TRNSYS - the TRaNsient SYstem Simulation program The Solar Energy Lab at the University of Wisconsin - Madison, USA Le Centre Scientifique et Technique du Batiment, Sophia Antipolis, France Transsolar Energietechnik GmBH, Stuttgart, Germany Thermal Energy System Specialists, Madison Wisconsin, USA Release 16.01.0003 Listing file for: "J:\9600\5. Berekeningen\basisconfiguratie energiebalans\standaard_kantoor.dck" *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : The TRNSYS Executable (TRNExe.exe) and main DLL (TRNDll.dll) are located in "L:\Program Files\Trnsys16_1\Exe" *** Pre-Processing the TRNSYS EQUATIONs and CONSTANTs to check for fatal errors. *** Pre-Processing of EQUATIONs and CONSTANTs completed with no fatal errors found. *** Evaluating the EQUATIONs and CONSTANTs to determine their initial values. *** Finished evaluating the EQUATIONs and CONSTANTs and ready to begin processing the remainder of the TRNSYS input file. VERSION 16 ******************************************************************************* *** TRNSYS input file (deck) generated by TrnsysStudio *** on donderdag, februari 24, 2011 at 10:10 *** from TrnsysStudio project: J:\9600\5. Berekeningen\basisconfiguratie energiebalans\Basisconfiguratie_E_balans_vaste_dT_tsa_geen_buffermodel.tpf *** *** If you edit this file, use the File/Import TRNSYS Input File function in *** TrnsysStudio to update the project. *** *** If you have problems, questions or suggestions please contact your local *** TRNSYS distributor or mailto:software@cstb.fr *** ******************************************************************************* ******************************************************************************* *** Units ******************************************************************************* ******************************************************************************* *** Control cards ******************************************************************************* * START, STOP and STEP CONSTANTS 3 START=0 STOP=262968 STEP=1 * User defined CONSTANTS ! Start time End time Time step SIMULATION 0.0000000000000000E+00 2.6296800000000000E+05 1.0000000000000000E+00 ! Integration Convergence TOLERANCES 1.0000000000000002E-03 1.0000000000000002E-03 ! Max iterations Max warnings Trace limit LIMITS 30 30 31 ! TRNSYS numerical integration solver method DFQ 1 ! TRNSYS output file width, number of characters WIDTH 72 ! NOLIST statement LIST ! MAP statement ! Solver statement Minimum relaxation factor Maximum relaxation factor SOLVER 0 1.000000000000000 1.000000000000000 ! Nan DEBUG statement NAN_CHECK 1 ! Overwrite DEBUG statement OVERWRITE_CHECK 1 ! enable time report statement TIME_REPORT 1 ! EQUATION SOLVER statement EQUATION SOLVING METHOD 0 * Model "meetgeg. klimaat" (Type 109) * UNIT 109 TYPE 109 klimaat *$UNIT_NAME meetgeg. klimaat *$MODEL .\Weather Data Reading and Processing\User Format\Type109-User.tmf *$POSITION 82 648 *$LAYER Buitenklimaat # PARAMETERS 4 ! 1 Data Reader Mode ! 2 Logical unit ! 3 Sky model for diffuse radiation ! 4 Tracking mode 1.0000000000000000E+00 8.1000000000000000E+01 4.0000000000000000E+00 1.0000000000000000E+00 INPUTS 9 ! [unconnected] Ground reflectance ! [unconnected] Slope of surface-1 ! [unconnected] Azimuth of surface-1 ! [unconnected] Slope of surface-2 ! [unconnected] Azimuth of surface-2 ! [unconnected] Slope of surface-3 ! [unconnected] Azimuth of surface-3 ! [unconnected] Slope of surface-4 ! [unconnected] Azimuth of surface-4 CONST CONST CONST CONST CONST CONST CONST CONST CONST *** INITIAL INPUT VALUES 2.0000000000000001E-01 9.0000000000000000E+01 2.6000000000000000E+02 9.0000000000000000E+01 8.0000000000000000E+01 9.0000000000000000E+01 -1.0000000000000000E+01 9.0000000000000000E+01 1.7000000000000000E+02 *** External files ASSIGN J:\9600\5. Berekeningen\klimaatgegevens\TRNSYS_DeBilt_1981_2010.txt 81 *|? Weather data file |1000 *------------------------------------------------------------------------------ * EQUATIONS "orientatie gebouw" * EQUATIONS 5 TURN = 80 AA_N = 180 + TURN AA_S = TURN AA_E = -90 + TURN AA_W = 90 + TURN *$UNIT_NAME orientatie gebouw *$LAYER Gebouw *$POSITION 374 648 *------------------------------------------------------------------------------ * EQUATIONS "parameters voor installaties" * EQUATIONS 48 !m^3 luchtvolume_A = 129 !m^3 luchtvolume_B = 206 !m^3 luchtvolume_C = 155 !m^3 luchtvolume_D = 129 aantal_zones_A = 1 aantal_zones_B = 1 aantal_zones_C = 1 aantal_zones_D = 1 !m2 bruto_vloeropp_A = 48.6 !m2 bruto_vloeropp_B = 77.76 !m2 bruto_vloeropp_C = 58.32 !m2 bruto_vloeropp_D = 48.6 ! m^2 bruto_vloeroppervlak = (bruto_vloeropp_A*aantal_zones_A+ bruto_vloeropp_B*aantal_zones_B+ bruto_vloeropp_C*aantal_zones_C+ bruto_vloeropp_D*aantal_zones_D)/0 .735 !m2 bruto_vloeropp_verk = 0.235*bruto_vloeroppervlak !m2 bruto_vloeropp_techn = 0.03*bruto_vloeroppervlak !kg/h q_max_bka_plaat_A = 177 !kg/h q_max_bka_plaat_B = 177 !kg/h q_max_bka_plaat_C = 133 !kg/h q_max_bka_plaat_D = 133 aantal_bka_platen_A = 3 aantal_bka_platen_B = 4.8 aantal_bka_platen_C = 3.6 aantal_bka_platen_D = 3.8 !kg/m^3 dichtheid_water = 998 !kg/m^3 dichtheid_lucht = 1.23 !J/kgK warmtecap_water = 4180 !J/kgK warmtecap_lucht = 1006 !kg/h q_max_wko = ((P_KM_geb_max_W_m2*bruto_vloeroppervlak*0.6)*3600)/ (warmtecap_water*dT_wko_min_wb_kb) !kg/h q_min_wko = 0.2*q_max_wko !K dT_wko_min_wb_kb = 4 !deg C Tmin_injectie_wko_kb = 7.0 !deg C Tmax_injectie_wko_wb = 25 !deg C Tin_cond_spec = 20 !deg C Tuit_cond_spec = 40 !deg C Tin_verd_spec = 11 !deg C Tuit_verd_spec = 6 COP_spec = 4.2 !- rendement (isotropisch * elektrisch * frictie) rend_wp_isotr_el_wri = 0.65*0.9*0.9 rend_verd = 0.6 rend_cond = 0.7 !W/m^2 P_KM_geb_max_W_m2 = 20 !W/m^2 P_VW_geb_max_W_m2 = 24 !W Pwp_cond_max = (P_VW_geb_max_W_m2*bruto_vloeroppervlak)*0.6 !W Pwp_verd_max = Pwp_cond_max-(Pwp_cond_max/COP_spec) !W Pmax_lbk_kbat = 0.48*(P_KM_geb_max_W_m2*bruto_vloeroppervlak) !W Pmax_lbk_vbat = 0.20*(P_VW_geb_max_W_m2*bruto_vloeroppervlak) !W Pdk_max = Pwp_cond_max+4000 !W Pketel_max = max((P_VW_geb_max_W_m2*bruto_vloeroppervlak)- Pwp_cond_max,0) *$UNIT_NAME parameters voor installaties *$LAYER Main *$POSITION 376 466 *------------------------------------------------------------------------------ * EQUATIONS "schakeling bka vraag" * EQUATIONS 7 ondergrens_beta = 19.45+0.11*[109,8] !deg C inschakelwaarde_verw = le([109,7], 12)*21+ gt([109,7], 12)*(-0.125*[109,7] + 22.5) !deg C inschakelwaarde_koel = le([109,7], 4)*23 + ge([109,7], 18)*22.5+ and(gt([109,7], 4), lt([109,7], 18))*(-0.0357*[109,7] + 23.143) dT_verw_aan = 0 dT_verw_uit = -0.9 dT_koel_aan = 0 dT_koel_uit = -0.9 *$UNIT_NAME schakeling bka vraag *$LAYER Betonkernactivering *$POSITION 744 914 *------------------------------------------------------------------------------ * EQUATIONS "regeling DK" * EQUATIONS 8 !- koude_laden_wko_dk = [80,1] !deg C Tin_tsa_gkw_cv = max(koudevraag_leidend*Tuit_cond_spec+ warmtevraag_leidend*[76,1]+ (1-(koudevraag_leidend+warmtevraag_leidend)* [76,1]),6) !W Pkoel_dk = max(koudevraag_leidend*(Pwp_cond-Pverw_cv)+ warmtevraag_leidend*koude_laden_wko_dk* (Pladen_max_wko-Pwp_verd)+ (1-(warmtevraag_leidend+koudevraag_ leidend))* koude_laden_wko_dk*(Pladen_max_wko-Pwp_verd),0) !W Pdk_actueel = min(max(Pkoel_dk,0),Pdk_max) !kg/hr q_tsa_gkw_cv = max(koudevraag_leidend*(q_cv_wp_cond-q_cv_lbk_bka)+ warmtevraag_leidend*koude_laden_wko_dk* ((Pdk_actueel*3600)/(warmtecap_water* ([76,1]-Tuit _verd_spec)))+ (1-(warmtevraag_leidend+koudevraag_leidend))* koude_laden_wko_dk* ((Pdk_actueel*3600)/(warmtecap_water* ([76,1]-Tuit_verd_spec))),0) Tna_dk_gewenst = min(max(koudevraag_leidend*Tin_cond_spec+ warmtevraag_leidend*Tuit_verd_spec+ (1-(warmtevraag_leidend+koudevraag_leidend))* koude_laden_wko_ dk*Tuit_verd_spec,4),40) !deg C Tna_dk = min(max(warmtevraag_leidend*Tna_dk_gewenst+ (1-(warmtevraag_leidend+koudevraag_leidend))*Tna_dk_gewenst+ koudevraag_leidend*(Tin_tsa_gkw_cv-((Pdk_act ueel*3600)/ (warmtecap_water*q_tsa_gkw_cv+0.001))) ,4),max(Tin_cond_spec+5,[109,1]+dT_tsa_dk)) !K dT_tsa_dk = 1.5 *$UNIT_NAME regeling DK *$LAYER Main *$POSITION 1405 541 *------------------------------------------------------------------------------ * Model "koude laden WKO met DK" (Type 2) * UNIT 80 TYPE 2 laden WKO met DK *$UNIT_NAME koude laden WKO met DK *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 1405 445 *$LAYER Main # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! [unconnected] Upper input temperature Th ! meetgeg. klimaat:Ambient temperature ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! koude laden WKO met DK:Output control function ->Input control function ! regeling DK:dT_tsa_dk ->Upper dead band dT ! [unconnected] Lower dead band dT CONST 109,1 CONST 80,1 DT_TSA_DK CONST *** INITIAL INPUT VALUES 6.0000000000000000E+00 1.0000000000000000E+01 5.0000000000000000E+01 0.0000000000000000E+00 1.5000000000000000E+00 0.0000000000000000E+00 *------------------------------------------------------------------------------ * EQUATIONS "stooklijn Tbka koelen" * EQUATIONS 9 X1_bka_gkw = 17 Y1_bka_gkw = 20 X2_bka_gkw = 28 Y2_bka_gkw = 19 minimum_bka_gkw = 17 maximum_bka_gkw = 22 Tair_koel_gewenst = 23 Tstooklijn_bka_gkw = min(max(Y1_bka_gkw-(([109,7]-X1_bka_gkw)/ (X2_bka_gkw-X1_bka_gkw))*(Y1_bka_gkw-Y2_bka_gkw), minimum_bka_gkw),maximum_bka_gkw) !min(max(Tstooklijn_bka_gkw+ (Tair_koel_gewenst-(([56,32]+[56,22]+[56,16]+[56,6])/4)), minimum_bka_gkw),maximum_bka_gkw) !deg C Tstook_bka_gkw_gecom = Tstooklijn_bka_gkw *$UNIT_NAME stooklijn Tbka koelen *$LAYER Main *$POSITION 435 909 *------------------------------------------------------------------------------ * EQUATIONS "stooklijn Tbka verwarmen" * EQUATIONS 9 X1_bka_cv = -7 Y1_bka_cv = 25 X2_bka_cv = 14 Y2_bka_cv = 22 minimum_bka_cv = 20 maximum_bka_cv = 30 Tair_verw_gewenst = 22 Tstooklijn_bka_cv = min(max(Y1_bka_cv-(([109,7]-X1_bka_cv)/ (X2_bka_cv-X1_bka_cv))*(Y1_bka_cv-Y2_bka_cv), minimum_bka_cv),maximum_bka_cv) !min(max(Tstooklijn_bka_cv+ (Tair_verw_gewenst-(([56,32]+[56,22]+[56,11]+[56,1])/4)), minimum_bka_cv),maximum_bka_cv) !deg C Tstook_bka_cv_gecomp = Tstooklijn_bka_cv *$UNIT_NAME stooklijn Tbka verwarmen *$LAYER Main *$POSITION 435 823 *------------------------------------------------------------------------------ * EQUATIONS "stooklijn clo" * EQUATIONS 5 clo = min(max(C1-(([109,8]-T1)/(T2-T1))*(C1-C2),C2),C1) T1 = 12 C1 = 0.9 T2 = 20 C2 = 0.7 *$UNIT_NAME stooklijn clo *$LAYER Gebouw *$POSITION 231 466 *------------------------------------------------------------------------------ * EQUATIONS "Straling" * EQUATIONS 18 AISZ = [109,10] AISA = [109,11] IT_H = Max([109,12],0) IB_H = Max([109,13],0) ID_H = [109,14] AI_H = [109,16] IT_N = [109,18] AI_N = [109,22] IB_N = [109,19] * LT(AI_N,90) IT_S = [109,24] IB_S = [109,25] AI_S = [109,28] IT_E = [109,30] IB_E = [109,31] AI_E = [109,34] IT_W = [109,36] IB_W = [109,37] AI_W = [109,40] *$UNIT_NAME Straling *$LAYER Buitenklimaat *$POSITION 231 573 *------------------------------------------------------------------------------ * Model "Mollier buiten" (Type 33) * UNIT 331 TYPE 33 buiten *$UNIT_NAME Mollier buiten *$MODEL .\Physical Phenomena\Thermodynamic Properties\Psychrometrics\Dry Bulb and Relative Humidity Known\Type33e.tmf *$POSITION 231 723 *$LAYER Buitenklimaat # PARAMETERS 3 ! 1 Psychrometrics mode ! 2 Wet bulb mode ! 3 Error mode 2.0000000000000000E+00 0.0000000000000000E+00 2.0000000000000000E+00 INPUTS 3 ! meetgeg. klimaat:Ambient temperature ->Dry bulb temp. ! meetgeg. klimaat:relative humidity ->Percent relative humidity ! [unconnected] Pressure 109,1 109,2 CONST *** INITIAL INPUT VALUES 2.0000000000000000E+01 5.0000000000000000E+01 1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "temp uitspansel" (Type 69) * UNIT 69 TYPE 69 uitspansel *$UNIT_NAME temp uitspansel *$MODEL .\Physical Phenomena\Sky Temperature\calculate cloudiness factor\Type69b.tmf *$POSITION 231 645 *$LAYER Buitenklimaat # PARAMETERS 2 ! 1 mode for cloudiness factor ! 2 height over sea level 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 4 ! Mollier buiten:Dry bulb temperature ->Ambient temperature ! Mollier buiten:Dew point temperature. ->Dew point temperature at ambient conditions ! meetgeg. klimaat:beam radiation on horitonzal ->Beam radiation on the horizontal ! meetgeg. klimaat:sky diffuse radiation on horizontal ->Diffuse radiation on the horizontal 331,7 331,8 109,13 109,14 *** INITIAL INPUT VALUES 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "output_comfort" (Type 65) * UNIT 77 TYPE 65 *$UNIT_NAME output_comfort *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1722 328 *$LAYER OutputSystem # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 -1.5000000000000000E+01 3.0000000000000000E+01 4.0000000000000000E+00 4.0000000000000000E+01 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 8.7000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! Standaard kantoor: 40- TOP_GROEP_A ->Left axis variable-1 ! Standaard kantoor: 29- TOP_GROEP_B ->Left axis variable-2 ! Standaard kantoor: 19- TOP_GROEP_C ->Left axis variable-3 ! Standaard kantoor: 8- TOP_GROEP_D ->Left axis variable-4 ! meetgeg. klimaat:Ambient temperature ->Left axis variable-5 ! meetgeg. klimaat:userdefined data 3 ->Left axis variable-6 ! schakeling bka vraag:ondergrens_beta ->Left axis variable-7 ! schakeling bka vraag:inschakelwaarde_verw ->Left axis variable-8 ! schakeling bka vraag:inschakelwaarde_koel ->Left axis variable-9 ! meetgeg. klimaat:userdefined data 4 ->Left axis variable-10 ! stooklijn Tgkw net:Tstook_gkw_net ->Right axis variable-1 ! stooklijn Tcv net:Tstook_cv_net ->Right axis variable-2 ! energiebalans:energie_balans_proc ->Right axis variable-3 ! [unconnected] Right axis variable-4 ! [unconnected] Right axis variable-5 ! [unconnected] Right axis variable-6 ! [unconnected] Right axis variable-7 ! [unconnected] Right axis variable-8 ! [unconnected] Right axis variable-9 ! [unconnected] Right axis variable-10 56,40 56,29 56,19 56,8 109,1 109,7 ONDERGRENS_BETA INSCHAKELWAARDE_VERW INSCHAKELWAARDE_KOEL 109,8 TSTOOK_GKW_NET TSTOOK_CV_NET ENERGIE_BALANS_PROC CONST CONST CONST CONST CONST CONST CONST *** INITIAL INPUT VALUES TOP_GROEP_A TOP_GROEP_B TOP_GROEP_ C TOP_G ROEP_D Ambient Tgew_gem_3d ondergrens_beta inschakelw aarde_verw insch akelwaarde_koel Te_ref Tstook_gkw_net Tstook_cv_net energie_ba lans_proc label label label label label label label LABELS 3 Temperatures Heat transfer rates zones_ambient *** External files ASSIGN output_comfort.txt 87 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * EQUATIONS "centraal BKA net" * EQUATIONS 10 !kg/hr q_bka_gkw = q_bka_water_D*aantal_bka_platen_D*aantal_zones_D*koelen_D +q_bka_water_C*aantal_bka_platen_C*aantal_zones_C*koelen_C +q_bka_water_B*aantal_bka_pla ten_B*aantal_zones_B*koelen_B +q_bka_water_A*aantal_bka_platen_A*aantal_zones_A*koelen_A !kg/hr q_bka_cv = q_bka_water_D*aantal_bka_platen_D*aantal_zones_D*verwarmen_D +q_bka_water_C*aantal_bka_platen_C*aantal_zones_C*verwarmen_C +q_bka_water_B*aantal_bk a_platen_B*aantal_zones_B*verwarmen_B +q_bka_water_A*aantal_bka_platen_A*aantal_zones_A*verwarmen_A !deg C Tret_bka_gkw = (q_bka_water_A*aantal_bka_platen_A*aantal_zones_A*Tuit_bka_A*koelen_A +q_bka_water_B*aantal_bka_platen_B*aantal_zones_B*Tuit_bka_B*koelen_B +q_ bka_water_C*aantal_bka_platen_C*aantal_zones_C*Tuit_bka_C*koelen_C +q_bka_water_D*aantal_bka_platen_D*aantal_zones_D*Tuit_bka_D*koelen_D)/ (q_bka_gkw+0.001) !deg C Tret_bka_cv = (q_bka_water_A*aantal_bka_platen_A*aantal_zones_A*Tuit_bka_A*verwarmen_A +q_bka_water_B*aantal_bka_platen_B*aantal_zones_B*Tuit_bka_B*verwarmen_B +q_bka_water_C*aantal_bka_platen_C*aantal_zones_C*Tuit_bka_C*verwarmen_C +q_bka_water_D*aantal_bka_platen_D*aantal_zones_D*Tuit_bka_D*verwarmen_D)/ (q_bka_c v+0.001) q_bka_bypass_gkw = max((1-[88,1])*q_bka_gkw*0.99999, min(max([88,1]* ((Tstook_bka_gkw_gecom-[70,2])/ (Tret_bka_gkw-[70,2]+0.001))*q_bka_gkw*0.99999,0),q_bka_ gkw*0.99999)) q_bka_bypass_cv = max((1-[87,1])*q_bka_cv*0.99999, min(max([87,1]* (([70,4]-Tstook_bka_cv_gecomp)/ ([70,4]-Tret_bka_cv+0.001))*q_bka_cv*0.99999,0),q_bka_cv*0 .99999)) q_centr_gkw_to_bka = max(q_bka_gkw-q_bka_bypass_gkw,0) q_centr_cv_to_bka = max(q_bka_cv-q_bka_bypass_cv,0) Tin_bka_gkw = (Tret_bka_gkw*q_bka_bypass_gkw+ [70,2]*q_centr_gkw_to_bka)/ (q_bka_gkw+0.001) Tin_bka_cv = (Tret_bka_cv*q_bka_bypass_cv+ [70,4]*q_centr_cv_to_bka)/ (q_bka_cv+0.001) *$UNIT_NAME centraal BKA net *$LAYER Main *$POSITION 596 818 *------------------------------------------------------------------------------ * EQUATIONS "regeling WP+buffer" * EQUATIONS 14 !deg C Tverd_spec = Tin_verd_spec-((Tin_verd_spec-Tuit_verd_spec)/ rend_verd) !deg C Tcond_spec = Tin_cond_spec-((Tin_cond_spec-Tuit_cond_spec)/ rend_cond) !deg C Tcond_act = warmtevraag_leidend*([64,1]- (([64,1]-Tstook_cv_net)/rend_cond))+ koudevraag_leidend*([64,1]- (([64,1]-Tuit_cond_spec)/rend_cond))+ (1-(koudevra ag_leidend+warmtevraag_leidend))* ([64,1]-(([64,1]-Tstook_cv_net)/ rend_cond)) !- COP_actueel = 1+((Tverd_spec+273.15)/(Tcond_act-Tverd_spec))* rend_wp_isotr_el_wri !W Pwp_verd_kvr_leidend = min(max((koudevraag_leidend*(q_gkw_lbk_bka/3600)* warmtecap_water*([76,1]-Tstook_gkw_net)),0), Pwp_verd_max) !W Pwp_verd_wvr_leidend = min(max(warmtevraag_leidend* (Pwp_cond_wvr_leidend-(Pwp_cond_wvr_leidend/COP_actueel)),0), Pwp_verd_max) !W Pwp_cond_kvr_leidend = min(max(koudevraag_leidend*(Pwp_verd_kvr_leidend+ (Pwp_verd_kvr_leidend/(COP_actueel-1))),0),Pwp_cond_max) !W Pwp_cond_wvr_leidend = min(max(warmtevraag_leidend*(q_cv_lbk_bka/3600)* warmtecap_water*(Tstook_cv_net-[64,1]),0), Pwp_cond_max) Pwp_verd = max(Pwp_verd_kvr_leidend,Pwp_verd_wvr_leidend) Pwp_cond = max(Pwp_cond_kvr_leidend,Pwp_cond_wvr_leidend) !kg/hr q_gkw_wp_verd = min(max((koudevraag_leidend*q_gkw_lbk_bka)+ (warmtevraag_leidend*((Pwp_verd*3600)/ (warmtecap_water*([76,1]-Tuit_verd_spec+0.001)))),0), ((Pw p_verd_max*3600)/(warmtecap_water*0.5))) !kg/hr q_cv_wp_cond = min(max(warmtevraag_leidend*q_cv_lbk_bka+ koudevraag_leidend*((Pwp_cond*3600)/ (warmtecap_water*(Tuit_cond_spec-[64,1]+0.001))),0), ((Pwp_cond _max*3600)/(warmtecap_water*0.75))) dTlog_verd = ((Tin_verd_spec-Tverd_spec)-(Tuit_verd_spec-Tverd_spec))/ ln((Tin_verd_spec-Tverd_spec)/ (Tuit_verd_spec-Tverd_spec)) dTlog_cond = warmtevraag_leidend*((([64,1]-Tcond_act)-(Tstook_cv_net-Tcond_act))/ max(ln(max([64,1]-Tcond_act,0.5)/ max(Tuit_verd_spec-Tcond_act,0.4)),0.1))+ koudevraag_leidend*((([64,1]-Tcond_act)-(Tuit_cond_spec-Tcond_act))/ max(ln(max([64,1]-Tcond_act,0.5)/ max(Tuit_cond_spec-Tcond_act,0.4)),0.1))+ (1-(koudevr aag_leidend+warmtevraag_leidend))* ((([64,1]-Tcond_act)-(Tstook_cv_net-Tcond_act))/ max(ln(max([64,1]-Tcond_act,0.5)/ max(Tstook_cv_net-Tcond_act,0.4)),0.1)) *$UNIT_NAME regeling WP+buffer *$LAYER Main *$POSITION 1253 541 *------------------------------------------------------------------------------ * EQUATIONS "centraal GKW & CV net" * EQUATIONS 21 !kg/hr q_gkw_bka = q_centr_gkw_to_bka !kg/hr q_cv_bka = q_centr_cv_to_bka !kg/hr q_gkw_lbk = gt(Pkoel_LBK,0)*q_lbk_gkw*dichtheid_water !kg/hr q_cv_lbk = gt(Pverw_LBK,0)*q_lbk_cv*dichtheid_water !deg C Tret_gkw_bka = Tret_bka_gkw !deg C Tret_cv_bka = Tret_bka_cv !deg C Tret_gkw_lbk = gt(Pkoel_LBK,0)*Tret_lbk_water_gkw !deg C Tret_cv_lbk = gt(Pverw_LBK,0)*Tret_lbk_water_cv !kg/hr q_cv_lbk_bka = q_cv_bka+q_cv_lbk !kg/hr q_gkw_lbk_bka = q_gkw_bka+q_gkw_lbk !deg C Tret_cv = min(max((Tret_cv_bka*q_cv_bka+Tret_cv_lbk*q_cv_lbk)/ (q_cv_bka+q_cv_lbk+0.001),10),50) !deg C Tret_gkw = min(max((Tret_gkw_bka*q_gkw_bka+Tret_gkw_lbk*q_gkw_lbk)/ (q_gkw_bka+q_gkw_lbk+0.001),5),40) warmtevraag_cv_net = gt(q_cv_lbk_bka,0) koudevraag_gkw_net = gt(q_gkw_lbk_bka,0) !W Pverw_cv = max(warmtevraag_cv_net* warmtecap_water* (Tstook_cv_net-Tret_cv)*(q_cv_lbk_bka/3600),0) !W Pkoel_gkw = max(koudevraag_gkw_net*warmtecap_water* (Tret_gkw-Tstook_gkw_net)*(q_gkw_lbk_bka/3600),0) !deg C Taanv_gkw_na_wko = min(max(koudevraag_leidend*Tgkw_na_wko+ warmtevraag_leidend*((Tgkw_na_wko*q_tsa_gkw+ Tret_gkw*q_gkw_lbk_bka)/ (q_tsa_gkw+q_gkw_lbk_bka+0.0 01))+ (1-(koudevraag_leidend+warmtevraag_leidend))* ((Tgkw_na_wko*q_tsa_gkw+ Tret_gkw*q_gkw_lbk_bka)/ (q_tsa_gkw+q_gkw_lbk_bka+0.001)),7),25) !deg C Taanv_cv_naar_wp = min(max(warmtevraag_leidend*Tret_cv+ koudevraag_leidend*((Tna_dk*q_tsa_gkw_cv+Tret_cv*q_cv_lbk_bka)/ (q_cv_lbk_bka+q_tsa_gkw_cv+0.001))+ ( 1-(koudevraag_leidend+warmtevraag_leidend))*Tret_cv,18),50) !deg C Tcv_na_wp_cond = min(max((warmtevraag_leidend+koudevraag_leidend)* (Taanv_cv_naar_wp+ ((Pwp_cond*3600)/(warmtecap_water*q_cv_wp_cond+0.001)))+ (1-(warmtevraa g_leidend+koudevraag_leidend))* Taanv_cv_naar_wp,18),50) !deg C Taanv_gkw = min(max( koudevraag_leidend*(Taanv_gkw_na_wko-((Pwp_verd*3600)/ (warmtecap_water*q_gkw_lbk_bka+0.001)))+ warmtevraag_leidend*Tuit_verd_spec+ (1- (warmtevraag_leidend+koudevraag_leidend))* (Taanv_gkw_na_wko*le(q_tsa_gkw_cv,0)+ Tna_dk*gt(q_tsa_gkw_cv,0)),5),25) !deg C Taanv_cv = min(max(Tcv_na_wp_cond+ (P_ketel/((q_cv_lbk_bka/3600)* warmtecap_water+0.001)),18),50) *$UNIT_NAME centraal GKW & CV net *$LAYER Main *$POSITION 827 552 *------------------------------------------------------------------------------ * EQUATIONS "flows kvbatterij" * EQUATIONS 13 !deg C Tmedium_in_kbat = min(max([70,2],4),30) !deg C Tmedium_in_vbat = min(max([70,4],15),50) qvent_kbat = gt(Tair_na_wwiel,Tvent_LBK_gewenst)*q_vent qvent_vbat = lt(Tair_na_wwiel,Tvent_LBK_gewenst)*q_vent Pkoel_lbk_nodig = max(dichtheid_lucht*(qvent_kbat/3600)* (Enthalpie_na_wwiel-([85,3]*1000)),0) Pverw_lbk_nodig = max(dichtheid_lucht*(qvent_vbat/3600)*warmtecap_lucht* (Tvent_LBK_gewenst-Tair_na_wwiel),0) Pkoel_lbk_kbat = min(Pkoel_lbk_nodig,Pmax_lbk_kbat) Pverw_lbk_vbat = min(Pverw_lbk_nodig,Pmax_lbk_vbat) !K dT_wwiss_kvbatterij = 0.5 Tmedium_uit_kbat = max(Tvent_LBK_gewenst-dT_wwiss_kvbatterij,Tmedium_in_kbat) Tmedium_uit_vbat = min(Tvent_LBK_gewenst+dT_wwiss_kvbatterij,Tmedium_in_vbat) !m^3/h Q_medium_in_kbat = min(max((Pkoel_lbk_kbat*3600)/ (dichtheid_water*warmtecap_water* (Tmedium_uit_kbat-Tmedium_in_kbat+0.001)),0), (Pmax_lbk_kbat*3600)/(warmt ecap_water*dichtheid_water*2)) !m^3/h Q_medium_in_vbat = min(max((Pverw_lbk_vbat*3600)/ (dichtheid_water*warmtecap_water* (Tmedium_in_vbat-Tmedium_uit_vbat)+0.001),0), (Pmax_lbk_vbat*3600)/(warmt ecap_water*dichtheid_water*2)) *$UNIT_NAME flows kvbatterij *$LAYER Main *$POSITION 534 275 *------------------------------------------------------------------------------ * EQUATIONS "return air naar LBK" * EQUATIONS 3 !deg C Tair_return = min(max(((ventvoud_A*luchtvolume_A*[56,32] +ventvoud_B*luchtvolume_B*[56,22] +ventvoud_C*luchtvolume_C*[56,11] +ventvoud_D*luchtvolume_D*[56,1] )/(q_vent+0.001)) +opwarming_fan,0),40) !% RHair_return = min(max((ventvoud_A*luchtvolume_A*[56,42] +ventvoud_B*luchtvolume_B*[56,31] +ventvoud_C*luchtvolume_C*[56,21] +ventvoud_D*luchtvolume_D*[56,10 ])/(q_vent+0.001),0),100) !deg C opwarming_fan = 1 *$UNIT_NAME return air naar LBK *$LAYER Main *$POSITION 529 189 *------------------------------------------------------------------------------ * EQUATIONS "stooklijn Tvent & qvent" * EQUATIONS 15 X1_vent = -5 Y1_vent = 20 X2_vent = 20 Y2_vent = 18 !deg C Tmaximum = 22 !deg C Tminimum = 16 !deg C Tstooklijn_lbk = min(max(Y1_vent-(([331,7]-X1_vent)/(X2_vent-X1_vent))* (Y1_vent-Y2_vent),Tminimum),Tmaximum) Tair_gewenst = 21 !deg C Tvent_LBK_gewenst = Tstooklijn_lbk !1/h ventvoud_A = min(max(1.35*[56,32]-27.85,0.5)+ [56,44]*0.5,3.2)*[56,45] !1/h ventvoud_B = min(max(0.05*[56,22]+0.9,1.9),2)*[56,45] !1/h ventvoud_C = min(max(0.05*[56,11]+0.9,1.9),2)*[56,45] !1/h ventvoud_D = min(max(0.05*[56,1]+0.9,1.9),2)*[56,45] !m^3/h q_vent = (ventvoud_A*luchtvolume_A*aantal_zones_A)+ (ventvoud_B*luchtvolume_B*aantal_zones_B)+ (ventvoud_C*luchtvolume_C*aantal_zones_C)+ (ventvoud_D*luchtvo lume_D*aantal_zones_D) !% RH_air_gewenst = 50 *$UNIT_NAME stooklijn Tvent & qvent *$LAYER Luchtbehandelingskast *$POSITION 379 189 *------------------------------------------------------------------------------ * EQUATIONS "BKA-net Groep A" * EQUATIONS 7 !kJ/hr Qcomb_plaat_A = ([56,34]+[56,35])/aantal_bka_platen_A !kJ/hr Qabs_plaat_A = [56,36]/aantal_bka_platen_A !kg/hr q_bka_water_A = (koelen_A+verwarmen_A)*q_max_bka_plaat_A !deg C Tin_bka_A = max(verwarmen_A*Tin_bka_cv,koelen_A*Tin_bka_gkw) !deg C Tuit_bka_A = [46,1] verwarmen_A = [33,1]*[56,48] koelen_A = [48,1]*[56,47] *$UNIT_NAME BKA-net Groep A *$LAYER Betonkernactivering *$POSITION 595 1304 *------------------------------------------------------------------------------ * EQUATIONS "BKA-net Groep B" * EQUATIONS 7 !kJ/hr Qcomb_plaat_B = ([56,24]+[56,25])/aantal_bka_platen_B !kJ/hr Qabs_plaat_B = [56,26]/aantal_bka_platen_B !kg/hr q_bka_water_B = (koelen_B+verwarmen_B)*q_max_bka_plaat_B !deg C Tin_bka_B = max(verwarmen_B*Tin_bka_cv,koelen_B*Tin_bka_gkw) !deg C Tuit_bka_B = [43,1] verwarmen_B = [32,1]*[56,48] koelen_B = [45,1]*[56,47] *$UNIT_NAME BKA-net Groep B *$LAYER Betonkernactivering *$POSITION 595 1197 *------------------------------------------------------------------------------ * EQUATIONS "BKA-net Groep C" * EQUATIONS 7 !kJ/hr Qcomb_plaat_C = ([56,13]+[56,14])/aantal_bka_platen_C !kJ/hr Qabs_plaat_C = [56,15]/aantal_bka_platen_C !kg/hr q_bka_water_C = (koelen_C+verwarmen_C)*q_max_bka_plaat_C !deg C Tin_bka_C = max(verwarmen_C*Tin_bka_cv,koelen_C*Tin_bka_gkw) !deg C Tuit_bka_C = [40,1] verwarmen_C = [28,1]*[56,48] koelen_C = [42,1]*[56,47] *$UNIT_NAME BKA-net Groep C *$LAYER Betonkernactivering *$POSITION 593 1090 *------------------------------------------------------------------------------ * EQUATIONS "BKA-net Groep D" * EQUATIONS 7 !kJ/hr Qcomb_plaat_D = ([56,3]+[56,4])/aantal_bka_platen_D !kJ/hr Qabs_plaat_D = [56,5]/aantal_bka_platen_D !kg/hr q_bka_water_D = (koelen_D+verwarmen_D)*q_max_bka_plaat_D !deg C Tin_bka_D = max(verwarmen_D*Tin_bka_cv,koelen_D*Tin_bka_gkw) !deg C Tuit_bka_D = [37,1] verwarmen_D = [27,1]*[56,48] koelen_D = [39,1]*[56,47] *$UNIT_NAME BKA-net Groep D *$LAYER Betonkernactivering *$POSITION 595 994 *------------------------------------------------------------------------------ * EQUATIONS "vermogen WKO, ketel" * EQUATIONS 6 !W Pontlaad_max_wko = max((q_max_wko/3600)*warmtecap_water* (Tmax_injectie_wko_wb-[66,4]),0) !W Pontlaad_min_wko = max((q_min_wko/3600)*warmtecap_water*dT_wko_min_wb_kb,0) !W Pladen_max_wko = max((q_max_wko/3600)*warmtecap_water* ([66,5]-Tmin_injectie_wko_kb),0) !W P_wko_ontladen = koudevraag_leidend*gt(Pkoel_gkw*3600,Pontlaad_min_wko*300)* min(Pkoel_gkw,Pontlaad_max_wko) !W P_wko_laden = max(warmtevraag_leidend*(Pwp_verd+Pdk_actueel-Pkoel_gkw)+ (1-(warmtevraag_leidend+koudevraag_leidend))* Pdk_actueel,0) !W P_ketel = warmtevraag_leidend*min(max((Tstook_cv_net-Tcv_na_wp_cond)* (q_cv_lbk_bka/3600)*warmtecap_water,0),Pketel_max) *$UNIT_NAME vermogen WKO, ketel *$LAYER Main *$POSITION 1042 639 *------------------------------------------------------------------------------ * EQUATIONS "regeling WKO" * EQUATIONS 19 system_state_wko = gt(P_wko_laden,0)+ gt(P_wko_ontladen,0)*-1 !K dT_tsa_wko = abs([82,2])*0.95 !deg C Tin_tsa_gkw = max(le(system_state_wko,0)*Tret_gkw+ gt(system_state_wko,0)*[70,1],4) !deg C Tin_tsa_wko = min(max(gt(system_state_wko,0)*[66,5]+ lt(system_state_wko,0)*[66,4],[66,4]-0.5), [66,5]+0.5) !kg/h q_tsa_gkw = max(le(system_state_wko,0)*q_gkw_lbk_bka+ gt(system_state_wko,0)* (q_tsa_gkw_cv+q_gkw_wp_verd-q_gkw_lbk_bka),0) !kg/h q_tsa_wko = min(max(max(((P_wko_ontladen*3600)/ (warmtecap_water*(Tin_tsa_gkw- ([66,4]+dT_tsa_wko))+0.001)), ((P_wko_laden*3600)/(warmtecap_water* ([66,5]-( Tin_tsa_gkw+dT_tsa_wko))+0.001))),0), min(q_tsa_gkw,q_max_wko)) !deg C Tuit_tsa_gkw = max(gt(system_state_wko,0)*([66,5]-dT_tsa_wko)+ lt(system_state_wko,0)*([66,4]+dT_tsa_wko),4) !deg C Tinjectie_wko = max(gt(system_state_wko,0)*([70,1]+dT_tsa_wko)+ lt(system_state_wko,0)*(Tret_gkw-dT_tsa_wko),4) !deg C Tgkw_na_wko = gt(q_tsa_wko,0)*Tuit_tsa_gkw+ le(q_tsa_wko,0)*Tin_tsa_gkw !kWh energie_ontladen = max(lt(system_state_wko,0)*q_tsa_wko*warmtecap_water* (Tinjectie_wko-Tin_tsa_wko)/3600000,0) !kWh energie_laden = max(gt(system_state_wko,0)*q_tsa_wko*warmtecap_water* (Tin_tsa_wko-Tinjectie_wko)/3600000,0) !W P_ontladen_actueel = lt(system_state_wko,0)*(q_tsa_wko/3600)*warmtecap_water* (Tinjectie_wko-Tin_tsa_wko) !W P_laden_actueel = gt(system_state_wko,0)*(q_tsa_wko/3600)*warmtecap_water* (Tin_tsa_wko-Tinjectie_wko) !m^2 Area_tsa = 7 !W/m^2K k_tsa_vollast = 4300 f_k = (1/k_tsa_vollast)/ (exp(-0.68*ln(q_max_wko/dichtheid_water/3600))+ exp(-0.68*ln(q_max_wko/dichtheid_water/3600))+0.000001) !W/m^2K k_tsa_deellast = gt(q_tsa_wko,0)*gt(q_tsa_gkw,0)* (1/(f_k*(exp(-0.68*ln((q_tsa_gkw/dichtheid_water/3600)+0.00001))+ exp(-0.68*ln((q_tsa_wko/dichtheid_water/36 00)+0.00001)))+0.000001)) !kJ/hrK kA_tsa_actueel = (k_tsa_deellast*Area_tsa*3600)/1000 dT_tsa_wko_berek = max(min( gt(system_state_wko,0)* (abs(abs(Tin_tsa_wko-[68,1])- abs([68,3]-Tin_tsa_gkw))/ (ln(abs(Tin_tsa_wko-[68,1]+0.0001)/ abs([68,3]- Tin_tsa_gkw+0.0001))+0.0001))+ lt(system_state_wko,0)* (abs(abs(Tin_tsa_gkw-[68,3])- abs([68,1]-Tin_tsa_wko))/ (ln(abs(Tin_tsa_gkw-[68,3]+0.0001)/ abs([68, 1]-Tin_tsa_wko+0.0001))+0.0001)) ,1.5),1) *$UNIT_NAME regeling WKO *$LAYER Main *$POSITION 1253 639 *------------------------------------------------------------------------------ * EQUATIONS "stooklijn Tgkw net" * EQUATIONS 3 Twater_LBK_gew_gkw = ((Tvent_LBK_gewenst-2-1)*2)-Tvent_LBK_gewenst Twater_BKA_gew_gkw = Tstook_bka_gkw_gecom !deg C Tstook_gkw_net = min(max(min(Twater_BKA_gew_gkw,Twater_LBK_gew_gkw), ([66,4]+dT_tsa_wko)*koudevraag_leidend*0),20) *$UNIT_NAME stooklijn Tgkw net *$LAYER Main *$POSITION 828 458 *------------------------------------------------------------------------------ * EQUATIONS "stooklijn Tcv net" * EQUATIONS 3 Twater_LBK_gew_cv = ((Tvent_LBK_gewenst+2+1)*2)-Tvent_LBK_gewenst Twater_BKA_gew_cv = Tstook_bka_cv_gecomp !deg C Tstook_cv_net = min(max(Twater_BKA_gew_cv,Twater_LBK_gew_cv),50) *$UNIT_NAME stooklijn Tcv net *$LAYER Main *$POSITION 829 383 *------------------------------------------------------------------------------ * Model "koelvraag D" (Type 2) * UNIT 39 TYPE 2 D *$UNIT_NAME koelvraag D *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 742 994 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! Standaard kantoor: 1- TAIR_GROEP_D ->Upper input temperature Th ! schakeling bka vraag:inschakelwaarde_koel ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! koelvraag D:Output control function ->Input control function ! schakeling bka vraag:dT_koel_aan ->Upper dead band dT ! schakeling bka vraag:dT_koel_uit ->Lower dead band dT 56,1 INSCHAKELWAARDE_KOEL CONST 39,1 DT_KOEL_AAN DT_KOEL_UIT *** INITIAL INPUT VALUES 2.0000000000000000E+01 2.2000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "koelvraag C" (Type 2) * UNIT 42 TYPE 2 C *$UNIT_NAME koelvraag C *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 740 1084 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! Standaard kantoor: 11- TAIR_GROEP_C ->Upper input temperature Th ! schakeling bka vraag:inschakelwaarde_koel ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! koelvraag C:Output control function ->Input control function ! schakeling bka vraag:dT_koel_aan ->Upper dead band dT ! schakeling bka vraag:dT_koel_uit ->Lower dead band dT 56,11 INSCHAKELWAARDE_KOEL CONST 42,1 DT_KOEL_AAN DT_KOEL_UIT *** INITIAL INPUT VALUES 2.0000000000000000E+01 2.2000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "koelvraag B" (Type 2) * UNIT 45 TYPE 2 B *$UNIT_NAME koelvraag B *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 740 1191 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! Standaard kantoor: 22- TAIR_GROEP_B ->Upper input temperature Th ! schakeling bka vraag:inschakelwaarde_koel ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! koelvraag B:Output control function ->Input control function ! schakeling bka vraag:dT_koel_aan ->Upper dead band dT ! schakeling bka vraag:dT_koel_uit ->Lower dead band dT 56,22 INSCHAKELWAARDE_KOEL CONST 45,1 DT_KOEL_AAN DT_KOEL_UIT *** INITIAL INPUT VALUES 2.0000000000000000E+01 2.2000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "koelvraag A" (Type 2) * UNIT 48 TYPE 2 A *$UNIT_NAME koelvraag A *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 740 1298 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! Standaard kantoor: 32- TAIR_GROEP_A ->Upper input temperature Th ! schakeling bka vraag:inschakelwaarde_koel ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! koelvraag A:Output control function ->Input control function ! schakeling bka vraag:dT_koel_aan ->Upper dead band dT ! schakeling bka vraag:dT_koel_uit ->Lower dead band dT 56,32 INSCHAKELWAARDE_KOEL CONST 48,1 DT_KOEL_AAN DT_KOEL_UIT *** INITIAL INPUT VALUES 2.0000000000000000E+01 2.2000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "verwarmvraag D" (Type 2) * UNIT 27 TYPE 2 D *$UNIT_NAME verwarmvraag D *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 885 988 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! schakeling bka vraag:inschakelwaarde_verw ->Upper input temperature Th ! Standaard kantoor: 1- TAIR_GROEP_D ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! verwarmvraag D:Output control function ->Input control function ! schakeling bka vraag:dT_verw_aan ->Upper dead band dT ! schakeling bka vraag:dT_verw_uit ->Lower dead band dT INSCHAKELWAARDE_VERW 56,1 CONST 27,1 DT_VERW_AAN DT_VERW_UIT *** INITIAL INPUT VALUES 2.0500000000000000E+01 2.0000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "verwarmvraag C" (Type 2) * UNIT 28 TYPE 2 C *$UNIT_NAME verwarmvraag C *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 888 1084 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! schakeling bka vraag:inschakelwaarde_verw ->Upper input temperature Th ! Standaard kantoor: 11- TAIR_GROEP_C ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! verwarmvraag C:Output control function ->Input control function ! schakeling bka vraag:dT_verw_aan ->Upper dead band dT ! schakeling bka vraag:dT_verw_uit ->Lower dead band dT INSCHAKELWAARDE_VERW 56,11 CONST 28,1 DT_VERW_AAN DT_VERW_UIT *** INITIAL INPUT VALUES 2.0500000000000000E+01 2.0000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "verwarmvraag B" (Type 2) * UNIT 32 TYPE 2 B *$UNIT_NAME verwarmvraag B *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 888 1191 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! schakeling bka vraag:inschakelwaarde_verw ->Upper input temperature Th ! Standaard kantoor: 22- TAIR_GROEP_B ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! verwarmvraag B:Output control function ->Input control function ! schakeling bka vraag:dT_verw_aan ->Upper dead band dT ! schakeling bka vraag:dT_verw_uit ->Lower dead band dT INSCHAKELWAARDE_VERW 56,22 CONST 32,1 DT_VERW_AAN DT_VERW_UIT *** INITIAL INPUT VALUES 2.0500000000000000E+01 2.0000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "verwarmvraag A" (Type 2) * UNIT 33 TYPE 2 A *$UNIT_NAME verwarmvraag A *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 885 1298 *$LAYER Betonkernactivering # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! schakeling bka vraag:inschakelwaarde_verw ->Upper input temperature Th ! Standaard kantoor: 32- TAIR_GROEP_A ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! verwarmvraag A:Output control function ->Input control function ! schakeling bka vraag:dT_verw_aan ->Upper dead band dT ! schakeling bka vraag:dT_verw_uit ->Lower dead band dT INSCHAKELWAARDE_VERW 56,32 CONST 33,1 DT_VERW_AAN DT_VERW_UIT *** INITIAL INPUT VALUES 2.0500000000000000E+01 2.0000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 -1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "output_wp_dk" (Type 65) * UNIT 84 TYPE 65 *$UNIT_NAME output_wp_dk *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1710 178 *$LAYER OutputSystem # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 1.0000000000000000E+03 0.0000000000000000E+00 1.5000000000000000E+01 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 9.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! regeling WP+buffer:Pwp_verd ->Left axis variable-1 ! regeling WP+buffer:Pwp_cond ->Left axis variable-2 ! regeling WP+buffer:q_gkw_wp_verd ->Left axis variable-3 ! regeling WP+buffer:q_cv_wp_cond ->Left axis variable-4 ! regeling DK:Pdk_actueel ->Left axis variable-5 ! regeling DK:Pkoel_dk ->Left axis variable-6 ! energiebalans:energie_balans ->Left axis variable-7 ! centraal BKA net:Tin_bka_gkw ->Left axis variable-8 ! centraal BKA net:Tin_bka_cv ->Left axis variable-9 ! regeling WP+buffer:Tverd_spec ->Left axis variable-10 ! regeling WP+buffer:COP_actueel ->Right axis variable-1 ! regeling WP+buffer:dTlog_verd ->Right axis variable-2 ! regeling WP+buffer:dTlog_cond ->Right axis variable-3 ! regeling WP+buffer:Tcond_spec ->Right axis variable-4 ! regeling DK:koude_laden_wko_dk ->Right axis variable-5 ! regeling DK:Tin_tsa_gkw_cv ->Right axis variable-6 ! regeling DK:q_tsa_gkw_cv ->Right axis variable-7 ! regeling DK:Tna_dk_gewenst ->Right axis variable-8 ! regeling DK:Tna_dk ->Right axis variable-9 ! regeling WP+buffer:Tcond_act ->Right axis variable-10 PWP_VERD PWP_COND Q_GKW_WP_VERD Q_CV_WP_COND PDK_ACTUEEL PKOEL_DK ENERGIE_BALANS TIN_BKA_GKW TIN_BKA_CV TVERD_SPEC COP_ACTUEEL DTLOG_VERD DTLOG_COND TCOND_SPEC KOUDE_LADEN_WKO_DK TIN_TSA_GKW_CV Q_TSA_GKW_CV TNA_DK_GEWENST TNA_DK TCOND_ACT *** INITIAL INPUT VALUES Pwp_verd Pwp_cond q_gkw_wp_v erd q_cv_ wp_cond Pdk_actueel Pkoel_dk Energie_balans Tin_bka_gk w Tin_b ka_cv Tverd_spec COP_actueel dTlog_verd dTlog_cond Tcond _spec koude_laden_wko_dk Tin_tsa_gkw_cv q_tsa_gkw_cv Tna_dk_gew enst Tna_d k Tcond_act LABELS 3 Temperatures Heat transfer rates WP_DK *** External files ASSIGN output_wp.txt 90 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * Model "klep naar centraal gkw net" (Type 2) * UNIT 88 TYPE 2 naar centraal gkw net *$UNIT_NAME klep naar centraal gkw net *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 742 823 *$LAYER Main # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! centraal BKA net:Tret_bka_gkw ->Upper input temperature Th ! stooklijn Tbka koelen:Tstook_bka_gkw_gecom ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! klep naar centraal gkw net:Output control function ->Input control function ! [unconnected] Upper dead band dT ! [unconnected] Lower dead band dT TRET_BKA_GKW TSTOOK_BKA_GKW_GECOM CONST ERD 88,1 CONST L CONST *** INITIAL INPUT VALUES 2.0500000000000000E+01 2.0000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 5.0000000000000000E-01 1.0000000000000001E-01 *------------------------------------------------------------------------------ * Model "klep naar centraal cv net" (Type 2) * UNIT 87 TYPE 2 naar centraal cv net *$UNIT_NAME klep naar centraal cv net *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 885 823 *$LAYER Main # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.0000000000000000E+02 INPUTS 6 ! stooklijn Tbka verwarmen:Tstook_bka_cv_gecomp ->Upper input temperature Th ! centraal BKA net:Tret_bka_cv ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! klep naar centraal cv net:Output control function ->Input control function ! [unconnected] Upper dead band dT ! [unconnected] Lower dead band dT TSTOOK_BKA_CV_GECOMP TRET_BKA_CV CONST ERD 87,1 CONST L CONST *** INITIAL INPUT VALUES 2.0500000000000000E+01 2.0000000000000000E+01 4.0000000000000000E+01 0.0000000000000000E+00 2.0000000000000000E+00 5.0000000000000000E-01 *------------------------------------------------------------------------------ * Model "Standaard kantoor" (Type 56) * UNIT 56 TYPE 56 kantoor *$UNIT_NAME Standaard kantoor *$MODEL .\Loads and Structures\Multi-Zone Building\With Standard Output Files\Type56a.tmf *$POSITION 376 573 *$LAYER Gebouw # *$# PARAMETERS 6 ! 1 Logical unit for building description file (.bui) ! 2 Star network calculation switch ! 3 Weighting factor for operative temperature ! 4 Logical unit for monthly summary ! 5 Logical unit for hourly temperatures ! 6 Logical unit for hourly loads 8.2000000000000000E+01 1.0000000000000000E+00 5.0000000000000000E-01 8.3000000000000000E+01 8.4000000000000000E+01 8.5000000000000000E+01 INPUTS 39 ! Mollier buiten:Dry bulb temperature -> 1- TAMB ! Mollier buiten:Percent relative humidity -> 2- RELHUMAMB ! temp uitspansel:Fictive sky temperature -> 3- TSKY ! Straling:IT_N -> 4- IT_NORTH ! Straling:IT_W -> 5- IT_WEST ! Straling:IT_H -> 6- IT_HORIZONT ! Straling:IT_S -> 7- IT_SOUTH ! Straling:IT_E -> 8- IT_EAST ! Straling:IB_N -> 9- IB_NORTH ! Straling:IB_W -> 10- IB_WEST ! Straling:IB_H -> 11- IB_HORIZONT ! Straling:IB_S -> 12- IB_SOUTH ! Straling:IB_E -> 13- IB_EAST ! Straling:AI_N -> 14- AI_NORTH ! Straling:AI_W -> 15- AI_WEST ! Straling:AI_H -> 16- AI_HORIZONT ! Straling:AI_S -> 17- AI_SOUTH ! Straling:AI_E -> 18- AI_EAST ! [unconnected] 19- CNAT_1 ! [unconnected] 20- T_COOL_ON ! [unconnected] 21- S_NORTH ! [unconnected] 22- S_SOUTH ! [unconnected] 23- S_EAST ! [unconnected] 24- S_WEST ! [unconnected] 25- BRIGHT ! Groep D:average mean temperature of the ceiling -> 26- T_OPP_BKA_D ! Groep C:average mean temperature of the ceiling -> 27- T_OPP_BKA_C ! Groep B:average mean temperature of the ceiling -> 28- T_OPP_BKA_B ! Groep A:average mean temperature of the ceiling -> 29- T_OPP_BKA_A ! Groep D:convective heat transfer coefficient on the ceiling surface -> 30- ALPHA_BKA_D ! Groep C:convective heat transfer coefficient on the ceiling surface -> 31- ALPHA_BKA_C ! Groep B:convective heat transfer coefficient on the ceiling surface -> 32- ALPHA_BKA_B ! Groep A:convective heat transfer coefficient on the ceiling surface -> 33- ALPHA_BKA_A ! stooklijn Tvent & qvent:ventvoud_A -> 34- A_VENT_VOUD ! stooklijn Tvent & qvent:ventvoud_B -> 35- B_VENT_VOUD ! stooklijn Tvent & qvent:ventvoud_C -> 36- C_VENT_VOUD ! stooklijn Tvent & qvent:ventvoud_D -> 37- D_VENT_VOUD ! stooklijn clo:clo -> 38- CLO ! T en R.V. uit LBK & Power:Tair_uit_LBK -> 39- TINBLAAS_VENT_LU 331,7 331,6 69,1 IT_N IT_W IT_H IT_S IT_E IB_N IB_W IB_H IB_S IB_E AI_N AI_W AI_H AI_S AI_E CONST CONST CONST CONST CONST CONST CONST 37,5 40,5 43,5 46,5 37,12 40,12 43,12 46,12 VENTVOUD_A VENTVOUD_B VENTVOUD_C VENTVOUD_D CLO TAIR_UIT_LBK *** INITIAL INPUT VALUES 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 *** External files ASSIGN Standaard_kantoor_abcd.BUI 82 *|? Building description file (*.bui) |1000 ASSIGN Bldg-Monthly.out 83 *|? Monthly Summary File |1000 ASSIGN Bldg-HourlyTemp.out 84 *|? Hourly Temperatures |1000 ASSIGN Bldg-HourlyLoads.out 85 *|? Hourly Loads |1000 *------------------------------------------------------------------------------ * EQUATIONS "warmtewiel" * EQUATIONS 4 Etha_wwiel_latent = .65 Etha_wwiel_sensible = .75 !deg C Tair_na_wwiel = min(max(Etha_wwiel_sensible* (Tair_return-[331,7])+[331,7],0),40) !J/kg Enthalpie_na_wwiel = max((Etha_wwiel_latent* ([50,3]-[331,3])+ [331,3])*1000,0) *$UNIT_NAME warmtewiel *$LAYER Main *$POSITION 678 189 *------------------------------------------------------------------------------ * Model "output_bka_2" (Type 65) * UNIT 91 TYPE 65 *$UNIT_NAME output_bka_2 *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1729 744 *$LAYER Main # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 1.0000000000000000E+03 0.0000000000000000E+00 1.0000000000000000E+03 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 9.2000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! centraal BKA net:Tin_bka_gkw ->Left axis variable-1 ! centraal BKA net:Tin_bka_cv ->Left axis variable-2 ! centraal BKA net:q_centr_gkw_to_bka ->Left axis variable-3 ! centraal BKA net:q_centr_cv_to_bka ->Left axis variable-4 ! BKA-net Groep A:Tin_bka_A ->Left axis variable-5 ! BKA-net Groep A:q_bka_water_A ->Left axis variable-6 ! BKA-net Groep A:Tuit_bka_A ->Left axis variable-7 ! BKA-net Groep B:q_bka_water_B ->Left axis variable-8 ! BKA-net Groep B:Tin_bka_B ->Left axis variable-9 ! BKA-net Groep B:Tuit_bka_B ->Left axis variable-10 ! BKA-net Groep C:q_bka_water_C ->Right axis variable-1 ! BKA-net Groep C:Tin_bka_C ->Right axis variable-2 ! BKA-net Groep C:Tuit_bka_C ->Right axis variable-3 ! BKA-net Groep D:q_bka_water_D ->Right axis variable-4 ! BKA-net Groep D:Tin_bka_D ->Right axis variable-5 ! BKA-net Groep D:Tuit_bka_D ->Right axis variable-6 ! TSA-WKO:Heat transfer rate ->Right axis variable-7 ! TSA-WKO:Effectiveness ->Right axis variable-8 ! [unconnected] Right axis variable-9 ! [unconnected] Right axis variable-10 TIN_BKA_GKW TIN_BKA_CV Q_CENTR_GKW_TO_BKA Q_CENTR_CV_TO_BKA TIN_BKA_A Q_BKA_WATER_A TUIT_BKA_A Q_BKA_WATER_B TIN_BKA_B TUIT_BKA_B Q_BKA_WATER_C TIN_BKA_C TUIT_BKA_C Q_BKA_WATER_D TIN_BKA_D TUIT_BKA_D 68,5 68,6 CONST CONST *** INITIAL INPUT VALUES Tin_bka_gkw Tin_bka_cv q_centr_gk w_to_bka q_cen tr_cv_to_bka Tin_bka_A q_bka_water_A Tuit_bka_A q_bka_wate r_B Tin_b ka_B Tuit_bka_B q_bka_water_C Tin_bka_C Tuit_bka_C q_bka _water_D Tin_bka_D Tuit_bka_D Heat_tsa_wko Eff_tsa_wk o label label LABELS 3 Temperatures Heat transfer rates OUTPUT_BKA_2 *** External files ASSIGN output_bka_2.txt 92 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * Model "delay in Taanv_gkw_na_wko" (Type 93) * UNIT 76 TYPE 93 in Taanv_gkw_na_wko *$UNIT_NAME delay in Taanv_gkw_na_wko *$MODEL .\Utility\Input Value Recall\Type93.tmf *$POSITION 827 701 *$LAYER Main # PARAMETERS 2 ! 1 Number of inputs to be stored ! 2 Number of timesteps to be stored 1.0000000000000000E+00 2.0000000000000000E+00 INPUTS 1 ! centraal GKW & CV net:Taanv_gkw_na_wko ->Input value TAANV_GKW_NA_WKO *** INITIAL INPUT VALUES 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "delay in Taanv_cv_ naar_ wp" (Type 93) * UNIT 64 TYPE 93 in Taanv_cv_ naar_ wp *$UNIT_NAME delay in Taanv_cv_ naar_ wp *$MODEL .\Utility\Input Value Recall\Type93.tmf *$POSITION 1042 701 *$LAYER Main # PARAMETERS 2 ! 1 Number of inputs to be stored ! 2 Number of timesteps to be stored 1.0000000000000000E+00 2.0000000000000000E+00 INPUTS 1 ! centraal GKW & CV net:Taanv_cv_naar_wp ->Input value TAANV_CV_NAAR_WP *** INITIAL INPUT VALUES 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "output_centr_gkw_cv" (Type 65) * UNIT 81 TYPE 65 *$UNIT_NAME output_centr_gkw_cv *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1719 253 *$LAYER OutputSystem # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 4.0000000000000000E+01 0.0000000000000000E+00 1.0000000000000000E+03 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 8.6000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! centraal GKW & CV net:Tret_gkw_bka ->Left axis variable-1 ! centraal GKW & CV net:Tret_cv_bka ->Left axis variable-2 ! centraal GKW & CV net:Tret_gkw_lbk ->Left axis variable-3 ! centraal GKW & CV net:Tret_cv_lbk ->Left axis variable-4 ! centraal GKW & CV net:Tret_cv ->Left axis variable-5 ! centraal GKW & CV net:Tret_gkw ->Left axis variable-6 ! centraal GKW & CV net:Taanv_gkw ->Left axis variable-7 ! centraal GKW & CV net:Taanv_cv ->Left axis variable-8 ! centraal GKW & CV net:Taanv_gkw_na_wko ->Left axis variable-9 ! centraal GKW & CV net:Taanv_cv_naar_wp ->Left axis variable-10 ! centraal GKW & CV net:q_gkw_bka ->Right axis variable-1 ! centraal GKW & CV net:q_cv_bka ->Right axis variable-2 ! centraal GKW & CV net:q_gkw_lbk ->Right axis variable-3 ! centraal GKW & CV net:q_cv_lbk ->Right axis variable-4 ! centraal GKW & CV net:q_cv_lbk_bka ->Right axis variable-5 ! centraal GKW & CV net:q_gkw_lbk_bka ->Right axis variable-6 ! centraal GKW & CV net:Pverw_cv ->Right axis variable-7 ! centraal GKW & CV net:Pkoel_gkw ->Right axis variable-8 ! warmte- of koudevraag aan WP leidend:warmtevraag_leidend ->Right axis variable-9 ! warmte- of koudevraag aan WP leidend:koudevraag_leidend ->Right axis variable-10 TRET_GKW_BKA TRET_CV_BKA TRET_GKW_LBK TRET_CV_LBK TRET_CV TRET_GKW TAANV_GKW TAANV_CV TAANV_GKW_NA_WKO TAANV_CV_NAAR_WP Q_GKW_BKA Q_CV_BKA Q_GKW_LBK Q_CV_LBK Q_CV_LBK_BKA Q_GKW_LBK_BKA PVERW_CV PKOEL_GKW WARMTEVRAAG_LEIDEND KOUDEVRAAG_LEIDEND *** INITIAL INPUT VALUES Tret_gkw_bka Tret_cv_bka Tret_gkw_l bk Tret_ cv_lbk Tret_cv Tret_gkw Taanv_gkw Taanv_cv Taanv _gkw_na_wko Taanv_cv_naar_wp q_gkw_bka q_cv_bka q_gkw_lbk q_cv_ lbk q_cv_lbk_bka q_gkw_lbk_bka Pverw_cv Pkoel_gkw warmt evraag_leidend koudevraag_leidend LABELS 3 Temperatures Heat transfer rates centr_gkw_cv_net *** External files ASSIGN output_centr_gkw_cv.txt 86 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * Model "delay in Taanv_gkw en cv" (Type 93) * UNIT 70 TYPE 93 in Taanv_gkw en cv *$UNIT_NAME delay in Taanv_gkw en cv *$MODEL .\Utility\Input Value Recall\Type93.tmf *$POSITION 827 639 *$LAYER Main # PARAMETERS 2 ! 1 Number of inputs to be stored ! 2 Number of timesteps to be stored 2.0000000000000000E+00 2.0000000000000000E+00 INPUTS 2 ! centraal GKW & CV net:Taanv_gkw ->Input value-1 ! centraal GKW & CV net:Taanv_cv ->Input value-2 TAANV_GKW TAANV_CV *** INITIAL INPUT VALUES 0.0000000000000000E+00 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "Taanv cv te laag" (Type 2) * UNIT 72 TYPE 2 cv te laag *$UNIT_NAME Taanv cv te laag *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 1042 362 *$LAYER Controls # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.5000000000000000E+00 INPUTS 6 ! stooklijn Tcv net:Tstook_cv_net ->Upper input temperature Th ! centraal GKW & CV net:Tret_cv ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! Taanv cv te laag:Output control function ->Input control function ! warmte- of koudevraag aan WP leidend:dT_cv_aan ->Upper dead band dT ! warmte- of koudevraag aan WP leidend:dT_cv_uit ->Lower dead band dT TSTOOK_CV_NET TRET_CV CONST BK 72,1 DT_CV_AAN DT_CV_UIT *** INITIAL INPUT VALUES 2.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 4.0000000000000000E+00 1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "Taanv gkw te hoog" (Type 2) * UNIT 73 TYPE 2 gkw te hoog *$UNIT_NAME Taanv gkw te hoog *$MODEL .\Controllers\Differential Controller w_ Hysteresis\for Temperatures\Solver 0 (Successive Substitution) Control Strategy\Type2b.tmf *$POSITION 1042 458 *$LAYER Main # *$# NOTE: This control strategy can only be used with solver 0 (Successive substitution) *$# PARAMETERS 2 ! 1 No. of oscillations ! 2 High limit cut-out 5.0000000000000000E+00 1.5000000000000000E+00 INPUTS 6 ! centraal GKW & CV net:Tret_gkw ->Upper input temperature Th ! stooklijn Tgkw net:Tstook_gkw_net ->Lower input temperature Tl ! [unconnected] Monitoring temperature Tin ! Taanv gkw te hoog:Output control function ->Input control function ! warmte- of koudevraag aan WP leidend:dT_gkw_aan ->Upper dead band dT ! warmte- of koudevraag aan WP leidend:dT_gkw_uit ->Lower dead band dT TRET_GKW TSTOOK_GKW_NET CONST BK 73,1 DT_GKW_AAN DT_GKW_UIT *** INITIAL INPUT VALUES 2.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 2.0000000000000000E+00 2.0000000000000001E-01 *------------------------------------------------------------------------------ * EQUATIONS "warmte- of koudevraag aan WP leidend" * EQUATIONS 6 dT_cv_aan = 2 dT_cv_uit = 0.5 dT_gkw_aan = 1.5 dT_gkw_uit = 0.2 warmtevraag_leidend = [72,1]*warmtevraag_cv_net* (1-([73,1]*koudevraag_gkw_net*(1-[72,1]))) koudevraag_leidend = koudevraag_gkw_net*(1-warmtevraag_leidend)*[73,1] *$UNIT_NAME warmte- of koudevraag aan WP leidend *$LAYER Main *$POSITION 1042 543 *------------------------------------------------------------------------------ * Model "output_lbk" (Type 65) * UNIT 89 TYPE 65 *$UNIT_NAME output_lbk *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1710 114 *$LAYER OutputSystem # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 1.0000000000000000E+03 0.0000000000000000E+00 1.0000000000000000E+03 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 8.9000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! flows kvbatterij:Pkoel_lbk_nodig ->Left axis variable-1 ! flows kvbatterij:Pverw_lbk_nodig ->Left axis variable-2 ! flows kvbatterij:Pkoel_lbk_kbat ->Left axis variable-3 ! flows kvbatterij:Pverw_lbk_vbat ->Left axis variable-4 ! Standaard kantoor: 45- SCHED_LBK_WEEK_STD_KANTOO ->Left axis variable-5 ! Standaard kantoor: 43- SCHED_WERKWEEK_STD_KANTOO ->Left axis variable-6 ! Standaard kantoor: 47- SCHED_BKA_K24H ->Left axis variable-7 ! Standaard kantoor: 48- SCHED_BKA_V24H ->Left axis variable-8 ! [unconnected] Left axis variable-9 ! [unconnected] Left axis variable-10 ! flows kvbatterij:Tmedium_uit_kbat ->Right axis variable-1 ! flows kvbatterij:Tmedium_uit_vbat ->Right axis variable-2 ! flows kvbatterij:Q_medium_in_kbat ->Right axis variable-3 ! flows kvbatterij:Q_medium_in_vbat ->Right axis variable-4 ! flows kvbatterij:Tmedium_in_kbat ->Right axis variable-5 ! flows kvbatterij:Tmedium_in_vbat ->Right axis variable-6 ! flows kvbatterij:qvent_kbat ->Right axis variable-7 ! flows kvbatterij:qvent_vbat ->Right axis variable-8 ! [unconnected] Right axis variable-9 ! [unconnected] Right axis variable-10 PKOEL_LBK_NODIG PVERW_LBK_NODIG PKOEL_LBK_KBAT PVERW_LBK_VBAT 56,45 56,43 56,47 56,48 CONST NA_WKO CONST AAR_WP TMEDIUM_UIT_KBAT TMEDIUM_UIT_VBAT Q_MEDIUM_IN_KBAT Q_MEDIUM_IN_VBAT TMEDIUM_IN_KBAT TMEDIUM_IN_VBAT QVENT_KBAT QVENT_VBAT CONST G_LEIDEND CONST _LEIDEND *** INITIAL INPUT VALUES Pkoel_lbk_nodig Pverw_lbk_nodig Pkoel_lbk_ kbat Pverw _lbk_vbat SCHED_LBK_WEEK_STD_K ANTOO SCHED_WERKWEEK_STD_K ANTOOSCHED_BKA_K24H SCHED_BKA_ V24H label label Tmedium_uit_kbat Tmedium_uit_vba t Q_medium_i n_kbat Q_med ium_in_vbat Tmedium_in_kbat Tmedium_in_vbat qvent_kbat qvent_vbat label label LABELS 3 Temperatures Heat transfer rates lbk *** External files ASSIGN output_lbk.txt 89 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * EQUATIONS "T en R.V. uit LBK & Power" * EQUATIONS 9 opwarming_kanalen = 1 !kW Pkoel_LBK = abs(Pkoel_lbk_kbat) !kW Pverw_LBK = abs(Pverw_lbk_vbat) !deg C Tair_uit_LBK = Tvent_LBK_gewenst+opwarming_kanalen !% RVair_uit_LBK = min(max(RH_air_gewenst,30),70) q_lbk_cv = Q_medium_in_vbat q_lbk_gkw = Q_medium_in_kbat Tret_lbk_water_gkw = Tmedium_uit_kbat Tret_lbk_water_cv = Tmedium_uit_vbat *$UNIT_NAME T en R.V. uit LBK & Power *$LAYER Main *$POSITION 685 274 *------------------------------------------------------------------------------ * Model "enthalpie naar LBK" (Type 33) * UNIT 50 TYPE 33 naar LBK *$UNIT_NAME enthalpie naar LBK *$MODEL .\Physical Phenomena\Thermodynamic Properties\Psychrometrics\Dry Bulb and Relative Humidity Known\Type33e.tmf *$POSITION 524 111 *$LAYER Luchtbehandelingskast # PARAMETERS 3 ! 1 Psychrometrics mode ! 2 Wet bulb mode ! 3 Error mode 2.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+00 INPUTS 3 ! return air naar LBK:Tair_return ->Dry bulb temp. ! return air naar LBK:RHair_return ->Percent relative humidity ! [unconnected] Pressure TAIR_RETURN RHAIR_RETURN CONST KBAT *** INITIAL INPUT VALUES 2.0000000000000000E+01 5.0000000000000000E+01 1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "enthalpie uit LBK" (Type 33) * UNIT 85 TYPE 33 uit LBK *$UNIT_NAME enthalpie uit LBK *$MODEL .\Physical Phenomena\Thermodynamic Properties\Psychrometrics\Dry Bulb and Relative Humidity Known\Type33e.tmf *$POSITION 383 275 *$LAYER Main # PARAMETERS 3 ! 1 Psychrometrics mode ! 2 Wet bulb mode ! 3 Error mode 2.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+00 INPUTS 3 ! stooklijn Tvent & qvent:Tvent_LBK_gewenst ->Dry bulb temp. ! stooklijn Tvent & qvent:RH_air_gewenst ->Percent relative humidity ! [unconnected] Pressure TVENT_LBK_GEWENST RH_AIR_GEWENST CONST KBAT *** INITIAL INPUT VALUES 2.0000000000000000E+01 5.0000000000000000E+01 1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "Groep A" (Type 360) * UNIT 46 TYPE 360 A *$UNIT_NAME Groep A *$MODEL .\nostand\Type360 BKA\Type360.tmf *$POSITION 435 1304 *$LAYER Betonkernactivering # *$# Dieses tmf wurde aus dem ia-file durch importieren in IISIBAT2 und einladen *$# des TYPE160.obj in IISIBAT3 erstellt TW 6/2002. *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# PARAMETERS 13 ! 1 Mode, 1: floor heating 2: hypocaust ! 2 Total width of the panel ! 3 Number of segments ! 4 Total length of the panel ! 5 corr. factor, 0.886: round channel, 1: rectang. channel ! 6 internal time step ! 7 logical unit to which geometry file is assigned ! 8 connected to type? 19: type 19, 56: type 56 ! 9 hor. or vert. application, 1: vertical, 2: horizontal ! 10 Number of segments to be monitored? ! 11 roughness of the channel ! 12 initial temperature of the panel ! 13 file read mode, 1: formatted, 0: unformatted 1.0000000000000000E+00 3.0000000000000000E+00 4.0000000000000000E+00 7.2000000000000002E+00 8.8600000000000001E-01 1.7999999099999999E+02 7.8000000000000000E+01 5.6000000000000000E+01 2.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 2.0000000000000000E+01 1.0000000000000000E+00 INPUTS 13 ! BKA-net Groep A:Tin_bka_A ->inlet temperature of the fluid ! BKA-net Groep A:q_bka_water_A ->fluid mass flow for the entire panel ! [unconnected] air temperature for the side floor ! Standaard kantoor: 32- TAIR_GROEP_A ->air temperature for the side ceiling ! [unconnected] equivalent temperature for the floor ! Standaard kantoor: 37- TSTAR_GROEP_A ->equivalent temperature for the ceiling ! [unconnected] surface temperature for the floor ! Standaard kantoor: 33- TSI_S91 ->surface temperature for the ceiling ! [unconnected] combined heat flux for the floor ! BKA-net Groep A:Qcomb_plaat_A ->combined heat flux for the ceiling ! [unconnected] solar radiation gains on the floor ! BKA-net Groep A:Qabs_plaat_A ->solar radiation gains on the ceiling ! [unconnected] density TIN_BKA_A Q_BKA_WATER_A CONST KBAT 56,32 CONST 56,37 CONST 56,33 CONST NA_WKO QCOMB_PLAAT_A CONST T_KBAT QABS_PLAAT_A CONST N_KBAT *** INITIAL INPUT VALUES 2.0000000000000000E+01 0.0000000000000000E+00 2.0000000000000000E+01 2.0000000000000000E+01 2.0000000000000000E+01 0.0000000000000000E+00 2.0010000000000002E+01 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+03 *** External files ASSIGN wing-rib-rechts-lambda-0.185.FBH 78 *|? which file contains the geometry information? |1000 *------------------------------------------------------------------------------ * Model "Groep B" (Type 360) * UNIT 43 TYPE 360 B *$UNIT_NAME Groep B *$MODEL .\nostand\Type360 BKA\Type360.tmf *$POSITION 435 1198 *$LAYER Betonkernactivering # *$# Dieses tmf wurde aus dem ia-file durch importieren in IISIBAT2 und einladen *$# des TYPE160.obj in IISIBAT3 erstellt TW 6/2002. *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# PARAMETERS 13 ! 1 Mode, 1: floor heating 2: hypocaust ! 2 Total width of the panel ! 3 Number of segments ! 4 Total length of the panel ! 5 corr. factor, 0.886: round channel, 1: rectang. channel ! 6 internal time step ! 7 logical unit to which geometry file is assigned ! 8 connected to type? 19: type 19, 56: type 56 ! 9 hor. or vert. application, 1: vertical, 2: horizontal ! 10 Number of segments to be monitored? ! 11 roughness of the channel ! 12 initial temperature of the panel ! 13 file read mode, 1: formatted, 0: unformatted 1.0000000000000000E+00 3.0000000000000000E+00 4.0000000000000000E+00 7.2000000000000002E+00 8.8600000000000001E-01 1.7999999099999999E+02 7.7000000000000000E+01 5.6000000000000000E+01 2.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 2.0000000000000000E+01 1.0000000000000000E+00 INPUTS 13 ! BKA-net Groep B:Tin_bka_B ->inlet temperature of the fluid ! BKA-net Groep B:q_bka_water_B ->fluid mass flow for the entire panel ! [unconnected] air temperature for the side floor ! Standaard kantoor: 22- TAIR_GROEP_B ->air temperature for the side ceiling ! [unconnected] equivalent temperature for the floor ! Standaard kantoor: 27- TSTAR_GROEP_B ->equivalent temperature for the ceiling ! [unconnected] surface temperature for the floor ! Standaard kantoor: 23- TSI_S78 ->surface temperature for the ceiling ! [unconnected] combined heat flux for the floor ! BKA-net Groep B:Qcomb_plaat_B ->combined heat flux for the ceiling ! [unconnected] solar radiation gains on the floor ! BKA-net Groep B:Qabs_plaat_B ->solar radiation gains on the ceiling ! [unconnected] density TIN_BKA_B Q_BKA_WATER_B CONST KBAT 56,22 CONST 56,27 CONST 56,23 CONST NA_WKO QCOMB_PLAAT_B CONST T_KBAT QABS_PLAAT_B CONST N_KBAT *** INITIAL INPUT VALUES 2.0000000000000000E+01 0.0000000000000000E+00 2.0000000000000000E+01 2.0000000000000000E+01 2.0000000000000000E+01 0.0000000000000000E+00 2.0010000000000002E+01 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+03 *** External files ASSIGN wing-rib-rechts-lambda-0.185.FBH 77 *|? which file contains the geometry information? |1000 *------------------------------------------------------------------------------ * Model "Groep C" (Type 360) * UNIT 40 TYPE 360 C *$UNIT_NAME Groep C *$MODEL .\nostand\Type360 BKA\Type360.tmf *$POSITION 435 1090 *$LAYER Betonkernactivering # *$# Dieses tmf wurde aus dem ia-file durch importieren in IISIBAT2 und einladen *$# des TYPE160.obj in IISIBAT3 erstellt TW 6/2002. *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# PARAMETERS 13 ! 1 Mode, 1: floor heating 2: hypocaust ! 2 Total width of the panel ! 3 Number of segments ! 4 Total length of the panel ! 5 corr. factor, 0.886: round channel, 1: rectang. channel ! 6 internal time step ! 7 logical unit to which geometry file is assigned ! 8 connected to type? 19: type 19, 56: type 56 ! 9 hor. or vert. application, 1: vertical, 2: horizontal ! 10 Number of segments to be monitored? ! 11 roughness of the channel ! 12 initial temperature of the panel ! 13 file read mode, 1: formatted, 0: unformatted 1.0000000000000000E+00 3.0000000000000000E+00 4.0000000000000000E+00 5.4000000000000004E+00 8.8600000000000001E-01 1.7999999099999999E+02 7.6000000000000000E+01 5.6000000000000000E+01 2.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 2.0000000000000000E+01 1.0000000000000000E+00 INPUTS 13 ! BKA-net Groep C:Tin_bka_C ->inlet temperature of the fluid ! BKA-net Groep C:q_bka_water_C ->fluid mass flow for the entire panel ! [unconnected] air temperature for the side floor ! Standaard kantoor: 11- TAIR_GROEP_C ->air temperature for the side ceiling ! [unconnected] equivalent temperature for the floor ! Standaard kantoor: 16- TSTAR_GROEP_C ->equivalent temperature for the ceiling ! [unconnected] surface temperature for the floor ! Standaard kantoor: 12- TSI_S67 ->surface temperature for the ceiling ! [unconnected] combined heat flux for the floor ! BKA-net Groep C:Qcomb_plaat_C ->combined heat flux for the ceiling ! [unconnected] solar radiation gains on the floor ! BKA-net Groep C:Qabs_plaat_C ->solar radiation gains on the ceiling ! [unconnected] density TIN_BKA_C Q_BKA_WATER_C CONST KBAT 56,11 CONST 56,16 CONST 56,12 CONST NA_WKO QCOMB_PLAAT_C CONST T_KBAT QABS_PLAAT_C CONST N_KBAT *** INITIAL INPUT VALUES 2.0000000000000000E+01 0.0000000000000000E+00 2.0000000000000000E+01 2.0000000000000000E+01 2.0000000000000000E+01 0.0000000000000000E+00 2.0010000000000002E+01 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+03 *** External files ASSIGN wing-rib-rechts-lambda-0.185.FBH 76 *|? which file contains the geometry information? |1000 *------------------------------------------------------------------------------ * Model "Groep D" (Type 360) * UNIT 37 TYPE 360 D *$UNIT_NAME Groep D *$MODEL .\nostand\Type360 BKA\Type360.tmf *$POSITION 435 994 *$LAYER Betonkernactivering # *$# Dieses tmf wurde aus dem ia-file durch importieren in IISIBAT2 und einladen *$# des TYPE160.obj in IISIBAT3 erstellt TW 6/2002. *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# *$# PARAMETERS 13 ! 1 Mode, 1: floor heating 2: hypocaust ! 2 Total width of the panel ! 3 Number of segments ! 4 Total length of the panel ! 5 corr. factor, 0.886: round channel, 1: rectang. channel ! 6 internal time step ! 7 logical unit to which geometry file is assigned ! 8 connected to type? 19: type 19, 56: type 56 ! 9 hor. or vert. application, 1: vertical, 2: horizontal ! 10 Number of segments to be monitored? ! 11 roughness of the channel ! 12 initial temperature of the panel ! 13 file read mode, 1: formatted, 0: unformatted 1.0000000000000000E+00 3.0000000000000000E+00 4.0000000000000000E+00 5.4000000000000004E+00 8.8600000000000001E-01 1.7999999099999999E+02 7.5000000000000000E+01 5.6000000000000000E+01 2.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 2.0000000000000000E+01 1.0000000000000000E+00 INPUTS 13 ! BKA-net Groep D:Tin_bka_D ->inlet temperature of the fluid ! BKA-net Groep D:q_bka_water_D ->fluid mass flow for the entire panel ! [unconnected] air temperature for the side floor ! Standaard kantoor: 1- TAIR_GROEP_D ->air temperature for the side ceiling ! [unconnected] equivalent temperature for the floor ! Standaard kantoor: 6- TSTAR_GROEP_D ->equivalent temperature for the ceiling ! [unconnected] surface temperature for the floor ! Standaard kantoor: 2- TSI_S54 ->surface temperature for the ceiling ! [unconnected] combined heat flux for the floor ! BKA-net Groep D:Qcomb_plaat_D ->combined heat flux for the ceiling ! [unconnected] solar radiation gains on the floor ! BKA-net Groep D:Qabs_plaat_D ->solar radiation gains on the ceiling ! [unconnected] density TIN_BKA_D Q_BKA_WATER_D CONST KBAT 56,1 CONST 56,6 CONST 56,2 CONST NA_WKO QCOMB_PLAAT_D CONST T_KBAT QABS_PLAAT_D CONST N_KBAT *** INITIAL INPUT VALUES 2.0000000000000000E+01 0.0000000000000000E+00 2.0000000000000000E+01 2.0000000000000000E+01 2.0000000000000000E+01 0.0000000000000000E+00 2.0010000000000002E+01 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+03 *** External files ASSIGN wing-rib-rechts-lambda-0.185.FBH 75 *|? which file contains the geometry information? |1000 *------------------------------------------------------------------------------ * Model "output_wko" (Type 65) * UNIT 79 TYPE 65 *$UNIT_NAME output_wko *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1724 466 *$LAYER OutputSystem # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 3.0000000000000000E+01 0.0000000000000000E+00 4.0000000000000000E+04 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 8.8000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! Aquifer-WKO:temperature_cold_well ->Left axis variable-1 ! Aquifer-WKO:temperature_warm_well ->Left axis variable-2 ! regeling WKO:Tin_tsa_gkw ->Left axis variable-3 ! regeling WKO:Tin_tsa_wko ->Left axis variable-4 ! regeling WKO:Tinjectie_wko ->Left axis variable-5 ! regeling WKO:Tgkw_na_wko ->Left axis variable-6 ! regeling WKO:dT_tsa_wko ->Left axis variable-7 ! regeling WKO:dT_tsa_wko_berek ->Left axis variable-8 ! regeling WKO:P_ontladen_actueel ->Left axis variable-9 ! regeling WKO:P_laden_actueel ->Left axis variable-10 ! energy_wko:Result of integration-1 ->Right axis variable-1 ! energy_wko:Result of integration-2 ->Right axis variable-2 ! regeling WKO:q_tsa_gkw ->Right axis variable-3 ! regeling WKO:q_tsa_wko ->Right axis variable-4 ! TSA-WKO:Hot-side outlet temperature ->Right axis variable-5 ! TSA-WKO:Cold-side outlet temperature ->Right axis variable-6 ! TSA-WKO:Effectiveness ->Right axis variable-7 ! vermogen WKO, ketel:P_wko_ontladen ->Right axis variable-8 ! vermogen WKO, ketel:P_wko_laden ->Right axis variable-9 ! vermogen WKO, ketel:P_ketel ->Right axis variable-10 66,4 66,5 TIN_TSA_GKW TIN_TSA_WKO TINJECTIE_WKO TGKW_NA_WKO DT_TSA_WKO DT_TSA_WKO_BEREK P_ONTLADEN_ACTUEEL P_LADEN_ACTUEEL 78,1 78,2 Q_TSA_GKW Q_TSA_WKO 68,1 68,3 68,6 P_WKO_ONTLADEN P_WKO_LADEN P_KETEL *** INITIAL INPUT VALUES temperature_cold_wel l temperature_war m_well Tin_tsa_gk w Tin_t sa_wko Tinjectie_wko Tgkw_na_wko dT_tsa_wko dT_tsa_wko _berek P_ont laden_actueel P_laden_actueel energie_ontladen energie_laden q_tsa_gkw q_tsa _wko Tgkw_uit_berek Twko_uit_berek effectivenes P_wko_ontl aden P_wko _laden P_ketel LABELS 3 Temperatures energy and flow wko *** External files ASSIGN output_wko.txt 88 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * Model "delay in dT_tsa_wko_berek" (Type 93) * UNIT 82 TYPE 93 in dT_tsa_wko_berek *$UNIT_NAME delay in dT_tsa_wko_berek *$MODEL .\Utility\Input Value Recall\Type93.tmf *$POSITION 1405 639 *$LAYER Main # PARAMETERS 2 ! 1 Number of inputs to be stored ! 2 Number of timesteps to be stored 1.0000000000000000E+00 2.0000000000000000E+00 INPUTS 1 ! regeling WKO:dT_tsa_wko_berek ->Input value DT_TSA_WKO_BEREK *** INITIAL INPUT VALUES 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "TSA-WKO" (Type 5) * UNIT 68 TYPE 5 *$UNIT_NAME TSA-WKO *$MODEL .\Heat Exchangers\Counter Flow\Type5b.tmf *$POSITION 1253 701 *$LAYER Main # PARAMETERS 4 ! 1 Counter flow mode ! 2 Specific heat of hot side fluid ! 3 Specific heat of cold side fluid ! 4 Not used 2.0000000000000000E+00 4.1799999999999997E+00 4.1799999999999997E+00 0.0000000000000000E+00 INPUTS 5 ! regeling WKO:Tin_tsa_gkw ->Hot side inlet temperature ! regeling WKO:q_tsa_gkw ->Hot side flow rate ! regeling WKO:Tin_tsa_wko ->Cold side inlet temperature ! regeling WKO:q_tsa_wko ->Cold side flow rate ! regeling WKO:kA_tsa_actueel ->Overall heat transfer coefficient of exchanger TIN_TSA_GKW Q_TSA_GKW TIN_TSA_WKO Q_TSA_WKO KA_TSA_ACTUEEL *** INITIAL INPUT VALUES 2.0000000000000000E+01 1.0000000000000000E+02 2.0000000000000000E+01 1.0000000000000000E+02 1.0000000000000000E+01 *------------------------------------------------------------------------------ * Model "Aquifer-WKO" (Type 203) * UNIT 66 TYPE 203 *$UNIT_NAME Aquifer-WKO *$MODEL .\DWAcomponents\type203 Aquifer.tmf *$POSITION 1253 764 *$LAYER Main # PARAMETERS 26 ! 1 system_type ! 2 aq_thickness ! 3 aq_thickness_closingLayers ! 4 aq_thermal_conductivity ! 5 aq_thermal_cond_closingLayers ! 6 aq_thermal_capacity ! 7 aq_thermal_capacity_closingLayers ! 8 aq_horiz_permeability ! 9 aq_porosity ! 10 aq_natural_temp_underground ! 11 aq_gwpeil ! 12 tf_energy_demand ! 13 tf_excess_capacity ! 14 tf_desired_inj_temp_cold ! 15 tf_desired_inj_temp_warm ! 16 tf_cutoff_temp_cold ! 17 tf_max_flow_unload ! 18 tf_max_flow_load ! 19 tf_min_flow_unload ! 20 tf_min_flow_load ! 21 pp_Vmax ! 22 pp_diff_press_Unload ! 23 pp_diff_press_Load ! 24 pp_efficiency_pumps ! 25 pp_inj_press ! 26 pp_extra_press_dirty 0.0000000000000000E+00 5.0000000000000000E+01 2.0000000000000000E+01 2.3999999999999999E+00 1.2000000000000000E+00 2.6000000000000000E+03 2.0000000000000000E+03 3.4722200000000006E-04 3.5000000000000003E-01 1.2000000000000000E+01 -2.0000000000000000E+00 5.0000000000000000E+05 2.0000000000000000E+01 7.5000000000000000E+00 1.7500000000000000E+01 1.2000000000000000E+01 4.0000000000000000E+03 4.0000000000000000E+03 5.0000000000000000E+01 5.0000000000000000E+01 4.1666670000000013E-04 1.5000000000000000E+02 1.5000000000000000E+02 5.0000000000000000E+01 1.0000000000000000E+02 2.0000000000000000E+00 INPUTS 3 ! regeling WKO:system_state_wko ->system_state ! regeling WKO:q_tsa_wko ->flow ! regeling WKO:Tinjectie_wko ->temperature_injection SYSTEM_STATE_WKO Q_TSA_WKO TINJECTIE_WKO *** INITIAL INPUT VALUES 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "energy_wko" (Type 24) * UNIT 78 TYPE 24 *$UNIT_NAME energy_wko *$MODEL .\Utility\Integrators\Quantity Integrator\Type24.tmf *$POSITION 1735 559 *$LAYER Main # PARAMETERS 2 ! 1 Integration period ! 2 Relative or absolute start time 2.6296800000000000E+05 0.0000000000000000E+00 INPUTS 3 ! regeling WKO:energie_ontladen ->Input to be integrated-1 ! regeling WKO:energie_laden ->Input to be integrated-2 ! [unconnected] Input to be integrated-3 ENERGIE_ONTLADEN ENERGIE_LADEN CONST WKO *** INITIAL INPUT VALUES 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "R.V. na wwiel" (Type 33) * UNIT 63 TYPE 33 na wwiel *$UNIT_NAME R.V. na wwiel *$MODEL .\Physical Phenomena\Thermodynamic Properties\Psychrometrics\Dry Bulb and Humidity Ratio Known\Type33c.tmf *$POSITION 674 111 *$LAYER Main # PARAMETERS 3 ! 1 Psychrometrics mode ! 2 Wet bulb mode ! 3 Error mode 4.0000000000000000E+00 0.0000000000000000E+00 1.0000000000000000E+00 INPUTS 3 ! warmtewiel:Tair_na_wwiel ->Dry bulb temp. ! [unconnected] Absolute humidity ratio ! [unconnected] Pressure TAIR_NA_WWIEL CONST DEN CONST WKO *** INITIAL INPUT VALUES 2.0000000000000000E+01 7.3000000000000009E-03 1.0000000000000000E+00 *------------------------------------------------------------------------------ * Model "output_bka" (Type 65) * UNIT 83 TYPE 65 *$UNIT_NAME output_bka *$MODEL .\Output\Online Plotter\Online Plotter With File\No Units\Type65c.tmf *$POSITION 1722 658 *$LAYER Main # PARAMETERS 12 ! 1 Nb. of left-axis variables ! 2 Nb. of right-axis variables ! 3 Left axis minimum ! 4 Left axis maximum ! 5 Right axis minimum ! 6 Right axis maximum ! 7 Number of plots per simulation ! 8 X-axis gridpoints ! 9 Shut off Online w/o removing ! 10 Logical Unit for output file ! 11 Output file units ! 12 Output file delimiter 1.0000000000000000E+01 1.0000000000000000E+01 0.0000000000000000E+00 1.0000000000000000E+03 0.0000000000000000E+00 1.0000000000000000E+03 1.0000000000000000E+00 1.2000000000000000E+01 -1.0000000000000000E+00 9.1000000000000000E+01 0.0000000000000000E+00 0.0000000000000000E+00 INPUTS 20 ! Groep A:heat input from the fluid into the panel ->Left axis variable-1 ! Groep A:heat output through the floor ->Left axis variable-2 ! Groep A:heat output through the ceiling ->Left axis variable-3 ! Groep A:energy stored in the panel at the end of a timestep ->Left axis variable-4 ! Groep A:relative error of the heat balance ->Left axis variable-5 ! Groep B:heat input from the fluid into the panel ->Left axis variable-6 ! Groep B:heat output through the floor ->Left axis variable-7 ! Groep B:heat output through the ceiling ->Left axis variable-8 ! Groep B:energy stored in the panel at the end of a timestep ->Left axis variable-9 ! Groep B:relative error of the heat balance ->Left axis variable-10 ! Groep C:heat input from the fluid into the panel ->Right axis variable-1 ! Groep C:heat output through the floor ->Right axis variable-2 ! Groep C:heat output through the ceiling ->Right axis variable-3 ! Groep C:energy stored in the panel at the end of a timestep ->Right axis variable-4 ! Groep C:relative error of the heat balance ->Right axis variable-5 ! Groep D:heat input from the fluid into the panel ->Right axis variable-6 ! Groep D:heat output through the floor ->Right axis variable-7 ! Groep D:heat output through the ceiling ->Right axis variable-8 ! Groep D:energy stored in the panel at the end of a timestep ->Right axis variable-9 ! Groep D:relative error of the heat balance ->Right axis variable-10 46,6 46,7 46,8 46,9 46,10 43,6 43,7 43,8 43,9 43,10 40,6 40,7 40,8 40,9 40,10 37,6 37,7 37,8 37,9 37,10 *** INITIAL INPUT VALUES heat_in_fluid_to_pan el_A heat_out_floor_ A heat_out_c eiling_A energ y_stored_A rel_error_heat_balan ce_A heat_in_fluid_to_pan el_B heat_out_floor_ B heat_out_c eiling_B energ y_stored_B rel_error_heat_balan ce_B heat_in_fluid_to_pan el_C heat_out_floor_ C heat_out_c eiling_C energ y_stored_C rel_error_heat_balan ce_C heat_in_fluid_to_pan el_D heat_out_floor_ D heat_out_c eiling_D energ y_stored_D rel_error_heat_balan ce_D LABELS 3 Temperatures Heat transfer rates bka *** External files ASSIGN output_bka.txt 91 *|? What file should the online print to? |1000 *------------------------------------------------------------------------------ * EQUATIONS "energiebalans" * EQUATIONS 2 !kWh energie_balans = [78,2]-[78,1] !% energie_balans_proc = ([78,1]-[78,2])/ ([78,1]+[78,2]+0.00001) *$UNIT_NAME energiebalans *$LAYER Main *$POSITION 1856 556 *------------------------------------------------------------------------------ END TRANSIENT SIMULATION STARTING AT TIME = 0.0000000000000000E+00 STOPPING AT TIME = 2.6296800000000000E+05 TIMESTEP = 1 / 1 DIFFERENTIAL EQUATION ERROR TOLERANCE = 1.0000000000000002E-03 ALGEBRAIC CONVERGENCE TOLERANCE = 1.0000000000000002E-03 DIFFERENTIAL EQUATIONS SOLVED BY MODIFIED EULER *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : The following Types were loaded from TRNDll.dll: Type2, Type33, Type56, Type93, Type5, Type69, Type65, Type24, Type109 *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "kvbatterij.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "TESSGHPLibrary_ReleaseVersion204.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "type127.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "type151TSAdll.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "Type157_demo_release.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "type200dll.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : The following Types were loaded from "type203Aquifer.dll": Type203 *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : "type210.dll" was found but did not contain any components from the input file. *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available Message : The following Types were loaded from "type360.dll": Type360 *** Notice at time : 0.000000 Generated by Unit : Not applicable or not available Generated by Type : Not applicable or not available TRNSYS Message 199 : TRNSYS found at least one user DLL in the UserLib directory. (Note: Only DLL's including Types that are used in the simulation are loaded) Reported information : 2 user DLLs were loaded after searching in "L:\Program Files\Trnsys16_1\UserLib\ReleaseDLLs" *** Notice at time : 0.000000 Generated by Unit : 109 Generated by Type : 109 Message : VARIABLE COLUMN # IPOL MULTIPLIER ADD_FACTOR SAMPLING ---------------------------------------------------------------------------- ==> IGLOB_H 8 - 2.7780 0.0000 -1 ==> TAMB 6 2 0.1000 0.0000 -1 ==> RHUM 11 1 1.0000 0.0000 -1 ==> WSPEED 5 1 0.1000 0.0000 -1 ==> WDIR 4 1 1.0000 0.0000 -1 fcloud 10 1 0.1111 0.0000 -1 TDEW 7 1 0.1000 0.0000 -1 TGEWGEM 12 2 0.1000 0.0000 -1 TEREF 13 2 0.1000 0.0000 -1 ---------------------------------------------------------------------------- LONGITUDE -5.18 LATITUDE 52.10 TIME SHIFT TO GMT 1 DATA TIME STEP 1.00 STARTTIME FOR DATA 1.00 SAMPLING FOR RAD. DATA -1.00 ---------------------------------------------------------------------------- RADIATION MODE: FULL REINDL