FXR Series Inverter/Charger FXR2012E FXR2024E FXR2348E VFXR2612E VFXR3024E VFXR3048E Operator’s Manual
About OutBack Power Technologies OutBack Power Technologies is a leader in advanced energy conversion technology. OutBack products include true sine wave inverter/chargers, maximum power point tracking charge controllers, and system communication components, as well as circuit breakers, batteries, accessories, and assembled systems.
Table of Contents Introduction .......................................................................................................... 7 Audience ................................................................................................................................................................................. 7 Symbols Used ........................................................................................................................................................................
Table of Contents Auxiliary Terminals ........................................................................................................................................................................45 System Display-Based Functions ................................................................................................................................. 48 Advanced Generator Start (AGS) ...........................................................................................................
Table of Contents List of Tables Table 1 Table 2 Table 3 Table 4 Table 5 Table 6 Table 7 Table 8 Table 9 Table 10 Table 11 Table 12 Table 13 Table 14 Table 15 Table 16 Table 17 Table 18 Table 19 Table 20 Table 21 Table 22 Table 23 Table 24 Table 25 Battery Indicator Values ............................................................................................................................. 11 Summary of Input Modes ....................................................................................
Table of Contents List of Figures Figure 1 Figure 2 Figure 3 Figure 4 Figure 5 Figure 6 Figure 7 Figure 8 Figure 9 Figure 10 Figure 11 Figure 12 Figure 13 Figure 14 Figure 15 Figure 16 Figure 17 Figure 18 Figure 19 Figure 20 6 FXR Series Inverter/Charger with Turbo Fan ......................................................................................... 8 MATE3 and AXS Port ................................................................................................................................
Introduction Audience This manual provides instructions for setup and operation of the product. It does not cover installation. The manual is intended to be used by anyone required to operate the FXR Series Inverter/Charger. Operators must be familiar with all the safety regulations pertaining to operating power equipment of this type as required by local code. Operators are advised to have basic electrical knowledge and a complete understanding of this equipment’s features and functions.
Introduction Welcome to OutBack Power Technologies Thank you for purchasing the OutBack FXR Series Inverter/Charger. It is designed to offer a complete power conversion system between batteries and AC power. As part of an OutBack Grid/Hybrid™ system, it can provide off-grid power, grid backup power, or grid-interactive service which sells excess renewable energy back to the utility.
Introduction Uses the MATE3™ System Display and Controller or the AXS Port™ SunSpec Modbus Interface (sold separately) for user interface as part of a Grid/Hybrid system Supports the OPTICS RE™ online tool1 for a cloud-based remote monitoring and control application MATE3 must have firmware revision 003.007.xxx or higher Requires the MATE3 or the AXS Port Visit www.outbackpower.com to download Uses the HUB10.
Introduction to include a MATE3 as part of the system. This provides the means to monitor system performance and respond quickly should it be necessary to correct a fault or shutdown condition. The MATE3’s Configuration Wizard is capable of automatically configuring inverters to a series of preset values. This is often more efficient than attempting to manually program each setting in each inverter. Affected fields include system type, battery charging, and AC source configuration.
Operation LED Indicators AUX Indicator (see page 45) Battery Indicators Status Indicators Figure 3 LED Indicators Battery Indicators The Battery LED indicators show the approximate battery state. (See IMPORTANT note below.) The Battery indicators and the Inverter Status indicators are independent. They may accompany each other depending on conditions. Common combinations are noted on page 12. A green indicator (FULL) means the batteries have an adequate charge at that time.
Operation Status Indicators STATUS INVERTER (Green): Solid: The FXR inverter is on and providing power. If accompanied by a solid yellow AC IN indicator (2), the inverter is also connected to the utility grid with an AC input mode that uses both inverter power and grid power (Support, Grid Tied, or GridZero). See page 13 for descriptions of AC input modes. Flashing: The inverter has been turned on but is idle. The inverter is likely in Search mode. See page 24.
Operation Inverter Functionality The FXR inverter can be used for many applications. Some of the inverter’s operations occur automatically. Others are conditional or must be enabled manually before they will operate. Most of the inverter’s individual operations and functions can be programmed using the system display. This allows customization or fine tuning of the inverter’s performance. Before operating the inverter: The operator needs to define the application and decide which functions will be needed.
Operation When multiple inverters are stacked together in parallel, the master inverter’s input mode is imposed on all slaves. (See the stacking section on page 39.) The slave settings are not changed; they retain any mode that was previously programmed. However, the slave will ignore its programmed mode and use that of the master. This also applies to any parameters in the mode menu (Voltage Limit, Connect Delay, and so on). The following pages compare the various functions of each input mode.
Operation NOTES: IMPORTANT: The inverter will draw energy from the batteries when the loads exceed the appropriate AC Limit. With sustained loads and no other DC source, the batteries may discharge to the Low Battery Cut-Out point. The inverter will shut down with a Low Battery error. (See pages 23 and 58.) To prevent the loss of power, load use should be planned accordingly. IMPORTANT: A “noisy” or irregular AC source may prevent Support from working normally.
Operation NOTES: The inverter has a delay before selling will begin. This function, the Re-Connect Delay Timer, has a default setting of one minute. During this time, the inverter will not connect to the utility grid. The timer is adjustable in the Grid Interface Protection menu (see below). Upon initial connection to the utility grid, the inverter may be required to perform a battery charging cycle. This may delay the operation of the grid-interactive function.
Operation The utility may simply name a standard to be followed. It may be necessary to look up the requirements for a local standard and program them accordingly.
Operation Backup Failure The Backup mode is intended for systems that have utility grid available as the primary AC source. This source will pass through the FXR inverter’s transfer circuit and will power the loads unless utility power is lost. If utility grid power is lost, then the inverter will supply energy to the loads from the battery bank. When the utility power returns, it will be used to power the loads again.
Operation Mini Grid mode is also incompatible with the Grid Use Time and Load Grid Transfer functions of the MATE3 system display. These functions do not have similar priorities to Mini Grid or HBX, but they do control the inverter’s connection and disconnection with the grid. Mini Grid should not be used with these functions. When deciding whether to use Mini Grid mode or HBX, the user should consider the aspects of each.
Operation NOTES: IMPORTANT: Setting DoD Volts too low will severely discharge the batteries. The battery bank may not have sufficient reserve to provide backup in the event of a grid failure. To prevent the loss of power, load use and the DoD Volts setting should be planned accordingly. If the renewable energy source is not greater than the size of the inverter loads, this mode will not work well over time. The renewable source must be capable of charging the batteries as well as running the loads.
Operation Table 2 Mode Summary Benefits Cautions Intended Charger Can use AC that may be Will pass irregular or unusable in other modes Can charge even with a poor generator or low-quality AC source low-quality power to the output; could damage sensitive loads Offset unavailable Source: Generator Loads: Nonsensitive devices Performs three-stage charge and goes silent as specified by settings Adds battery power to augment an AC source that has limited output Can use battery power Dr
Operation NOTES: 22 900-0169-01-00 Rev B
Operation Description of Inverter Operations The items in this section are operations common to all FXR inverters. These are used in most or all of the input modes described in the preceding section. Some of the items in this section are functions which can be manually selected, enabled, or customized. Other items are general topics or applications for the inverter. These items may not have their own menus, but their activity can still be influenced or optimized by changing certain settings.
Operation Output Voltage: The AC output voltage can be adjusted. Along with small changes, this allows the inverter to be used for different nominal voltages such as 220 Vac and 240 Vac. IMPORTANT: The output voltage can adjusted to a different nominal value for a particular region. Making this change will not affect the default input voltage range accepted by the inverter from an AC source. The input range must be adjusted manually. These changes should be made at the same time.
Operation NOTE: Increment sizes are difficult to define due to varying load characteristics. However, the default setting, 30 increments, is approximately sufficient to detect the load of one compact fluorescent light (CFL). A load which draws this amount or greater will “wake up” the inverter. Search mode is not particularly useful with loads requiring continuous power. (These loads include clocks, answering machines, and similar devices.
Operation allows certain models to sell power using the input connection. The Support mode can use battery power to assist a smaller AC source. When GridZero mode is selected, the battery charger cannot be used. See page 21 for descriptions of these and other input modes. AC Current Settings A A A The AC current settings, Grid Input AC Limit and Gen Input AC Limit, control the amount of current that the inverter draws from the source. Adjust these settings to match the input circuit breakers.
Operation Gen AC Input Mode and Limits). The settings are titled Voltage Limit Lower and Upper. There can be side effects to changing the range of allowed voltages. Each of the AC input selections has a settable Connect Delay. This is intended as a warmup period which allows an input source to stabilize before connection. The default setting for the Grid input is 0.2 minutes (12 seconds). The default setting for the Gen input is 0.5 minutes (30 seconds).
Operation Generator Input A generator should be sized to provide enough power for all inverters, both for loads and for battery charging. The generator’s voltage and frequency must match the inverter’s acceptance settings. It is usually recommended that the generator be sized at twice the wattage of the inverter system. Many generators may not be able to maintain AC voltage or frequency for long periods of time if they are loaded more than 80% of rated capacity.
Operation Battery Charging IMPORTANT: Battery charger settings need to be correct for a given battery type. Always follow battery manufacturer recommendations. Making incorrect settings, or leaving them at factory default settings, may cause the batteries to be undercharged or overcharged. Charge Current Batteries or battery banks usually have a recommended limit on the maximum current used for charging. Often this is calculated as a percentage or fraction of the battery capacity, represented by “C”.
Operation Limiting Charge Current (Multiple Inverters) It is not advisable to set Charger AC Limit less than 6 Aac in a stacked system. The Power Save function requires the master to activates the slave chargers in sequence only when the charge current exceeds 5 Aac. If the setting is less than 6, Power Save will not activate any other chargers. For more information on this function, see the Power Save section beginning on page 42.
Operation Advanced Battery Charging (ABC) Advanced battery technologies such as lithium-ion and sodium-sulfur may require very different settings from the inverter’s defaults or the three-stage cycle in general. The Charging Steps section describes the individual selections and behavior. All charger settings are adjustable for different priorities. For example, the Float voltage could be set higher than the Absorption voltage, or a step could be completely skipped.
Operation Time limit: Absorb Time setting. The charger does not necessarily run through its full duration if it retained time from a previous charge cycle. The timer counts down from the inception of the Absorption stage until it reaches zero. The time remaining can be viewed in the system display. The Absorption timer does not reset to its maximum amount, or to zero, when AC power is disconnected or reconnected.
Operation Time limit: Float Time setting. The charger will go Silent once the timer has expired (if another stage is not still in progress.) The Float timer is reset to its maximum amount whenever the batteries decrease to the Re-Float Voltage setting. NOTE: The Float timer begins running any time the battery voltage exceeds the Float Voltage set point. This usually means that it begins running during the Bulk stage, once the battery voltage rises above that level.
Operation Voltage Cycle 1 Absorption Silent Refloat Cycle 2 Float AC Loss Refloat Float Silent Absorption Set Point Float Set Point Re-Float Set Point Absorption timer runs Float timer resets Time Float timer runs (part) Float timer runs Inverter now charging to a new set point Inverter completed charging; the previous set point is no longer in use Inverter has reached the charging set point Inverter waiting to charge when AC restored; the previous set point is still in use Figure 7 Rep
Operation Cycle 3 AC Loss Cycle 5 Cycle 4 AC Loss Bulk Abs.
Operation Equalization Equalization is a controlled overcharge that is part of regular battery maintenance. Equalization brings the batteries to a much higher voltage than usual and maintains this high voltage for a period of time. This has the result of removing inert lead sulfate compounds from the battery plates. It also reduces stratification by circulating the electrolyte. Equalization follows the same pattern as standard three-stage charging, as shown in the figures on page 30.
Operation Battery Temperature Compensation Battery performance will change when the temperature varies above or below room temperature (77°F or 25°C). Temperature compensation is a process that adjusts battery charging to correct for these changes. When a battery is cooler than room temperature, its internal resistance goes up and the voltage changes more quickly. This makes it easier for the charger to reach its voltage set points.
Operation Offset Offset is an automatic operation which occurs in certain conditions. It is not a programmable function. This operation uses excess battery energy to power the loads when an AC source is present. The system can take advantage of renewable energy sources, “offsetting” dependence on the AC source. The battery voltage increases as a renewable energy source charges the batteries. When the voltage exceeds a designated reference voltage, the FXR inverter begins inverting.
Operation Multiple-Inverter Installations (Stacking) Multiple inverters in a single system can support larger loads than a single inverter. Installing inverters in this configuration is called “stacking”. Stacking refers to how inverters are wired within the system and programmed to coordinate activity. Stacking allows inverters to work together as one system. Each inverter is programmed to power an individual phase of the system and to operate at certain times.
Operation Stacking Configurations Each inverter must be assigned a particular mode in the Stack Mode menu. In the figures for each configuration below, the mode names are shown next to each inverter. For example, Figure 10 shows Master for the first inverter in a parallel-stacked system. The remaining inverters are designated Slave. Figure 11 and Figure 12 show Master and Slave designations for Phases A, B, and C in three-phase systems.
Operation LOAD PANEL Master 2.0 kVA 230 Vac 2.0 kVA 230 Vac B Phase Master 2.0 kVA 230 Vac 2.0 kVA 230 Vac OR 6.0 kVA 400 Vac C Phase Master 2.0 kVA 230 Vac 2.0 kVA 230 Vac Figure 11 Example of Three-Phase Stacking Arrangement (Three Inverters) LOAD PANEL Master 2.0 kVA 230 Vac 2.0 kVA 230 Vac B Phase Master C Phase Master Figure 12 900-0169-01-00 Rev B Slave 2.0 kVA 230 Vac 2.0 kVA 230 Vac 2.0 kVA 230 Vac Slave Slave 2.0 kVA 230 Vac Slave 2.0 kVA 230 Vac 6.0 kVA 230 Vac Slave 2.
Operation Power Save Each FXR inverter consumes 34 watts of idle power while it remains on, even if it is not actively inverting or charging. The Power Save function allows the option to put part of a parallel system into a quiescent state known as Silent mode. This mode minimizes the idle consumption. The inverters will come on again when the loads require power. (The term “Silent” is also used in an unrelated context during battery charging. See page 32.
Operation Master Power Save Level appears on an inverter which is set as master (the default setting). The range of rank numbers is 0 to 10. The default value is 0. The master is normally left at this value. The Master Power Save Level function is used for the master inverter on Port 1. It is also used for any subphase masters in a three-phase system. The ranking of a subphase master is treated the same as the master. If the master is set at 0, subphase masters should also be 0.
Operation Master Port 1 Master Power Save = 0 Slave 1 Port 2 Slave Power Save = 1 <6 Aac On Off 6 Aac On 12 Aac On 18 Aac 8 Aac Slave 2 Port 3 Slave Power Save = 2 Slave 3 Port 4 Slave Power Save = 3 Off Off On Off Off On On Off On On On On On On On Off Figure 14 Power Save Priority (Parallel) The fourth line shows that loads of 18 Aac or more (approximately 4 to 4.5 kW) are present on the system. This load causes all four inverters to be activated.
Operation Auxiliary Terminals The FXR inverter has a 12V AUX output which can respond to different criteria and control many operations. These terminals provide a 12 Vdc output that can deliver up to 0.7 Adc. The AUX output has three states: continuous Off, continuous On, and Auto, which allows that output to be activated using the automatic auxiliary functions. (All functions are defaulted to Auto.) These items are based in the inverter and accessed using the system display.
Operation Settable Gen Alert parameters include: Low and high DC voltage On and off delay Gen Alert control logic is located in the inverter. It has the advantage of functioning when the system display is removed. However, it may not completely charge the batteries and does not have all the advantages of the Advanced Generator Start (AGS) function that is found in the system display. For many users, the AGS function may prove more useful than Gen Alert.
Operation when energized. Diversion is usually used to regulate battery charging. The AC device is usually wired to the output or load panel and must be left on. It must be sized to dissipate all energy from the renewable source if necessary. Diversion will turn off following a delay when a low DC voltage setting is reached. The AUX output will automatically turn on to run the loads if the inverter accepts an AC source.
Operation System Display-Based Functions A system display such as the OutBack MATE3 can provide functions not available in the inverter. These functions are summarized here to provide a better idea of overall system capabilities. The system display must be present for these functions to operate. If a function is set up (or already in operation) but the system display is removed, the function will not operate.
Operation Grid Use Time The inverter system is capable of connecting to, or disconnecting from, the utility grid based on time of day. It can also be programmed to connect at different times on weekdays and on weekends. Load Grid Transfer The inverter system is capable of connecting to, or disconnecting from, the utility grid based on load size. This avoids undesirable battery discharge from excessive loads.
Operation NOTES: 50 900-0169-01-00 Rev B
Metering MATE3 Screens The MATE3 system display can monitor the FXR inverter and other networked OutBack devices. From the Home screen, the “soft” key accesses the screens for monitoring the inverter. Inverter Soft Key Figure 16 Home Screen Inverter Screen The Inverter soft key opens a screen showing the inverter operating mode, battery voltage, and status of several AC operations. The soft key will select other networked OutBack inverters, if present.
Metering Load displays kilowatts and AC amperage consumed by devices on the inverter’s output. It can be the same as Invert. Buy displays the kilowatts and AC amperage brought into the inverter’s input for both charging and loads. This is usually a total of Charge and Load. Battery displays the uncompensated battery voltage. AC Out displays the AC voltage measured at the inverter’s output. If an AC source is present, this reading is usually the same as AC In.
Troubleshooting Basic Troubleshooting Table 7 is organized in order of common symptoms, with a series of possible causes. Each cause also shows possible troubleshooting remedies, including system display checks where appropriate. These instructions are for use by qualified personnel who meet all local and governmental code requirements for licensing and training for the installation of electrical power systems with AC and DC voltage up to 600 volts.
Troubleshooting Table 7 Symptom One or more units have no output but others do (in multiinverter system). Will not connect to the AC source. 6 Troubleshooting Possible Cause Possible Remedy Unit is slave and is in Silent mode. MATE3 system display only: Check Power Save levels in the Inverter Stacking menu and test with loads. Determine if the inverter comes on at the appropriate levels. (If this setting was intentional, then no action is required.) No AC input.
Troubleshooting Table 7 Symptom Troubleshooting Possible Cause Possible Remedy Charge complete or nearly complete. Check the DC voltage and charging stage using the MATE3, if present. Confirm with DC voltmeter. MATE3’s DC meter reads significantly higher than actual battery voltage. Check the DC voltage on the inverter’s DC terminals. If different from the MATE3 reading, the inverter could be damaged. Otherwise, check the DC voltage on batteries with a voltmeter.
Troubleshooting Table 7 Symptom Inverter does not perform the Offset function when expected. Unusual voltage on hot or neutral output line. Unusual and different voltages on AC hot input lines. Loads drop out or crash during transfer. Unit reads AC input, even though no source is present. 7 Troubleshooting Possible Cause Possible Remedy Incorrect input mode. Offset does not function in Generator, UPS, and Backup modes. Specific mode only offsets under particular conditions.
Troubleshooting Table 7 Symptom Inverter clicks repeatedly. AC output voltage rises or drops to unusual levels with every click. Inverter hums loudly. System display may show messages for high battery voltage, low battery voltage, or backfeed error. Generator, external fan, etc. fails to start when signal is provided by AUX output. Advanced Generator Start (AGS) fails to activate when conditions are met (or starts when conditions are not met).
Troubleshooting Error Messages An error is caused by a critical fault. In most cases when this occurs, the ERROR indicator will illuminate and the inverter will shut down. (See page 11 for the FXR inverter’s LED indicators.) The MATE3 system display will show an event and a specific error message. The Inverter Errors screen is viewed using the MATE3 Home screen’s soft keys. (See the MATE3 manual for more instructions.) One or more messages will display Y (yes).
Troubleshooting Warning Messages A warning message is caused by a non-critical fault. When this occurs, the ERROR indicator will flash, although the inverter will not shut down. (See page 11 for the FXR inverter’s LED indicators.) The MATE3 system display will show an event and a specific warning message. The Inverter Warnings screen is viewed using the MATE3 Home screen’s soft keys. (See the MATE3 manual for more instructions.) One or more messages will display Y (yes).
Troubleshooting Table 9 Warning Troubleshooting Message Definition Possible Remedy Fan Failure The inverter’s internal cooling fan is not operating properly. Lack of cooling may result in derated inverter output wattage. Turn the battery disconnect off, and then on, to determine if the fan self-tests. After this test, contact OutBack Technical Support for the next step. (The next step will depend on the results of the test.
Troubleshooting Disconnect Messages Disconnect messages explain why the inverter has disconnected from an AC source after previously being connected. The unit returns to inverting mode if turned on. The Last AC Disconnect screen is viewed using the AC INPUT hot key on the MATE3. One or more messages will display Y (yes). If a message says N (no), it is not the cause of the disconnection. The MATE3 system display may generate a concurrent event and warning message following the disconnection. (See page 59.
Troubleshooting Sell Status Sell Status messages describe conditions relating to the inverter’s grid-interactive mode. This screen is viewed using the MATE3 Home screen’s soft keys. (See the MATE3 manual for more instructions.) One or more messages will display Y (yes). If a message says N (no), it is not the cause of the disconnection. If the inverter has stopped selling or charging unexpectedly, this screen may identify the reason.
Specifications Electrical Specifications NOTE: Items qualified with “default” can be manually changed using the system display.
Specifications Table 15 Electrical Specifications for 24-Volt FXR Models Specification FXR2024E VFXR3024E Continuous Output Power at 25°C 2000 VA 3000 VA Continuous AC Output Current at 25°C 8.
Specifications Table 16 Electrical Specifications for 48-Volt FXR Models Specification FXR2348E VFXR3048E Continuous Output Power at 25°C 2300 VA 3600 VA Continuous AC Output Current at 25°C 10 Aac 13 Aac AC Output Voltage (default) 230 Vac 230 Vac AC Output Frequency (default) 50 Hz 50 Hz AC Output Type Single-phase Single-phase AC Waveform True Sinewave True Sinewave Typical Efficiency 93% 93% Total Harmonic Distortion (maximum) < 5% < 5% Harmonic Distortion (maximum single volt
Specifications Mechanical Specifications Table 17 Mechanical Specifications for FXR Models Specification FXR2012E, FXR2024E, and FXR2348E VFXR2612E, VFXR3024E, and VFXR3048E Inverter Dimensions (H x W x D) 13 x 8.25 x 16.25" (33 x 21 x 41 cm) 12 x 8.25 x 16.25" (30 x 21 x 41 cm) Shipping Dimensions (H x W x L) 21.75 x 13 x 22” (55 x 33 x 56 cm) 21.
Specifications Temperature Derating All FXR inverters can deliver their full rated wattage at temperatures up to 25°C (77°F). The FXR maximum wattage is rated less in higher temperatures. Above 25°C, each inverter model is derated by a factor of 1% of that model’s rated wattage for every increase of 1°C. This derating applies to all power conversion functions (inverting, charging, selling, offsetting, etc.
Specifications Compliance EN 61000-3-3 — EMC Standard: Limitation of Voltage Changes, Voltage Fluctuations, and Flicker in Public LowVoltage Supply Systems EN 61000-6-1 — EMC Standard: Immunity for Residential, Commercial, and Light-Industrial Environments EN 61000-6-3 — EMC Standard: Emissions for Residential, Commercial, and Light-Industrial Environments RoHS: per directive 2011/65/EU These inverter/charger models have grid-interactive functions.
Specifications Summary of Operating Limits Severe conditions cause the inverter to limit its output or shut down for protection. The most common conditions are high voltage, low voltage, and temperature. The limits for these conditions are summarized in Table 19. See pages 58 and 60 for more information on these conditions and the warning or error messages which accompany them.
Specifications To determine the chargers and settings using Table 20: 1. 2. 3. 4. 5. Obtain the battery bank’s maximum charge current (in Adc) from the battery manufacturer. Locate the closest number to this amount (rounded down) on Table 20. Read across to the entry for the appropriate inverter model. Adjust the master inverter’s Charger AC Limit setting to the designated amount (in Aac). Turn off the chargers for all inverters that exceed the number shown as On.
Specifications Calculating Limits If other numbers are needed than those featured in Table 20, the results can be calculated. Do not use the calculations on page 29, due to charger efficiencies and other factors. To calculate the chargers and settings: 1. Look up the values for A, B, and C. A = the battery bank’s maximum charge current (in Adc) from the battery manufacturer. B = the maximum DC output of the appropriate inverter model. This is taken from Table 21.
Specifications Default Settings and Ranges NOTES: Certain items are retained at the present setting even when the inverter is reset to factory defaults. These items are noted with the letter “X” in the Item column. Certain items, particularly those in the Auxiliary menus, share common set points. If one of these items is changed in a mode menu, all menus with this set point will show the same change.
Specifications Table 22 Field Battery Equalize FXR Settings for 12-Volt Models Item Default 14.6 Vdc 11.0 Vdc 17.0 Vdc (Equalize) Time 1.0 hours 0.0 hours 24.
Specifications Table 23 Field FXR Settings for 24-Volt Models Item Default Minimum Maximum INVERTER Hot Key Inverter Mode Off On, Off, or Search CHARGER Hot Key Charger Control On On or Off AC Input Hot Key AC Input Mode Use Drop or Use 30 0 200 Pulse Length 8 AC Cycles 4 AC Cycles 20 AC Cycles Pulse Spacing 60 AC Cycles 4 AC Cycles 120 AC Cycles Sensitivity (see page 24 for increments) Search Input Type Grid Charger Control AC Input and Current Limit 30 Aac 2.
Specifications Table 23 Field FXR Settings for 24-Volt Models Item Default Aux Control Auto Aux Mode Auxiliary Output Inverter Stacking Power Save Ranking Stack Mode Maximum 28.0 Vdc 0.5 minutes 22.0 Vdc 0.5 minutes 22.0 Vdc 0.5 minutes 28.0 Vdc 0.5 minutes 28.0 Vdc 0.5 minutes 28.0 Vdc 0.5 minutes 22.0 Vdc 0.5 minutes 28.0 Vdc 0.5 minutes 22.0 Vdc 0.5 minutes Off, Auto or On Load Shed, Gen Alert, Fault, Vent Fan, Cool Fan, DC Divert, GT Limits, Source Status, AC Divert 20.0 Vdc 36.0 Vdc 0.
Specifications Table 24 Field FXR Settings for 48-Volt Models Item Default Minimum Maximum INVERTER Hot Key Inverter Mode Off On, Off, or Search CHARGER Hot Key Charger Control On On or Off AC Input Hot Key AC Input Mode Use Drop or Use Sensitivity (see page 24 for increments) 30 0 Pulse Length 8 AC Cycles 4 AC Cycles 20 AC Cycles Pulse Spacing 60 AC Cycles 4 AC Cycles 120 AC Cycles Search Input Type Grid Charger Control AC Input and Current Limit 30 Aac 0 Aac 7 Aac VFXR
Specifications Table 24 Field FXR Settings for 48-Volt Models Item Default Aux Control Auto Aux Mode Auxiliary Output Inverter Stacking Power Save Ranking Grid-Tie Sell Stack Mode Mode = Master: Master Power Save Level Slave Power Save Level Mode = Slave: Offset Enable Calibrate Sell Voltage AC Input Voltage AC Output Voltage Battery Voltage 56.0 Vdc 0.5 minutes 44.0 Vdc 0.5 minutes 44.0 Vdc 0.5 minutes 56.0 Vdc 0.5 minutes 56.0 Vdc 0.5 minutes 56.0 Vdc 0.5 minutes 44.0 Vdc 0.5 minutes 56.
Specifications Definitions The following is a list of initials, terms, and definitions used in conjunction with this product. Table 25 Terms and Definitions Term Definition 12V AUX Auxiliary connection that supplies 12 Vdc to control external devices AC Alternating Current; refers to voltage produced by the inverter, utility grid, or generator AGS Advanced Generator Start CSA Canadian Standards Association; establishes Canadian national standards and the Canadian Electrical Code, including C22.
Index 1 12V AUX ................................................................................45 A Absorption Stage...............................................................31 AC Input .................................................................... 9, 13, 25 AC Source Acceptance.....................................................26 AC Test Points .....................................................................53 Advanced Battery Charging...........................................31 AGS ..
Index Grid Tied ................................................... 15, 26, 60, 62, 68 Grid Use Time............................................................... 18, 49 Grid-Interactive ..................................................................15 GridZero................................................................................19 GT Limits ...............................................................................46 GT Warnings ............................................................
Index Warning Messages ......................................................59 V U Vent Fan Control ................................................................46 Updating Firmware .................................................... 49, 71 UPS .........................................................................................17 W Warning Symbol .................................................................. 7 Warnings ......................................................................
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