2.8.2.11. Block 51 — INPCHN — Channel-Dependent Options and Integer Input¶
IDBUGV
1
Channel-dependent debug flag. (See IDBUG0
and IERSTP
).
Time step control output for 2 ≤ IDBUG0
≤ 6.
IDBUG0
= 0.IERSTP
)IERSTP
)IERSTP
2
IRHOK
3
Fuel density, heat capacity and thermal conductivity selection parameter.
Correlations for oxide fuel (IMETAL=0):
COEFDS
, COEFDL
are required.COEFK
is required.Note: The parameter values associated with IRHOK
=1 or 3 need not be input. For oxide fuel, tabular heat capacity is used even if IRHOK
> 0.
Correlations for U-Fs fuel (IMETAL=1):
REFDEN
with thermal expansion function subprogram ALPHF. Correlation for fuel conductivity depends on temperature. Porosity and sodium logging is accounted for by the method of ANL/RAS 85-19.Note: For U-Fs fuel, tabular heat capacity is used even if IRHOK
> 0.
Correlations for ternary/binary fuel (IMETAL=2,3):
Note: Input IFUELM
is required for this fuel.
IMETAL
= 2 or 3.For IFUELM
=0:
> 0, Correlation for fuel density depends on temperature. Input
RHOZN
is required. Correlation for fuel heat capacity depends on alloy composition/type and temperature. InputsPUZRTP
,TFSOL
,TFLIQ
are required. Correlation for fuel conductivity depends on composition/ type, temperature, porosity and sodium logging. InputsPRSTY
andXLOGNA
are required.
For IFUELM
=1:
> 0, Correlation for fuel density depends on alloy composition and temperature. Correlation for fuel heat capacity depends on alloy composition and temperature. Correlation for fuel conductivity depends on composition, temperature, porosity and sodium logging. Inputs
POROSS
,PORMSS
,PORCSS
,FPORNA
are required.
For IFUELM
=2:
> 0, Correlation for Mark-V & U-10Zr fuel densities. Input composition from array PUZRTP is used with thermal expansion. Correlation for Mark-V & U-10Zr fuel heat capacities depend on temperature. Correlation for Mark-V & U-10Zr fuel conductivities depend on composition, temperature and burnup. Input
BURNFU
is required, based on memos of Billone to Briggs dated 1/14/91, 3/8/91 & 10/21/91.
NZNODE (KZ)
7-13
Number of segments in zone KZ. (KZ ≤ 7).
Total number of all segments in all zones ≤ 48. Only one segment per node is necessary, but if the LEVITATE or PLUTO2 region can extend into a node the segments there should be in the range from 0.03 meters to 0.1 meters. Neighboring cells for PLUTO2 and LEVITATE should not differ much in length. A length ratio of 1.5 is still reasonable.
ICLADV
17
Table number of property value to be used for cladding table.
NGRDSP
18
Number of spacer grids in pin. 2 ≤ NGRDSP
≤ 10.
KTING
19
Fission-gas release model option.
NAXOP
20
Model selection for axial expansion and crack volume.
Crack Volume |
Axial Plane Strain |
Axial Swelling |
|
---|---|---|---|
0 |
No |
No |
No |
1 |
No |
Yes |
No |
2 |
No |
No |
Yes |
3 |
No |
Yes |
Yes |
4 |
Yes |
No |
No |
5 |
Yes |
Yes |
No |
6 |
Yes |
No |
Yes |
7 |
Yes |
Yes |
Yes |
If NAXOP
= X with X above, mixed plane strain.
MSTEP
21
Number of main steady-state power change and constant power intervals. One required for each power change. One required for each constant power interval. (≤ 8).
ITAU
22
Irradiation induced cladding swelling incubation parameter options.
IRATE
23
Irradiation induced cladding swelling rate options.
IHGAP
24
NPIN
25
Number of pins per subassembly.
NSUBAS
26
Number of subassemblies in channel.
MZUB
27
Number of segments in upper blanket.
MZLB
28
Number of segments in lower blanket.
IHEX
29
IRELAX
30
Stress relaxation options. Use IRELAX
= 0.
NGRAIN
31
Model selection for grain growth theory.
NGRAIN
is the grain diameter exponent in Eq. 8.3-9.Suggested value: 4.
ISSFUE
32
IRAD
33
Not currently used.
ILAG
34
Suggested value: 0.
NOSTRN
35
Option to avoid radial strain in the cladding even if conditions would produce strain.
JRUPT
36
Not currently used.
NPLIN (M)
37-44
Number of subdivisions in each of the MSTEP
divisions. There should be enough subdivisions to allow for reasonable feedback of the restructuring into the thermal calculation. At least 4 subdivisions for each power change and enough constant power subdivisions so that each does not exceed about 10 days (preferably 2 days during early irradiation).
(M = 1, MSTEP
)
IROR
45
Controls assumption used when molten cavity extends to the cracked fuel zone.
JPRNT1
46
The lowest axial node for which debug output is produced from DEFORM.
JPRNT2
47
The highest axial node for which debug output is produced from DEFORM.
Note: The debug output is produced for all nodes from JPRNT1
to JPRNT2
inclusive. If these two values are set to 0 but the time step controls and IDBUGF
are activated, then the debug output is from the molten cavity routine and the axial expansion and feedback calculation only (the axial node independent part of the calculation).
NNBUG1
48
The time step at which to start the debug output from DEFORM.
NNBUG2
49
The time step which is the last time step for debug output from DEFORM
IDBUGF
50
The control for the type of debug output desired from DEFORM.
NNBUG1
.NSKIP (M)
51-58
MPL1
59
MPL7
65
MPL8
66
Not currently used.
MPL9
67
Not currently used.
KKSBTP
68
Not currently used.
KKSBRI
69
Not currently used.
NRPI
70
Not currently used.
NRPI1
71
NRPI2
72
Not currently used.
NRPI3
73
Not currently used.
IPSIZE
74
IBUGPL
75
Debug flag, should currently always be 0.
ICFINE
76
DTPLIN
as the initial and later on the minimum time step.IPRINT
77
Should currently always be 0.
IPLOT
78
IBNEW
81
Debug levels:
IPGO
82
ICLADB
85
MFAIL
86
Fuel-pin failure option. (See FSPEC
).
FSPEC
is failure time.FSPEC
is fuel failure temperature.FSPEC
is fuel mass melt fraction at failure.FSPEC
is cavity pressure at failure.FSPEC
is cladding yield stress at failure. Not yet operational.FSPEC
is eutectic temperature.JFAIL
88
ISUBAS
89
Subassembly number, only required for the detailed coolant sub-channel model.
JCLN
90
JNEN
91
JNCN
92
JNSN
93
JRPRO
94
IPSIG
95
Hydrostatic pressure for fuel swelling:
IHTPRS
96
IPRD
97
Controls the amount of DEFORM output in the transient calculation.
(For steady-state control see NSKIP
)
IDBFLG
98-107
IDBFLG
(4) > 0 gives reentry temperature debug print.
(10)
IDBFLG
(5) > 2 gives TSCA debug print.
IDBFLG
(6) > 0 gives subassembly-subassembly heat transfer prints.
IDBFLG
(7) > 0 for film motion of debugs.
IDBFLG
(8) > 0 for Wallis flooding correlation debugs.
IDBFLG
(9) > 0 for sub-channel analysis coolant debugs
IDBFLG
(10) > 0 for sub-channel analysis heat transfer debugs
IEQMAS
118
Radial fuel mesh size assumption.
IBLPRN
119
ISSFU2
122
IAXEXP
).IHEALC
123
IAXTHF
124
Determine components active in the axial expansion calculation in DEFORM.
IDCLGO
125
Value of ICOUNT (number of cladding time steps) when cladding debug print begins.
IDCLSP
126
Value of ICOUNT when CLAP debug print ends.
IFILM
128
Number of nodes dried out before switch from wet (a few boiling segments) to dry (larger boiling length) minimum film thickness.
Suggested value: 3 or 4. Do not input 0.
NZONF
129-131
Not currently used.
IFUELI
132-155
Not currently used.
NODSUM
156-179
Not currently used.
IFUOPT
180
Not currently used.
IAXEXP
181
IMOMEN
182
LEVITATE option referring to the convective momentum flux formulation.
JSTRDX
183
Axial node number in structure corresponding to the above core load pad. Use only if IRADEX
= 1,2,3 or -1,-2,-3.
IFAE
184
Fuel adjacency effect in Kramer-DiMelfi cladding failure model.
ICLADK
185
Cladding thermal conductivity option.
(Not currently operational, use = 0)
IFRFAC
186
IRDEXP
187
IBUGPN
188
Debug flag, should currently always be 0.
IMETAL
189
Indicates fuel type.
IPNPLT
190
IFUELO
191
IFUELM
192
Option for the thermal properties of the U-Pu-Zr alloy fuel (for the case of IMETAL
> 1 only).
IMETAL
= 2 or 3) based on the metallic fuels handbook dataIFUELC
193
User input fuel zone specification flag.
IPNGO
194
IDM51
197-202
Not currently used.
IDKCRV
203
Power or decay heat curve for this channel.
ITP20
204
CHANNEL-TO-CHANNEL HEAT TRANSFER
NCHCH
205
Number of other channels that this channel is in contact with for duct wall-to-duct wall heat transfer. Maximum 8.
If NCHCH
< 0, Q(ICH to JCH) = -Q(JCH to ICH)
ICHCH
206-213
Channel number of the K-th channel that this channel is in contact with. See also HACHCH
.
If ICHCH
< 0, then -ICHCH
is a bypass channel number.
If ICHCH
(1) < -8, then -ICHCH
(K) is the temperature of a constant temperature heat sink in axial zone K.
If ICHCH
> 500000, transfer heat from structure of ICH to coolant of ICHCH
- 500000.
If ICHCH
> 750000, transfer heat from coolant of ICH to coolant of ICHCH
- 750000.
MULTIPLE PIN OPTION
JJMLTP
214
Multiple pin option.
JJMLTP
channels used to represent the subassembly.Notes:
ICHCH
refers to subassembly-to-subassembly heat transfer from the current channel to channel ICHCH
. This heat transfer is from outer surface node to outer surface node. ICHCH
> 1000 is an exception. This exception was included for modeling the thimble flow region of the XX09 subassembly in EBR-II. If ICHCH
≠ 0 then the heat transfer coefficient times area per unit height is specified by HACHCH
.DETAILED COOLANT SUB-CHANNEL MODEL
JCHMPN (K)
215-218
NUMKLT
219
KSWIRL
220
NULST1
221
SSCOMP METAL FUEL BEHAVIOR MODEL
IPORC
222
Options to control open porosity considerations in metal fuel axial swelling during transient calculation.
FCLOP
before axial movement takes place.IDSSC
223
END SSCOMP METAL FUEL BEHAVIOR MODEL
IDRY
224
ICTYPE
225
SUBASSEMBLY-TO-SUBASSEMBLY HEAT TRANSFER
IOPCHC (K)
226-233
Subassembly-to-subassembly heat transfer option.
KTRANC
234-249
Not currently used.
KTRANM
250-273
Not currently used.
IPRSKP
274
Skip the prints for channel ICH if IPRSKP
is nonzero. To be used to reduce the volume of printed output from TSPRNT.
ITREAT
275
For use with oxide fuel TREAT experiment analysis.
IOPPL
276
Not currently used.
IBUBND
277
IGASRL
278
IGRLTM
279
Not currently used.
IRAPEN
280
Rapid eutectic formation rate assumption.
LCHTYP
281
Core channel designator.
IGSPRS
282
Controls fission gas assumptions used with metal fuel pins.
INDFAL
283
Failure node number on the fuel pin axial mesh for pin failure and gas release if IGASRL
=2.
IAXCON
284
Axial coolant heat conduction option.
JJMLTP
not equal to 0).FPIN-2 INPUT
IFPIN2
285
No other data required when IFPIN2
=0.
IFPI01
286
No other data required when IFPI01
=1.
IHTFLG
287
LHTOPT
288
This input is required only for IHTFLG
=1.
LCRACK
289
Fuel cracking option.
LFPLAS
290
Option for creep-plastic strains in fuel.
LCPLAS
291
Option for creep-plastic strains in cladding.
LFSWEL
292
Option for swelling-hotpressing strains in fuel.
LCSWEL
293
Option for swelling strains in cladding.
LLRGST
294
Option for strain analysis.
LFCSLP
295
LOUTSW
296
LFREQA
297
Initial print frequency, number of time steps between normal detailed printout.
LFREQB
299
Final print frequency.
LGRAPH
300
Graphics file option.
LDBSTP
302
LDBFPL
303
LDBFDV
304
LDBCPL
305
LGPRES
306
Not currently used.
LGAPCL
307
LCPROP
308
(SAS thermal properties are used for IFPI01
=0).
LSKIPM
309
LGCLOS
310
LDBOTA (J)
311-334
Axial debug print vector.
LDBOTF (IF)
335-345
Fuel radial debug print vector.
LDBOTC (IC)
346-348
Clad radial debug print vector.
NONE
349-360
Reserved.
PRIMAR-4 MULTIPLE INLET/OUTLET PLENA
NSEGMP
361
PRIMAR-4 segment number to which this channel is assigned in the multiple inlet/outlet plena model (See IFMIOP
).
CONTROL ROD DRIVE FEEDBACK
ICHUIS
362
PINACLE
LQSLTP
363
POWER AND REACTIVITY MESH
IPOWRZ
364
IREACZ
365
FUEL ZONE TYPE ASSIGNMENT
IZNC (J)
366-389
IZNM (J)
390-413
MFTZN (L,J)
414-485
Fuel type (IFUEL) assignment to radial zones at axial segment J. Maximum value = 8. Used only for IFUELC
= 1.
L=1, fuel type assigned to central (inner) zone. L=2, fuel type assigned to middle intermediate) zone. L=3, fuel type assigned to outer zone.
Note: A maximum of three radial zones may be specified at each axial level. Fewer than three zones may also be specified, with a minimum of a single zone assigned to all the fuel in the pin at a given axial location. Zones are assigned assuming azimuthal symmetry; the central (inner) zone begins at the fuel centerline and extends outward radially through radial mesh interval IZNC
(J). The middle (intermediate) zone begins at radial mesh interval IZNC
(J)+1 and extends outward radially through radial mesh interval IZNM
(J). The outer zone begins in radial mesh interval IZNM
(J)+1 and extends outward radially to the fuel surface (radial temperature node NT
). The central zone may be eliminated by setting IZNC
(J) = 0. The middle zone may be eliminated by setting IZNM
(J) = IZNC
(J). The outer zone may be eliminated by setting IZNM
(J) = NT
. Both inner and middle zones may be eliminated by setting IZNC
(J) = IZNM
(J) = 0. The central zone is present only if IZNC
(J) > 0. The middle zone is present only if IZNM
(J) > IZNC
(J). The outer zone is present only if IZNM
(J) < NT
. The MFTZN
array assigns a fuel type to a zone; fuel types and zones have a one- to-one correspondence at each axial level. The fuel types assigned here specify the fuel thermo-physical properties to be used in the solution of the fuel pin heat transfer equations. See IFUELC
.
IPINFG
486
Metal fuel fission gas model flag.
IPINRE
487
PINACLE ejected fuel re-entry flag.
IPORFG
488
Density correction to porosity in DEFORM-5 fission gas model.
IPRSS1
489
IMKVPL
490
EBR-II Mark-V safety case plotting data.
MZCHCH
491
See FED.
KZEMFM
492
See FED.
MTREAT
493
TREAT fuel channel modeling flag.
CFLAT
and FFLAT
. RBR
, RER
, and ROUTFP
contain TREAT fuel assembly half-thickness dimensions. In fuel and cladding heat transfer calculations, the correct periphery will be used in place of the circumference. The structure field will be eliminated. The fission gas plenum will be eliminated. Air properties will be used for the coolant. The coolant pressure drop calculation will be eliminated. One pin per channel will be used. The DEFORM, PRIMAR, and multiple pin models are not allowed. Only equally-spaced radial heat transfer mesh (IEQMAS
=0) is allowed.IFLOOD
494
DETAILED COOLANT SUB-CHANNEL MODEL
IFT24
495
ILATF
496
Always use ILATF
= 0 to include lateral flow terms in the momentum equation for the detailed coolant sub-channel model.
Reserved for the detailed coolant sub-channel model.
IDEFOPT
497
Note that the extended DEFORM-4 models will be fully available at later versions. Currently, only 15-15Ti cladding models (ICTYPE
= 4) are supported.
IDEFSTFAL
498
IDMICH
499
Not currently used.
LDETL
500
Visualization Data Detail Flag:
NFT24
501
Number of items to be output on fort.24
Reserved for the detailed coolant sub-channel model.
JCFT24 (K)
502-521
Axial node for the Kth output on fort.24.
Reserved for the detailed coolant sub-channel model.
ITYP24 (K)
522-541
Variable type for the Kth output on fort.24
Reserved for the detailed coolant sub-channel model.
NULPT1
542
IDMICH
543-600
Not currently used.