RRECL IAUTOP I1 HROP WEATH,DPRES,DH20, DWEATHJWEATH ALP ASTART REFTHP, AREF,REFRC REFLP,REFPIP,FPLH,FPLC ITHEL,ETAREF,FEFF REFPRL,FSP PF SMULT CCMUL,CCMULY,CCMULC FCR,RHOML,RNHOML CSTREF,VSTREF,ESTREF,XST CSRMD,VMAX,EMPTY ISTR,NSTR NAX,NAY,NUMPT, XAIM,YAIM EFFSTR FEP IPH FLXLIM ICAVF IFLAUT IFLX IFXOUT NFLXMX,NMXFLX IS B AZMSEP,DENSIT FSLIP IDENS IHPR IUSERF NRADMN,NRADMX REFRCl,REFRC2,REFRC3 IRADFL HRPRE,HRSTRT,HRWEATH PA RL 1, PA RL2 ,PARL3, PARL4,PARLS,PARLG, PARL7,PARL8,PARL9, PARL lO,TPRE,TSTRT 150 n n Total number of designs written on TAPE30 (55) Total annual hours of plant operation BASIC FIELD BASIC NLEFF n n n n n Multipliers on direct capital cost fl Econoniic parameters NLCOST OPT REC NLEFF n n NLFLUX n n n n n HSTAT FIELD n n n n n NLEFF n Annual hours of operations <strong>for</strong> parasitics NLEFF
) Power level specific <strong>for</strong> detailed per<strong>for</strong>mance calculation (1 set <strong>for</strong> each power saved) Y2(N) NTM I N ( K) , NTM A X( K) (K= 1,NAZM) AZMTR(L),DENTR(L) (L= 1,NLAND) FLANI),XTOWER,YTOWER ,SLEW SLNS,CLE,C!LN, NL AND THT RX,RY, W,H,RWOAV TOWD,TOWL AC W OSY, AC: W OSC AC! H Y , AC H C ESTOR XFC ,Y FC , ZFO , DI AMF, POLF,AZMF N X FLX, FA Z M IN, FA Z M AX, NYFLX,FZMIN,FZMAX c) Power level Miniinuni, niaxiniuni zone occupied Azimuthal separation, density FIELD,OPT R EC! Arrays <strong>for</strong> piott,ing (nil power levels: N==l,NP) 77 11 Capital cost, without storage (escalated current) First year capital cost intermediate value M n.xiniu in st orage capacity NLFLIJX NP Total niiniber power levels (220) YZ(N) Power levels ALLBIJ SC: ( N) Levelizecl eiiergy costs (current $) HSTSAVE( N) Nuniber of lieliostats ARES AVE( N) 2 Total land area (km ) ALLCC:( N) Total capital cost ALLPOL( N) (m capital cost in land ALLPC W (N) 1) wiring ALL PC: H (N) n heliost ats ALLPOT( N) n tower ALLPCR (N) n receiver ALLPOP( N) ALLPCB( N) n , piping pumps ALL PCS ( N) ALL PC E( N) n n storage t urbine/generator ALLPC:A(N) (%, capital cost in steam generators ALLPCF(N) n fixed costs ALLTOA( N) Overall system .total efficiency A LLHR (N) Hours of storage A L LK W H ( N) Net energy <strong>prod</strong>uction ALLCOS( N) Cosine AL LS AB( N) Sliadowing and blocking (net efficiency) A L 1, ATM ( N ) Atniospheric tmnsniittance ALLSPL( N) Intercept ALLRCR ( N) Annual average receiver efficiency n 15 1
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- SANDIA REPORT SAND86-8018 Unlimit
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SAND 86-8018 Unlimited Release Prin
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' The computer code which this repo
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I. Introduction CONTENTS A. Differe
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1. More Accurate Images from Canted
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VII. Comparison of DELSOL, MIRVAL,
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111-1 Insolation Models 111-2 Atmos
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A USER’S MANUAL FOR DELSOLS: A CO
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owing, blocking, atmospheric attenu
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The fourth major enhancement in DEL
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W- 26 S ? Jr RECEIVER NORMAL COORDI
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ZONE FlEL 180" Figure 11-3. Surroun
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30 ZONE 60 Figure 11-4. Method of Z
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Figure 11-5. North-only Field (INOR
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34 N' Figure 11-6. Code Defined Fie
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36 Figure 11-7. Schematic Diagram o
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-SLEW (1)- Figure 11-8. Example of
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Figure 11-9. Radial Stagger Arrange
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Note that when IDENS=l or 2 the azi
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J1.D. Heliostats Either rectangular
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Given that heliostats will be mass
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(A) FLAT REFLECTED RAY FROM (B) FOC
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IROUND = 0 WM = 9.91 (m) HM = 9.93
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That is, the aperture is always loc
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controlled by the IAUTOP parameter
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only be used with rectangular cavit
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grid of points on the DELSOL assume
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W E Figure 11-17. Flux Points on a
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flux point grid defined during syst
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To see whether this problem is occu
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Cal cul ati onal Day 1 2 3 4 5 Tabl
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1II.B-I. Position 01 the Sun-The su
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where SO is given by Equation (1II.
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c 0 w V c LL .r a 0 0 0 0 0 s /s 0
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1II.C. Field Performance Calculatio
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1II.F. Flux Density and SDillane Th
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III. G-1. Atmospheric Attenuation:
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eceiver) or with aperture area (cav
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In other words, PLOST,R is the same
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Following the approach in the previ
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86 - - - LLLLLL www CLee o m 4 I i
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This approximate method of calculat
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RECEIVER STARTUP WEATHER SUN PARASI
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111.1. Relationship Between Perform
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IV. System Optimization Calculation
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power and annual energy. Section 11
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- Page 101 and 102: . production. When each design powe
- Page 103 and 104: large enough fraction of total capi
- Page 105 and 106: _____ Table IV-2. Design Parameters
- Page 107 and 108: DELSOL will examine NUMHTW (520) eq
- Page 109 and 110: The final step of cavity receiver o
- Page 111 and 112: . furthermore, that the assumed tur
- Page 113 and 114: point in the NMXFLX(1) array (I=l,
- Page 115 and 116: , flux level. DELSOL determines the
- Page 117 and 118: optimum for any power level is 13.
- Page 119 and 120: I V. System Costs and Economics Whi
- Page 121 and 122: for meteorological equipment. The d
- Page 123 and 124: 0 co I I I 0 co J 0 c\! c, 0 3 Ln 0
- Page 125 and 126: w/2 x RWCAV W/2 x RWCAV IN (180. -
- Page 127 and 128: S M ~ , = ~ solar F multiple for re
- Page 129 and 130: nSTOR is determined from an assumed
- Page 131 and 132: CTK,REF (CSTREF) = $9.70 x loG VTK,
- Page 133 and 134: XHE,A = scaling exponent. ni is cal
- Page 135 and 136: . CCFIXED = 2.OE6 +'0.14 x DCC + 0.
- Page 137 and 138: (V.B - 6) The discount rate rDIS is
- Page 139 and 140: VI. Program Flow DELSOL can be used
- Page 141 and 142: .I c to reach a certain design powe
- Page 143 and 144: an optimum storage size based on en
- Page 145 and 146: I Read i n N + K t x ] ITAPE=O or 1
- Page 147 and 148: Read in System Definition from File
- Page 149: . TABLE VI-2 OUTPIJT FROM OPTIMIZAT
- Page 153 and 154: V1.B. DescriDtion of Subroutines in
- Page 155 and 156: C cy c: C C
- Page 157 and 158: L C c C c C c: C c C C c C C C c: c
- Page 159: C C C C C C C C C C C C C C C C C C
- Page 162 and 163: At the time of the comparisons MIRV
- Page 164 and 165: 164 n m W * ? 0 F F 0 ( z W /M W) X
- Page 166 and 167: 166 Phase 1; CDRL Item 2, Pilot Pla
- Page 168 and 169: 168 43. Vittitoe, C. N. et al., “
- Page 170 and 171: since the values have been already
- Page 172 and 173: Title Card $BASIC$ $FIELD$ $HSTAT$
- Page 174 and 175: IPROB NYEAR HRDEL UDAY UTIME NUAZ N
- Page 176 and 177: TDESP PLAT ALT INSOL SOLCON IWEATH
- Page 178 and 179: REFTIM REFSOL ASTART IATM ATMl ATM2
- Page 180 and 181: IHPR NLAND XTOWER YTOWER (I= 1 ,NLA
- Page 182 and 183: 182 1 1-40 2 1-10 11-20 3 1-10 11-2
- Page 184 and 185: SIGTX SIGTY ICANT NCANTX NCANTY HCA
- Page 186 and 187: THT TOWL TOWD IREC W H RRECL IAUTOP
- Page 188 and 189: For cavities or flat plates, the fo
- Page 190 and 191: NXFLX FAZMIN FAZMAX 190 AZMF (North
- Page 192 and 193: NMXFLXY) identifies the exact point
- Page 194 and 195: REFPRL FSP FEP EFFSTR PF SMULT IP H
- Page 196 and 197: IHOPT NUMTHT THTST THTEND NUMREC WS
- Page 198 and 199: SMULT IPLFL(1) (I=l ,NUMOPT) IPROPT
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CH CL CWR CWDR CWDA ITHT CTOWl CTOW
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ICHE CHEREF PHEREF XHEP APHREF PPHR
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CKNREF PKNREF XKN 204 Sodium-to-sal
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TC TR FDEBT RDEBT ROE IDEP NDEP NYO
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The next set of cards is read at th
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value of insolation from the specif
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For optimizing cavity depth, the IO
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For the final detailed performance
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from that specified during the opti
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Sample Problem 4 - User Defined Fie
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GLOSSARY Absorber: The portion of t
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Heat Exchanger: A component in whic
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Receiver System Efficiency: The rat
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Variable AEVMAX AEVREF AFDC ALP(I)
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Variable H H20 HCANT HM HPANL HRDEL
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Variable PARL7,PARLI) PARL9,PARLlO
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Variable W WEATH WEND WM WPANL WST
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Analysis Review and Critique 6503 8
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Martin Marietta Aerospace P.O. Box
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Stone and Webster Engineering Corpo