Computation of Flow Between Two Disks Rotating at Different SpeedsSource: Journal of Turbomachinery:;2003:;volume( 125 ):;issue: 002::page 394DOI: 10.1115/1.1539515Publisher: The American Society of Mechanical Engineers (ASME)
Abstract: Disks rotating at different speeds are found in the internal cooling-air systems of most gas turbines. Defining Γ as the ratio of the rotational speed of the slower disk to that of the faster one then Γ=−1, 0 and +1 represents the three important cases of contra-rotating disks, rotor-stator systems and co-rotating disks, respectively. A finite-volume, axisymmetric, elliptic, multigrid solver, employing a low-Reynolds-number k-ε turbulence model, is used for the fluid-dynamics computations in these systems. The complete Γ region, −1≤Γ≤+1, is considered for rotational Reynolds numbers of up to Reϕ=1.25×106, and the effect of a radial outflow of cooling air is also included for nondimensional flow rates of up to Cw=9720. As Γ→−1, Stewartson-flow occurs with radial outflow in boundary layers on both disks and between which is a core of nonrotating fluid. For Γ≈0, Batchelor-flow occurs, with radial outflow in the boundary layer on the faster disk, inflow on the slower one, and between which is a core of rotating fluid. As Γ→+1, Ekman-layer flow dominates with nonentraining boundary layers on both disks and a rotating core between. Where available, measured velocity distributions are in good agreement with the computed values.
keyword(s): Flow (Dynamics) , Disks , Computation , Boundary layers AND Outflow ,
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| contributor author | Muhsin Kilic | |
| contributor author | J. Michael Owen | |
| date accessioned | 2017-05-09T00:11:44Z | |
| date available | 2017-05-09T00:11:44Z | |
| date copyright | April, 2003 | |
| date issued | 2003 | |
| identifier issn | 0889-504X | |
| identifier other | JOTUEI-28702#394_1.pdf | |
| identifier uri | http://yetl.yabesh.ir/yetl/handle/yetl/129284 | |
| description abstract | Disks rotating at different speeds are found in the internal cooling-air systems of most gas turbines. Defining Γ as the ratio of the rotational speed of the slower disk to that of the faster one then Γ=−1, 0 and +1 represents the three important cases of contra-rotating disks, rotor-stator systems and co-rotating disks, respectively. A finite-volume, axisymmetric, elliptic, multigrid solver, employing a low-Reynolds-number k-ε turbulence model, is used for the fluid-dynamics computations in these systems. The complete Γ region, −1≤Γ≤+1, is considered for rotational Reynolds numbers of up to Reϕ=1.25×106, and the effect of a radial outflow of cooling air is also included for nondimensional flow rates of up to Cw=9720. As Γ→−1, Stewartson-flow occurs with radial outflow in boundary layers on both disks and between which is a core of nonrotating fluid. For Γ≈0, Batchelor-flow occurs, with radial outflow in the boundary layer on the faster disk, inflow on the slower one, and between which is a core of rotating fluid. As Γ→+1, Ekman-layer flow dominates with nonentraining boundary layers on both disks and a rotating core between. Where available, measured velocity distributions are in good agreement with the computed values. | |
| publisher | The American Society of Mechanical Engineers (ASME) | |
| title | Computation of Flow Between Two Disks Rotating at Different Speeds | |
| type | Journal Paper | |
| journal volume | 125 | |
| journal issue | 2 | |
| journal title | Journal of Turbomachinery | |
| identifier doi | 10.1115/1.1539515 | |
| journal fristpage | 394 | |
| journal lastpage | 400 | |
| identifier eissn | 1528-8900 | |
| keywords | Flow (Dynamics) | |
| keywords | Disks | |
| keywords | Computation | |
| keywords | Boundary layers AND Outflow | |
| tree | Journal of Turbomachinery:;2003:;volume( 125 ):;issue: 002 | |
| contenttype | Fulltext |