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Huawei Sun2000 & ioBroker via JS script funktioniert
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@hussi
Ich habe das Ganze mit Hilfe dieses Bildes umgesetzt:
Das habe ich irgendwo im Netz gefunden. Die Variable unter 'Derived' (abgeleitet) sind (unter anderem) nach dieser Abbildung erstellt. Die vom Netz importierte / exportierte Leistung an einem Tag findest Du unter:javascript.0.Solarpower.Derived.GridExportToday
javascript.0.Solarpower.Derived.GridImportTodayGruss
Christian@chris_b said in Huawei Sun2000 & ioBroker via JS script funktioniert:
javascript.0.Solarpower.Derived.GridExportToday
javascript.0.Solarpower.Derived.GridImportTodayHallo Christian,
die Punkte habe ich nicht.
Das Bild verstehe ich, glaube ich. Aber ich habe (noch) keine Batterie. Also kann ich ja nicht "Portal Yield today" errechnen.
Ich habe hier einen eigenen Thread eröffnet. Ich glaube das stört hier sonst.
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Ich habe das Skript nochmals etwas erweitert:
Jetzt werden auch jeden Tag 1 Minute vor Mitternacht die Tagesdaten in die Datei /opt/iobroker/iobroker-data/SolarpowerLog.csv geschrieben. Pro Tag werden folgende Daten geschrieben:- Datum
- Yield Today
- GridExportToday
- GridImportToday
- ConsumptionToday
Mit dieser csv Datei kann man dann in Excel wunderbar seine eigenen Stattistiken zeichen und analysieren.
Gruss, ChristianACHTUNG: Irgendwie kopiert es mir das Skript komisch in den 'Code' Bereich. Bitte die komischen {1} im Skript wegnehmen. Weiss jemand, wie diese entstehen? Die sind im Code nicht drin, und ich habe mehrere Arten versucht es zu kopieren...
// From iobroker Forum: "Huawei Sun2000 & ioBroker via JS script funktioniert" // https://forum.iobroker.net/topic/53005/huawei-sun2000-iobroker-via-js-script-funktioniert // createState("javascript.0.Solarpower.Derived.BatteryOverview", "", {read: true, write: true, name: "Battery Overview SOC"}); createState("javascript.0.Solarpower.Derived.HouseConsumption", "", {read: true, write: true, name: "Consumption of House", unit: "W"}); createState("javascript.0.Solarpower.Derived.YieldToday", "", {read: true, write: true, name: "Yield Today", unit: "kW"}); createState("javascript.0.Solarpower.Derived.IsBatteryLoading", 0, {read: true, write: true, name: "Luna 2000 Battery is loading", type: "number"}); createState("javascript.0.Solarpower.Derived.IsGridExporting", 0, {read: true, write: true, name: "Exporting Power to Grid", type: "number"}); createState("javascript.0.Solarpower.Derived.PeakPanelPower", 0, {read: true, write: true, name: "Peak panel power today"}); createState("javascript.0.Solarpower.Derived.GridExportSum", 0, {read: true, write: true, name: "Total export to grid", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.GridImportSum", 0, {read: true, write: true, name: "Total import from grid", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.GridExportToday", 0, {read: true, write: true, name: "Export to grid today", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.GridImportToday", 0, {read: true, write: true, name: "Import from grid today", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.ConsumptionToday", 0, {read: true, write: true, name: "Consumption today", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.ConsumptionSum", 0, {read: true, write: true, name: "Consumption total sum", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.ConsumptionStart", 0, {read: true, write: true, name: "Consumption total sum at start of day", unit: "kWh"}); var ModbusRTU = require("modbus-serial"); var fs = require('fs'); var client = new ModbusRTU(); var testCreateState = 0; var modbusErrorMessages = [ "Unknown error", "Illegal function (device does not support this read/write function)", "Illegal data address (register not supported by device)", "Illegal data value (value cannot be written to this register)", "Slave device failure (device reports internal error)", "Acknowledge (requested data will be available later)", "Slave device busy (retry request again later)" ]; // open connection to a tcp line client.setTimeout(10000); // Enter your inverter modbus IP and port here: client.connectTCP("192.168.1.127", { port: 502 }); // Enter the Modbus-IDs of your Sun2000 inverters here (example for two inverters): const ModBusIDs = [16, 1]; const ModBusIDs = [1]; // On which Modbus-ID can we reach the power meter? (via Sun2000!) const PowerMeterID = 0; // Enter your battery stack setup. 2 dimensional array, e.g. [[3, 2], [3, 0]] means: // First inverter has two battery stacks with 3 + 2 battery modules // while second inverter has only one battery stack with 3 battery modules const BatteryUnits = [[3, 0]]; // These register spaces need to be read: const RegisterSpacesToReadContinuously = [[30000, 81], [37100, 114], [32000, 116], [37000, 68], [37700, 100], [37800, 100], [38200, 100], [38300, 100], [38400, 100], [35300, 40]]; var RegisterSpacesToReadContinuouslyPtr = 0; var GlobalDataBuffer = new Array(2); for ( var i=0; i < ModBusIDs.length; i++) { GlobalDataBuffer[i] = new Array(50000); // not optimized.... } // Some helper functions: function readUnsignedInt16(array) { return array[0]; } function readUnsignedInt32(array) { return array[0] * 256 * 256 + array[1]; } function readSignedInt16(array) { var value = 0; if (array[0] > 32767) value = array[0] - 65535; else value = array[0]; return value; } function readSignedInt32(array) { var value = 0; for (var i = 0; i < 2; i++) { value = (value << 16) | array[i]; } return value; } function getU16(dataarray, index) { return readUnsignedInt16(dataarray.slice(index, index+1)); } function getU32(dataarray, index) { return readUnsignedInt32(dataarray.slice(index, index+2)); } function getI16(dataarray, index) { return readSignedInt16(dataarray.slice(index, index+1)); } function getI32(dataarray, index) { return readSignedInt32(dataarray.slice(index, index+2)); } function getString(dataarray, index, length) { var shortarray = dataarray.slice(index, index+length); var bytearray = []; for (var i = 0; i < length; i++) { bytearray.push(dataarray[index+i] >> 8); bytearray.push(dataarray[index+i] & 0xff); } var value = String.fromCharCode.apply(null, bytearray); return value; } function getZeroTerminatedString(dataarray, index, length) { var shortarray = dataarray.slice(index, index+length); var bytearray = []; for(var i = 0; i < length; i++) { bytearray.push(dataarray[index+i] >> 8); bytearray.push(dataarray[index+i] & 0xff); } var value = String.fromCharCode.apply(null, bytearray); var value2 = new String(value).trim(); return value2; } function forcesetState(objectname, value, options) //------------------------------------------------ // perform createState() only if variable does not yet exist, and perform the check via existsState() only once for each processing round { if (testCreateState == 0) { if (!existsState("javascript.0." + objectname)) { createState(objectname, value, options); } else { setState(objectname, value); } } else { setState(objectname, value); } } // Functions to map registers into ioBreaker objects function ProcessOptimizers(id) //---------------------------- { forcesetState("Solarpower.Huawei.Inverter." + id + ".OptimizerTotalNumber", getU16(GlobalDataBuffer[id-1], 37200), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".OptimizerOnlineNumber", getU16(GlobalDataBuffer[id-1], 37201), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".OptimizerFeatureData", getU16(GlobalDataBuffer[id-1], 37202), {name: "", unit: ""}); } function ProcessInverterPowerAdjustments(id) //------------------------------------------ { forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ActiveAdjustementMode", getU16(GlobalDataBuffer[id-1], 35300), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ActiveAdjustementValue", getU32(GlobalDataBuffer[id-1], 35301), {name: "", unit: ""}); // Note: This might be an error in the manual. It says register 35302 with quantity 2, but on 35303 is already the next value. forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ActiveAdjustementCommand", getU16(GlobalDataBuffer[id-1], 35303), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ReactiveAdjustementMode", getU16(GlobalDataBuffer[id-1], 35304), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ReactiveAdjustementValue", getU32(GlobalDataBuffer[id-1], 35305), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ReactiveAdjustementCommand",getU16(GlobalDataBuffer[id-1], 35307), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.PowerMeterActivePower", getI32(GlobalDataBuffer[id-1], 35313), {name: "", unit: ""}); } function ProcessBattery(id) //------------------------- { // Battery registers 1-15 (Stack 1 related) if ( BatteryUnits[id-1][0] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RunningStatus", getU16(GlobalDataBuffer[id-1], 37000), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 37001), {name: "Charge and Discharge Power", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BusVoltage", getU16(GlobalDataBuffer[id-1], 37003) / 10, {name: "Busvoltage", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BatterySOC", getU16(GlobalDataBuffer[id-1], 37004) / 10, {name: "Battery SOC", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.WorkingMode", getU16(GlobalDataBuffer[id-1], 37006), {name: "Working Mode", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RatedChargePower", getU32(GlobalDataBuffer[id-1], 37007), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RatedDischargePower", getU32(GlobalDataBuffer[id-1], 37009), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.FaultID", getU16(GlobalDataBuffer[id-1], 37014), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.CurrentDayChargeCapacity", getU32(GlobalDataBuffer[id-1], 37015) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.CurrentDayDischargeCapacity", getU32(GlobalDataBuffer[id-1], 37017) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BusCurrent", getI16(GlobalDataBuffer[id-1], 37021) / 10, {name: "Buscurrent", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BatteryTemperature", getI16(GlobalDataBuffer[id-1], 37022) / 10, {name: "Battery Temperatue", unit: "°C"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RemainingChargeDischargeTime",getU16(GlobalDataBuffer[id-1], 37025), {name: "", unit: "mins"}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.DCDCversion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37026, 10), {name: "", unit: ""}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BMSversion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37036, 10), {name: "", unit: ""}); } // Battery registers 16+17 (Storage-related) forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.MaximumChargePower", getU32(GlobalDataBuffer[id-1], 37046), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.MaximumDischargePower", getU32(GlobalDataBuffer[id-1], 37048), {name: "", unit: "W"}); // Battery register 18-20 (Stack 1 related) if (BatteryUnits[id-1][0] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 37052, 10), {name: "Serialnumber", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.TotalCharge", getU32(GlobalDataBuffer[id-1], 37066) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.TotalDischarge", getU32(GlobalDataBuffer[id-1], 37068) / 100, {name: "", unit: "kWh"}); } // Battery register 21-31 (Stack 2 related) if ( BatteryUnits[id-1][1] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 37700, 10), {name: "Serialnumber", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BatterySOC", getU16(GlobalDataBuffer[id-1], 37738) / 10, {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.RunningStatus", getU16(GlobalDataBuffer[id-1], 37741), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 37743), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.CurrentDayChargeCapacity", getU32(GlobalDataBuffer[id-1], 37746) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.CurrentDayDischargeCapacity", getU32(GlobalDataBuffer[id-1], 37748) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BusVoltage", getU16(GlobalDataBuffer[id-1], 37750) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BusCurrent", getI16(GlobalDataBuffer[id-1], 37751) / 10, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BatteryTemperature", getI16(GlobalDataBuffer[id-1], 37752) / 10, {name: "", unit: "°C"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.TotalCharge", getU32(GlobalDataBuffer[id-1], 37753) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.TotalDischarge", getU32(GlobalDataBuffer[id-1], 37755) / 100, {name: "", unit: "kWh"}); } // Battery register 32-41 (Storage related) forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.RatedCapacity", getU32(GlobalDataBuffer[id-1], 37758) / 1, {name: "", unit: "Wh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.SOC", getU16(GlobalDataBuffer[id-1], 37760) / 10, {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.RunningStatus", getU16(GlobalDataBuffer[id-1], 37762) / 1, {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.BusVoltage", getU16(GlobalDataBuffer[id-1], 37763) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.BusCurrent", getI16(GlobalDataBuffer[id-1], 37764) / 10, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 37765) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.TotalCharge", getU32(GlobalDataBuffer[id-1], 37780) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.TotalDischarge", getU32(GlobalDataBuffer[id-1], 37782) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.CurrentDayChargeCapacity", getU32(GlobalDataBuffer[id-1], 37784) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.CurrentDayDischargeCapacity", getU32(GlobalDataBuffer[id-1], 37786) / 100, {name: "Current DayDiscarge ", unit: "kWh"}); // Battery registers 42+43 (Battery stack related) if ( BatteryUnits[id-1][1] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.SoftwareVersion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37814, 8), {name: "Softwareversion", unit: ""}); } if ( BatteryUnits[id-1][0] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.SoftwareVersion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37799, 8), {name: "Softwareversion", unit: ""}); } // Registers 44 to 98: (Battery pack related) for(var i = 1; i <= 2; i++) { if(BatteryUnits[id-1][i-1] >= 0) { for(var j = 1; j <= BatteryUnits[id-1][i-1]; j++) { //[[38200, 38242, 38284] [38326, 38368, 38410]]; (+42 for each battery pack, +126 for each stack) forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 38200+(i-1)*126+(j-1)*42, 6), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".FirmwareVersion", getZeroTerminatedString(GlobalDataBuffer[id-1], 38210+(i-1)*126+(j-1)*42, 8), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".WorkingStatus", getU16(GlobalDataBuffer[id-1], 38228+(i-1)*126+(j-1)*42), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".BatterySOC", getU16(GlobalDataBuffer[id-1], 38229+(i-1)*126+(j-1)*42) / 10, {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 38233+(i-1)*126+(j-1)*42) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".Voltage", getU16(GlobalDataBuffer[id-1], 38235+(i-1)*126+(j-1)*42) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".Current", getI16(GlobalDataBuffer[id-1], 38236+(i-1)*126+(j-1)*42) / 10, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".TotalCharge", getU32(GlobalDataBuffer[id-1], 38238+(i-1)*126+(j-1)*42) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".TotalDischarge", getU32(GlobalDataBuffer[id-1], 38240+(i-1)*126+(j-1)*42) / 100, {name: "", unit: "kWh"}); // [[38452, 38454, 38456][38458, 38460, 38462]] ( +2 for each pack, +6 for each stack) createState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".MaxTemperature", getI16(GlobalDataBuffer[id-1], 38452+(i-1)*6+(j-1)*2) / 10, {name: "", unit: "°C"}); createState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".MinTemperature", getI16(GlobalDataBuffer[id-1], 38453+(i-1)*6+(j-1)*2) / 10, {name: "", unit: "°C"}); } } } // Battery registers 110-141 are not supported by this script yet! } function ProcessPowerMeterStatus() //-------------------------------- { forcesetState("Solarpower.Huawei.Meter.Status", getU16(GlobalDataBuffer[PowerMeterID], 37100), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Meter.VoltageL1", getI32(GlobalDataBuffer[PowerMeterID], 37101) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL2", getI32(GlobalDataBuffer[PowerMeterID], 37103) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL3", getI32(GlobalDataBuffer[PowerMeterID], 37105) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.CurrentL1", getI32(GlobalDataBuffer[PowerMeterID], 37107) / 100, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Meter.CurrentL2", getI32(GlobalDataBuffer[PowerMeterID], 37109) / 100, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Meter.CurrentL3", getI32(GlobalDataBuffer[PowerMeterID], 37111) / 100, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Meter.ActivePower", getI32(GlobalDataBuffer[PowerMeterID], 37113) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Meter.ReactivePower", getI32(GlobalDataBuffer[PowerMeterID], 37115) / 1, {name: "", unit: "Var"}); forcesetState("Solarpower.Huawei.Meter.PowerFactor", getI16(GlobalDataBuffer[PowerMeterID], 37117) / 1000, {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Meter.GridFrequency", getI16(GlobalDataBuffer[PowerMeterID], 37118) / 100, {name: "", unit: "Hz"}); forcesetState("Solarpower.Huawei.Meter.PositiveActiveEnergy", getI32(GlobalDataBuffer[PowerMeterID], 37119) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Meter.ReverseActiveEnergy", getI32(GlobalDataBuffer[PowerMeterID], 37121) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Meter.AccumulatedReactivePower", getI32(GlobalDataBuffer[PowerMeterID], 37123) / 100, {name: "", unit: "kVarh"}); //forcesetState("Solarpower.Huawei.Meter.MeterType", getU16(GlobalDataBuffer[PowerMeterID], 37125), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Meter.VoltageL1-L2", getI32(GlobalDataBuffer[PowerMeterID], 37126) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL2-L3", getI32(GlobalDataBuffer[PowerMeterID], 37128) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL3-L1", getI32(GlobalDataBuffer[PowerMeterID], 37130) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.ActivePowerL1", getI32(GlobalDataBuffer[PowerMeterID], 37132) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Meter.ActivePowerL2", getI32(GlobalDataBuffer[PowerMeterID], 37134) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Meter.ActivePowerL3", getI32(GlobalDataBuffer[PowerMeterID], 37136) / 1, {name: "", unit: "W"}); //forcesetState("Solarpower.Huawei.Meter.MeterModel", getU16(GlobalDataBuffer[PowerMeterID], 37138), {name: "", unit: ""}); } function ProcessInverterStatus(id) //-------------------------------- { forcesetState("Solarpower.Huawei.Inverter." + id + ".State1", getU16(GlobalDataBuffer[id-1], 32000), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".State2", getU16(GlobalDataBuffer[id-1], 32001), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".State3", getU16(GlobalDataBuffer[id-1], 32002), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Alarm1", getU16(GlobalDataBuffer[id-1], 32008), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Alarm2", getU16(GlobalDataBuffer[id-1], 32009), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Alarm3", getU16(GlobalDataBuffer[id-1], 32010), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".String.1_Voltage", getI16(GlobalDataBuffer[id-1], 32016) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".String.1_Current", getI16(GlobalDataBuffer[id-1], 32017) / 100 , {name: "", unit: "A"}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".String.2_Voltage", getI16(GlobalDataBuffer[id-1], 32018) / 10 , {name: "", unit: "V"}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".String.2_Current", getI16(GlobalDataBuffer[id-1], 32019) / 100 , {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".InputPower", getI32(GlobalDataBuffer[id-1], 32064) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L1-L2_Voltage", getU16(GlobalDataBuffer[id-1], 32066) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L2-L3_Voltage", getU16(GlobalDataBuffer[id-1], 32067) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L3-L1_Voltage", getU16(GlobalDataBuffer[id-1], 32068) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L1_Voltage", getU16(GlobalDataBuffer[id-1], 32069) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L2_Voltage", getU16(GlobalDataBuffer[id-1], 32070) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L3_Voltage", getU16(GlobalDataBuffer[id-1], 32071) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L1_Current", getI32(GlobalDataBuffer[id-1], 32072) / 1000, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L2_Current", getI32(GlobalDataBuffer[id-1], 32074) / 1000, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L3_Current", getI32(GlobalDataBuffer[id-1], 32076) / 1000, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PeakActivePowerDay", getI32(GlobalDataBuffer[id-1], 32078) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActivePower", getI32(GlobalDataBuffer[id-1], 32080) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ReactivePower", getI32(GlobalDataBuffer[id-1], 32082) / 1000, {name: "", unit: "kVar"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PowerFactor", getI16(GlobalDataBuffer[id-1], 32084) / 1000, {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".GridFrequency", getU16(GlobalDataBuffer[id-1], 32085) / 100 , {name: "", unit: "Hz"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Efficiency", getU16(GlobalDataBuffer[id-1], 32086) / 100 , {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".InternalTemperature", getI16(GlobalDataBuffer[id-1], 32087) / 10 , {name: "", unit: "°C"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".InsulationResistance", getU16(GlobalDataBuffer[id-1], 32088) / 1000, {name: "", unit: "MOhm"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".DeviceStatus", getU16(GlobalDataBuffer[id-1], 32089), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".FaultCode", getU16(GlobalDataBuffer[id-1], 32090), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".StartupTime", getU16(GlobalDataBuffer[id-1], 32091), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ShutdownTime", getU16(GlobalDataBuffer[id-1], 32093), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".AccumulatedEnergyYield", getU32(GlobalDataBuffer[id-1], 32106) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".DailyEnergyYield", getU32(GlobalDataBuffer[id-1], 32114) / 100, {name: "", unit: "kWh"}); } function ProcessDeviceInfo(id) //---------------------------- { // Note: Manual says its quantitiy is 15, but that is the number (+1) of 8bit characters forcesetState("Solarpower.Huawei.Inverter." + id + ".Model", getZeroTerminatedString(GlobalDataBuffer[id-1], 30000, 8), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 30015, 6), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PN", getZeroTerminatedString(GlobalDataBuffer[id-1], 30025, 6), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ModelID", getU16(GlobalDataBuffer[id-1], 30070), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PVStrings", getU16(GlobalDataBuffer[id-1], 30071), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MPPTrackers", getU16(GlobalDataBuffer[id-1], 30072), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxRatedPower", getU32(GlobalDataBuffer[id-1], 30073) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxActivePower", getU32(GlobalDataBuffer[id-1], 30075) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxApparentPower", getU32(GlobalDataBuffer[id-1], 30077) / 1000, {name: "", unit: "kVA"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxReactivePowerToGrid", getI32(GlobalDataBuffer[id-1], 30079) / 1000, {name: "", unit: "kVAr"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxReactivePowerFromGrid", getI32(GlobalDataBuffer[id-1], 30081) / 1000, {name: "", unit: "kVAr"}); } function readRegisterSpace(id, address, length) //--------------------------------------------- { client.setID(ModBusIDs[id-1]); client.readHoldingRegisters(address, length, function(err, data) { if (err) { console.warn("Error received reading address " + address + " from id: " + ModBusIDs[id-1] + " with error: " + modbusErrorMessages[err.modbusCode]); } else { console.debug("Read data from id/address " + ModBusIDs[id-1] + "/" + address + "\nData is: " + data.data); for (var i = 0; i < length; i++) GlobalDataBuffer[id-1][address+i] = data.data[i]; } }); } function ProcessData() //-------------------- { console.debug("Processing new data..."); // this was originally .log for ( var i = 1; i <= ModBusIDs.length; i++) { ProcessDeviceInfo(i); ProcessInverterStatus(i); ProcessBattery(i); //ProcessInverterPowerAdjustments(i); ProcessOptimizers(i); } ProcessPowerMeterStatus(); // get SOC of first battery stack and combine to one string var BatOverview = ""; for(var j = 1; j <= BatteryUnits[0][0]; j++) { if (j > 1) BatOverview += ", "; BatOverview += getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.Battery" + j + ".BatterySOC").val + "%"; } setState("javascript.0.Solarpower.Derived.BatteryOverview", BatOverview); // determine peak panel power var PanelPower = getState("javascript.0.Solarpower.Huawei.Inverter.1.InputPower").val; var PanelMax = getState("javascript.0.Solarpower.Derived.PeakPanelPower").val; if (PanelPower > PanelMax) setState("javascript.0.Solarpower.Derived.PeakPanelPower", PanelPower); // determine power used by house setState("javascript.0.Solarpower.Derived.HouseConsumption", getState("javascript.0.Solarpower.Huawei.Inverter.1.ActivePower").val * 1000 - getState("javascript.0.Solarpower.Huawei.Meter.ActivePower").val); // determine yield today setState("javascript.0.Solarpower.Derived.YieldToday", getState("javascript.0.Solarpower.Huawei.Inverter.1.DailyEnergyYield").val + getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.CurrentDayChargeCapacity").val - getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.CurrentDayDischargeCapacity").val) // determine if battery is loading setState("javascript.0.Solarpower.Derived.IsBatteryLoading", getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.ChargeAndDischargePower").val > 0 ? 0 : 1); // determine if power is imported or exported setState("javascript.0.Solarpower.Derived.IsGridExporting", getState("javascript.0.Solarpower.Huawei.Meter.ActivePower").val > 0 ? 1 : 0); // compute export and import today setState("javascript.0.Solarpower.Derived.GridExportToday", getState("javascript.0.Solarpower.Huawei.Meter.PositiveActiveEnergy").val - getState("javascript.0.Solarpower.Derived.GridExportSum").val); setState("javascript.0.Solarpower.Derived.GridImportToday", getState("javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy").val - getState("javascript.0.Solarpower.Derived.GridImportSum").val); // compute consumption today setState("javascript.0.Solarpower.Derived.ConsumptionSum", getState("javascript.0.Solarpower.Huawei.Inverter.1.AccumulatedEnergyYield").val + getState("javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy").val - getState("javascript.0.Solarpower.Huawei.Meter.PositiveActiveEnergy").val); setState("javascript.0.Solarpower.Derived.ConsumptionToday", getState("javascript.0.Solarpower.Derived.ConsumptionSum").val - getState("javascript.0.Solarpower.Derived.ConsumptionStart").val); testCreateState = 1; // do not check on createState any more console.debug("Processing done!"); // this was originally .log } var triggerprocessing = 0; var currentinverter = 1; setInterval(function() // ------------------- // This is the main function triggering a read via modbus-tcp every 2 seconds - changed to 5 seconds // Processing of data is triggered as soon as one complete set of registers is copied // with 5 seconds, new values are displyed every 50 seconds { if (triggerprocessing == 1) { triggerprocessing = 0; ProcessData(); } // this was originally also a .log console.debug("Triggering read of inverter " + currentinverter + " at address " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0] + " with length " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); readRegisterSpace(currentinverter, RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0], RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); RegisterSpacesToReadContinuouslyPtr++; if (RegisterSpacesToReadContinuouslyPtr >= RegisterSpacesToReadContinuously.length) { RegisterSpacesToReadContinuouslyPtr = 0; currentinverter++ if (currentinverter > ModBusIDs.length) { currentinverter = 1; triggerprocessing = 1; } } }, 5000); // one minute before midnight - perform housekeeping actions schedule("59 23 * * *", function () { // reset peak power for next day setState("javascript.0.Solarpower.Derived.PeakPanelPower", 0); // copy current export/import kWh - used to compute daily import/export in kWh setState("javascript.0.Solarpower.Derived.GridExportSum", getState("javascript.0.Solarpower.Huawei.Meter.PositiveActiveEnergy").val); setState("javascript.0.Solarpower.Derived.GridImportSum", getState("javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy").val); // copy consumption Sum to Start for the next day setState("javascript.0.Solarpower.Derived.ConsumptionStart", getState("javascript.0.Solarpower.Derived.ConsumptionSum").val); // log important iformation to file SolarPowerLogging(); }); function SolarPowerLogging() //-------------------------- // write values of today in file { // get var log1 = getState("javascript.0.Solarpower.Derived.YieldToday").val; var log2 = getState("javascript.0.Solarpower.Derived.GridExportToday").val; var log3 = getState("javascript.0.Solarpower.Derived.GridImportToday").val; var log4 = getState("javascript.0.Solarpower.Derived.ConsumptionToday").val; // Zerlege Datum und Zeit in Variable var now = new Date(); var year = now.getFullYear(); var month = addZero(now.getMonth() + 1); var day = addZero(now.getDate()); var currDate = day + '.' + month + '.' + year; var string = " "; // create string that is appended to the file string = currDate + ";" + log1.toFixed(3) + ";" + log2.toFixed(3) + ";" + log3.toFixed(3) + ";" + log4.toFixed(3) + "\n"; fs.appendFileSync("/opt/iobroker/iobroker-data/SolarpowerLog.csv", string); // erzeuge Log-Eintrag log("Solerpower log:" + string, "info"); } function addZero(Num) //----------------- // if number <10 add zero values at the beginning of numbers { if (Num < 10) Num = "0" + Num; return Num; }@chris_b said in Huawei Sun2000 & ioBroker via JS script funktioniert:
Ich habe das Skript nochmals etwas erweitert:
Jetzt werden auch jeden Tag 1 Minute vor Mitternacht die Tagesdaten in die Datei /opt/iobroker/iobroker-data/SolarpowerLog.csv geschrieben. Pro Tag werden folgende Daten geschrieben:Danke, gestern hab ich das Script mit dem neuen WR in Betrieb genommen - läuft einwandfrei.
Weil die Frage zu den Optimierern schon gekommen ist, die wären in folgender lib schon mit integriert => https://github.com/wlcrs/huawei-solar-lib
-
Ich habe das Skript nochmals etwas erweitert:
Jetzt werden auch jeden Tag 1 Minute vor Mitternacht die Tagesdaten in die Datei /opt/iobroker/iobroker-data/SolarpowerLog.csv geschrieben. Pro Tag werden folgende Daten geschrieben:- Datum
- Yield Today
- GridExportToday
- GridImportToday
- ConsumptionToday
Mit dieser csv Datei kann man dann in Excel wunderbar seine eigenen Stattistiken zeichen und analysieren.
Gruss, ChristianACHTUNG: Irgendwie kopiert es mir das Skript komisch in den 'Code' Bereich. Bitte die komischen {1} im Skript wegnehmen. Weiss jemand, wie diese entstehen? Die sind im Code nicht drin, und ich habe mehrere Arten versucht es zu kopieren...
// From iobroker Forum: "Huawei Sun2000 & ioBroker via JS script funktioniert" // https://forum.iobroker.net/topic/53005/huawei-sun2000-iobroker-via-js-script-funktioniert // createState("javascript.0.Solarpower.Derived.BatteryOverview", "", {read: true, write: true, name: "Battery Overview SOC"}); createState("javascript.0.Solarpower.Derived.HouseConsumption", "", {read: true, write: true, name: "Consumption of House", unit: "W"}); createState("javascript.0.Solarpower.Derived.YieldToday", "", {read: true, write: true, name: "Yield Today", unit: "kW"}); createState("javascript.0.Solarpower.Derived.IsBatteryLoading", 0, {read: true, write: true, name: "Luna 2000 Battery is loading", type: "number"}); createState("javascript.0.Solarpower.Derived.IsGridExporting", 0, {read: true, write: true, name: "Exporting Power to Grid", type: "number"}); createState("javascript.0.Solarpower.Derived.PeakPanelPower", 0, {read: true, write: true, name: "Peak panel power today"}); createState("javascript.0.Solarpower.Derived.GridExportSum", 0, {read: true, write: true, name: "Total export to grid", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.GridImportSum", 0, {read: true, write: true, name: "Total import from grid", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.GridExportToday", 0, {read: true, write: true, name: "Export to grid today", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.GridImportToday", 0, {read: true, write: true, name: "Import from grid today", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.ConsumptionToday", 0, {read: true, write: true, name: "Consumption today", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.ConsumptionSum", 0, {read: true, write: true, name: "Consumption total sum", unit: "kWh"}); createState("javascript.0.Solarpower.Derived.ConsumptionStart", 0, {read: true, write: true, name: "Consumption total sum at start of day", unit: "kWh"}); var ModbusRTU = require("modbus-serial"); var fs = require('fs'); var client = new ModbusRTU(); var testCreateState = 0; var modbusErrorMessages = [ "Unknown error", "Illegal function (device does not support this read/write function)", "Illegal data address (register not supported by device)", "Illegal data value (value cannot be written to this register)", "Slave device failure (device reports internal error)", "Acknowledge (requested data will be available later)", "Slave device busy (retry request again later)" ]; // open connection to a tcp line client.setTimeout(10000); // Enter your inverter modbus IP and port here: client.connectTCP("192.168.1.127", { port: 502 }); // Enter the Modbus-IDs of your Sun2000 inverters here (example for two inverters): const ModBusIDs = [16, 1]; const ModBusIDs = [1]; // On which Modbus-ID can we reach the power meter? (via Sun2000!) const PowerMeterID = 0; // Enter your battery stack setup. 2 dimensional array, e.g. [[3, 2], [3, 0]] means: // First inverter has two battery stacks with 3 + 2 battery modules // while second inverter has only one battery stack with 3 battery modules const BatteryUnits = [[3, 0]]; // These register spaces need to be read: const RegisterSpacesToReadContinuously = [[30000, 81], [37100, 114], [32000, 116], [37000, 68], [37700, 100], [37800, 100], [38200, 100], [38300, 100], [38400, 100], [35300, 40]]; var RegisterSpacesToReadContinuouslyPtr = 0; var GlobalDataBuffer = new Array(2); for ( var i=0; i < ModBusIDs.length; i++) { GlobalDataBuffer[i] = new Array(50000); // not optimized.... } // Some helper functions: function readUnsignedInt16(array) { return array[0]; } function readUnsignedInt32(array) { return array[0] * 256 * 256 + array[1]; } function readSignedInt16(array) { var value = 0; if (array[0] > 32767) value = array[0] - 65535; else value = array[0]; return value; } function readSignedInt32(array) { var value = 0; for (var i = 0; i < 2; i++) { value = (value << 16) | array[i]; } return value; } function getU16(dataarray, index) { return readUnsignedInt16(dataarray.slice(index, index+1)); } function getU32(dataarray, index) { return readUnsignedInt32(dataarray.slice(index, index+2)); } function getI16(dataarray, index) { return readSignedInt16(dataarray.slice(index, index+1)); } function getI32(dataarray, index) { return readSignedInt32(dataarray.slice(index, index+2)); } function getString(dataarray, index, length) { var shortarray = dataarray.slice(index, index+length); var bytearray = []; for (var i = 0; i < length; i++) { bytearray.push(dataarray[index+i] >> 8); bytearray.push(dataarray[index+i] & 0xff); } var value = String.fromCharCode.apply(null, bytearray); return value; } function getZeroTerminatedString(dataarray, index, length) { var shortarray = dataarray.slice(index, index+length); var bytearray = []; for(var i = 0; i < length; i++) { bytearray.push(dataarray[index+i] >> 8); bytearray.push(dataarray[index+i] & 0xff); } var value = String.fromCharCode.apply(null, bytearray); var value2 = new String(value).trim(); return value2; } function forcesetState(objectname, value, options) //------------------------------------------------ // perform createState() only if variable does not yet exist, and perform the check via existsState() only once for each processing round { if (testCreateState == 0) { if (!existsState("javascript.0." + objectname)) { createState(objectname, value, options); } else { setState(objectname, value); } } else { setState(objectname, value); } } // Functions to map registers into ioBreaker objects function ProcessOptimizers(id) //---------------------------- { forcesetState("Solarpower.Huawei.Inverter." + id + ".OptimizerTotalNumber", getU16(GlobalDataBuffer[id-1], 37200), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".OptimizerOnlineNumber", getU16(GlobalDataBuffer[id-1], 37201), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".OptimizerFeatureData", getU16(GlobalDataBuffer[id-1], 37202), {name: "", unit: ""}); } function ProcessInverterPowerAdjustments(id) //------------------------------------------ { forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ActiveAdjustementMode", getU16(GlobalDataBuffer[id-1], 35300), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ActiveAdjustementValue", getU32(GlobalDataBuffer[id-1], 35301), {name: "", unit: ""}); // Note: This might be an error in the manual. It says register 35302 with quantity 2, but on 35303 is already the next value. forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ActiveAdjustementCommand", getU16(GlobalDataBuffer[id-1], 35303), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ReactiveAdjustementMode", getU16(GlobalDataBuffer[id-1], 35304), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ReactiveAdjustementValue", getU32(GlobalDataBuffer[id-1], 35305), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.ReactiveAdjustementCommand",getU16(GlobalDataBuffer[id-1], 35307), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActiveAdjustement.PowerMeterActivePower", getI32(GlobalDataBuffer[id-1], 35313), {name: "", unit: ""}); } function ProcessBattery(id) //------------------------- { // Battery registers 1-15 (Stack 1 related) if ( BatteryUnits[id-1][0] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RunningStatus", getU16(GlobalDataBuffer[id-1], 37000), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 37001), {name: "Charge and Discharge Power", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BusVoltage", getU16(GlobalDataBuffer[id-1], 37003) / 10, {name: "Busvoltage", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BatterySOC", getU16(GlobalDataBuffer[id-1], 37004) / 10, {name: "Battery SOC", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.WorkingMode", getU16(GlobalDataBuffer[id-1], 37006), {name: "Working Mode", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RatedChargePower", getU32(GlobalDataBuffer[id-1], 37007), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RatedDischargePower", getU32(GlobalDataBuffer[id-1], 37009), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.FaultID", getU16(GlobalDataBuffer[id-1], 37014), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.CurrentDayChargeCapacity", getU32(GlobalDataBuffer[id-1], 37015) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.CurrentDayDischargeCapacity", getU32(GlobalDataBuffer[id-1], 37017) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BusCurrent", getI16(GlobalDataBuffer[id-1], 37021) / 10, {name: "Buscurrent", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BatteryTemperature", getI16(GlobalDataBuffer[id-1], 37022) / 10, {name: "Battery Temperatue", unit: "°C"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.RemainingChargeDischargeTime",getU16(GlobalDataBuffer[id-1], 37025), {name: "", unit: "mins"}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.DCDCversion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37026, 10), {name: "", unit: ""}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.BMSversion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37036, 10), {name: "", unit: ""}); } // Battery registers 16+17 (Storage-related) forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.MaximumChargePower", getU32(GlobalDataBuffer[id-1], 37046), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.MaximumDischargePower", getU32(GlobalDataBuffer[id-1], 37048), {name: "", unit: "W"}); // Battery register 18-20 (Stack 1 related) if (BatteryUnits[id-1][0] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 37052, 10), {name: "Serialnumber", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.TotalCharge", getU32(GlobalDataBuffer[id-1], 37066) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.TotalDischarge", getU32(GlobalDataBuffer[id-1], 37068) / 100, {name: "", unit: "kWh"}); } // Battery register 21-31 (Stack 2 related) if ( BatteryUnits[id-1][1] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 37700, 10), {name: "Serialnumber", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BatterySOC", getU16(GlobalDataBuffer[id-1], 37738) / 10, {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.RunningStatus", getU16(GlobalDataBuffer[id-1], 37741), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 37743), {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.CurrentDayChargeCapacity", getU32(GlobalDataBuffer[id-1], 37746) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.CurrentDayDischargeCapacity", getU32(GlobalDataBuffer[id-1], 37748) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BusVoltage", getU16(GlobalDataBuffer[id-1], 37750) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BusCurrent", getI16(GlobalDataBuffer[id-1], 37751) / 10, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.BatteryTemperature", getI16(GlobalDataBuffer[id-1], 37752) / 10, {name: "", unit: "°C"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.TotalCharge", getU32(GlobalDataBuffer[id-1], 37753) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.TotalDischarge", getU32(GlobalDataBuffer[id-1], 37755) / 100, {name: "", unit: "kWh"}); } // Battery register 32-41 (Storage related) forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.RatedCapacity", getU32(GlobalDataBuffer[id-1], 37758) / 1, {name: "", unit: "Wh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.SOC", getU16(GlobalDataBuffer[id-1], 37760) / 10, {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.RunningStatus", getU16(GlobalDataBuffer[id-1], 37762) / 1, {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.BusVoltage", getU16(GlobalDataBuffer[id-1], 37763) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.BusCurrent", getI16(GlobalDataBuffer[id-1], 37764) / 10, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 37765) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.TotalCharge", getU32(GlobalDataBuffer[id-1], 37780) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.TotalDischarge", getU32(GlobalDataBuffer[id-1], 37782) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.CurrentDayChargeCapacity", getU32(GlobalDataBuffer[id-1], 37784) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Battery.CurrentDayDischargeCapacity", getU32(GlobalDataBuffer[id-1], 37786) / 100, {name: "Current DayDiscarge ", unit: "kWh"}); // Battery registers 42+43 (Battery stack related) if ( BatteryUnits[id-1][1] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.2.SoftwareVersion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37814, 8), {name: "Softwareversion", unit: ""}); } if ( BatteryUnits[id-1][0] > 0) { forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack.1.SoftwareVersion", getZeroTerminatedString(GlobalDataBuffer[id-1], 37799, 8), {name: "Softwareversion", unit: ""}); } // Registers 44 to 98: (Battery pack related) for(var i = 1; i <= 2; i++) { if(BatteryUnits[id-1][i-1] >= 0) { for(var j = 1; j <= BatteryUnits[id-1][i-1]; j++) { //[[38200, 38242, 38284] [38326, 38368, 38410]]; (+42 for each battery pack, +126 for each stack) forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 38200+(i-1)*126+(j-1)*42, 6), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".FirmwareVersion", getZeroTerminatedString(GlobalDataBuffer[id-1], 38210+(i-1)*126+(j-1)*42, 8), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".WorkingStatus", getU16(GlobalDataBuffer[id-1], 38228+(i-1)*126+(j-1)*42), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".BatterySOC", getU16(GlobalDataBuffer[id-1], 38229+(i-1)*126+(j-1)*42) / 10, {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".ChargeAndDischargePower", getI32(GlobalDataBuffer[id-1], 38233+(i-1)*126+(j-1)*42) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".Voltage", getU16(GlobalDataBuffer[id-1], 38235+(i-1)*126+(j-1)*42) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".Current", getI16(GlobalDataBuffer[id-1], 38236+(i-1)*126+(j-1)*42) / 10, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".TotalCharge", getU32(GlobalDataBuffer[id-1], 38238+(i-1)*126+(j-1)*42) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".TotalDischarge", getU32(GlobalDataBuffer[id-1], 38240+(i-1)*126+(j-1)*42) / 100, {name: "", unit: "kWh"}); // [[38452, 38454, 38456][38458, 38460, 38462]] ( +2 for each pack, +6 for each stack) createState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".MaxTemperature", getI16(GlobalDataBuffer[id-1], 38452+(i-1)*6+(j-1)*2) / 10, {name: "", unit: "°C"}); createState("Solarpower.Huawei.Inverter." + id + ".Batterystack." + i + ".Battery" + j + ".MinTemperature", getI16(GlobalDataBuffer[id-1], 38453+(i-1)*6+(j-1)*2) / 10, {name: "", unit: "°C"}); } } } // Battery registers 110-141 are not supported by this script yet! } function ProcessPowerMeterStatus() //-------------------------------- { forcesetState("Solarpower.Huawei.Meter.Status", getU16(GlobalDataBuffer[PowerMeterID], 37100), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Meter.VoltageL1", getI32(GlobalDataBuffer[PowerMeterID], 37101) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL2", getI32(GlobalDataBuffer[PowerMeterID], 37103) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL3", getI32(GlobalDataBuffer[PowerMeterID], 37105) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.CurrentL1", getI32(GlobalDataBuffer[PowerMeterID], 37107) / 100, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Meter.CurrentL2", getI32(GlobalDataBuffer[PowerMeterID], 37109) / 100, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Meter.CurrentL3", getI32(GlobalDataBuffer[PowerMeterID], 37111) / 100, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Meter.ActivePower", getI32(GlobalDataBuffer[PowerMeterID], 37113) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Meter.ReactivePower", getI32(GlobalDataBuffer[PowerMeterID], 37115) / 1, {name: "", unit: "Var"}); forcesetState("Solarpower.Huawei.Meter.PowerFactor", getI16(GlobalDataBuffer[PowerMeterID], 37117) / 1000, {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Meter.GridFrequency", getI16(GlobalDataBuffer[PowerMeterID], 37118) / 100, {name: "", unit: "Hz"}); forcesetState("Solarpower.Huawei.Meter.PositiveActiveEnergy", getI32(GlobalDataBuffer[PowerMeterID], 37119) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Meter.ReverseActiveEnergy", getI32(GlobalDataBuffer[PowerMeterID], 37121) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Meter.AccumulatedReactivePower", getI32(GlobalDataBuffer[PowerMeterID], 37123) / 100, {name: "", unit: "kVarh"}); //forcesetState("Solarpower.Huawei.Meter.MeterType", getU16(GlobalDataBuffer[PowerMeterID], 37125), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Meter.VoltageL1-L2", getI32(GlobalDataBuffer[PowerMeterID], 37126) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL2-L3", getI32(GlobalDataBuffer[PowerMeterID], 37128) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.VoltageL3-L1", getI32(GlobalDataBuffer[PowerMeterID], 37130) / 10, {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Meter.ActivePowerL1", getI32(GlobalDataBuffer[PowerMeterID], 37132) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Meter.ActivePowerL2", getI32(GlobalDataBuffer[PowerMeterID], 37134) / 1, {name: "", unit: "W"}); forcesetState("Solarpower.Huawei.Meter.ActivePowerL3", getI32(GlobalDataBuffer[PowerMeterID], 37136) / 1, {name: "", unit: "W"}); //forcesetState("Solarpower.Huawei.Meter.MeterModel", getU16(GlobalDataBuffer[PowerMeterID], 37138), {name: "", unit: ""}); } function ProcessInverterStatus(id) //-------------------------------- { forcesetState("Solarpower.Huawei.Inverter." + id + ".State1", getU16(GlobalDataBuffer[id-1], 32000), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".State2", getU16(GlobalDataBuffer[id-1], 32001), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".State3", getU16(GlobalDataBuffer[id-1], 32002), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Alarm1", getU16(GlobalDataBuffer[id-1], 32008), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Alarm2", getU16(GlobalDataBuffer[id-1], 32009), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Alarm3", getU16(GlobalDataBuffer[id-1], 32010), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".String.1_Voltage", getI16(GlobalDataBuffer[id-1], 32016) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".String.1_Current", getI16(GlobalDataBuffer[id-1], 32017) / 100 , {name: "", unit: "A"}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".String.2_Voltage", getI16(GlobalDataBuffer[id-1], 32018) / 10 , {name: "", unit: "V"}); //forcesetState("Solarpower.Huawei.Inverter." + id + ".String.2_Current", getI16(GlobalDataBuffer[id-1], 32019) / 100 , {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".InputPower", getI32(GlobalDataBuffer[id-1], 32064) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L1-L2_Voltage", getU16(GlobalDataBuffer[id-1], 32066) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L2-L3_Voltage", getU16(GlobalDataBuffer[id-1], 32067) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L3-L1_Voltage", getU16(GlobalDataBuffer[id-1], 32068) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L1_Voltage", getU16(GlobalDataBuffer[id-1], 32069) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L2_Voltage", getU16(GlobalDataBuffer[id-1], 32070) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L3_Voltage", getU16(GlobalDataBuffer[id-1], 32071) / 10 , {name: "", unit: "V"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L1_Current", getI32(GlobalDataBuffer[id-1], 32072) / 1000, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L2_Current", getI32(GlobalDataBuffer[id-1], 32074) / 1000, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Grid.L3_Current", getI32(GlobalDataBuffer[id-1], 32076) / 1000, {name: "", unit: "A"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PeakActivePowerDay", getI32(GlobalDataBuffer[id-1], 32078) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ActivePower", getI32(GlobalDataBuffer[id-1], 32080) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ReactivePower", getI32(GlobalDataBuffer[id-1], 32082) / 1000, {name: "", unit: "kVar"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PowerFactor", getI16(GlobalDataBuffer[id-1], 32084) / 1000, {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".GridFrequency", getU16(GlobalDataBuffer[id-1], 32085) / 100 , {name: "", unit: "Hz"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".Efficiency", getU16(GlobalDataBuffer[id-1], 32086) / 100 , {name: "", unit: "%"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".InternalTemperature", getI16(GlobalDataBuffer[id-1], 32087) / 10 , {name: "", unit: "°C"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".InsulationResistance", getU16(GlobalDataBuffer[id-1], 32088) / 1000, {name: "", unit: "MOhm"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".DeviceStatus", getU16(GlobalDataBuffer[id-1], 32089), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".FaultCode", getU16(GlobalDataBuffer[id-1], 32090), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".StartupTime", getU16(GlobalDataBuffer[id-1], 32091), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ShutdownTime", getU16(GlobalDataBuffer[id-1], 32093), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".AccumulatedEnergyYield", getU32(GlobalDataBuffer[id-1], 32106) / 100, {name: "", unit: "kWh"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".DailyEnergyYield", getU32(GlobalDataBuffer[id-1], 32114) / 100, {name: "", unit: "kWh"}); } function ProcessDeviceInfo(id) //---------------------------- { // Note: Manual says its quantitiy is 15, but that is the number (+1) of 8bit characters forcesetState("Solarpower.Huawei.Inverter." + id + ".Model", getZeroTerminatedString(GlobalDataBuffer[id-1], 30000, 8), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".SN", getZeroTerminatedString(GlobalDataBuffer[id-1], 30015, 6), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PN", getZeroTerminatedString(GlobalDataBuffer[id-1], 30025, 6), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".ModelID", getU16(GlobalDataBuffer[id-1], 30070), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".PVStrings", getU16(GlobalDataBuffer[id-1], 30071), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MPPTrackers", getU16(GlobalDataBuffer[id-1], 30072), {name: "", unit: ""}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxRatedPower", getU32(GlobalDataBuffer[id-1], 30073) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxActivePower", getU32(GlobalDataBuffer[id-1], 30075) / 1000, {name: "", unit: "kW"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxApparentPower", getU32(GlobalDataBuffer[id-1], 30077) / 1000, {name: "", unit: "kVA"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxReactivePowerToGrid", getI32(GlobalDataBuffer[id-1], 30079) / 1000, {name: "", unit: "kVAr"}); forcesetState("Solarpower.Huawei.Inverter." + id + ".MaxReactivePowerFromGrid", getI32(GlobalDataBuffer[id-1], 30081) / 1000, {name: "", unit: "kVAr"}); } function readRegisterSpace(id, address, length) //--------------------------------------------- { client.setID(ModBusIDs[id-1]); client.readHoldingRegisters(address, length, function(err, data) { if (err) { console.warn("Error received reading address " + address + " from id: " + ModBusIDs[id-1] + " with error: " + modbusErrorMessages[err.modbusCode]); } else { console.debug("Read data from id/address " + ModBusIDs[id-1] + "/" + address + "\nData is: " + data.data); for (var i = 0; i < length; i++) GlobalDataBuffer[id-1][address+i] = data.data[i]; } }); } function ProcessData() //-------------------- { console.debug("Processing new data..."); // this was originally .log for ( var i = 1; i <= ModBusIDs.length; i++) { ProcessDeviceInfo(i); ProcessInverterStatus(i); ProcessBattery(i); //ProcessInverterPowerAdjustments(i); ProcessOptimizers(i); } ProcessPowerMeterStatus(); // get SOC of first battery stack and combine to one string var BatOverview = ""; for(var j = 1; j <= BatteryUnits[0][0]; j++) { if (j > 1) BatOverview += ", "; BatOverview += getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.Battery" + j + ".BatterySOC").val + "%"; } setState("javascript.0.Solarpower.Derived.BatteryOverview", BatOverview); // determine peak panel power var PanelPower = getState("javascript.0.Solarpower.Huawei.Inverter.1.InputPower").val; var PanelMax = getState("javascript.0.Solarpower.Derived.PeakPanelPower").val; if (PanelPower > PanelMax) setState("javascript.0.Solarpower.Derived.PeakPanelPower", PanelPower); // determine power used by house setState("javascript.0.Solarpower.Derived.HouseConsumption", getState("javascript.0.Solarpower.Huawei.Inverter.1.ActivePower").val * 1000 - getState("javascript.0.Solarpower.Huawei.Meter.ActivePower").val); // determine yield today setState("javascript.0.Solarpower.Derived.YieldToday", getState("javascript.0.Solarpower.Huawei.Inverter.1.DailyEnergyYield").val + getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.CurrentDayChargeCapacity").val - getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.CurrentDayDischargeCapacity").val) // determine if battery is loading setState("javascript.0.Solarpower.Derived.IsBatteryLoading", getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.ChargeAndDischargePower").val > 0 ? 0 : 1); // determine if power is imported or exported setState("javascript.0.Solarpower.Derived.IsGridExporting", getState("javascript.0.Solarpower.Huawei.Meter.ActivePower").val > 0 ? 1 : 0); // compute export and import today setState("javascript.0.Solarpower.Derived.GridExportToday", getState("javascript.0.Solarpower.Huawei.Meter.PositiveActiveEnergy").val - getState("javascript.0.Solarpower.Derived.GridExportSum").val); setState("javascript.0.Solarpower.Derived.GridImportToday", getState("javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy").val - getState("javascript.0.Solarpower.Derived.GridImportSum").val); // compute consumption today setState("javascript.0.Solarpower.Derived.ConsumptionSum", getState("javascript.0.Solarpower.Huawei.Inverter.1.AccumulatedEnergyYield").val + getState("javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy").val - getState("javascript.0.Solarpower.Huawei.Meter.PositiveActiveEnergy").val); setState("javascript.0.Solarpower.Derived.ConsumptionToday", getState("javascript.0.Solarpower.Derived.ConsumptionSum").val - getState("javascript.0.Solarpower.Derived.ConsumptionStart").val); testCreateState = 1; // do not check on createState any more console.debug("Processing done!"); // this was originally .log } var triggerprocessing = 0; var currentinverter = 1; setInterval(function() // ------------------- // This is the main function triggering a read via modbus-tcp every 2 seconds - changed to 5 seconds // Processing of data is triggered as soon as one complete set of registers is copied // with 5 seconds, new values are displyed every 50 seconds { if (triggerprocessing == 1) { triggerprocessing = 0; ProcessData(); } // this was originally also a .log console.debug("Triggering read of inverter " + currentinverter + " at address " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0] + " with length " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); readRegisterSpace(currentinverter, RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0], RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); RegisterSpacesToReadContinuouslyPtr++; if (RegisterSpacesToReadContinuouslyPtr >= RegisterSpacesToReadContinuously.length) { RegisterSpacesToReadContinuouslyPtr = 0; currentinverter++ if (currentinverter > ModBusIDs.length) { currentinverter = 1; triggerprocessing = 1; } } }, 5000); // one minute before midnight - perform housekeeping actions schedule("59 23 * * *", function () { // reset peak power for next day setState("javascript.0.Solarpower.Derived.PeakPanelPower", 0); // copy current export/import kWh - used to compute daily import/export in kWh setState("javascript.0.Solarpower.Derived.GridExportSum", getState("javascript.0.Solarpower.Huawei.Meter.PositiveActiveEnergy").val); setState("javascript.0.Solarpower.Derived.GridImportSum", getState("javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy").val); // copy consumption Sum to Start for the next day setState("javascript.0.Solarpower.Derived.ConsumptionStart", getState("javascript.0.Solarpower.Derived.ConsumptionSum").val); // log important iformation to file SolarPowerLogging(); }); function SolarPowerLogging() //-------------------------- // write values of today in file { // get var log1 = getState("javascript.0.Solarpower.Derived.YieldToday").val; var log2 = getState("javascript.0.Solarpower.Derived.GridExportToday").val; var log3 = getState("javascript.0.Solarpower.Derived.GridImportToday").val; var log4 = getState("javascript.0.Solarpower.Derived.ConsumptionToday").val; // Zerlege Datum und Zeit in Variable var now = new Date(); var year = now.getFullYear(); var month = addZero(now.getMonth() + 1); var day = addZero(now.getDate()); var currDate = day + '.' + month + '.' + year; var string = " "; // create string that is appended to the file string = currDate + ";" + log1.toFixed(3) + ";" + log2.toFixed(3) + ";" + log3.toFixed(3) + ";" + log4.toFixed(3) + "\n"; fs.appendFileSync("/opt/iobroker/iobroker-data/SolarpowerLog.csv", string); // erzeuge Log-Eintrag log("Solerpower log:" + string, "info"); } function addZero(Num) //----------------- // if number <10 add zero values at the beginning of numbers { if (Num < 10) Num = "0" + Num; return Num; }@chris_b
Für das Schreiben der Log-Datei würde ich noch vorschlagen, die Nachkommastellen-Punkte in Kommata umzuwandeln, also so in der Art:string = currDate + ";" + log1.toFixed(2).replace('.',',') + ";" + log2.toFixed(2).replace('.',',') ...Ansonsten habe ich die Register nach "Wichtigkeit" sortiert
// These register spaces need to be read: const RegisterSpacesToReadContinuously = [[32000, 116], // Inverter.ActivePower: 32080, Inverter.InputPower: 32064 [37100, 114], // Meter.ActivePower: 37113 [37700, 100], // Inverter.Battery.SOC: 37760, Inverter.Battery.ChargeAndDischargePower: 37765 [47075, 10], // MaximumChargingPower,... [37000, 68], // Batterystack,... [37800, 100], // Batterystack [38200, 100], // Batterystack [38300, 100], // Batterystack [38400, 100], // Batterystack [30000, 81] // --> ProcessDeviceInfo() // [35300, 40] // Inverter.ActiveAdjustement.* ];und lasse nur die ersten 4 regelmäßig auslesen und nur alle 50 Runden mal (~ jede Viertel Stunde) alle zusammen. Weil ich nur eine Batterie habe ergibt das bei mir also alle 16s frische Daten (immerhin...).
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@chris_b
Für das Schreiben der Log-Datei würde ich noch vorschlagen, die Nachkommastellen-Punkte in Kommata umzuwandeln, also so in der Art:string = currDate + ";" + log1.toFixed(2).replace('.',',') + ";" + log2.toFixed(2).replace('.',',') ...Ansonsten habe ich die Register nach "Wichtigkeit" sortiert
// These register spaces need to be read: const RegisterSpacesToReadContinuously = [[32000, 116], // Inverter.ActivePower: 32080, Inverter.InputPower: 32064 [37100, 114], // Meter.ActivePower: 37113 [37700, 100], // Inverter.Battery.SOC: 37760, Inverter.Battery.ChargeAndDischargePower: 37765 [47075, 10], // MaximumChargingPower,... [37000, 68], // Batterystack,... [37800, 100], // Batterystack [38200, 100], // Batterystack [38300, 100], // Batterystack [38400, 100], // Batterystack [30000, 81] // --> ProcessDeviceInfo() // [35300, 40] // Inverter.ActiveAdjustement.* ];und lasse nur die ersten 4 regelmäßig auslesen und nur alle 50 Runden mal (~ jede Viertel Stunde) alle zusammen. Weil ich nur eine Batterie habe ergibt das bei mir also alle 16s frische Daten (immerhin...).
@r4
Interessanter Input!
Zu 1: Es gibt da die kleinen, subtilen Unterschiede zwischen Deutschland und der Schweiz... :blush: Und wir hier in der Schweiz verwenden tatsächlich einen Punkt für die Nachkommastellen von Zahlen (das weiss bspw. auch Excel und Windows im Allgemeinen). In diesem Sinn wäre diese Änderung für mich falsch. Nach meiner Meinung sollte das durch die Ländereinstellungen im iobroker gelöst sein..
Zu 2) Das wollte ich auch noch in Angriff nehmen. Guter Lösungsvorschlag; verringert die Kommunikation auf ein 'sinnvolles' Mass. Werde ich auch umsetzen.
Danke für den Input
Christian -
@chris_b sagte in Huawei Sun2000 & ioBroker via JS script funktioniert:
@r4
Interessanter Input!
Zu 1: ... Nach meiner Meinung sollte das durch die Ländereinstellungen im iobroker gelöst sein..Muss ich mir mal anschauen (bin neu in diesem Thema).
(Hab eh noch Probleme mit der Uhrzeit / Zeitzone... da wird meist die richtige angezeigt, z.B. in der Console, aber ich muss schedule("59 21 * * *") angeben um 23:59 Uhr zu triggern :man-shrugging: )Im Übrigen... so funktioniert es besser:
string = log1.toFixed(2) + ";" + log2.toFixed(2) + ";" + log3.toFixed(2) + ... string = currDate + ";" + string.replaceAll(".",","); -
@chris_b
Für das Schreiben der Log-Datei würde ich noch vorschlagen, die Nachkommastellen-Punkte in Kommata umzuwandeln, also so in der Art:string = currDate + ";" + log1.toFixed(2).replace('.',',') + ";" + log2.toFixed(2).replace('.',',') ...Ansonsten habe ich die Register nach "Wichtigkeit" sortiert
// These register spaces need to be read: const RegisterSpacesToReadContinuously = [[32000, 116], // Inverter.ActivePower: 32080, Inverter.InputPower: 32064 [37100, 114], // Meter.ActivePower: 37113 [37700, 100], // Inverter.Battery.SOC: 37760, Inverter.Battery.ChargeAndDischargePower: 37765 [47075, 10], // MaximumChargingPower,... [37000, 68], // Batterystack,... [37800, 100], // Batterystack [38200, 100], // Batterystack [38300, 100], // Batterystack [38400, 100], // Batterystack [30000, 81] // --> ProcessDeviceInfo() // [35300, 40] // Inverter.ActiveAdjustement.* ];und lasse nur die ersten 4 regelmäßig auslesen und nur alle 50 Runden mal (~ jede Viertel Stunde) alle zusammen. Weil ich nur eine Batterie habe ergibt das bei mir also alle 16s frische Daten (immerhin...).
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Moin!
Das klingt interressant (wichtige Daten öfter)...
Magst Du mal Deinen Code für die Abfrage posten? Oder Dein gesamtes Script?
Danke Dir!
Mr.Leehab das Script inzwischen ganz schön umgebaut.
Zum Thema Priorisierung ist das hier wesentlich:// These register spaces need to be read: const RegisterSpacesToReadContinuously = [[32000, 116], // read often: Inverter.ActivePower: 32080, Inverter.InputPower: 32064 [37100, 114], // read often: Meter.ActivePower: 37113 [37700, 100], // read often: Inverter.Battery.SOC: 37760, Inverter.Battery.ChargeAndDischargePower: 37765 [47075, 10], // read often: MaximumChargingPower,... [37000, 68], // Batterystack,... --> read rarely [37800, 100], // Batterystack --> read rarely [38200, 100], // Batterystack --> read rarely [38300, 100], // Batterystack --> read rarely [38400, 100], // Batterystack --> read rarely [30000, 81] // ProcessDeviceInfo() --> read rarely // [35300, 40] // Inverter.ActiveAdjustement.* --> no use ]; var RegisterSpacesToReadContinuouslyPtr = 0; const RegisterSpacesToReadPrioLoops = 56; // number of fast read cycles before full read cycle (~ every 15 mins at 4s cycle time) const RegisterSpacesToReadFast = 4; // number of registers to be read fast var RegisterSpacesToReadPrioLoopCount = 0;Dazu kommen noch für meine Schreibarbeiten ins Register 47075 (mehr brauche ich derzeit nicht):
var triggerWriteProcessing = false; // write instead of read a register var batteryChargePower = 0; // value to be written into register 47075Die werden im Ablauf gesetzt durch on() oder durch zeitliche Ereignisse...
Dann die Intervall-Funktion:
setInterval(function() // ------------------- // This is the main function triggering a read or a write via modbus-tcp every xx seconds (see value below in ms) // Processing of data is triggered as soon as one complete set of registers is copied // with 4 seconds, new values are displyed every 16/40 seconds { var RegisterSpacesToReadContinuouslyLength; if (triggerprocessing == 1) { ProcessData(); triggerprocessing = 0; } if (triggerWriteProcessing == false) // read register (either read or write in one interval) { console.debug("Triggering read of inverter at address " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0] + " with length " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); readRegisterSpace(RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0], RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); RegisterSpacesToReadContinuouslyPtr++; if (RegisterSpacesToReadPrioLoopCount == 0) RegisterSpacesToReadContinuouslyLength = RegisterSpacesToReadContinuously.length; else RegisterSpacesToReadContinuouslyLength = RegisterSpacesToReadFast; // number of registers to be read if (RegisterSpacesToReadContinuouslyPtr >= RegisterSpacesToReadContinuouslyLength) { RegisterSpacesToReadContinuouslyPtr = 0; RegisterSpacesToReadPrioLoopCount++; if (RegisterSpacesToReadPrioLoopCount >= RegisterSpacesToReadPrioLoops) RegisterSpacesToReadPrioLoopCount = 0; triggerprocessing = 1; // everything was read, now set the datapoints } } else // triggerWriteProcessing == true --> write register { client.writeRegisters(47075, [0, batteryChargePower]); // write the value 0, xxx to registers starting at address 47075 triggerWriteProcessing = false; } }, 4000);Hinweis - statt
// get SOC of first battery stack and combine to one string var BatOverview = ""; for(var j = 1; j <= BatteryUnits[0][0]; j++) { if (j > 1) BatOverview += ", "; BatOverview += getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.Battery" + j + ".BatterySOC").val + "%"; } setState("javascript.0.Solarpower.Derived.BatteryOverview", BatOverview);hab ich, weil nur 5kWh Batterie:
// get SOC of all batteries and combine to one string (only one battery here...) var BatOverview = getState("javascript.0.Solarpower.Huawei.Inverter.Battery.SOC").val; setState("javascript.0.Solarpower.Derived.BatteryOverview", BatOverview);das spart Registerbereiche - Inverter.1.Batterystack.1.Battery.* wird bei mir ja nur noch alle 15 Minuten aktualisiert. Selbiges für YieldToday, IsBatteryLoading.
(und ja, den DP Derived.BatteryOverview könnte ich mir sparen indem ich gleich Inverter.Battery.SOC verwende...)
BatOverview und der DP Derived.BatteryOverview sind bei mir auch kein String, sondern 'ne Zahl, weil ich damit weiterrechne. -
hab das Script inzwischen ganz schön umgebaut.
Zum Thema Priorisierung ist das hier wesentlich:// These register spaces need to be read: const RegisterSpacesToReadContinuously = [[32000, 116], // read often: Inverter.ActivePower: 32080, Inverter.InputPower: 32064 [37100, 114], // read often: Meter.ActivePower: 37113 [37700, 100], // read often: Inverter.Battery.SOC: 37760, Inverter.Battery.ChargeAndDischargePower: 37765 [47075, 10], // read often: MaximumChargingPower,... [37000, 68], // Batterystack,... --> read rarely [37800, 100], // Batterystack --> read rarely [38200, 100], // Batterystack --> read rarely [38300, 100], // Batterystack --> read rarely [38400, 100], // Batterystack --> read rarely [30000, 81] // ProcessDeviceInfo() --> read rarely // [35300, 40] // Inverter.ActiveAdjustement.* --> no use ]; var RegisterSpacesToReadContinuouslyPtr = 0; const RegisterSpacesToReadPrioLoops = 56; // number of fast read cycles before full read cycle (~ every 15 mins at 4s cycle time) const RegisterSpacesToReadFast = 4; // number of registers to be read fast var RegisterSpacesToReadPrioLoopCount = 0;Dazu kommen noch für meine Schreibarbeiten ins Register 47075 (mehr brauche ich derzeit nicht):
var triggerWriteProcessing = false; // write instead of read a register var batteryChargePower = 0; // value to be written into register 47075Die werden im Ablauf gesetzt durch on() oder durch zeitliche Ereignisse...
Dann die Intervall-Funktion:
setInterval(function() // ------------------- // This is the main function triggering a read or a write via modbus-tcp every xx seconds (see value below in ms) // Processing of data is triggered as soon as one complete set of registers is copied // with 4 seconds, new values are displyed every 16/40 seconds { var RegisterSpacesToReadContinuouslyLength; if (triggerprocessing == 1) { ProcessData(); triggerprocessing = 0; } if (triggerWriteProcessing == false) // read register (either read or write in one interval) { console.debug("Triggering read of inverter at address " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0] + " with length " + RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); readRegisterSpace(RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][0], RegisterSpacesToReadContinuously[RegisterSpacesToReadContinuouslyPtr][1]); RegisterSpacesToReadContinuouslyPtr++; if (RegisterSpacesToReadPrioLoopCount == 0) RegisterSpacesToReadContinuouslyLength = RegisterSpacesToReadContinuously.length; else RegisterSpacesToReadContinuouslyLength = RegisterSpacesToReadFast; // number of registers to be read if (RegisterSpacesToReadContinuouslyPtr >= RegisterSpacesToReadContinuouslyLength) { RegisterSpacesToReadContinuouslyPtr = 0; RegisterSpacesToReadPrioLoopCount++; if (RegisterSpacesToReadPrioLoopCount >= RegisterSpacesToReadPrioLoops) RegisterSpacesToReadPrioLoopCount = 0; triggerprocessing = 1; // everything was read, now set the datapoints } } else // triggerWriteProcessing == true --> write register { client.writeRegisters(47075, [0, batteryChargePower]); // write the value 0, xxx to registers starting at address 47075 triggerWriteProcessing = false; } }, 4000);Hinweis - statt
// get SOC of first battery stack and combine to one string var BatOverview = ""; for(var j = 1; j <= BatteryUnits[0][0]; j++) { if (j > 1) BatOverview += ", "; BatOverview += getState("javascript.0.Solarpower.Huawei.Inverter.1.Batterystack.1.Battery" + j + ".BatterySOC").val + "%"; } setState("javascript.0.Solarpower.Derived.BatteryOverview", BatOverview);hab ich, weil nur 5kWh Batterie:
// get SOC of all batteries and combine to one string (only one battery here...) var BatOverview = getState("javascript.0.Solarpower.Huawei.Inverter.Battery.SOC").val; setState("javascript.0.Solarpower.Derived.BatteryOverview", BatOverview);das spart Registerbereiche - Inverter.1.Batterystack.1.Battery.* wird bei mir ja nur noch alle 15 Minuten aktualisiert. Selbiges für YieldToday, IsBatteryLoading.
(und ja, den DP Derived.BatteryOverview könnte ich mir sparen indem ich gleich Inverter.Battery.SOC verwende...)
BatOverview und der DP Derived.BatteryOverview sind bei mir auch kein String, sondern 'ne Zahl, weil ich damit weiterrechne.@r4 Hallo, da ich immer nur sporadisch hier rein schaue.. wo kann ich das von Dir umgebaute Script finden? Ich würde es doch gern mal wieder mit meiner Anlage probieren.. mit einer älteren Version des Scripts gab es bei mir zu viele Probleme bzw. Fehlermeldungen und komische Daten.
DANKE!!
Viele Grüße!! -
@r4 Hallo, da ich immer nur sporadisch hier rein schaue.. wo kann ich das von Dir umgebaute Script finden? Ich würde es doch gern mal wieder mit meiner Anlage probieren.. mit einer älteren Version des Scripts gab es bei mir zu viele Probleme bzw. Fehlermeldungen und komische Daten.
DANKE!!
Viele Grüße!!@road_runner31
Sorry, da ich aus dem Script von chris_b zu viel Allgemeines rausgeworfen habe (ich werde z.B. absehbar nie einen zweiten WR oder mehrere Luna haben und habe auch keine Optimierer) kann ich dir auf diese Weise eher nicht weiterhelfen. Das "Originalscript" funktioniert doch ganz gut, da musst du praktisch nichts anpassen?!
Meine Erweiterungen müsstest du schon selbst einfügen, gewisse Programmier-Kenntnisse sind da sicher hilfreich... -
@road_runner31
Sorry, da ich aus dem Script von chris_b zu viel Allgemeines rausgeworfen habe (ich werde z.B. absehbar nie einen zweiten WR oder mehrere Luna haben und habe auch keine Optimierer) kann ich dir auf diese Weise eher nicht weiterhelfen. Das "Originalscript" funktioniert doch ganz gut, da musst du praktisch nichts anpassen?!
Meine Erweiterungen müsstest du schon selbst einfügen, gewisse Programmier-Kenntnisse sind da sicher hilfreich...@r4 Naja, mein Problem ist, dass auch das Originalscript (mit den notwendigen Anpassungen, also IP-Adresse, Anzahl Batterien) bei mir Fehler produziert.
javascript.0 2023-07-08 19:10:33.215 warn script.js.huawei.modbus_get: Error received reading address 32000 from id: 1 with error: undefined javascript.0 2023-07-08 19:10:13.214 warn script.js.huawei.modbus_get: Error received reading address 37100 from id: 1 with error: undefined javascript.0 2023-07-08 19:09:53.226 warn script.js.huawei.modbus_get: Error received reading address 30000 from id: 1 with error: undefined javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: getState(id=javascript.0.Solarpower.Derived.ConsumptionStart, timerId=undefined) => {"val":0,"ack":true,"ts":1688834773251,"q":0,"c":"script.js.huawei.modbus_get","from":"system.adapter.javascript.0","user":"system.user.admin","lc":1688834773251} javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: setForeignState(id=javascript.0.Solarpower.Derived.ConsumptionSum, state={"val":null,"ack":false,"ts":1688836193226,"q":0,"from":"system.adapter.javascript.0","lc":1688836193226,"c":"script.js.huawei.modbus_get"}) javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: getState(id=javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy, timerId=undefined) => {"val":0,"ack":false,"ts":1688835993211,"q":0,"c":"script.js.huawei.modbus_get","from":"system.adapter.javascript.0","user":"system.user.admin","lc":1688834993396} javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: setForeignState(id=javascript.0.Solarpower.Derived.GridImportToday, state={"val":0,"ack":false,"ts":1688836193226,"q":0,"from":"system.adapter.javascript.0","lc":1688834773249,"c":"script.js.huawei.modbus_get"}) javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: getState(id=javascript.0.Solarpower.Huawei.Meter.ReverseActiveEnergy, timerId=undefined) => {"val":0,"ack":false,"ts":1688835993211,"q":0,"c":"script.js.huawei.modbus_get","from":"system.adapter.javascript.0","user":"system.user.admin","lc":1688834993396} javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: getState(id=javascript.0.Solarpower.Derived.GridExportSum, timerId=undefined) => {"val":0,"ack":true,"ts":1688834773247,"q":0,"c":"script.js.huawei.modbus_get","from":"system.adapter.javascript.0","user":"system.user.admin","lc":1688834773247} javascript.0 2023-07-08 19:09:53.226 info script.js.huawei.modbus_get: setForeignState(id=javascript.0.Solarpower.Derived.IsGridExporting, state={"val":0,"ack":false,"ts":1688836193226,"q":0,"from":"system.adapter.javascript.0","lc":1688834773245,"c":"script.js.huawei.modbus_get"}) javascript.0 2023-07-08 19:09:53.225 info script.js.huawei.modbus_get: getState(id=javascript.0.Solarpower.Huawei.Meter.ActivePower, timerId=undefined) => {"val":0,"ack":false,"ts":1688835993211,"q":0,"c":"script.js.huawei.modbus_get","from":"system.adapter.javascript.0","user":"system.user.admin","lc":1688834993395} javascript.0Der Wechselrichter ist per Ping erreichbar, auch der Port stimmt. Die Objekte werden im iobroker auch erzeugt, steht allerdings überall 0 drin. :(
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@road_runner31
Sorry, da ich aus dem Script von chris_b zu viel Allgemeines rausgeworfen habe (ich werde z.B. absehbar nie einen zweiten WR oder mehrere Luna haben und habe auch keine Optimierer) kann ich dir auf diese Weise eher nicht weiterhelfen. Das "Originalscript" funktioniert doch ganz gut, da musst du praktisch nichts anpassen?!
Meine Erweiterungen müsstest du schon selbst einfügen, gewisse Programmier-Kenntnisse sind da sicher hilfreich...@r4 Ich habs gefunden.. bei mir läuft in einem anderen Docker-Containert "evcc", der steuert das PV-Überschussladen vom Auto. Und der "prügelt" sich anscheinend mit dem Script um den Modbus-Port :)
Mit denm Snippet, das den Verbindungsstatus checkt und neu connected ging es dann, aber wenn beide sich permanent neu auf den Port verbinden, ist das sicher auch nicht der gewünschte Effekt.. -
@r4 Ich habs gefunden.. bei mir läuft in einem anderen Docker-Containert "evcc", der steuert das PV-Überschussladen vom Auto. Und der "prügelt" sich anscheinend mit dem Script um den Modbus-Port :)
Mit denm Snippet, das den Verbindungsstatus checkt und neu connected ging es dann, aber wenn beide sich permanent neu auf den Port verbinden, ist das sicher auch nicht der gewünschte Effekt..@road_runner31 evcc hätte einen modbus proxy, ich würde den vorschalten.
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@r4 Ich habs gefunden.. bei mir läuft in einem anderen Docker-Containert "evcc", der steuert das PV-Überschussladen vom Auto. Und der "prügelt" sich anscheinend mit dem Script um den Modbus-Port :)
Mit denm Snippet, das den Verbindungsstatus checkt und neu connected ging es dann, aber wenn beide sich permanent neu auf den Port verbinden, ist das sicher auch nicht der gewünschte Effekt..@road_runner31
Ja, nur ein Zugriff geht.
Wie meloneA sagt, ggf. über einen Proxy ("Vermittler") gehen...(Insgesamt etwas schwach, dieser Dongle. Ist mir auch noch nirgends untergekommen, dass man (mit aktueller HW) sooo lange aufs einfache Datenauslesen warten muss!)
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@road_runner31
Ja, nur ein Zugriff geht.
Wie meloneA sagt, ggf. über einen Proxy ("Vermittler") gehen...(Insgesamt etwas schwach, dieser Dongle. Ist mir auch noch nirgends untergekommen, dass man (mit aktueller HW) sooo lange aufs einfache Datenauslesen warten muss!)
Eigentlich läuft alles, aber nun, wo ich die Daten auswerte fällt mir folgendes auf:
ForceSetState("Solarpower.Huawei.Inverter." + id + ".AccomulatedEnergyYield", GetU32(globalDataBuffer[id-1], 32106), {name: "", unit: "kWh"});Der Wert ist doch das, was die PV Anlage seit Inbetriebnahme generiert hat?
In den Objekten ergibt dieser Wert bei mir
Aber auf der Weboberfläche von FS steht
Sprich ich habe in den Objekten 205,325 mWh und im Portal 3,59 mWh.
Wie kommt das? -
Eigentlich läuft alles, aber nun, wo ich die Daten auswerte fällt mir folgendes auf:
ForceSetState("Solarpower.Huawei.Inverter." + id + ".AccomulatedEnergyYield", GetU32(globalDataBuffer[id-1], 32106), {name: "", unit: "kWh"});Der Wert ist doch das, was die PV Anlage seit Inbetriebnahme generiert hat?
In den Objekten ergibt dieser Wert bei mir
Aber auf der Weboberfläche von FS steht
Sprich ich habe in den Objekten 205,325 mWh und im Portal 3,59 mWh.
Wie kommt das?@hussi sagte in Huawei Sun2000 & ioBroker via JS script funktioniert:
AccomulatedEnergyYield
Bei mir ist das jetzt:
forcesetState("Solarpower.Huawei.Inverter.AccumulatedEnergyYield", getU32(GlobalDataBuffer, 32106) / 100, {name: "", unit: "kWh"});("AccumulatedEnergyYield" und "/100")
und das passt bei mir mit Web-"Gesamtenergieertrag" überein.
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@hussi sagte in Huawei Sun2000 & ioBroker via JS script funktioniert:
AccomulatedEnergyYield
Bei mir ist das jetzt:
forcesetState("Solarpower.Huawei.Inverter.AccumulatedEnergyYield", getU32(GlobalDataBuffer, 32106) / 100, {name: "", unit: "kWh"});("AccumulatedEnergyYield" und "/100")
und das passt bei mir mit Web-"Gesamtenergieertrag" überein.
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Moin,
bei mir läuft aktuell das Code-Red Script, ich hab es aber noch ein bisschen erweitert.
Habe aber ein Problem mit den Optimierern, weiss jemand wie ich über Modbus die Optimierer Dateien pullen kann?
Habe einen 10KTL-M1 mit 30kw Akku und 35x 390er Module, an String 1 sind 20 Module mit Optimierer an drei Hausseiten (Ost-West-Südfasade). Ich würde gern die Leistung der einzelnen Seiten auslesen.
Für jede Hilfe wäre ich dankbar.
Sonnige Grüße
Til -
Moin,
bei mir läuft aktuell das Code-Red Script, ich hab es aber noch ein bisschen erweitert.
Habe aber ein Problem mit den Optimierern, weiss jemand wie ich über Modbus die Optimierer Dateien pullen kann?
Habe einen 10KTL-M1 mit 30kw Akku und 35x 390er Module, an String 1 sind 20 Module mit Optimierer an drei Hausseiten (Ost-West-Südfasade). Ich würde gern die Leistung der einzelnen Seiten auslesen.
Für jede Hilfe wäre ich dankbar.
Sonnige Grüße
Til@agent-til
Für Optimierer gibt es (noch) keinen Zugriff über Modbus.
Wohl nur über die API: https://forum.huawei.com/enterprise/en/communicate-with-fusionsolar-through-an-openapi-account/thread/591478-100027 -
@agent-til
Für Optimierer gibt es (noch) keinen Zugriff über Modbus.
Wohl nur über die API: https://forum.huawei.com/enterprise/en/communicate-with-fusionsolar-through-an-openapi-account/thread/591478-100027Es ist ein wenig zusätzlicher Aufwand notwendig, aber es geht auch lokal:
https://gitlab.com/Emilv2/huawei-solar/-/blob/master/src/huawei_solar/files.py
https://github.com/wlcrs/huawei-solar-lib -
Es ist ein wenig zusätzlicher Aufwand notwendig, aber es geht auch lokal:
https://gitlab.com/Emilv2/huawei-solar/-/blob/master/src/huawei_solar/files.py
https://github.com/wlcrs/huawei-solar-lib
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