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SOURA MinSol V101Single Phase Mini Solar lighting System 50Hz, 230V sine wave output, Solar charge controller, Inverter diagnosis, with nano Watt Technology SOURA Solar lighting system on single chip50Hz sine wave output, Solar Charge Controller, System diagnosis, with nano Watt TechnologyHigh-Performance Inverter and Solar Charge controller IC:Accurate two 50 hz logically inverted PWM sine wave outputsOn chip inverter diagnosisBattery voltage ,solar voltage and power supply monitorAutomatic backup on power cut with 3 different selectable power backup modesAutomatic switchover to inverter when in night, to use stored solar energySpecial Features:Complete Inverter and charge controller functionality on single chipConfigurable thresh hold battery voltages for charging, On Chip Inverter diagnosis, networking feature.Power Features:Controller Standby Current: 50 nA @ 2.0V, typicalController Operating Current: 220uA @ 4 MHz, 2.0V, typicalSystem Operating current standby : TBCSystem Operating current Full load (60VA max) :TBCSafety futures:Load Over current protection Battery over current protection Battery reverse polarity protectionSolar panel reveres polarity protection 1. IC Overview1.1 Pin Diagram:2. Technical Document2.1 Functional Overview System consists of nine modules. They are FET driver and inverter module, Inverter diagnosis module, Battery voltage, Mains supply and solar voltage sensing module, Backup relay module, over current protection module and charge controller module.FET driver and inverter module: FET driver is responsible for operation of two FETs Field effect transistor, used to drive primary winding (low voltage side) of center tapped (12-0-20)v to 250v transformer. FET driver takes care that there will be no overlapping of transistor input signals.Inverter module is responsible for selecting mode of inverter operation (1:square wave, 2:modified sine wave and 3:pure sine wave).This module is also responsible for responding to abnormal condition such as low?battery voltage disconnect and providing backup incase of Abnormal Mains.Inverter module ( MinSol V101 ) is responsible for selecting different backup supply steerages discussed belowBackup supply Strategy modeConditionsDescriptionNormal ModeBattery and Inverter modules healthyInverter wakes up when mains supply is not presentBackup relay switches load to inverter supply. Backup relay switches load to mains supply when mains supply is present and inverter switches to low power modeFORCE modeNo conditionInverter wakes up and Backup relay switches load to inverter supply. This mode is useful when inverter is networked with IOT (internet of things) or when inverter is controlled by other device via networking.SOLAR Only Night ModeBattery and Inverter modules healthyInverter automatically wakes up and Backup relay switches load to inverter supply when there is no solar power available (night time). Backup relay switches load to mains supply when battery voltage falls below 10 volts. This mode can be used for solar powered street lights and can be used in home lighting to automatically utilize solar power stored in battery.SOLAR Only Hybrid ModeBattery and Inverter modules healthyInverter automatically wakes up and Backup relay switches load to inverter supply when there is mains power failure in (night time) .Battery voltage sensor module:Battery status module monitors battery voltage range and updates battery voltage status.Battery VoltageBattery Status< 10.2 V0:Battery Low 10.2V to 13.2 V 1:Battery Normal>13.2V 2:Battery Full Mains supply sensor module:Mains supply module monitors mains voltage status and updates mains supply voltage status.Mains VoltageMains Voltage Status<120 V RMS 0:Mains Dead>120 V RMS1:Mains voltage healthyBackup relay module: Backup relay module is responsible for switching over of load from mains supply to inverter supply or from inverter supply to mains supply voltage. Switching over is done based on the inverter backup mode strategy.Charge control module:Charge controller module is responsible for charging of batteries from solar energy. It also disconnects the battery from solar panes when fully charged. Charge controller is also responsible for protecting the reverse flow of current from battery to solar panel.Battery is charged using relay on off control and uses hysteresis charging method to enhance batter life.Diagnosis module:Inverter diagnosis module is responsible for reporting status of supply voltage, load sensor, inverter current, inverter voltage, relay status and all the software modules. This module also allows user to calibrate complete system parameters. This is done by Software UART at 1200 baud. This functionality is multiplexed and available only in diagnosis mode. Diagnosis mode can be achieved by proper jumper connection i.e. holding Mains supply sensor pin high and solar voltage sensor pin low at controller reset.Diagnosis service:Diagnosis service routine module is responsible for responding to user requested diagnosis service. User can read the inverter parameter values using RDBI (Read data by identifiers) services. User can perform actuator tests for relay inverter using AC (Actuator Control) services. User can configure System calibrations using Calibration service. Each service is responded with Acknowledgment signal on successful service execution. Send below services in ASCII format through comport. ServicedescriptionPhysical unitResolutionRange ResponseRemark01Battery voltageVolts0.10 to 24 -02Solar panel voltageVolts0.10 to 24- 03Mains Supply voltageStatus0: No Mains1: Mains present0 to 1 -04Makes charge controller relay on-- 05Makes charge controller relay off-06Makes mains relay on-07Makes mains relay off-08Makes inverter on09Makes inverter off10 -> dataSets battery threshold 1calibration11 -> dataSets battery threshhold2 calibration12 -> dataSets solar voltage for night /dark detection calibrationIncase of Service not available system responds with INVALID data 0x7F.System Safety:System is protected from Battery Over current, Inverter Overload, Battery reverse polarity and Solar panel reverse polarity. These safety futures are implemented in electronic hardware.Battery over voltage disconnects and Battery low voltage inverter cutoff is implemented as software functionality.Test Circuit:1) Original2) With corrections after self reviewPCB layout 1) Original2) After Self review and correctionsPCB Corrections:PCB component values:Gerber files uncorrectedGerber files with corrections will be updated in next release Note:1)Use 12v-0-12v, 230 v, 50va transformer for testing2) Use 2*10 watt cfl or 5 * 5watt cfl for testing3) Use 12v ,7Ah battery for testingPCB module sub circuit working:Video will be updated in next releaseInvertor casing CAD DESIGN:will be updated in next release Manual for assemblingManual for userHex file:Code file: will be updated in next releaseBasic algoritham: will be updated in next releaseNote: More advance functions are available in advance variant of product. Kindly check our blog.Statements in red are proposed and in development and are software enhancement, hardware remains same for minsolv101. Customer Support: For questions, demos, samples or comments regarding this publication, please write to us at sauraurjatech@Our YouTube channel: will be updated next releaseJoin us on Face book: will be updated next releaseVisit our blog : sauraurjatech.Make Our Globe Green ................
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