Quasi 3D Multi-stage Turbomachinery Pre-optimizer

Burdyshaw, Chad Eric

04 August 2001

A pre-optimizer has been developed which modifies existing turbomachinery blades to create new geometries with improved selected aerodynamic coefficients calculated using a linear panel method. These blade rows can then be further refined using a Navier-Stokes method for evaluation. This pre-optimizer was developed in hopes of reducing the overall CPU time required for optimization when using only Navier-Stokes evaluations. The primary method chosen to effect this optimization is a parallel evolutionary algorithm. Variations of this method have been analyzed and compared for convergence and degree of improvement. Test cases involved both single and multiple row turbomachinery. For each case, both single and multiple criteria fitness evaluations were used.

optimization

turbomachinery

evolutionary algorithm

genetic algorithm

hybrid algorithm

aerodynamics

parallelization

Development of a Methodology to Estimate Aero-Performance and Aero-Operability Limits of a Multistage Axial Flow Compressor for Use in Preliminary Design

Kulkarni, Sameer

January 1900

No description available.

Aerospace Engineering

Mechanical Engineering

axial compressors

computational fluid dynamics

turbomachinery

A General Multidisciplinary Turbomachinery Design Optimization system Applied to a Transonic Fan

Nemnem, Ahmed M. F.

January 2014

No description available.

Aerospace Materials

Multidisciplinary

Optimization

Turbomachinery

Aero-mechanical

Design

AMBIENT AND HIGH TEMPERATURE EROSION INVESTIGATION OF MATERIALS AND COATINGS USED IN TURBOMACHINERY

DRENSKY, GEORGE KERILOV

11 June 2002

No description available.

erosion

coatings

turbomachinery

erosion tunnel facility

Titanium Nitride protective coats

Investigation of Particle Deposition in Internal Cooling Cavities of a Nozzle Guide Vane

Casaday, Brian Patrick

January 2013

No description available.

Aerospace Engineering

particle deposition

turbomachinery

internal cooling, engine fouling

Unsteady Turbomachinery Flow Simulation With Unstructured Grids Using ANSYS Fluent

Longo, Joel Joseph

January 2013

No description available.

Aerospace Engineering

fluent

turbomachinery

turbine

unstructured grid

TURBO

An Investigation of the Performance of Compliant Finger Seals for use in Gas Turbine Engines using Navier-Stokes and Reynolds Equation Based Numerical Models and Experimental Evaluation

Kline, Sara E.

January 2016

No description available.

Mechanical Engineering

gas turbines

finger seals

turbomachinery

aircraft engine seals

Development of the second-generation IMTS (Intelligent Monitoring and Trending System) and WOT (Wizard of Tech) expert system for rotating machinery

Pawtowski, E. C.

02 October 2008

IMTS and WOT form a PC-based hardware and software system designed to continuously monitor large numbers of rotating machinery, evaluate each machine's condition through a series of user-definable standards, and alert operators to potential problems. This system requires a rack of data acquisition equipment located near the machines being monitored and a PC that can be located remotely. This system has been tested under actual plant conditions at the Virginia Tech Power Plant. The software operates under Windows 3.1, and allows data to be acquired and evaluated simultaneously. This thesis discusses the development of this system over earlier versions and the installation procedures and first runs at the Power Plant. It discusses in detail the operation of some of the main programs that comprise the Intelligent Trending and Expert System. / Master of Science

turbomachinery

data acquisition

data trending

LD5655.V855 1996.P398

Effects of Two-Phase Flow in a Multistage Centrifugal Compressor

Halbe, Chaitanya Vishwajit

19 October 2016

The performance of a vapor compression system is known to be affected by the ingestion of liquid droplets in the compressor. In these multiphase flows, the liquid and the vapor phase are tightly coupled. Therefore the interphase heat, mass and momentum transfer as well as droplet dynamics including droplet breakup and droplet-wall interactions play a vital role in governing these flows. Only thermodynamic analyses or two-dimensional mean-line calculations are not sufficient to gain an in-depth understanding of the complex multiphase flow field within the compressor. The objective of this research was to extend the current understanding of the operation of a multistage centrifugal compressor under two-phase flow conditions, by performing three-dimensional computational analysis. In this work, two-phase flow of a single constituent (refrigerant R134a) through a two-stage, in-line centrifugal compressor was analyzed using CFD. The CFD model accounted for real gas behavior of the vapor phase. Novel user defined routines were implemented to ensure accurate calculations of interphase heat, mass and momentum transfer terms and to model droplet impact on the compressor surfaces. An erosion model was developed and implemented to locate the erosion "hot spots" and to estimate the amount of material eroded. To understand the effects of increasing liquid carryover, the mass flow rate of the liquid phase was increased from 1% to 5% of the vapor mass flow rate. The influence of droplet size on the compressor performance was assessed by varying the droplet diameter at the inlet from 100 microns to 400 microns. The results of the two-phase flow simulations were compared with the simulation involving only the vapor phase. Liquid carryover altered the flow field within the compressor, and as a result, both impellers were observed to operate at off-design conditions. This effect was more pronounced for the second impeller. The overall effects of liquid carryover were detrimental to the compressor performance. The erosion calculations showed maximum erosion potential on the blade and shroud of the first impeller. The results from this investigation provided new and useful information that can be used to support improved design solutions. / Ph. D. / The performance of a compressor is known to be affected by the ingestion of liquid droplets, and thus, it is a research topic of interest for both academia as well as industry. This work extends the current understanding of the operation of a multistage centrifugal compressor under two-phase flow conditions, by employing high-fidelity computational fluid dynamics (CFD). In this research, the two-phase flow of refrigerant R134a through a two-stage, in-line centrifugal compressor was analyzed. The CFD model used in this research incorporated real gas behavior of the vapor phase, as well as the interphase heat, mass and momentum transfer processes. An erosion model was also developed and implemented to locate the erosion "hot spots" on the compressor surfaces, and to estimate the amount of material eroded. The effects of increasing the liquid carryover, as well as the influence of droplet size on the compressor performance were assessed. Liquid carryover altered the flow field within the compressor. As a result, the compressor operated at off-design conditions. The overall effects of liquid carryover were detrimental to the compressor performance. The erosion calculations showed maximum erosion potential on the blade and shroud of the first impeller. The results from this investigation provided new and useful information that can be used to support improved design solutions.

Turbomachinery

Compressor

Centrifugal

Multistage

Multiphase

Computational fluid dynamics

Performance

Aerodynamic and mechanical performance of a high-pressure turbine stage in a transient wind tunnel

Sheard, A. G.

January 1989

Unsteady three-dimensional flow phenomena have major effects on the aerodynamic performance of, and heat transfer to, gas-turbine blading. Investigation of the mechanisms associated with these phenomena requires an experimental facility that is capable of simulating a gas turbine, but at lower levels of temperature and pressure to allow conventional measurement techniques. This thesis reports on the design, development and commissioning of a new experimental facility that models these unsteady three-dimensional flow phenomena. The new facility, which consists of a 62%-size, high-pressure gas-turbine stage mounted in a transient wind tunnel, simulates the turbine design point of a full-stage turbine. The thesis describes the aerodynamic and mechanical design of the new facility, a rigorous stress analysis of the facility’s rotating system and the three-stage commissioning of the facility. The thesis concludes with an assessment of the turbine stage performance.

621.4352