On the performance of a cascade of turbine rotor tip section blading in nucleating steam Part 3: Theoretical treatment

Bakhtar, F.; Mahpeykar, Mohammad Reza

doi:10.1243/0954406971521773

Cited by 44 publications

(63 citation statements)

References 37 publications

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“…To validate the present in-house code, the experimental data reported by Bakhtar and Mahpeykar [7] have been used. The boundary conditions for the current numerical simulation have been chosen as identical to those in the experimental test, such as the in ow direction ( ) is 38 and the in ow stagnation pressure Figure 2.…”

Section: Validationmentioning

confidence: 99%

“…At the inlet section, the wetness fraction = 0; at the outlet section, the back-pressure P b = 42:7 kPa. Comparison of the pressure ratio on the suction and pressure surfaces between numerical and experimental results [7]; distribution of pressure ratio on the pressure and suction surfaces. The present computation is performed with grid size of 498 65.…”

Section: Validationmentioning

confidence: 99%

“…He studied the e ects of inlet superheating and outlet Mach number on the trailing edge shock structure. Bakhtar et al [7][8][9] carried out some experiments to study two-phase nucleating steam ow in a blade passage. Also, they performed a comparative study of the treatment of two-dimensional nucleating ows using Runge-Kutta and Denton's methods [10].…”

Section: Introductionmentioning

confidence: 99%

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Effects of non-equilibrium condensation on aerodynamics of the flow field in a steam turbine cascade

Esfe¹,

Kermani²,

Saffar‐Avval³

2017

Scientia Iranica

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Abstract. In the present paper, an in-house CFD code is developed using Roe scheme to simulate a condensing two-phase ow in blade to blade passage of a steam turbine. E ects of condensation on the ow eld of steam turbine rotor tip section are investigated for di erent outlet pressures. Firstly, comparison is performed between results of wet and dry cases. Then, e ects of outlet pressure variations on the ow eld are studied. Finally, e ects of condensation on di erent speci cations of the ow eld (total pressure loss coe cient, entropy generation, and deviation angle) are investigated. Also, the mechanism of ow deviation in the cascade ow eld is described. Condensation has a great in uence on the behavior of the ow eld based on the numerical results of this paper. It changes the out ow direction, and consequently the ow entering to the next blade deviates from its on-design condition; thus, additional losses are produced. For example, the value of deviation angle reaches 7:62 for wet case and exit Mach number M e = 1:45. Also, there are stagnation pressure loss and entropy generation due to non-equilibrium condensation that reduce the e ciency of the steam turbine.

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Section: Validationmentioning

confidence: 99%

Section: Validationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Effects of non-equilibrium condensation on aerodynamics of the flow field in a steam turbine cascade

Esfe¹,

Kermani²,

Saffar‐Avval³

2017

Scientia Iranica

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“…Implicit boundary conditions for the variations of variables are incorporated. The basic solver strategy employs a Gauss-Seidel relaxation procedure, sequentially applied to the systems of Equations [1] and [8]. In addition Newton sub-iterations are used at each global time step to increase stability and reduce linearization errors.…”

Section: Numerical Techniquementioning

confidence: 99%

A Unified CFD Based Approach to a Variety of Condensation Processes in a Viscous Turbulent Wet Steam Flow

Liberson¹,

Hesler²

2017

IJMNTA

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A family of quasi linear mathematical models is presented and calculations made for viscous turbulent wet steam flow with a variety of condensation phenomena. These models can be applied to the analysis of equilibrium condensation, homogeneous (spontaneous) condensation, heterogeneous condensation on extraneous particles, and condensation of charged dispersed phase moving in an electrostatic field. The unified model is represented by coupled systems of gas dynamic equations for viscous turbulent two-phase flow, kinetic and electro-kinetic equations tracing out combined processes of size and charge growth, and electromagnetic field equations described an electric field with an account of self-induced in-part by a moving electrical cluster. The numerical procedure is time marching, monotone, implicit, of second order accuracy by space and time coordinates, and exhibits high resolution shock capturing ability. Viscous flow field calculations made with this procedure reveal significant influence on condensation by the shear boundary layers and wakes. Distributions of cooling rate, droplet radius and parameters of the bulk flow are predicted. Verification of the codes against known experimental data is presented.

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“…The additional thermodynamics loss is caused by nonequilibrium condensing flow where the rapid-expansion pure steam will be in supercooled state, and the heat transfer process is anisothermal 2 . Many experimental and numerical investigations on nonequilibrium condensing flow have been conducted for years, where the classical condensation theory and the growth rate of water droplets have been validated and studied in Laval nozzles 3-5 and turbine cascades [6][7][8] . Moreover, experiments have been carried on in model or full-scale LP steam turbines…”

mentioning

confidence: 99%

Study on water extraction of hollow stationary blade under wet steam flow conditions

Wu¹,

Yang²,

2017

European Conference on Turbomachinery Fluid Dynamics and Hermodynamics

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In addition to mechanical losses, such as interphase drag loss, braking loss and pumping loss 1 , the presence of wetness in steam turbine can also lead to many additional losses in thermodynamics, profile, shock wave and blade end, etc. The additional thermodynamics loss is caused by nonequilibrium condensing flow where the rapid-expansion pure steam will be in supercooled state, and the heat transfer process is anisothermal 2 . Many experimental and numerical investigations on nonequilibrium condensing flow have been conducted for years, where the classical condensation theory and the growth rate of water droplets have been validated and studied in Laval nozzles 3-5 and turbine cascades [6][7][8] . Moreover, experiments have been carried on in model or full-scale LP steam turbines

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On the performance of a cascade of turbine rotor tip section blading in nucleating steam Part 3: Theoretical treatment

Cited by 44 publications

References 37 publications

Effects of non-equilibrium condensation on aerodynamics of the flow field in a steam turbine cascade

Effects of non-equilibrium condensation on aerodynamics of the flow field in a steam turbine cascade

A Unified CFD Based Approach to a Variety of Condensation Processes in a Viscous Turbulent Wet Steam Flow

Study on water extraction of hollow stationary blade under wet steam flow conditions

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