Xantrex Technology PS2.5, PS3.0 installation and operation guide Operation

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Section 5: Operation

After all the AC and DC wiring has been installed, you can follow the instructions below to perform the initial startup. First, take a moment to go back over all connections and make sure they are secure and in the proper terminal. If the system utilizes flooded lead-acid type batteries instead of sealed gel- cell type, use the ACS or the DIP switch settings to change the set-up for battery type from gel-cell to flooded lead-acid. If you don’t know which battery type you have, use the gel-cell setting just to be safe, and then contact the battery manufacturer.

1.Verify that the DIP switch settings are correct for your system. See “Section 3: Configuration” if you have the standard control panel, or the ACS Control Panel section if you have that.

2.Check to see that the inverter BYPASS/ON slide switch is in the BYPASS position.

3.Connect the battery cable (or close the battery disconnect switch) to complete the battery circuit. Turn the inverter BYPASS/ON slide switch to the ON position. The System Startup Default is set at the factory at INV OFF/ CHG ON. Press the Inverter ON/OFF switch on the control panel to enable the inverter. When the DC connection is completed, the inverter will begin inverting if there is an AC load and the AC shorepower has not been connected.

4.Place a load on the inverter (plug in a light or other load to an outlet the inverter is powering), and make sure it works. The inverter should run a load without AC shorepower connected (battery only).

5.If the inverter does not come on or go through the start-up, check all connections. Check the inverter’s DC voltage on the positive (+) and negative (–) terminals. If the DC voltage is low or if the battery bank needs to be charged, go directly to Step 6.

6.To charge your batteries, connect shorepower to the inverter by plugging in the shorepower cord and turning on the shorepower breaker. After a few seconds delay, the utility/shorepower LED should light and the Charge LED on the front of the inverter should indicate it is charging. This indicates the charger is working properly. Any AC loads connected to the AC output should also work at this point.

The delay before connecting to the utility AC supply is the inverter sampling the shorepower to see that it is within acceptable frequency and voltage limits. This delay also allows time for a generator to spin up to a stable operating condition before the inverter/charger places a load on it.

7.Disconnect shorepower by turning the shorepower breaker off, or unplugging the shorepower. The inverter should transfer to inverter mode immediately. This will be indicated by a clicking sound as the internal transfer relays change position. The loads should continue to operate uninterrupted.

The preceding steps will complete a functional test of the inverter. If all areas pass, the inverter is ready for use. If any area fails, determine why before proceeding. “Appendix C: Troubleshooting” will help you solve problems you encounter.

Prosine 2.5/3.0 Installation & Operation Guide

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Contents PS2.5 PS3.0 Page ProsineTM Installation and Operation GuideDate and Revision Important Safety Instructions Precautions When Working with Batteries Materials List System / Installation Information Inverter/Charger Components Prosine 2.5/3.0 Installation & Operation Guide Warranty Product DisclaimerReturn Material Authorization Policy Return Procedure Contents Configuration Operation Appendix B Inverter Applications Battery Charger Features FeaturesInverter Features Features Inverter Features DIP Switch Panel Controls and IndicatorsAccessory Jacks DC Terminals & Covers AC Bypass SelectorAC Terminals & Covers Standard LED Control Panel Display Standard LED Control PanelFaults Indicators & Reset Button Battery Status IndicatorInverter Status Indicators and On/Off Button Charger Status Indicator and On/Off Button Power IndicatorMounting and Installing the LED Control Panel ACS Control Panel Control Buttons Liquid Crystal DisplayACS Menu Tree Menu Navigation ProcedureAC Information Menu Inverter Information Menu Battery Information MenuCharger Status Charger Information MenuSystem Information Menu Version Information Menu Inverter Status Indicators and On/Off Button Faults Display & Reset ButtonCharger Status Indicator and On/Off Button Power IndicatorMounting and Installing the ACS Control Panel Battery Temperature Sensor Battery Temperature SensorBattery Temperature Sensor DIP Switch Settings ConfigurationBattery Temperature Battery TypeNot used Load SenseSwitch Breaker MaxAC Switch 2 Not Used RatingAmps CurrentDrawSwitch 5, 6, 7 12V 24VUser Configuration Items ACS ConfigurationInstaller Configuration Items ACS Configuration Considerations AC Shorepower Configuration Battery Type Battery ConfigurationBattery Size Battery Temperature Battery Info Type Flooded Load Sense TURN- on POWER1401 W Inverter ConfigurationHigh and Low Voltage Alarms and Cutoffs Charger ConfigurationEqualize is NOW Disabled Equalize is NOW Enabled System Configuration Safety Instructions Inverter/Charger InstallationInstallation Overview Installation Overview Inverter/Charger Installation Designing the Installation Gfci Models Tools and Materials Required Where to Install the Prosine Inverter/ChargerAmbient temperature deg. C Mounting the Prosine Inverter/Charger AC and DC Wiring Separation Recommended Wire Size vs Breaker RatingAC Cabling AC Disconnect and Overload ProtectionDC Cabling Wire Size Fuse SizeDC Over-Current Protection DC Disconnect Battery Cable RoutingDC Cabling Connections 10 ft 15 ft 20 ft 30 ftRecommended DC Cable Sizes For Proper Operation DC Cabling ProcedureDC Grounding Connecting the Battery Temperature SensorMounting Options BTS Attached to Negative Battery Terminal Mounting to the Negative Battery TerminalBTS Attached to Battery Case Mounting to the Side of the Battery CaseResidential Backup System Typical System DiagramsRecreational Vehicle System Residential Solar and Wind System Operation Operating Limits for Inverter Operation Prosine Inverter Load Sense ModeProsine Operating Voltage Limits Operating Limits for Inverter Operation Charging Profile Multistage ChargingBulk Charge Absorption ChargeEqualization Charge Float ChargeOperation in Equalization Mode Operation in Charger ModeEqualization Procedure Adjustable Charger Mode Settings Operating Limits for Charger Operation Battery Charging TimesModel Flooded Comments Gel Battery Charging and Equalization GuideAGM Operating Limits for Charger Operation Terminology BatteriesTypes Deep-Cycle Batteries Starting BatteriesSealed Gel Cell TemperatureEnvironment LocationEstimating Battery Requirements Battery Bank SizingBattery Sizing Example Battery Bank Sizing Example & WorksheetBattery Sizing Worksheet Cleaning Batteries Monthly Battery MaintenancePreparation AttireEquipment ProcedureSupplies Cables Cabling & Hook-up ConfigurationsParallel Connection 50 Ah100 Ah Series Connection24V Series Parallel ConnectionCabling & Hook-up Configurations Prosine 2.5 12-volt Prosine 3.0 12-volt Appendix a SpecificationsVolt in parenthesis Prosine 2.5 12-volt Prosine 3.0 12-volt Volt in parenthesis Charger Output VoltagesProsine 2.5/3.0 Chassis Dimensions Prosine 2.5/3.0 Chassis Dimensions with Brackets Prosine Over-Current Shutdown Response Prosine 2.5 Efficiency CurveProsine 2.5 Efficiency 120Vac, 12Vdc model Prosine 2.5/3.0 Installation & Operation Guide Appendix B Inverter Applications Problem Loads in Load SenseResistive Loads Inductive LoadsOther Problem Loads What to do if a problem occurs Appendix C TroubleshootingControl Panel Error Code Displays and What They MeanAdvanced Control System ACS Error Description of Fault Possible Cause Solution Code Error Code TableError Code Table Appendix C Troubleshooting Error Description of Fault Possible Cause Solution Code Error Description of Fault Possible Cause Solution Code Error Code Table Index Index Gases, battery venting, 50 gel-cell,30 Index Index 100 Page 445-0096-01-01

PS3.0, PS2.5 specifications

Xantrex Technology has made significant strides in the power electronics sector with the introduction of their PS2.5 and PS3.0 inverter models. These inverters are designed primarily for solar energy applications, offering reliable and efficient power conversion for residential and commercial solar installations. The PS series stands out in the market due to its advanced features, innovative technologies, and user-friendly characteristics.

One of the main features of the Xantrex PS2.5 and PS3.0 inverters is their high efficiency rating, typically above 97%. This means that a minimal amount of energy is lost during conversion, allowing users to maximize their solar energy utilization. Additionally, these inverters come with a wide input voltage range, making them versatile and capable of handling various solar panel configurations.

Both models are equipped with advanced MPPT (Maximum Power Point Tracking) technology. This feature optimizes the energy output from solar panels by constantly adjusting the operating point to ensure maximum power is extracted, even in variable weather conditions or partial shading. This capability significantly enhances the overall energy harvest from solar systems.

Another notable characteristic is their compact and lightweight design, which facilitates easy installation and integration into existing systems. The inverters are also designed with robust thermal management solutions, ensuring they operate effectively even in high-temperature environments. This durability extends their lifespan and increases reliability, critical factors for any solar installation.

Xantrex has also prioritized user experience with the PS2.5 and PS3.0 models by providing a built-in monitoring system. Users can access real-time data on energy production, performance metrics, and system status through a user-friendly interface. This connectivity allows for quick troubleshooting and maintenance, thus enhancing the overall efficiency of solar energy systems.

Safety is paramount in the design of these inverters. They meet stringent international safety standards and come equipped with comprehensive protection features, including over-voltage, under-voltage, and short-circuit protection. This ensures the inverter operates safely, protecting both the user and the connected solar array.

In summary, Xantrex Technology's PS2.5 and PS3.0 inverters are engineered with cutting-edge features and technologies that cater to the evolving needs of solar energy users. Their efficiency, adaptability, and focus on safety make them an excellent choice for those looking to invest in renewable energy solutions. As the demand for sustainable energy continues to rise, Xantrex is poised to play a significant role in the market with these innovative inverter solutions.