Xantrex Technology PS3.0, PS2.5 Starting Batteries, Deep-Cycle Batteries

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Types

Your Prosine inverter/charger is designed to be used with deep-cycle, lead-acid batteries. These batteries are designed for deep discharge service where they will be repeatedly charged and discharged. This type of battery is often labeled as a marine, recreational vehicle, or golf cart battery. Xantrex recommends you use one or more of these batteries separated from the starting battery of your vehicle or boat with a battery isolator.

Starting Batteries

Starting batteries are designed for high cranking power, not deep discharge cycling. Do not use them with your inverter. They do not hurt the inverter but they simply will not last long in a deep-cycle application. The way they are rated should give a good indication of their intended use: “Cold Cranking Amps” is a measure of the amperage output of a starting battery.

Starting batteries use lots of thin plates to maximize the surface area of the battery. This allows very high starting current but allows the plates to warp when the battery is cycled. The most familiar lead- acid battery is probably the starting battery in your automobile. An automotive starting battery is designed to deliver a large amount of current for a short period of time (so it can start your engine). Only a small portion of the battery’s capacity is used when starting the engine and it is quickly recharged by the running engine. It is not designed for repeated charge-discharge cycles where the battery is almost completely discharged and then recharged. Starting batteries used in this kind of deep discharge service will wear out rapidly.

Deep-Cycle Batteries

Deep-cycle batteries are best suited for use with inverters. They are designed to have the majority of their capacity used before being recharged. Available in many sizes and types, the most common type is the non-sealed, liquid electrolyte “flooded” battery used in boats and motor homes. Non-sealed types have removable battery caps. The caps should be removed at least monthly to check the level of electrolyte. When a cell is low, only distilled water should be added. The electrolyte level should be checked monthly and topped up if needed after recharging.

The many different types of deep cycle lead acid batteries can be grouped into four categories: flooded (or wet), sealed flooded (“maintenance free”), recombinant flooded (often “starved electrolyte”), and gel batteries.

Another popular and inexpensive battery of this type is the “golf car” (T-105 or CG220) battery. Rated at about 220 amp-hours, these six-volt batteries can be connected in series to produce 12- or 24-volt battery banks, and discharged repeatedly to 80% of their capacity without being damaged. This is the minimum quality of battery that should be used with the Prosine inverter in normal applications.

Some systems use the L16 type of battery. These are 6-volt batteries rated at 350 amp-hours and are available from a number of manufacturers. They are 17 inches (430mm) in height and weigh up to 130 pounds (60kg) each—which may be troublesome in some installations.

Type 8D batteries are available in either cranking or deep-cycle construction. The deep-cycle versions are 12-volt batteries rated at 200 amp-hours or so. Since they are most commonly used to start truck engines, you should make sure you purchase the deep cycle version, not the cranking version. Type 4D batteries are very similar in construction, but somewhat smaller (about 170Ah).

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Prosine 2.5/3.0 Installation & Operation Guide

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Contents PS2.5 PS3.0 Page Installation and Operation Guide ProsineTMDate 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 Disclaimer ProductReturn Material Authorization Policy Return Procedure Contents Configuration Operation Appendix B Inverter Applications Features Battery Charger FeaturesInverter Features Features Inverter Features Accessory Jacks Controls and IndicatorsDIP Switch Panel AC Terminals & Covers AC Bypass SelectorDC Terminals & Covers Standard LED Control Panel Standard LED Control Panel DisplayBattery Status Indicator Faults Indicators & Reset ButtonInverter Status Indicators and On/Off Button Power Indicator Charger Status Indicator and On/Off ButtonMounting and Installing the LED Control Panel ACS Control Panel Liquid Crystal Display Control ButtonsMenu Navigation Procedure ACS Menu TreeAC Information Menu Battery Information Menu Inverter Information MenuCharger Information Menu Charger StatusSystem Information Menu Version Information Menu Faults Display & Reset Button Inverter Status Indicators and On/Off ButtonPower Indicator Charger Status Indicator and On/Off ButtonMounting and Installing the ACS Control Panel Battery Temperature Sensor Battery Temperature SensorBattery Temperature Sensor Configuration DIP Switch SettingsNot used Battery TypeBattery Temperature Load SenseSwitch 5, 6, 7 Switch 2 Not Used RatingAmps CurrentDrawSwitch Breaker MaxAC 12V 24VInstaller Configuration Items ACS ConfigurationUser Configuration Items ACS Configuration Considerations AC Shorepower Configuration Battery Size Battery Temperature Battery ConfigurationBattery Type Battery Info Type Flooded Inverter Configuration Load Sense TURN- on POWER1401 WCharger Configuration High and Low Voltage Alarms and CutoffsEqualize is NOW Disabled Equalize is NOW Enabled System Configuration Installation Overview Inverter/Charger InstallationSafety Instructions Installation Overview Inverter/Charger Installation Designing the Installation Gfci Models Where to Install the Prosine Inverter/Charger Tools and Materials RequiredAmbient temperature deg. C Mounting the Prosine Inverter/Charger AC Cabling Recommended Wire Size vs Breaker RatingAC and DC Wiring Separation AC Disconnect and Overload ProtectionDC Over-Current Protection Wire Size Fuse SizeDC Cabling DC Cabling Connections Battery Cable RoutingDC Disconnect 10 ft 15 ft 20 ft 30 ftDC Cabling Procedure Recommended DC Cable Sizes For Proper OperationMounting Options Connecting the Battery Temperature SensorDC Grounding Mounting to the Negative Battery Terminal BTS Attached to Negative Battery TerminalMounting to the Side of the Battery Case BTS Attached to Battery CaseTypical System Diagrams Residential Backup SystemRecreational Vehicle System Residential Solar and Wind System Operation Prosine Inverter Load Sense Mode Operating Limits for Inverter OperationProsine Operating Voltage Limits Operating Limits for Inverter Operation Bulk Charge Multistage ChargingCharging Profile Absorption ChargeFloat Charge Equalization ChargeEqualization Procedure Operation in Charger ModeOperation in Equalization Mode Adjustable Charger Mode Settings Battery Charging Times Operating Limits for Charger OperationBattery Charging and Equalization Guide Model Flooded Comments GelAGM Operating Limits for Charger Operation Types BatteriesTerminology Starting Batteries Deep-Cycle BatteriesEnvironment TemperatureSealed Gel Cell LocationBattery Bank Sizing Estimating Battery RequirementsBattery Bank Sizing Example & Worksheet Battery Sizing ExampleBattery Sizing Worksheet Preparation Monthly Battery MaintenanceCleaning Batteries AttireSupplies ProcedureEquipment Parallel Connection Cabling & Hook-up ConfigurationsCables 50 AhSeries Connection 100 AhSeries Parallel Connection 24VCabling & Hook-up Configurations Volt in parenthesis Appendix a SpecificationsProsine 2.5 12-volt Prosine 3.0 12-volt Charger Output Voltages Prosine 2.5 12-volt Prosine 3.0 12-volt Volt in parenthesisProsine 2.5/3.0 Chassis Dimensions Prosine 2.5/3.0 Chassis Dimensions with Brackets Prosine 2.5 Efficiency 120Vac, 12Vdc model Prosine 2.5 Efficiency CurveProsine Over-Current Shutdown Response Prosine 2.5/3.0 Installation & Operation Guide Resistive Loads Problem Loads in Load SenseAppendix B Inverter Applications Inductive LoadsOther Problem Loads Appendix C Troubleshooting What to do if a problem occursAdvanced Control System ACS Error Code Displays and What They MeanControl Panel Error Code Table Error Description of Fault Possible Cause Solution CodeError 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.