ML18086B208

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University of Massachusetts at Lowell, Enclosure to March 31, 2017 License Renewal RAI Response, Flow Dist
ML18086B208
Person / Time
Site: University of Lowell
Issue date: 03/31/2017
From: Edward Helvenston
Research and Test Reactors Licensing Projects Branch
To:
Helvenston E, NRR/DLP, 415-4067
References
Download: ML18086B208 (1)
v  d  e


Text

NOTES:

This file focuses on the flow distribution calculation - all axial power info in separate file Here we do calcs for both the UMLRR and WPI fuel elements For the bypasses, all the calcs have 5 RBs, 4 control blades, and 1 RegBlade We also do a calc based on only flow area for comparison purposes Basic geometry parameters and assumption are tabulated at the top and then the PLTEMP input is prepared below This file is based on the original work done by JRWhite back in 1991 for the HEU to LEU conversion.

Added the power-to-flow plot on 7/30/15 Reviewed in March 2017 -- Fixed a couple of typos in the comments and changed the # channels from 19 to 18 in the min flow area calc for the fuel channels...

This was modified to account for the fact that the two end channels are only approximately 1/2 the size of the interior channels (19 full channels was simply not correct).

This change only affected the flow area distribution for the no-friction case (Tables 8 and 9 in the safety analysis report), but this was only used for comparison purposes anyway.

Thus, this change does not affect any of the results and conclusions from the PLTEMP full-core analysis.

Fuel Assembly Info (units==> centimeters)

UMLRR WPI fuel top channel area (assume 2.6" x 2.6")

43.613 43.613 top channel length (about 4.5" for top end box) 11.430 11.430

  1. fuel assy fuel 5 rad baskets 4 large blades 1 regblade total plate height 63.500 62.548 20 704.435 88.595 106.819 10.068 909.918 channel width 6.604 6.706 21 739.657 88.595 106.819 10.068 945.140 channel thickness 0.296 0.271 22 774.879 88.595 106.819 10.068 980.362 bottom channel area (assume 2.6" x 2.6")

43.613 43.613 23 810.101 88.595 106.819 10.068 1015.584 bottom channel length (about 6" for grid plate) 15.240 15.240 24 845.323 88.595 106.819 10.068 1050.805 min flow area 35.222 32.698 25 880.544 88.595 106.819 10.068 1086.027 26 915.766 88.595 106.819 10.068 1121.249 rad basket flow area (1.87" diameter hole) 17.719 length (35")

88.900 min flow area 17.719

  1. fuel assy fuel 5 rad baskets 4 large blades 1 regblade total 20 0.774 0.097 0.117 0.011 1.000 control blade shroud area (10.844 x 0.75) 52.471 21 0.783 0.094 0.113 0.011 1.000 blade area (10.65 x 0.375) 25.766 22 0.790 0.090 0.109 0.010 1.000 top control in flow area (shroud - blade) 26.705 23 0.798 0.087 0.105 0.010 1.000 top length (30")

76.200 24 0.804 0.084 0.102 0.010 1.000 middle control out flow area 52.471 25 0.811 0.082 0.098 0.009 1.000 middle length (21")

53.340 26 0.817 0.079 0.095 0.009 1.000 bottom (10.844 x.47) -- very conservative since ignore holes 32.882 bottom length (6")

15.240 min flow area 26.705

  1. fuel assy fuel 5 rad baskets 4 large blades 1 regblade total 20 653.957 88.595 106.819 10.068 859.440 regblade shroud area (2.465 x 2.465) 39.201 21 686.655 88.595 106.819 10.068 892.138 blade area (2.125 x 2.125) 29.133 22 719.353 88.595 106.819 10.068 924.835 top control in (shroud - blade) 10.068 23 752.050 88.595 106.819 10.068 957.533 top length (26")

66.040 24 784.748 88.595 106.819 10.068 990.231 middle control out 39.201 25 817.446 88.595 106.819 10.068 1022.929 middle length (25")

63.500 26 850.144 88.595 106.819 10.068 1055.627 bottom (grid box) 43.613 bottom length (6")

15.240 min flow area 10.068

  1. fuel assy fuel 5 rad baskets 4 large blades 1 regblade total 20 0.761 0.103 0.124 0.012 1.000 convert cm to m 100 21 0.770 0.099 0.120 0.011 1.000 convert cm^2 to m^2 10000 22 0.778 0.096 0.116 0.011 1.000 23 0.785 0.093 0.112 0.011 1.000 PLTEMP Data for LEU Core Flow Distribution Calculation 24 0.792 0.089 0.108 0.010 1.000 Card 0100 25 0.799 0.087 0.104 0.010 1.000 ANAME case description umlrr_flow21 wpi_flow21 26 0.805 0.084 0.101 0.010 1.000 Card 0200 IH heat transfer correlation option 0

IB boiling correlation option 0

Summary Results ICHF CHF correlation option 0

NFTYP number of fuel types 1

  1. fuel assy flow area calc PLTEMP calc flow area calc PLTEMP calc NCTYP number of bypass types 3

20 0.783 0.688 0.771 0.677 NEDIT number of Del P intervals between edits 20 21 0.792 0.705 0.779 0.689 NAXDIS axial temp calc flag (0/1 no/yes) 0 22 0.799 0.714 0.787 0.699 NELPRT element edit flag (ULowell mod - usually zero) 0 23 0.806 0.722 0.794 0.708 Card 0300 (fuel type 1) 24 0.813 0.732 0.801 0.716 NELF number of fuel elements 21 25 0.819 0.740 0.808 0.724 NF number of axial regions 3

26 0.825 0.746 0.814 0.730 WFGES guess for flow rate (kg/s) 1.00 FB HCF for bulk water temp rise 1.00 FQ HCF for heat flux 1.00 FH HCF for heat transfer coeff 1.00 Card 0301 (fuel type 1)

FZ(J) axial peaking factors (NELF entries) -- no effect here 1.50 Card 0302 (fuel type 1) (axial region 1) (top)

AF flow area (m^2) 4.361E-03 4.361E-03 DF hydraulic diameter (m) 6.604E-02 6.604E-02 LF length of region (m) 1.143E-01 1.143E-01 ZF entrance coeff (reentrant pipe) -- all fric losses based on Mott 5th Ed 1.000E+00 1.000E+00 Card 0302 (fuel type 1) (axial region 2 - must be fuel)

AF flow area (m^2) (calc from card 305 if zero) 0.000E+00 0.000E+00 DF hydraulic diameter (m) (calc internally if 0) 0.000E+00 0.000E+00 LF length of region (m) 6.350E-01 6.255E-01 ZF entrance coeff (reentrant pipe) 1.000E+00 1.000E+00 Card 0302 (fuel type 1) (axial region 3)

AF flow area (m^2) (calc from card 305 if zero) 4.361E-03 4.361E-03 DF hydraulic diameter (m) (calc internally if 0) 6.604E-02 6.604E-02 LF length of region (m) 1.524E-01 1.524E-01 ZF entrance+exit coeff (2 sudden expansions) 2.000E+00 2.000E+00 Note: need a conversion factor to go from assembly mass flow rate (kg/s) in PLTEMP Note: In the documentation for this work I decided to treat this conversion factor Card 0303 to overall pump volumetric flow rate in gal/min (gpm) a little differently. I wrote it as wassy = 0.0630 (f/N) Qpump (gpm)

FCOEF friction factor coeff 0.316 where N = Nassy and f = 0.50 + 0.0088N FEXPF exponent in friction factor correlation 0.250

  1. fuel assy Conv. Factor Let's use these to compute some of the same data as before (just as a check)

Card 0304 20 469.8 Ptot (kW) 1000 Qpump (gpm) 1700 NCHNF number of coolant channels 19 21 487.0

  1. fuel assy kW/assy f

gpm/assy kW/gpm wchan (kg/s)

UMLRR WPI IDF fuel material option (03/01 UMLRR U3Si2-AL /WPI UAlx-Al) 3 1

22 503.7 20 50.0 0.676 57.5 0.870 0.201 1.028E+03 1.107E+03 IDC clad type (3 - Al 6061) 3 23 520.0 21 47.6 0.685 55.4 0.859 0.194 9.916E+02 1.068E+03 UDEN uraniun density (g/cc) (w/o if IDF = 0) 3.420E+00 1.700E+00 24 535.9 22 45.5 0.694 53.6 0.848 0.188 9.587E+02 1.033E+03 UNFUEL width of unfueled end of fuel plate (m) 2.595E-03 3.103E-03 25 551.4 23 43.5 0.702 51.9 0.837 0.182 9.286E+02 1.000E+03 L

length of fuel region (m) 5.969E-01 5.969E-01 26 566.5 24 41.7 0.711 50.4 0.827 0.176 9.011E+02 9.706E+02 CLAD clad thickness (m) 3.800E-04 3.810E-04 25 40.0 0.720 49.0 0.817 0.171 8.757E+02 9.433E+02 TAEM meat thickness (m) 5.100E-04 7.620E-04 26 38.5 0.729 47.7 0.807 0.167 8.523E+02 9.181E+02 Card 0305 (central channels)

AFF flow area (m^2) 1.957E-04 1.817E-04 Ptot (kW) 1000 Qpump (gpm) 1650 DFF hydraulic diameter (m) (calc internally if zero) 0.000E+00 0.000E+00

  1. fuel assy kW/assy f

gpm/assy kW/gpm wchan (kg/s)

UMLRR WPI PERF wetted perimeter (m) 1.380E-01 1.395E-01 20 50.0 0.676 55.8 0.897 0.195 9.975E+02 1.075E+03 XIF heated perimeter (m) (calc internally if zero) 0.000E+00 0.000E+00 21 47.6 0.685 53.8 0.885 0.188 9.624E+02 1.037E+03 Card 0305 (end channels) 22 45.5 0.694 52.0 0.874 0.182 9.305E+02 1.002E+03 AFF flow area (m^2) 9.784E-05 9.083E-05 23 43.5 0.702 50.4 0.863 0.176 9.013E+02 9.709E+02 DFF hydraulic diameter (m) (calc internally if zero) 0.000E+00 0.000E+00 24 41.7 0.711 48.9 0.852 0.171 8.746E+02 9.421E+02 PERF wetted perimeter (m) 6.900E-02 6.977E-02 25 40.0 0.720 47.5 0.842 0.166 8.500E+02 9.156E+02 XIF heated perimeter (m) (calc internally if zero) 0.000E+00 0.000E+00 26 38.5 0.729 46.3 0.832 0.162 8.273E+02 8.911E+02 Card 0306 CIRCF width of fuel plate (repeat 18 times) 6.604E-02 6.706E-02 Ptot (kW) 1000 Qpump (gpm) 1600 Card 0307 (don't forget dummy endplates - RP = 0 for UMLRR only)

  1. fuel assy kW/assy f

gpm/assy kW/gpm wchan (kg/s)

UMLRR WPI FACTF RP factor by plate (NELF*18 entries) 1.00 1.00 20 50.0 0.676 54.1 0.925 0.189 9.673E+02 1.042E+03 loop over 3 types of bypasses (if present)

Note: the power to flow ratio vs Nassy is also of interest. As the # assy increases, the power 21 47.6 0.685 52.2 0.913 0.183 9.332E+02 1.005E+03 Card 0400 (bypass 1 - radiation baskets) per assy decreases (for constant Ptot), but the flow rate per assy aslo decreases. Thus, 22 45.5 0.694 50.4 0.901 0.177 9.023E+02 9.719E+02 NCRS number of bypasses of this type 5

addressing how the power to flow (kW/gpm) changes is important.

23 43.5 0.702 48.9 0.890 0.171 8.740E+02 9.415E+02 NC number of axial regions 1

24 41.7 0.711 47.4 0.879 0.166 8.481E+02 9.135E+02 WCGES guess for flow rate (kg/s) 1.00 Ptot (kW) 1000 Qpump (gpm) 1700 25 40.0 0.720 46.1 0.868 0.161 8.242E+02 8.878E+02 Card 0401 26 38.5 0.729 44.8 0.858 0.157 8.022E+02 8.641E+02 AC flow area (m^2) 1.772E-03

  1. fuel assy kW/assy gpm/assy kW/gpm DC hydraulic diameter (m) 4.750E-02 20 50.0 57.5 0.869 Ptot (kW) 1000 Qpump (gpm) 1400 LC length of region (m) 8.890E-01 21 47.6 55.8 0.854
  1. fuel assy kW/assy f

gpm/assy kW/gpm wchan (kg/s)

UMLRR WPI ZC entrance+exit loss coeff (contract+expand) 1.500E+00 22 45.5 54.0 0.842 20 50.0 0.676 47.3 1.057 0.166 8.464E+02 9.117E+02 Card 0402 23 43.5 52.3 0.831 21 47.6 0.685 45.7 1.043 0.160 8.166E+02 8.796E+02 FCOEC friction factor coeff 3.160E-01 24 41.7 50.7 0.822 22 45.5 0.694 44.1 1.030 0.154 7.895E+02 8.504E+02 FEXPC exponent in friction factor correlation 2.500E-01 25 40.0 49.2 0.812 23 43.5 0.702 42.8 1.017 0.150 7.647E+02 8.238E+02 Card 0400 (bypass 2 - control blades) 26 38.5 47.7 0.806 24 41.7 0.711 41.5 1.004 0.145 7.421E+02 7.993E+02 NCRS number of bypasses of this type 4

25 40.0 0.720 40.3 0.992 0.141 7.212E+02 7.769E+02 NC number of axial regions 3

26 38.5 0.729 39.2 0.980 0.137 7.019E+02 7.561E+02 WCGES guess for flow rate (kg/s) 1.00 Card 0401 (top) -- control in --

Ptot (kW) 1000 Qpump (gpm) 1300 AC flow area (m^2) 2.670E-03

  1. fuel assy kW/assy f

gpm/assy kW/gpm wchan (kg/s)

UMLRR WPI DC hydraulic diameter (m) 9.296E-03 20 50.0 0.676 43.9 1.138 0.154 7.859E+02 8.466E+02 LC length of region (m) 7.620E-01 21 47.6 0.685 42.4 1.123 0.148 7.583E+02 8.168E+02 ZC entrance loss coeff (reentrant pipe) 1.000E+00 22 45.5 0.694 41.0 1.109 0.143 7.331E+02 7.897E+02 Card 0401 (middle) -- control out --

23 43.5 0.702 39.7 1.095 0.139 7.101E+02 7.649E+02 AC flow area (m^2) 5.247E-03 24 41.7 0.711 38.5 1.082 0.135 6.891E+02 7.422E+02 DC hydraulic diameter (m) 3.564E-02 25 40.0 0.720 37.4 1.068 0.131 6.697E+02 7.214E+02 LC length of region (m) 5.334E-01 26 38.5 0.729 36.4 1.055 0.128 6.518E+02 7.021E+02 ZC entrance loss coeff (sudden expansion) 2.411E-01 Card 0401 (bottom) -- grid region --

AC flow area (m^2) 3.288E-03 DC hydraulic diameter (m) 2.288E-02 LC length of region (m) 1.524E-01 ZC loss coeffs (use two sudden expansions) 2.000E+00 Card 0402 FCOEC friction factor coeff 3.160E-01 FEXPC exponent in friction factor correlation 2.500E-01 Card 0400 (bypass 3 - regulating rod)

NCRS number of bypasses of this type 1

NC number of axial regions 3

WCGES guess for flow rate (kg/s) 1.00 Card 0401 (top) -- control in --

AC flow area (m^2) 1.007E-03 DC hydraulic diameter (m) 8.636E-03 LC length of region (m) 6.604E-01 ZC entrance loss coeff (reentrant pipe) 1.000E+00 Card 0401 (middle) -- control out --

AC flow area (m^2) 3.920E-03 DC hydraulic diameter (m) 6.261E-02 LC length of region (m) 6.350E-01 ZC entrance loss coeff (sudden expansion) 5.523E-01 Card 0401 (bottom) -- grid box --

AC flow area (m^2) 4.361E-03 DC hydraulic diameter (m) 6.554E-02 LC length of region (m) 1.524E-01 ZC entrance loss coeff (sudden expansion) 1.000E+00 Card 0402 FCOEC friction factor coeff 3.160E-01 FEXPC exponent in friction factor correlation 2.500E-01 Card 0500 DPO initial Del P (MPa) 1.000E-03 DDP Del P increment (MPa) 2.500E-04 DPMAX max Del P (MPa) 4.000E-03 POWER total power (MW) (for portion modelled) 1.000E+00 TIN inlet water temp (C) 4.300E+01 P

inlet pressure (MPa) (about 25 psi converted to Mpa) 1.724E-01 Card 0600 ITER max number of iterations 100 CONV convergence ctiterion 0.0001 ETA flow instability parameter (default=25) 25.00 Card 0700 NN number of axial interfaces (nodes+1) rest not needed Card 0701 for flow ZR distance of interface from inlet (normalized) distribution QVZ relative power density at interface (fz = 1.5 for hot assy)

Card 0702 NIJK number of channels for axial edits Card 0703 (repeat NIJK times)

NII element type NJJ element number NKK channel number Prepared in June 2015 with latest update by JRWhite in July 2015 (and again in March 2017)

UMLRR Flow Areas (cm^2)

UMLRR Normalized Flow Areas WPI Normalized Flow Areas WPI Flow Areas (cm^2) mass flux (kg/s/m^2) mass flux (kg/s/m^2)

UMLRR Assembly WPI Assembly mass flux (kg/s/m^2) mass flux (kg/s/m^2) mass flux (kg/s/m^2) y = 8.786E-03x + 5.041E-01 0.640 0.660 0.680 0.700 0.720 0.740 0.760 20 21 22 23 24 25 26 Series2 Series4 Linear (Series4) y = 16.111x + 148.62 450.0 475.0 500.0 525.0 550.0 575.0 20 21 22 23 24 25 26 Series1 Linear (Series1) 0.800 0.810 0.820 0.830 0.840 0.850 0.860 0.870 0.880 20 21 22 23 24 25 26 27 Series1

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