76_SolarForecast: contrib Version 1.60.4
git-svn-id: https://svn.fhem.de/fhem/trunk@30507 2b470e98-0d58-463d-a4d8-8e2adae1ed80
This commit is contained in:
DS_Starter
@@ -162,7 +162,7 @@ BEGIN {
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# Versions History intern
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my %vNotesIntern = (
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"1.60.4" => "09.11.2025 smoothValue as OOP implemantation, battery efficiency rework, edit comref ",
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"1.60.4" => "09.11.2025 smoothValue as OOP implemantation, battery efficiency rework, edit comref, expand loadTarget by time target ",
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"1.60.3" => "06.11.2025 more preparation for barrierSoC, ___batFindMinPhWh: code change, new parameter ctrlBatSocManagementXX->barrierSoC ",
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"1.60.2" => "03.11.2025 fix lowSoC comparison, ___batAdjustPowerByMargin: more preparation for barrierSoC ",
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"1.60.1" => "02.11.2025 ___batAdjustPowerByMargin: minor code change, preparation for barrierSoC ",
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@@ -7664,7 +7664,7 @@ sub _attrBatSocManagement { ## no critic "not used"
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careCycle => { comp => '\d+', must => 0, act => 0 },
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loadAbort => { comp => '(?:100|[1-9]?[0-9]):\d+(?::(?:100|[1-9]?[0-9]))?', must => 0, act => 0 },
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loadStrategy => { comp => '(loadRelease|optPower|smartPower)', must => 0, act => 0 },
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loadTarget => { comp => '(100|[1-9]?[0-9])', must => 0, act => 0 },
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loadTarget => { comp => '(?:100|[1-9]?\d)(?::-?(?:[1-9]|1[0-9]|20))?', must => 0, act => 0 },
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safetyMargin => { comp => '(?:100|[1-9]?\d)(?::(?:100|[1-9]?\d))?', must => 0, act => 0 },
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weightOwnUse => { comp => '(100|[1-9]?[0-9])', must => 0, act => 0 },
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};
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@@ -7713,6 +7713,7 @@ sub _attrBatSocManagement { ## no critic "not used"
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my $upSoc = $parsed->{upSoc};
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my $maxSoc = $parsed->{maxSoc};
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my $barrierSoc = $parsed->{barrierSoc};
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my $loadTarget = $parsed->{loadTarget};
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unless ($lowSoc < $upSoc && $upSoc < $maxSoc) {
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return 'The specified values are not plausible. Compare the attribute help.';
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@@ -7723,6 +7724,12 @@ sub _attrBatSocManagement { ## no critic "not used"
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return 'The specified values are not plausible. Compare the attribute help.';
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}
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}
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if (defined $loadTarget) {
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unless ($lowSoc <= $loadTarget) {
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return 'The first value of loadTarget must be higher than lowSoc.';
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}
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}
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}
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else {
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deleteReadingspec ($hash, 'Battery_.*');
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@@ -11710,10 +11717,11 @@ sub __parseAttrBatSoc {
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my $name = shift;
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my $cgbt = shift // return;
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my ($lrMargin, $otpMargin, $barrierSoC, $barrierPar);
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my ($lrMargin, $otpMargin, $barrierSoC, $barrierPar, $loadTarget, $timeTarget);
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my ($pa, $ph) = parseParams ($cgbt);
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($lrMargin, $otpMargin) = split (':', $ph->{safetyMargin}) if(defined $ph->{safetyMargin});
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($barrierSoC, $barrierPar) = split (':', $ph->{barrierSoC}, 2) if(defined $ph->{barrierSoC});
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($loadTarget, $timeTarget) = split (':', $ph->{loadTarget}) if(defined $ph->{loadTarget});
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my $parsed = {
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lowSoc => $ph->{lowSoc},
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@@ -11724,8 +11732,9 @@ sub __parseAttrBatSoc {
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lcslot => $ph->{lcSlot},
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loadAbort => $ph->{loadAbort},
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loadStrategy => $ph->{loadStrategy},
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loadTarget => $ph->{loadTarget},
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weightOwnUse => $ph->{weightOwnUse},
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weightOwnUse => $ph->{weightOwnUse},
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loadTarget => $loadTarget,
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timeTarget => $timeTarget,
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lrMargin => $lrMargin,
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otpMargin => $otpMargin,
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barrierSoc => $barrierSoC, # SoC Barriere ab der eine Ladeleistungssteuerung aktiv sein soll
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@@ -11885,7 +11894,6 @@ sub _batChargeMgmt {
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my $bpinreduced = BatteryVal ($name, $bn, 'bpinreduced', 0); # Standardwert bei <=lowSoC -> Anforderungsladung vom Grid
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my $befficiency = BatteryVal ($name, $bn, 'befficiency', STOREFFDEF) / 100; # Speicherwirkungsgrad
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my $cgbt = AttrVal ($name, 'ctrlBatSocManagement'.$bn, undef);
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#my $sf = __batCapShareFactor ($name, $bn); # Anteilsfaktor der Batterie XX Kapazität an Gesamtkapazität
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my $sf = __batDeficitShareFactor ($name, $bn); # V 1.59.5 Anteilsfaktor Ladungsdefizit
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$strategy = 'loadRelease'; # 'loadRelease', 'optPower', 'smartPower'
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my $wou = 0; # Gewichtung Prognose-Verbrauch als Anteil "Eigennutzung" (https://forum.fhem.de/index.php?msg=1348429)
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@@ -11895,7 +11903,7 @@ sub _batChargeMgmt {
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my $goalwh = $batinstcap; # initiales Ladeziel (Wh)
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my $lrMargin = SFTYMARGIN_50;
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my $otpMargin = SFTYMARGIN_20;
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my ($lcslot, $barrierPar);
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my ($lcslot, $barrierPar, $timeTarget);
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if ($cgbt) {
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my $parsed = __parseAttrBatSoc ($name, $cgbt);
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@@ -11908,15 +11916,19 @@ sub _batChargeMgmt {
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$otpMargin = $parsed->{otpMargin} // $otpMargin; # Sicherheitszuschlag OTP (%)
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$strategy = $parsed->{loadStrategy} // $strategy;
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$wou = $parsed->{weightOwnUse} // $wou;
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my $tgt = $parsed->{loadTarget}; # Ladeziel-SoC in %
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$tgt = $batoptsoc if(defined $tgt && $tgt < $batoptsoc); # Wert Battery_OptimumTargetSoC_XX beachten
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$goalwh = defined $tgt
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? sprintf "%.0f", ___batSocPercentToWh ($batinstcap, $tgt)
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: $goalwh; # Ladeziel-SoC in Wh
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$timeTarget = $parsed->{timeTarget}; # Uhrzeit (volle Stunde) wann Ladeziel erreicht sein soll
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my $tgt = $parsed->{loadTarget} // 100; # Ladeziel-SoC in %
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$tgt = max ($tgt, $batoptsoc); # höheren Wert aus Ziel und optimalen SoC verwenden
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$goalwh = sprintf "%.0f", ___batSocPercentToWh ($batinstcap, $tgt); # Ladeziel-SoC in Wh
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}
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my $barrierSocWh = sprintf "%.0f", ___batSocPercentToWh ($batinstcap, $barrierSoc);
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my $goalpercent = sprintf "%.0f", ___batSocWhToPercent ($batinstcap, $goalwh); # Ladeziel in %
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if (defined $timeTarget && $timeTarget < 0) { # Ladezielzeit relativ zum Sonnenuntergang
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my $dt = timestringsFromOffset ($tdaysset, $timeTarget * 3600);
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$timeTarget = int ($dt->{hour}); # Uhrzeit ohne führende 0
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}
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## generelle Ladeabbruchbedingung evaluieren
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##############################################
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@@ -11953,14 +11965,13 @@ sub _batChargeMgmt {
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######################
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if ($paref->{debug} =~ /batteryManagement/) {
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - selected charging strategy: $strategy");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - General load termination condition: $labortCond");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - general load termination condition: $labortCond");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - control time Slot - Slot start: $lcstart, Slot end: $lcend");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - control barrier SoC: $barrierSoc % / $barrierSocWh Wh");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - control barrier Parameter: $barrierPar");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - control barrier Parameter: ".(defined $barrierPar ? $barrierPar : '-'));
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - Battery efficiency used: ".($befficiency * 100)." %");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - weighted self-consumption: $wou %");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - charging target: $goalpercent % / $goalwh Wh");
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#Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - Installed Battery capacity: $batinstcap Wh, Percentage of total capacity: ".(sprintf "%.1f", $sf*100)." %");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - Target load and target time: $goalpercent % / $goalwh Wh / ".(defined $timeTarget ? $timeTarget.' oclock' : '-'));
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - Percentage of the total amount of charging energy required: ".(sprintf "%.1f", $sf*100)." %");
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Log3 ($name, 1, "$name DEBUG> ChargeMgmt Bat $bn - The PV generation, consumption and surplus listed below are based on the battery's share of the total amount of charging energy required!");
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}
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@@ -12059,6 +12070,7 @@ sub _batChargeMgmt {
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$hsurp->{$fd}{$hod}{$bn}{initsocwh} = $socwh; # durch LR fortgeschriebener SoC
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$hsurp->{$fd}{$hod}{$bn}{batinstcap} = $batinstcap; # installierte Batteriekapazität (Wh)
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$hsurp->{$fd}{$hod}{$bn}{goalwh} = $goalwh; # Ladeziel
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$hsurp->{$fd}{$hod}{$bn}{timeTarget} = $timeTarget; # gewünschte Zeit (volle Stunde) für Zielerreichung
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$hsurp->{$fd}{$hod}{$bn}{bpinmax} = $bpinmax; # max. mögliche Ladeleistung
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$hsurp->{$fd}{$hod}{$bn}{bpinreduced} = $bpinreduced; # Standardwert bei <=lowSoC -> Anforderungsladung vom Grid
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$hsurp->{$fd}{$hod}{$bn}{bpoutmax} = $bpoutmax; # max. mögliche Entladeleistung
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@@ -12298,16 +12310,14 @@ sub __batChargeOptTargetPower {
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my $nexthod = sprintf "%02d", (int $hod + 1);
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my $nextnhr = $hsurp->{$nexthod}{nhr};
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my @remaining_hods = grep { int $_ >= int $hod } @sortedhods;
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my $remainingSurp = 0;
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my ($remainingSurp_o, $remainingHodsRef_o) = ___batRemainHodsAndSurp ( $hod, # verbleibender Überschuß ohne Zielzeit gesetzt
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$hsurp,
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$replacement,
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\@sortedhods
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);
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my ($remainingSurp, $remainingHodsRef);
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for my $h (@remaining_hods) { # Gesamtwert PV-Überschuß aller Stunden mit PV-Überschuß ermitteln
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my $val = defined $hsurp->{$h}{nhr} && $hsurp->{$h}{nhr} eq '00'
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? int ($replacement) // 0
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: $hsurp->{$h}{surplswh};
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$remainingSurp += int $val;
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}
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for my $sbn (sort { $a <=> $b } @batteries) { # jede Batterie
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my $bpinmax = $hsurp->{$hod}{$sbn}{bpinmax}; # Bat max. mögliche Ladelesitung
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my $batinstcap = $hsurp->{$hod}{$sbn}{batinstcap}; # Kapa dieser Batterie
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@@ -12319,6 +12329,7 @@ sub __batChargeOptTargetPower {
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my $bpinreduced = $hsurp->{$hod}{$sbn}{bpinreduced}; # Standardwert bei <=lowSoC -> Anforderungsladung vom Grid
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my $befficiency = $hsurp->{$hod}{$sbn}{befficiency}; # Speicherwirkungsgrad
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my $strategy = $hsurp->{$hod}{$sbn}{strategy}; # Ladestrategie
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my $timeTarget = $hsurp->{$hod}{$sbn}{timeTarget}; # gewünschte Zeit (volle Stunde) für Zielerreichung
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# Initialisierung / Fortschreibung Prognose-SOC (Wh)
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######################################################
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@@ -12338,8 +12349,19 @@ sub __batChargeOptTargetPower {
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## Ziel und dessen Erreichbarkeit
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###################################
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if ($timeTarget) { # verbleibender Überschuß mit Zielzeit gesetzt
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($remainingSurp, $remainingHodsRef) = ___batRemainHodsAndSurp ( $hod,
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$hsurp,
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$replacement,
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\@sortedhods,
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$timeTarget
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);
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}
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else {
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($remainingSurp, $remainingHodsRef) = ($remainingSurp_o, $remainingHodsRef_o);
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}
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my $goalwh = $hsurp->{$hod}{$sbn}{goalwh}; # Ladeziel
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#my $runwhneed = ($goalwh - $runwh) / $befficiency;
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my $runwhneed = $goalwh - $runwh;
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my $achievable = 1;
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@@ -12350,9 +12372,6 @@ sub __batChargeOptTargetPower {
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storeReading ('Battery_TargetAchievable_'.$sbn, $achievable) if($nhr eq '00');
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$hsurp->{$hod}{$sbn}{loadrel} = $runwhneed > 0 ? 1 : 0; # Ladefreigabe abhängig von Ziel-SoC Erfüllung
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#$hsurp->{$hod}{$sbn}{achievelog} = "charging target: $goalwh Wh, remaining: ".
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# (sprintf "%.0f", ($runwhneed * $befficiency)).' Wh -> target likely achievable? '.
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# ($achievable ? 'yes' : 'no');
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$hsurp->{$hod}{$sbn}{achievelog} = "charging target: $goalwh Wh, remaining: ".
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(sprintf "%.0f", $runwhneed).' Wh -> target likely achievable? '.
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($achievable ? 'yes' : 'no');
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@@ -12392,12 +12411,11 @@ sub __batChargeOptTargetPower {
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#########################
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my $otpMargin = $hsurp->{$hod}{$sbn}{otpMargin};
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my $fref = ___batFindMinPhWh ( { hsurp => $hsurp,
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hodsref => \@remaining_hods,
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hodsref => $remainingHodsRef,
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remainingSurp => $remainingSurp,
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Ereq => $runwhneed,
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replacement => $replacement,
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achievable => $achievable,
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#befficiency => $befficiency,
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minute => $minute
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}
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);
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@@ -12409,7 +12427,6 @@ sub __batChargeOptTargetPower {
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? min ($fref->{ph}, $spls) # Ladeleistung auf den kleineren Wert begrenzen (es kommen Nachberechnungen)
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: $fref->{ph};
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#$limpower = $limpower // 0 > 0 ? $limpower / $befficiency : 0; # Zielleistung mit Batterie Effizienzgrad erhöhen
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$limpower = $limpower // 0 > 0 ? $limpower : 0;
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$limpower = $bpinmax if(!$hsurp->{$hod}{$sbn}{lcintime});
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$limpower = max ($limpower, $bpinreduced); # Mindestladeleistung bpinreduced sicherstellen
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@@ -12438,9 +12455,6 @@ sub __batChargeOptTargetPower {
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}
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);
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#$pneedmin = min ($pneedmin, $bpinmax); # Begrenzung auf max. mögliche Batterieladeleistung
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#$pneedmin = max ($pneedmin, 0);
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#$pneedmin = sprintf "%.0f", $pneedmin;
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$pneedmin = ___batAdjustEfficiencyAndLimits ($pneedmin, $befficiency, $bpinmax, 0); # Apply Bat Effizienz und Ladeleistungsbegrenzungen
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$hsurp->{$hod}{$sbn}{pneedmin} = $pneedmin;
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@@ -12486,10 +12500,7 @@ sub __batChargeOptTargetPower {
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bpinmax => $bpinmax
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}
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);
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#$target = min ($target, $bpinmax); # Begrenzung auf max. mögliche Batterieladeleistung
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#$target = max ($target, $bpinreduced);
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#$target = sprintf "%.0f", $target;
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$target = ___batAdjustEfficiencyAndLimits ($target, $befficiency, $bpinmax, $bpinreduced); # Apply Bat Effizienz und Ladeleistungsbegrenzungen
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$otp->{$sbn}{target} = $target;
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@@ -12500,7 +12511,6 @@ sub __batChargeOptTargetPower {
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if ($nhr eq '00') { $diff = min ($spls, $otp->{$sbn}{target} / 60 * (60 - int $minute)) } # aktuelle (Rest)-Stunde -> zeitgewichteter Ladungszufluß
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else { $diff = min ($spls, $hsurp->{$hod}{$sbn}{pneedmin}) } # kleinster Wert aus PV-Überschuß oder Ladeleistungsbegrenzung
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#$runwh = min ($goalwh, $runwh + ($diff * $befficiency)); # Endwert Prognose
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$runwh = min ($goalwh, $runwh + $diff); # Endwert Prognose
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$runwh = ___batClampValue ($runwh, $lowSocwh, $batoptsocwh, $batinstcap); # runwh begrenzen
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$runwh = sprintf "%.0f", $runwh;
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@@ -12517,6 +12527,28 @@ sub __batChargeOptTargetPower {
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return ($hsurp, $otp);
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}
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################################################################
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# Verbleibende Aktivstunden und deren Überschußsumme liefern
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################################################################
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sub ___batRemainHodsAndSurp {
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my ($hod, $hsurp, $replacement, $sortedhodsref, $timeTarget) = @_;
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my @remaining_hods;
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my $remainingSurp = 0;
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if (defined $timeTarget) { @remaining_hods = grep { int $_ >= int $hod && int $_ <= int $timeTarget } @$sortedhodsref }
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else { @remaining_hods = grep { int $_ >= int $hod } @$sortedhodsref }
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for my $h (@remaining_hods) { # Gesamtwert PV-Überschuß aller Stunden mit PV-Überschuß ermitteln
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my $val = defined $hsurp->{$h}{nhr} && $hsurp->{$h}{nhr} eq '00'
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? int ($replacement) // 0
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: $hsurp->{$h}{surplswh};
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$remainingSurp += int $val;
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}
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return ($remainingSurp, \@remaining_hods);
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}
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################################################################
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# Zielleistung mit Sicherheitszuschlag behandeln
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# abfallend proportional zum linearen Rest-Überschuss des Tages
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@@ -12663,7 +12695,6 @@ sub ___batFindMinPhWh {
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my $Ereq = $paref->{Ereq};
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my $replacement = $paref->{replacement};
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my $achievable = $paref->{achievable};
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#my $befficiency = $paref->{befficiency};
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my $minute = $paref->{minute};
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my @hods = @$hodsref;
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@@ -12696,7 +12727,6 @@ sub ___batFindMinPhWh {
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if ($nhr eq '00') { $cap = min ($mid, $hsurp->{$hod}{surplswh}) / 60 * (60 - int $minute)} # Zeitgewichtung aktuelle Stunde
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else { $cap = min ($mid, $hsurp->{$hod}{surplswh})}
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#$cap *= $befficiency;
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$charged += $cap;
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}
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@@ -25909,38 +25939,9 @@ return $def;
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}
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###################################################################################################
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# Wert des current-Hash zurückliefern
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# Wert des Current-Speichers auslesen
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# Usage:
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# CurrentVal ($hash or $name, $key, $def)
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#
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# $key: aiinitstate - Initialisierungsstatus der KI
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# aitrainstate - Traisningsstatus der KI
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# aiaddistate - Add Instanz Status der KI
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# ctrunning - aktueller Ausführungsstatus des Central Task
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# dwdRad1hAge - Alter des Rad1h Wertes als Datumstring
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# dwdRad1hAgeTS - Alter des Rad1h Wertes als Unix Timestamp
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# genslidereg - Schieberegister PV Erzeugung (Array)
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# h4fcslidereg - Schieberegister 4h PV Forecast (Array)
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# surplusslidereg - Schieberegister PV Überschuß (Array)
|
||||
# moonPhaseI - aktuelle Mondphase (1 .. 8)
|
||||
# batsocslidereg - Schieberegister Batterie SOC (Array)
|
||||
# consumption - aktueller Verbrauch (W)
|
||||
# consumerdevs - alle registrierten Consumerdevices (Array)
|
||||
# consumerCollected - Statusbit Consumer Attr gesammelt und ausgewertet
|
||||
# gridconsumption - aktueller Netzbezug
|
||||
# temp - aktuelle Außentemperatur
|
||||
# surplus - aktueller PV Überschuß
|
||||
# tomorrowconsumption - Verbrauch des kommenden Tages
|
||||
# allstringspeak - Peakleistung aller Strings nach temperaturabhängiger Korrektur
|
||||
# allstringscount - aktuelle Anzahl der Anlagenstrings
|
||||
# tomorrowconsumption - erwarteter Gesamtverbrauch am morgigen Tag
|
||||
# sunriseToday - Sonnenaufgang heute
|
||||
# sunriseTodayTs - Sonnenaufgang heute Unix Timestamp
|
||||
# sunsetToday - Sonnenuntergang heute
|
||||
# sunsetTodayTs - Sonnenuntergang heute Unix Timestamp
|
||||
#
|
||||
# $def: Defaultwert
|
||||
#
|
||||
###################################################################################################
|
||||
sub CurrentVal {
|
||||
my $name = shift;
|
||||
@@ -26440,7 +26441,7 @@ sub SM_new {
|
||||
return $self;
|
||||
}
|
||||
|
||||
sub SM_update { # update mit neuem Messwert; gibt den geglätteten Wert zurück
|
||||
sub SM_update { # update mit neuem Messwert; gibt den geglätteten Wert zurück
|
||||
my ($self, $newval) = @_;
|
||||
return $self->{value} unless defined $newval;
|
||||
|
||||
@@ -26448,16 +26449,12 @@ sub SM_update { # update mit
|
||||
my $diff = $newval - $current;
|
||||
my $abs = $diff >= 0 ? $diff : -$diff;
|
||||
|
||||
if ($abs <= $self->{deadband}) { # innerhalb der deadband: kein Wechsel
|
||||
if ($abs <= $self->{deadband}) { # innerhalb der deadband: kein Wechsel
|
||||
return $current;
|
||||
}
|
||||
|
||||
if ($self->{alpha} >= 1) { # außerhalb deadband: Ziel ist der neue Messwert; gleiten je nach alpha
|
||||
$self->{value} = $newval;
|
||||
}
|
||||
else {
|
||||
$self->{value} = $current + $self->{alpha} * $diff;
|
||||
}
|
||||
if ($self->{alpha} >= 1) { $self->{value} = $newval } # außerhalb deadband: Ziel ist der neue Messwert; gleiten je nach alpha
|
||||
else { $self->{value} = $current + $self->{alpha} * $diff }
|
||||
|
||||
return $self->{value};
|
||||
}
|
||||
@@ -27947,11 +27944,14 @@ to ensure that the system configuration is correct.
|
||||
<tr><td> </td><td>For more information on selecting a strategy, see german <a href="https://wiki.fhem.de/wiki/SolarForecast_-_Solare_Prognose_(PV_Erzeugung)_und_Verbrauchersteuerung#Welche_Ladestrategie_soll_ich_w%C3%A4hlen?_-_eine_M%C3%B6glichkeit_zur_Best-Practice_Findung_mit_Codebeispiel">Wiki</a>. </td></tr>
|
||||
<tr><td> </td><td>Value: <b>loadRelease</b> | <b>optPower</b> | <b>smartPower</b>, default: loadRelease </td></tr>
|
||||
<tr><td> </td><td> </td></tr>
|
||||
<tr><td> <b>loadTarget</b> </td><td>Optional target SoC in % for calculating charge release or optimal charging power. </td></tr>
|
||||
<tr><td> </td><td>The target value is a calculated figure. The actual SoC may be higher or lower than this within </td></tr>
|
||||
<tr><td> </td><td>certain limits, depending on the situation. The higher value from Reading </td></tr>
|
||||
<tr><td> </td><td><b>Battery_OptimumTargetSoC_XX</b> and 'loadTarget' takes precedence for the calculation. </td></tr>
|
||||
<tr><td> </td><td>Value: <b>0..100</b>, default: 100 </td></tr>
|
||||
<tr><td> <b>loadTarget</b> </td><td>Optional target SoC (%), target time for calculating charge release, and optimal charging power.</td></tr>
|
||||
<tr><td> </td><td>The specified target SoC must be greater than the value of 'lowSoC'. A higher value in the </td></tr>
|
||||
<tr><td> </td><td>reading <b>Battery_OptimumTargetSoC_XX</b> takes precedence over the parameter setting. </td></tr>
|
||||
<tr><td> </td><td>A specified target time is the full hour (1..20) or, as a negative value (-20..-1), the </td></tr>
|
||||
<tr><td> </td><td>last full hour before sunset minus this value. </td></tr>
|
||||
<tr><td> </td><td>Syntax: <b><Target SoC>[:<Target time>]</b> </td></tr>
|
||||
<tr><td> </td><td>Value range Target SoC: <b>lowSoc..100</b>, default: 100 </td></tr>
|
||||
<tr><td> </td><td>Value range Target time: <b>-20..20</b>(without leading zero), default: undefined </td></tr>
|
||||
<tr><td> </td><td> </td></tr>
|
||||
<tr><td> <b>safetyMargin</b> </td><td>When calculating the load clearance and optimized load capacity, safety margins are taken </td></tr>
|
||||
<tr><td> </td><td>into account in the predicted load requirements. </td></tr>
|
||||
@@ -27973,7 +27973,7 @@ to ensure that the system configuration is correct.
|
||||
All SoC values are whole numbers in %. The following applies: 'lowSoc' < 'upSoC' < 'maxSoC'. <br><br>
|
||||
|
||||
<b>Example: </b> <br>
|
||||
attr <name> ctrlBatSocManagement01 lowSoc=10 upSoC=50 maxSoC=99 careCycle=25 lcSlot=11:00-17:30 loadAbort=99:40:90 safetyMargin=30 weightOwnUse=20 <br>
|
||||
attr <name> ctrlBatSocManagement01 lowSoc=10 upSoC=50 maxSoC=99 careCycle=25 lcSlot=11:00-17:30 loadAbort=99:40:90 safetyMargin=30 weightOwnUse=20 loadTarget=90:-2 <br>
|
||||
</li>
|
||||
<br>
|
||||
|
||||
@@ -30728,11 +30728,14 @@ die ordnungsgemäße Anlagenkonfiguration geprüft werden.
|
||||
<tr><td> </td><td>Weitere Informationen zur Auswahl der Strategie siehe <a href="https://wiki.fhem.de/wiki/SolarForecast_-_Solare_Prognose_(PV_Erzeugung)_und_Verbrauchersteuerung#Welche_Ladestrategie_soll_ich_w%C3%A4hlen?_-_eine_M%C3%B6glichkeit_zur_Best-Practice_Findung_mit_Codebeispiel">Wiki</a>. </td></tr>
|
||||
<tr><td> </td><td>Wert: <b>loadRelease</b> | <b>optPower</b> | <b>smartPower</b>, default: loadRelease </td></tr>
|
||||
<tr><td> </td><td> </td></tr>
|
||||
<tr><td> <b>loadTarget</b> </td><td>Optionaler Ziel-SoC in % für die Berechnung der Ladefreigabe bzw. der optimalen Ladeleistung. </td></tr>
|
||||
<tr><td> </td><td>Der Zielwert ist eine kalkulatorische Rechengröße. Der reale SoC kann situativ in Grenzen </td></tr>
|
||||
<tr><td> </td><td>über- oder unterschritten werden. Der höhere Wert aus Reading <b>Battery_OptimumTargetSoC_XX</b></td></tr>
|
||||
<tr><td> </td><td>und 'loadTarget' hat für die Berechnung Vorrang. </td></tr>
|
||||
<tr><td> </td><td>Wert: <b>0..100</b>, default: 100 </td></tr>
|
||||
<tr><td> <b>loadTarget</b> </td><td>Optionaler Ziel-SoC (%), Zielzeit zur Berechnung der Ladefreigabe und optimalen Ladeleistung. </td></tr>
|
||||
<tr><td> </td><td>Der angegebene Ziel-SoC muß größer als der Wert von 'lowSoC' sein. Ein höherer Wert im Reading </td></tr>
|
||||
<tr><td> </td><td><b>Battery_OptimumTargetSoC_XX</b> gegenüber der Parametervorgabe hat Vorrang. </td></tr>
|
||||
<tr><td> </td><td>Eine angegebene Zielzeit ist die volle Stunde (1..20) oder als negativer Wert (-20..-1) die </td></tr>
|
||||
<tr><td> </td><td>letzte volle Stunde vor dem Sonnenuntergang abzüglich diesem Wert. </td></tr>
|
||||
<tr><td> </td><td>Syntax: <b><Ziel-SoC>[:<Zielzeit>]</b> </td></tr>
|
||||
<tr><td> </td><td>Wertebereich Ziel-SoC: <b>lowSoc..100</b>, default: 100 </td></tr>
|
||||
<tr><td> </td><td>Wertebereich Zielzeit: <b>-20..20</b> (ohne führende Null), default: undefiniert </td></tr>
|
||||
<tr><td> </td><td> </td></tr>
|
||||
<tr><td> <b>safetyMargin</b> </td><td>Bei der Berechnung der Ladefreigabe und optimierten Ladeleistung werden Sicherheitszuschläge </td></tr>
|
||||
<tr><td> </td><td>auf den prognostizierten Ladungsbedarf berücksichtigt. </td></tr>
|
||||
@@ -30754,7 +30757,7 @@ die ordnungsgemäße Anlagenkonfiguration geprüft werden.
|
||||
Alle SoC-Werte sind ganze Zahlen in %. Dabei gilt: 'lowSoc' < 'upSoC' < 'maxSoC'. <br><br>
|
||||
|
||||
<b>Beispiel: </b> <br>
|
||||
attr <name> ctrlBatSocManagement01 lowSoc=10 upSoC=50 maxSoC=99 careCycle=25 lcSlot=11:00-17:30 loadAbort=99:40:90 safetyMargin=30 weightOwnUse=20 <br>
|
||||
attr <name> ctrlBatSocManagement01 lowSoc=10 upSoC=50 maxSoC=99 careCycle=25 lcSlot=11:00-17:30 loadAbort=99:40:90 safetyMargin=30 weightOwnUse=20 loadTarget=90:-2 <br>
|
||||
</li>
|
||||
<br>
|
||||
|
||||
|
||||
Reference in New Issue
Block a user