes equations, which are reduced to coupled systems of Lorenz equations via the Galerkin method. The simulations reveal different stages of flow of the Rayleigh number increases, e.g., from heat conduction, steady convective flow, to chaotic time-dependent flow. The control objective is either stabilized the flow in each loop at one its equilibrium points or track a reference signal in the chaotic range of the Rayleigh number. The controller design is based on proportional and integral (PI) control principles. The design can be easily implemented because the feedback state is measurable.",

keywords = "Chaos, Lorenze equations, Navier-Stokes Equations, Perturbation, Proportional-integral control, Termosyphon, jacobian",

author = "Yan Wu",

year = "2011",

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language = "American English",

booktitle = "Applications of Mathematics and Computer Engineering: Proceedings of the American Conference on Applied Mathematics",

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T1 - On the Modeling and Control of Coupled Multi-Loop Thermosyphons

AU - Wu, Yan

PY - 2011/1/29

Y1 - 2011/1/29

N2 - This paper presents a one-dimensional model for natural convection in coupled multi-loop thermosyphons. The physical model is governed by a system of Navier-Stokes equations, which are reduced to coupled systems of Lorenz equations via the Galerkin method. The simulations reveal different stages of flow of the Rayleigh number increases, e.g., from heat conduction, steady convective flow, to chaotic time-dependent flow. The control objective is either stabilized the flow in each loop at one its equilibrium points or track a reference signal in the chaotic range of the Rayleigh number. The controller design is based on proportional and integral (PI) control principles. The design can be easily implemented because the feedback state is measurable.

AB - This paper presents a one-dimensional model for natural convection in coupled multi-loop thermosyphons. The physical model is governed by a system of Navier-Stokes equations, which are reduced to coupled systems of Lorenz equations via the Galerkin method. The simulations reveal different stages of flow of the Rayleigh number increases, e.g., from heat conduction, steady convective flow, to chaotic time-dependent flow. The control objective is either stabilized the flow in each loop at one its equilibrium points or track a reference signal in the chaotic range of the Rayleigh number. The controller design is based on proportional and integral (PI) control principles. The design can be easily implemented because the feedback state is measurable.

KW - Chaos

KW - Lorenze equations

KW - Navier-Stokes Equations

KW - Perturbation

KW - Proportional-integral control

KW - Termosyphon

KW - jacobian

UR - http://www.wseas.us/e-library/conferences/2011/Mexico/CEMATH/CEMATH-17.pdf

M3 - Chapter

BT - Applications of Mathematics and Computer Engineering: Proceedings of the American Conference on Applied Mathematics

ER -

On the Modeling and Control of Coupled Multi-Loop Thermosyphons

Abstract

Disciplines

Keywords

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