/*--------------------------------*- C++ -*----------------------------------*\ | ========= | | | \\ / F ield | foam-extend: Open Source CFD | | \\ / O peration | Version: 4.0 | | \\ / A nd | Web: http://www.foam-extend.org | | \\/ M anipulation | | \*---------------------------------------------------------------------------*/ FoamFile { version 2.0; format ascii; class dictionary; object blockMeshDict; } // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // // General macros to create 2D/extruded-2D meshes changecom(//)changequote([,]) define(calc, [esyscmd(perl -e 'printf ($1)')]) //define(calc, [esyscmd(echo $1 | bc | tr -d \\n)]) define(VCOUNT, 0) define(vlabel, [[// ]Vertex $1 = VCOUNT define($1, VCOUNT)define([VCOUNT], incr(VCOUNT))]) define(pi, calc(3.14159265/20)) define(hex2D, hex ($1b $2b $3b $4b $1t $2t $3t $4t)) define(quad2D, ($1b $2b $2t $1t)) define(frontQuad, ($1t $2t $3t $4t)) define(backQuad, ($1b $4b $3b $2b)) // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // convertToMeters 1; // HUB AND SHROUD RADIUS // Hub radius (m) define(hr, 0.05) // Shroud radius (m) define(sr, 0.1) // GUIDE VANE REGION GEOMETRY AND MESH PROPERTIES // Guide vane inlet axial length (m) define(GVial, 0.1) // Guide vane axial length (m) define(GVbal, 0.1) // Guide vane outlet axial length (m) define(GVoal, 0.02) // Number of guide vanes per 360 degrees (integer!) define(GVnb, 5) // Number of cells in radial direction at guide vane define(GVrc, 10) // Number of cells in tangential direction between guide vanes define(GVtc, 10) // Number of cells in axial direction at guide vane inlet define(GViac, 10) // Number of cells in axial direction between guide vanes define(GVbac, 10) // Number of cells in axial direction at guide vane outlet define(GVoac, 2) // RUNNER REGION GEOMETRY AND MESH PROPERTIES // Runner inlet axial length (m) define(RUial, 0.02) // Runner axial length (m) define(RUal, 0.1) // Runner outlet axial length (m) define(RUoal, 0.02) // Number of runner blades per 360 degrees (integer!) define(RUnb, 5) // Number of cells in radial direction in runner define(RUrc, 10) // Number of cells in tangential direction between runner blades define(RUtc, 10) // Number of cells in axial direction at runner inlet define(RUiac, 2) // Number of cells in axial direction between runner blades define(RUbac, 10) // Number of cells in axial direction at runner outlet define(RUoac, 2) // DRAFT TUBE REGION GEOMETRY AND MESH PROPERTIES // "Draft tube" axial length (m) define(DTal, 0.07) // Number of sections per 360 degrees (integer!) define(DTns, 5) // Number of cells in radial direction in "draft tube" define(DTrc, 10) // Number of cells in tangential direction in "draft tube" define(DTtc, 10) // Number of cells in axial direction in "draft tube" define(DTac, 7) // * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * // // TANGENTIAL PITCHES (RADIANS) // Guide vane region define(GVp, calc(2*pi/GVnb)) // Runner region define(RUp, calc(2*pi/RUnb)) // Draft tube region define(DTp, calc(2*pi/DTns)) // TANGENTIAL SHIFTS BETWEEN AXIAL LEVELS (BOTTOM-UP) // Tangential shift from level DT0 to DT1 define(DTts01, calc(5*DTp)) // Runner region // Tangential shift from level RU0 to RU1 define(RUts01, calc(-1/10*RUp)) // Tangential shift from level RU1 to RU2 define(RUts12, calc(-4/5*RUp)) // Tangential shift from level RU2 to RU3 define(RUts23, calc(-1/10*RUp)) // Guide vane region // Tangential shift from level GV0 to GV1 define(GVts01, calc(1/10*GVp)) // Tangential shift from level GV1 to GV2 define(GVts12, calc(1/2*GVp)) // Tangential shift from level GV2 to GV3 define(GVts23, calc(0*GVp)) // AXIAL/TANGENTIAL BASE POINTS FOR EACH LEVEL (BOTTOM-UP): // (CENTER OF RUNNER SET TO THETA=0, Z=0) // Draft tube: define(DTa0, calc(-RUoal-0.5*RUal-DTal)) //Center runner define(DTt0, calc(-0.5*RUp-(0.5*RUts12)-(0*DTts01))) // Straight draft tube! define(DTt1, calc(-0.5*RUp-(0.5*RUts12))) //Center runner // Runner: define(RUa0, calc(-RUoal-0.5*RUal)) //Center runner define(RUt0, calc(-0.5*RUp-(0.5*RUts12))) //Center runner define(RUt1, calc(RUt0+RUts01)) define(RUt2, calc(RUt1+RUts12)) define(RUt3, calc(RUt2+RUts23)) // Guide vane: define(GVa0, calc(0.5*RUal+RUial)) //Center runner define(GVt0, calc(-0.5*RUp-(0.5*RUts12)+RUts01+RUts12+RUts23)) //Center runner define(GVt1, calc(GVt0+GVts01)) define(GVt2, calc(GVt1+GVts12)) define(GVt3, calc(GVt2+GVts23)) vertices //(radial [m], tangential [radians], axial [m]) ( //Guide vane hub: (hr GVt0 GVa0) vlabel(GV0lb) (hr calc(GVt0+GVp) GVa0) vlabel(GV0rb) (hr GVt1 calc(GVa0+GVoal)) vlabel(GV1lb) (hr calc(GVt1+GVp) calc(GVa0+GVoal)) vlabel(GV1rb) (hr GVt2 calc(GVa0+GVoal+GVbal)) vlabel(GV2lb) (hr calc(GVt2+GVp) calc(GVa0+GVoal+GVbal)) vlabel(GV2rb) (hr GVt3 calc(GVa0+GVoal+GVbal+GVial)) vlabel(GV3lb) (hr calc(GVt3+GVp) calc(GVa0+GVoal+GVbal+GVial)) vlabel(GV3rb) //Guide vane shroud: (sr GVt0 GVa0) vlabel(GV0lt) (sr calc(GVt0+GVp) GVa0) vlabel(GV0rt) (sr GVt1 calc(GVa0+GVoal)) vlabel(GV1lt) (sr calc(GVt1+GVp) calc(GVa0+GVoal)) vlabel(GV1rt) (sr GVt2 calc(GVa0+GVoal+GVbal)) vlabel(GV2lt) (sr calc(GVt2+GVp) calc(GVa0+GVoal+GVbal)) vlabel(GV2rt) (sr GVt3 calc(GVa0+GVoal+GVbal+GVial)) vlabel(GV3lt) (sr calc(GVt3+GVp) calc(GVa0+GVoal+GVbal+GVial)) vlabel(GV3rt) //Runner hub: (hr RUt0 RUa0) vlabel(RU0lb) (hr calc(RUt0+RUp) RUa0) vlabel(RU0rb) (hr RUt1 calc(RUa0+RUoal)) vlabel(RU1lb) (hr calc(RUt1+RUp) calc(RUa0+RUoal)) vlabel(RU1rb) (hr RUt2 calc(RUa0+RUoal+RUal)) vlabel(RU2lb) (hr calc(RUt2+RUp) calc(RUa0+RUoal+RUal)) vlabel(RU2rb) (hr RUt3 calc(RUa0+RUoal+RUal+RUial)) vlabel(RU3lb) (hr calc(RUt3+RUp) calc(RUa0+RUoal+RUal+RUial)) vlabel(RU3rb) //Runner shroud: (sr RUt0 RUa0) vlabel(RU0lt) (sr calc(RUt0+RUp) RUa0) vlabel(RU0rt) (sr RUt1 calc(RUa0+RUoal)) vlabel(RU1lt) (sr calc(RUt1+RUp) calc(RUa0+RUoal)) vlabel(RU1rt) (sr RUt2 calc(RUa0+RUoal+RUal)) vlabel(RU2lt) (sr calc(RUt2+RUp) calc(RUa0+RUoal+RUal)) vlabel(RU2rt) (sr RUt3 calc(RUa0+RUoal+RUal+RUial)) vlabel(RU3lt) (sr calc(RUt3+RUp) calc(RUa0+RUoal+RUal+RUial)) vlabel(RU3rt) //Draft tube hub: (hr DTt0 DTa0) vlabel(DT0lb) (hr calc(DTt0+DTp) DTa0) vlabel(DT0rb) (hr DTt1 calc(DTa0+DTal)) vlabel(DT1lb) (hr calc(DTt1+DTp) calc(DTa0+DTal)) vlabel(DT1rb) //Draft tube shroud: (sr DTt0 DTa0) vlabel(DT0lt) (sr calc(DTt0+DTp) DTa0) vlabel(DT0rt) (sr DTt1 calc(DTa0+DTal)) vlabel(DT1lt) (sr calc(DTt1+DTp) calc(DTa0+DTal)) vlabel(DT1rt) ); blocks ( //Guide vane: hex2D(GV0l, GV0r, GV1r, GV1l) (GVtc GVoac GVrc) simpleGrading (1 1 1) hex2D(GV1l, GV1r, GV2r, GV2l) (GVtc GVbac GVrc) simpleGrading (1 1 1) hex2D(GV2l, GV2r, GV3r, GV3l) (GVtc GViac GVrc) simpleGrading (1 1 1) //Runner: hex2D(RU0l, RU0r, RU1r, RU1l) rotor (RUtc RUoac RUrc) simpleGrading (1 1 1) hex2D(RU1l, RU1r, RU2r, RU2l) rotor (RUtc RUbac RUrc) simpleGrading (1 1 1) hex2D(RU2l, RU2r, RU3r, RU3l) rotor (RUtc RUiac RUrc) simpleGrading (1 1 1) //Draft tube: hex2D(DT0l, DT0r, DT1r, DT1l) (DTtc DTac DTrc) simpleGrading (1 1 1) ); edges // Inappropriate with arc due to coordinate conversion ( //Runner spline RU1lt RU2lt ( (sr calc(RUt1+0.65*(RUt2-(RUt1))) calc(RUa0+RUoal+0.5*RUal)) ) spline RU1lb RU2lb ( (hr calc(RUt1+0.65*(RUt2-(RUt1))) calc(RUa0+RUoal+0.5*RUal)) ) spline RU1rt RU2rt ( (sr calc(RUt1+RUp+0.75*(RUt2-(RUt1))) calc(RUa0+RUoal+0.5*RUal)) ) spline RU1rb RU2rb ( (hr calc(RUt1+RUp+0.75*(RUt2-(RUt1))) calc(RUa0+RUoal+0.5*RUal)) ) //Guide vane spline GV1lt GV2lt ( (sr calc(GVt1+0.75*(GVt2-(GVt1))) calc(GVa0+GVoal+0.5*GVbal)) ) spline GV1lb GV2lb ( (hr calc(GVt1+0.75*(GVt2-(GVt1))) calc(GVa0+GVoal+0.5*GVbal)) ) spline GV1rt GV2rt ( (sr calc(GVt1+GVp+0.65*(GVt2-(GVt1))) calc(GVa0+GVoal+0.5*GVbal)) ) spline GV1rb GV2rb ( (hr calc(GVt1+GVp+0.65*(GVt2-(GVt1))) calc(GVa0+GVoal+0.5*GVbal)) ) ); boundary ( GVINLET { type patch; faces ( quad2D(GV3r, GV3l) ); } GVOUTLET { type overlapGgi; shadowPatch RUINLET; zone GVOUTLETZone; rotationAxis ( 0 0 1 ); nCopies 5; faces ( quad2D(GV0l, GV0r) ); } GVCYCLIC1 { type cyclicGgi; shadowPatch GVCYCLIC2; zone GVCYCLIC1Zone; bridgeOverlap false; rotationAxis (0 0 1); rotationAngle 72; separationOffset (0 0 0); faces ( quad2D(GV1l, GV0l) quad2D(GV3l, GV2l) ); } GVCYCLIC2 { type cyclicGgi; shadowPatch GVCYCLIC1; zone GVCYCLIC2Zone; bridgeOverlap false; rotationAxis (0 0 1); rotationAngle -72; separationOffset (0 0 0); faces ( quad2D(GV0r, GV1r) quad2D(GV2r, GV3r) ); } //GVCYCLIC //{ // type cyclic; // faces // ( // quad2D(GV1l, GV0l) // quad2D(GV3l, GV2l) // quad2D(GV0r, GV1r) // quad2D(GV2r, GV3r) // ); //} GVBLADE { type wall; faces ( quad2D(GV2l, GV1l) quad2D(GV1r, GV2r) ); } GVHUB { type wall; faces ( backQuad(GV0l, GV0r, GV1r, GV1l) backQuad(GV1l, GV1r, GV2r, GV2l) backQuad(GV2l, GV2r, GV3r, GV3l) ); } GVSHROUD { type wall; faces ( frontQuad(GV0l, GV0r, GV1r, GV1l) frontQuad(GV1l, GV1r, GV2r, GV2l) frontQuad(GV2l, GV2r, GV3r, GV3l) ); } RUINLET { type overlapGgi; shadowPatch GVOUTLET; zone RUINLETZone; rotationAxis ( 0 0 1 ); nCopies 5; faces ( quad2D(RU3r, RU3l) ); } RUOUTLET { type overlapGgi; shadowPatch DTINLET; zone RUOUTLETZone; rotationAxis ( 0 0 1 ); nCopies 5; faces ( quad2D(RU0l, RU0r) ); } RUCYCLIC1 { type cyclicGgi; shadowPatch RUCYCLIC2; zone RUCYCLIC1Zone; bridgeOverlap false; rotationAxis (0 0 1); rotationAngle 72; separationOffset (0 0 0); faces ( quad2D(RU1l, RU0l) quad2D(RU3l, RU2l) ); } RUCYCLIC2 { type cyclicGgi; shadowPatch RUCYCLIC1; zone RUCYCLIC2Zone; bridgeOverlap false; rotationAxis (0 0 1); rotationAngle -72; separationOffset (0 0 0); faces ( quad2D(RU0r, RU1r) quad2D(RU2r, RU3r) ); } //RUCYCLIC //{ // type cyclic; // faces // ( // quad2D(RU1l, RU0l) // quad2D(RU3l, RU2l) // quad2D(RU0r, RU1r) // quad2D(RU2r, RU3r) // ); //} RUBLADE { type wall; faces ( quad2D(RU2l, RU1l) quad2D(RU1r, RU2r) ); } RUHUB { type wall; faces ( backQuad(RU0l, RU0r, RU1r, RU1l) backQuad(RU1l, RU1r, RU2r, RU2l) backQuad(RU2l, RU2r, RU3r, RU3l) ); } RUSHROUD { type wall; faces ( frontQuad(RU0l, RU0r, RU1r, RU1l) frontQuad(RU1l, RU1r, RU2r, RU2l) frontQuad(RU2l, RU2r, RU3r, RU3l) ); } DTINLET { type overlapGgi; shadowPatch RUOUTLET; zone DTINLETZone; rotationAxis ( 0 0 1 ); nCopies 5; faces ( quad2D(DT1r, DT1l) ); } DTOUTLET { type patch; faces ( quad2D(DT0l, DT0r) ); } DTCYCLIC1 { type cyclicGgi; shadowPatch DTCYCLIC2; zone DTCYCLIC1Zone; bridgeOverlap false; rotationAxis (0 0 1); rotationAngle 72; separationOffset (0 0 0); faces ( quad2D(DT1l, DT0l) ); } DTCYCLIC2 { type cyclicGgi; shadowPatch DTCYCLIC1; zone DTCYCLIC2Zone; bridgeOverlap false; rotationAxis (0 0 1); rotationAngle -72; separationOffset (0 0 0); faces ( quad2D(DT0r, DT1r) ); } //DTCYCLIC //{ // type cyclic; // faces // ( // quad2D(DT1l, DT0l) // quad2D(DT0r, DT1r) // ); //} DTHUB { type wall; faces ( backQuad(DT0l, DT0r, DT1r, DT1l) ); } DTSHROUD { type wall; faces ( frontQuad(DT0l, DT0r, DT1r, DT1l) ); } ); // 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